the interactive effects of fire and herbivory on ...... · vi paper i: foster, c.n., barton, p.s....
TRANSCRIPT
The interactive effects of fire and
herbivory on understorey vegetation and
its dependent fauna
Claire Foster
A thesis submitted for the degree of Doctor of Philosophy of
The Australian National University
August 2015
© Copyright by Claire Foster 2015
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Declaration
This thesis is my own work, except where otherwise acknowledged
(see Preface and Acknowledgements)
Claire Foster
August 2015
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Preface
This thesis is structured as a series of connected papers that have been published in, or
were submitted to, peer reviewed journals at the time of thesis submission. These papers are
listed at the end of this preface and are referred to in the text by their roman numerals. All
papers were intended as stand-alone pieces of work. For this reason, there is some unavoidable
repetition between chapters, for example in the background material, and the description of the
study area and experimental design. Due to journal copy-editing there may be minor differences
between the papers presented here and their published versions.
The formatting and content of this thesis complies with The Australian National
University’s College of Medicine, Biology and Environment guidelines for ‘Thesis by
Compilation’. In line with these guidelines, an Extended Context Statement has been provided
at the beginning of the thesis. The Extended Context Statement is not intended to be a complete
literature review, but rather a framework for understanding the relationships between all aspects
of the research. Paper I provides a detailed review of literature concerning the effects of large
herbivores on other animals, and Papers II, III, IV and V each present a review of the literature
relevant to the focus of the paper.
I performed the majority of the work for the papers that form this thesis. This included
developing research questions and experimental designs, data collection and analysis, and
writing manuscripts. My supervisors (Philip Barton, Chloe Sato and David Lindenmayer) and
collaborators provided advice on conceptualisation, experimental design, data analysis, and
manuscript revisions. The addition of different co-authors to each paper reflects contributions
from collaborators, which are detailed below. The author contribution statements below have
been agreed to in writing by all authors. Other assistance is acknowledged in the
acknowledgments section at the end of each paper.
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Paper I: Foster, C.N., Barton, P.S. and D.B. Lindenmayer (2014) The effects of large native
herbivores on other animals. Journal of Applied Ecology. 51, 929-938.
Conceptualisation & design: CNF, DBL, PSB; Data extraction and analysis: CNF; Manuscript
drafting: CNF; Manuscript revision: CNF, PSB, DBL.
Paper II: Foster, C.N., Barton, P.S., Sato, C.F., Wood, J.T., Macgregor, C.I., and D.B.
Lindenmayer (2016) Herbivory and fire interact to affect forest understory habitat, but
not its use by small vertebrates. Animal Conservation. 19, 15-25.
Conceptualisation & design: CNF, DBL, CIM, PSB, JTW; Data collection: CNF, CIM; Data
analysis: CNF, JTW, CFS; Manuscript drafting: CNF; Manuscript revision: CNF, PSB,
DBL, CFS, CIM, and JTW.
Paper III: Foster, C.N, Barton, P.S, Sato, C.F, Macgregor, C.I, and D.B. Lindenmayer (2015)
Synergistic interactions between fire and browsing drive plant diversity in a forest
understory. Journal of Vegetation Science. 26, 1112-1123.
Conceptualisation & design: CNF, DBL, CIM, PSB; Data collection: CNF, CIM; Data analysis:
CNF, CFS; Manuscript drafting: CNF; Manuscript revision: CNF, PSB, DBL, CFS, CIM.
Paper IV: Foster, C.N, Barton, P.S., Wood, J.T. and D.B. Lindenmayer (2015) Interactive
effects of fire and large herbivores on web-building spiders. Oecologia. 179, 237-248.
Conceptualisation & design: CNF, DBL, PSB, JTW; Data collection: CNF, Data analysis: CNF,
PSB, JTW; Manuscript drafting CNF, Manuscript revision: CNF, PSB, DBL, JTW.
Paper V: Foster, C.N, Sato, C.F., Lindenmayer, D.B., and P.S. Barton (Accepted) Integrating
theory into disturbance interaction experiments to better inform ecosystem management.
Global Change Biology, doi:10.1111/gcb.13155.
Conceptualisation & design: CNF, PSB, CFS, DBL; Data extraction: CNF; Manuscript drafting:
CNF, Manuscript revision: CNF, PSB, CFS, DBL.
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Acknowledgements
Thank you to my supervisors David Lindenmayer, Chloe Sato, and Philip Barton for their
support and guidance during my candidature. David’s confidence in me was pivotal for
allowing me to get my experiments up and running within a few months of commencing. The
freedom David allowed me in my topics and approach enabled me to complete a PhD that I
have found both interesting and thoroughly enjoyable. Chloe’s advice on analyses, discussions
on applied management, and general assistance with the whole PhD process has been
invaluable. Philip’s advice, constructive feedback and patience with trawling through every first
draft have been fantastic. Our regular meetings have helped me stay focussed, and turn my
disjointed rambles into something worth writing about. My PhD would have been a very
different experience without your advice and encouragement. I would also like to thank Chris
MacGregor, Peter Lane and Jeff Wood for their assistance and advice at various times during
my candidature. In particular, Chris MacGregor’s cheerful company, willing assistance and
ongoing advice made my fieldwork, and especially the dreaded fence construction, so much
more enjoyable. Chris was always happy to keep an eye on my experiments, chainsaw a tree
from exclosure fences or help identify a difficult specimen. John Evans also provided invaluable
assistance with sorting and identifying invertebrate collections. All of my supervisors and
collaborators have been outstanding in providing constructive and timely feedback on my
written work, for which I am very grateful.
I would like to thank the Department of Environment and the landowners and co-
managers of Booderee National Park, the Wreck Bay Aboriginal Community, for allowing me
to conduct this study in Booderee National Park and providing in-kind support. I would
particularly like to thank Nick Dexter and Martin Fortescue for their ongoing support, advice
and interest in this project, and making the burning of my experimental plots a reality. Thank
you also to all the staff of Booderee National Park who were involved in conducting the
prescribed burns, especially Stuart James, who gave me training so I could participate myself.
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Much of my field work would not have been possible without the assistance of a band
of willing volunteers. Thank you to Angela, Stuart, Darren, Dylan, Helen, Emily, Xiying, Laura,
Kevin, Daniela, Anna and Luke for cheerfully putting up with the early starts, leeches and ticks
and wrestling with all the gates.
Thank you to the Long Term Ecological Research Network, the Australian Academy of
Science (Margaret Middleton Fund) and the Normal Wettenhall Foundation for granting
financial support to this project. Thank you also to the ANU College of Medicine and Biology
for providing me with a supplementary scholarship.
My fellow students and the staff at the Fenner School created an environment of
encouragement, active discussion and constructive feedback that made my candidature so much
more enjoyable. In particular, thank you to Ben Scheele for great discussions, good company,
and reading drafts, and Karen Ikin for your friendship, encouragement and the morning coffee
run. I would also like to thank Nélida Villaseñor, Darren Le Roux, Will Batson, Laurence
Berry, Nick Engerer, John Evans, Geoff Kay, Miles Kieghley, Megan Evans, Stephanie
Pulsford, Laura Rayner, Chloe Sato, Philip Barton, Ingrid Stirnemann, Martin Westgate, Alessio
Mortelliti, Jenny Pierson and Crid Fraser for numerous instances of assistance and
encouragement, as well as many great lunchtime discussions. Thank you also to Claire
Shepherd and Tabitha Boyer for your assistance with navigating the university administration
jungle.
Thank you to my family for their love and support throughout this experience. In
particular to my partner Stuart, who has provided love, good humour and positivity over the last
3.5 years. Thank you for continuing to visit during long periods of field work, even when I
made you get up at five, or count poo for your trouble, and for putting things in perspective
when I needed it. Finally, thank you to my Mum, for making the effort to understand what I do,
correcting my grammar, and encouraging my curiosity from the very beginning.
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Abstract
Interactions between multiple disturbances have been shown to have unexpected, and often
undesirable effects on ecosystems and biodiversity. Improving our ability to predict and manage
the outcomes of multiple disturbances is therefore an important research priority. In this thesis, I
focussed on the interaction between fire and grazing (or browsing) by large herbivores.
Evidence of the individual effects of fire and large herbivores is substantial, but there
has been little quantitative synthesis of the effects of native herbivores on biodiversity. Using a
systematic review and meta-analysis, I found that high densities of large herbivores usually
have negative effects on other animals. However, I found that interactions between large
herbivores and episodic disturbances, such as fire, remain poorly understood.
I therefore designed a field experiment to test the interactive effects of prescribed fire
and large herbivores on forest flora and fauna. I used full and partial exclosure fences to create a
gradient of herbivore pressure across both burnt and unburnt sites, and measured the responses
of vegetation, spiders and small vertebrates.
I found that fire and herbivory interacted strongly to affect vegetation, with herbivory
limiting the recovery of vegetation from fire. In contrast to the vegetation response, small
vertebrates responded to the individual, but not interactive effects of disturbance. I then
focussed on the mechanisms driving interactive effects on vegetation, and found that the
interaction occurred through both numerically mediated (concentration of herbivores in burnt
sites) and functionally moderated (stronger effect of herbivores post-fire) pathways.
The differing responses of plants and animals to fire and herbivory was at odds with
existing literature, where the effects of large herbivores on fauna are usually attributed to
vegetation changes. I therefore tested to what extent vegetation mediated the effects of fire and
herbivory on web-building spiders – a group sensitive to changes in habitat structure.
Vegetation structure partially mediated the negative effect of fire on spider density, while
negative effects of large herbivores on spiders were mostly independent of vegetation. Different
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types of web builders differed in their responses, resulting in important changes to the spider
community following disturbance.
The results of my experiments highlight the importance of focussing on mechanistic
pathways for understanding and managing disturbance interactions. However, in reviewing
recently published fire-grazing studies, I found that most reported only net effects of
interactions. I demonstrate how by failing to identify mechanistic pathways, or non-linear
effects, such studies are limited in their management applications. I describe adjustments to
disturbance interaction studies that would improve their ability to inform effective management
and advance theory.
Collectively, my research shows that fire and large herbivores can have strong
interactive effects on forested ecosystems and their associated biota, and highlights the
importance of considering large herbivores in forest fire planning. It also demonstrates the value
of a mechanistic understanding of interactions for the management of disturbance regimes. Such
considerations are of broad relevance to the management of multiple disturbances, particularly
in the context of increasing global change.
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Table of Contents
Declaration ................................................................................................................................... iii
Preface .......................................................................................................................................... v
Acknowledgements ..................................................................................................................... vii
Abstract ........................................................................................................................................ ix
Context Statement ....................................................................................................................... 1
Introduction ............................................................................................................................... 1
Overview of Aims ..................................................................................................................... 4
Study Area ................................................................................................................................ 7
Summary of Outcomes ............................................................................................................. 9
Synthesis and Management Implications ................................................................................ 11
Conclusion .............................................................................................................................. 17
References ............................................................................................................................... 18
Paper I: Effects of large native herbivores on other animals ................................................ 25
Summary ................................................................................................................................. 26
Keywords ................................................................................................................................ 27
Introduction ............................................................................................................................. 27
Materials and Methods ............................................................................................................ 29
Results ..................................................................................................................................... 33
Discussion ............................................................................................................................... 39
Acknowledgements ................................................................................................................. 46
References ............................................................................................................................... 46
Supporting Information ........................................................................................................... 51
Paper II: Herbivory and fire interact to affect forest understory habitat, but not its use by
small vertebrates ....................................................................................................................... 81
Abstract ................................................................................................................................... 82
Keywords ................................................................................................................................ 82
Introduction ............................................................................................................................. 82
Materials and methods ............................................................................................................ 85
Results ..................................................................................................................................... 88
Discussion ............................................................................................................................... 95
Acknowledgments ................................................................................................................. 100
References ............................................................................................................................. 100
Appendices ............................................................................................................................ 105
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Paper III: Synergistic interactions between fire and browsing drive plant diversity in a
forest understory ..................................................................................................................... 115
Abstract ................................................................................................................................. 116
Keywords ............................................................................................................................... 116
Introduction ........................................................................................................................... 117
Methods ................................................................................................................................. 119
Results ................................................................................................................................... 124
Discussion.............................................................................................................................. 129
Acknowledgements ............................................................................................................... 134
Literature Cited ...................................................................................................................... 134
Supporting Information ......................................................................................................... 138
Paper IV: Interactive effects of fire and large herbivores on web-building spiders ......... 145
Abstract ................................................................................................................................. 146
Keywords ............................................................................................................................... 146
Introduction ........................................................................................................................... 147
Materials and methods ........................................................................................................... 149
Results ................................................................................................................................... 156
Discussion.............................................................................................................................. 161
Acknowledgements ............................................................................................................... 165
References ............................................................................................................................. 165
Supplementary Material ........................................................................................................ 171
Paper V: Integrating theory into disturbance interaction experiments to better inform
ecosystem management ........................................................................................................... 183
Abstract ................................................................................................................................. 184
Keywords ............................................................................................................................... 184
Introduction ........................................................................................................................... 185
Recent advances in disturbance interaction theory ................................................................ 186
Where are the gaps between theory and experimental studies?............................................. 190
Bridging the gap to improve management applications ........................................................ 199
Conclusions ........................................................................................................................... 203
Acknowledgements ............................................................................................................... 204
Literature Cited ...................................................................................................................... 204
Supporting Information ......................................................................................................... 209
1
Context Statement
Introduction
Ecological disturbance is a key process driving patterns of temporal and spatial heterogeneity in
ecosystems worldwide. Disturbance regimes are strongly linked with drivers of global change,
and hence many disturbance regimes have been dramatically altered in recent decades, and
continue to undergo rapid change (Turner 2010). While there has been increasing interest in
interactions between global change drivers (e.g. Tylianakis et al. 2008, Oliver and Morecroft
2014, Mantyka-Pringle et al. 2015), and also global change and disturbance (e.g. Didham et al.
2007, Gibb et al. 2015), the interactions between disturbance processes themselves remain
poorly understood (Turner 2010, Buma 2015). This knowledge gap is of critical importance for
ecological management as disturbances are becoming increasingly managed in both natural and
modified ecosystems, rarely occur in isolation from other disturbance processes, and are
predicted to continue to change in frequency and intensity as a result of global change (Turner
2010, Buma 2015). Improving our understanding of both the individual and combined effects of
disturbance is therefore imperative for the successful conservation of ecosystems and
biodiversity.
Disturbance can be defined as any “relatively discrete event that disrupts the structure
of an ecosystem, community or population, and changes resource availability or the physical
environment” (White and Pickett 1985). A disturbance regime refers to the spatio-temporal
distribution of disturbance, including aspects such as size, intensity, severity and frequency
(Turner et al. 1998). Two of the most widespread and commonly studied disturbance processes
in terrestrial ecosystems are fire and herbivory (grazing and browsing by large herbivores).
Fire occurs over a wide range of temperate and tropical landscapes, and fire regimes
drive the distribution of vegetation types and dominant species in many ecosystems (Bond and
Keeley 2005). Fire regimes have undergone substantial changes in recent decades, from
widespread fire suppression in some ecosystems, to an increase in fire intensity, severity and
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frequency in others (Bowman et al. 2009, Syphard et al. 2009). Attempts to re-introduce
historical fire regimes to contemporary ecosystems can be contentious, particularly in human-
dominated landscapes, where wildfire is often perceived as a “devastating” destructive event
(Stephens and Ruth 2005, Stephens et al. 2013). Managing fire for the (often competing)
priorities of both life and property protection and biodiversity conservation is therefore a key
challenge for managers of many ecosystems (Driscoll et al. 2010, Gibbons et al. 2012).
Browsing and grazing by large mammalian herbivores is also a widespread disturbance
process that occurs in most of the world’s ecosystems (Danell et al. 2006). Rangelands, due to
their suitability for livestock grazing, have been particularly affected by changes to grazing
regimes (Gordon et al. 2004). However, wild herbivore assemblages have also undergone
substantial changes in recent decades, with dramatic declines from over-hunting in some areas,
and increases to historically high levels in others, due to relaxation of hunting pressure and loss
of native predators (Gordon et al. 2004). Changes in herbivore densities can have dramatic
effects on ecosystems, from altering dominance and diversity patterns in plant and animal
communities (Hester et al. 2006, Suominen and Danell 2006), to changing landscape-scale
processes such as nutrient cycling, erosion and hydrological cycles (Asner et al. 2004,
Tanentzap and Coomes 2012). Due to their strong effects on ecosystems, and widespread
changes in abundance, large herbivore populations are actively managed for conservation
outcomes throughout much of their range (Danell et al. 2006).
As common and widespread disturbances, fire and herbivory co-occur in a wide range
of habitats. Understanding how these processes interact in the different ecosystems in which
they co-occur is therefore essential if the management of either is to be effective and efficient
(Wisdom et al. 2006, Fuhlendorf et al. 2009). Existing studies of fire-grazing interactions
generally focus on one of two interaction types. The first interaction (referred to in this thesis as
an interaction chain) involves feedbacks between fire and grazing through space and time: fire
leads to a concentration of grazing pressure in burnt areas, which then reduces the chance of
future fire in those areas, but increases the risk in unburnt areas where reduced grazing pressure
allows greater accumulation of biomass (Fuhlendorf et al. 2009, Kimuyu et al. 2014). Some
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researchers argue that this coupling of fire and grazing in space and time should be thought of as
a single disturbance process, termed “pyric herbivory” (Fuhlendorf et al. 2009). The second type
of interaction (referred to in this thesis as an interaction modification) is generally studied at the
site-level and occurs when the effect of grazing on plants or animals is modified by fire (or vice
versa) (Eby et al. 2014, Koerner and Collins 2014). These interactions often occur via changes
to the traits or behaviours of plants or animals. For example, fire can remove the chemical and
physical defences of plants, making generally unpalatable plants palatable (Augustine and
McNaughton 1998, Augustine and Derner 2015). After fire, the selectivity of grazers, and
therefore their effects on patterns of plant dominance and diversity can be significantly altered
(e.g. Augustine and Derner 2015). While often studied separately, both of these interaction
types are likely to be acting when fire and herbivory co-occur in natural systems.
The majority of fire-grazing interaction studies to date have been of domestic
herbivores in rangeland ecosystems. This bias is understandable due to the large global extent of
livestock grazing in rangelands, as well as the comparative ease of manipulating domestic
livestock densities compared with manipulating populations of wild herbivores. However, fire
and large herbivores also co-occur, and are actively managed, in forested systems, but here their
interactions remain poorly understood (Wisdom et al. 2006, Royo et al. 2010a). Browsing can
affect the successional trajectory of forests, resulting in shifts in the abundance and composition
of both canopy, and understory species (Olofsson et al. 2005, Royo and Carson 2006, Mathisen
et al. 2010, Tanentzap et al. 2012, Hidding et al. 2013, Holm et al. 2013). As fire re-starts
succession, and can alter vegetation species composition, plant traits, and herbivore behaviour,
there is strong potential for fire to interact with browsing, with possible long-term consequences
for the state of forest ecosystems (Royo et al. 2010a, Pekin et al. 2014). Indeed, the few existing
studies to date indicate that fire-browsing interactions are prevalent in forests (Royo et al.
2010a, Kerns et al. 2011). The effect of fire-browsing interactions on biodiversity therefore
warrants urgent attention from both managers and researchers of forested ecosystems.
In this thesis I investigated how fire and browsing interact to affect understory flora and
fauna in a eucalypt forest ecosystem of south-eastern Australia. I focussed on this system as the
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role of native herbivores in Australian ecosystems remains poorly understood, but existing
studies show that the effects of macropod herbivores on both plants and animals can be
substantial (Bulinski and McArthur 1999, Meers and Adams 2003, Tuft et al. 2012, Howland et
al. 2014). Further, although both fire and macropods are managed in many Australian
ecosystems (Clarke 2008, Gowans et al. 2010, Lunney 2010, Wiggins and Bowman 2011,
Enright and Fontaine 2014), they are generally considered as separate issues in contemporary
management decisions (Meers and Adams 2003). Fire is usually managed with the aim of
reducing the risk of large, high intensity wildfires to prevent life and property loss, although
some burning is also done for ecological purposes (Morrison et al. 1996, Driscoll et al. 2010).
Macropod populations are also managed in many Australian ecosystems, either directly through
culling (or other control) of overabundant populations (Coulson et al. 2008, Gowans et al. 2010,
Wiggins and Bowman 2011, Howland et al. 2014), or indirectly via ongoing control of both
native (dingo, Canis familliaris) and introduced (European red foxes, Vulpes vulpes) predators
(Banks et al. 2000, Coates 2008, Nimmo et al. 2015). The few existing studies of the effects of
fire and macropod herbivores on biodiversity indicate that interactive effects are likely to be
prevalent (Catling et al. 2001, Meers and Adams 2003, Tuft et al. 2012, Dexter et al. 2013,
Pedersen et al. 2014). The forests of south-eastern Australia therefore provide an opportunity to
study general questions about the interactive effects of fire and browsing on patterns of plant
and animal diversity, and also to generate insights into how to account for fire-browsing
interactions in the management of these forests.
Overview of Aims
This thesis includes three related components (Fig. 1), each addressing different questions, but
all of which contribute to the central aim of improving understanding and management of fire-
herbivore interactions. These components are: a global review of the effects of large herbivores
on other animals (Paper I); a series of field studies to test the interactive effects of fire and
herbivory on forest flora and fauna (Papers II, III and IV); and a synthesis (Paper V) which
builds on my field studies and the broader literature to critically evaluate the way that empirical
studies inform the management of interacting disturbances.
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Numerous studies have highlighted the important role played by large herbivores in
shaping ecosystem structure and function (Danell et al. 2006). However, there has been limited
quantitative synthesis of the effect of native herbivores on biodiversity, despite wild herbivore
populations being managed for biodiversity conservation in many ecosystems worldwide. In
Paper I, I conducted a quantitative review of the effects of large native herbivores on other
animals. This paper aimed to (i) summarise generalities and trends in the effects of large
herbivores on different animal groups, (ii) identify gaps and limitations in the literature, and the
reasons for these gaps, and (iii) highlight priorities for future research.
Figure 1. Relationships between the key questions explored in this thesis.
Paper III: By which mechanisms do fire and large herbivores interact to affect forest plant diversity?
Paper II: How do fire-herbivore interactions affect forest vegetation and small vertebrates?
Paper IV: To what extent are effects on animals mediated by vegetation structure?
Field experiment: Fire-browsing interactions
Paper V:
Could a focus on interaction pathways improve the ability of fire-grazing studies to inform ecological management?
Paper I: How do large herbivores affect other animals?
Interactions with other processes poorly understood
Vegetation change cited as a key mechanism, but rarely quantitatively tested
Multi-taxa studies rare, but needed to identify key pathways
Different groups of biota have different responses to disturbance interactions
Fauna responses not predictable from vegetation responses
Herbivores, and the fire x herbivore interaction can have important effects on fauna that are not vegetation mediated
Mechanistic understanding of interaction types useful for targeted, efficient management, and identifying novel solutions
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Understanding of how the effects of large herbivores plants and animals are modified
by management practices and disturbance regimes remains limited, particularly for forested
ecosystems (Paper I, Wisdom et al. 2006). However, understanding these interactions is
essential for informing effective and efficient management of the effects of large herbivore on
biodiversity (Wisdom et al. 2006). I therefore conducted a field experiment to test whether large
herbivores and fire interact to affect the forest ecosystem. I used this experiment to: (i) test the
interactive effects of fire and large herbivores on forest understory plants and animals (Paper
II), (ii) identify the mechanisms by which fire and large herbivores interacted (Paper III), and
(iii) test the extent to which the effects of fire and large herbivores on other animals were
mediated by changes in vegetation (Paper IV). Collectively, these papers (II-IV) aimed to
develop an improved, mechanistic understanding of the interaction between fire and large
herbivores, and how this affects biodiversity in forested ecosystems.
Several recent studies have highlighted the value of understanding interaction pathways
for both predicting and managing the effects of co-occurring stressors or threats (Didham et al.
2007, Boyd and Brown 2015, Doherty et al. 2015). I also found that the multi-taxa, mechanistic
approach I took in Papers II, III and IV allowed me to critically evaluate different management
options. However, in exploring the fire-grazing literature, I encountered few examples of studies
which took a similar mechanistic approach. In Paper V, I examined whether a focus on
interaction pathways could improve the ability of fire-grazing studies to inform ecological
management. This final paper aimed to: (i) quantify the extent to which fire-grazing studies
do/do not take a mechanistic approach, (ii) investigate whether failing to take a mechanistic
approach limits the management relevance of studies, and (iii) identify adjustments to
disturbance interaction studies that could improve their ability to inform effective ecological
management. Overall, Paper V aimed to identify approaches to studying disturbance
interactions that provide valuable insights for management, and should therefore form the basis
of future studies investigate fire-grazing or fire-browsing interactions.
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Study Area
The empirical papers in this thesis (Papers II, III, and IV) are based on a field experiment that I
conducted in the Eucalypt forests of Booderee National Park (BNP). A description of the
experimental design can be found in Paper II (Paper II, Methods, and Appendix 1), and a map
of the study area is included in Paper III (Paper III, Fig. 1). Below, I provide a more detailed
description of the study area and its management, as well as some aspects of the methods, which
could not be included in individual papers due to journal space limitations.
Booderee National Park is located on a 6 500 ha peninsula of coastal South-Eastern
Australia (35°10′S, 150°40′E). The area has a temperate maritime climate with rainfall (average
1225 mm per annum) occurring throughout the year (Lindenmayer et al. 2008). The vegetation
of BNP comprises a spatially heterogeneous mosaic of vegetation types, the most widespread of
which are eucalypt forest, heathland, eucalyptus/banksia woodland, and shrubland (Taws 1998,
Lindenmayer et al. 2008). Fire occurs naturally in the ecosystems of south-eastern Australia,
and many native species are well adapted to intermittent fire, but not to frequent fire (fire return
intervals of < 8-10 years cannot be survived by many species, Morrison et al. 1996, Enright and
Fontaine 2014). Booderee National Park has a complex mosaic of fire histories, which includes
a large wildfire in 2003 which burnt over 50% of the park’s area (Lindenmayer et al. 2008).
While large wildfire events occur occasionally in BNP, because of the proximity of urban areas
and the presence of important populations of threatened species, small-scale prescribed fires are
used to reduce fuel loads and minimise the risk of large wildfires.
Management of BNP also includes an intensive pest control program, targeting the
European red fox, which has been in place since 1999 (Dexter et al. 2007). This program has
been successful in increasing the abundances of some native small mammals in the park (Dexter
et al. 2007). However, the loss of large predators (dingoes), and the absence of hunting, means
that without foxes, predation pressure on larger mammals is low (Lindenmayer et al. 2014).
This has resulted in increases in the abundance of native macropod herbivores, with counts
increasing ten-fold between 2003 and 2009 (Dexter et al. 2012, Lindenmayer et al. 2014). The
most abundant of these macropods is the swamp wallaby (Wallabia bicolor, a mixed feeder,
8
Davis et al. 2008, Di Stefano and Newell 2008), but eastern grey kangaroos (Macropus
giganteus, grazers, Davis et al. 2008), and red-necked wallabies (M. rufogriseus, grazers, Sprent
and McArthur 2002) also occur (Dexter et al. 2012, Dexter et al. 2013). Non-native European
rabbits (Oryctolagus cuniculus) also occur within BNP, however they are at low abundance and
do not appear to be increasing (Dexter et al. 2013, Stutz et al. 2015). The high abundances of
macropods currently present in BNP are compromising efforts to restore ex-plantation areas
(Stutz et al. 2015), and also may be limiting the recovery of some plant species following weed
control burns (Dexter et al. 2013). Park managers are therefore concerned about what broader
impacts these abundant macropods may be having on the flora and fauna of the park, and
whether these impacts interact with the prescribed burning program.
In the empirical chapters of this thesis (Papers II, III and IV) I report results from an
experiment where I used a factorial combination of prescribed fire (burnt, unburnt) and
herbivore exclosure (open, partial exclosure and full exclosure) treatments to test the responses
of a range of plant and animal groups to the interactive effects of fire and herbivory (see Paper
II, Methods, and Appendix 1). In this experiment, I monitored the use of sites by macropod
herbivores using scat counts, which allowed me to compare quantitatively the activity of
herbivores in each treatment, and between sites over time. In these counts, I did not attempt to
distinguish between the different macropod species. Most of the scats would have been from
swamp wallabies (browsers) as they are the most common macropod in Booderee National
Park. However, some scats would have been from grey kangaroos (grazers), which I
occasionally observed at the sites. For this reason, my conclusions and recommendations
throughout the thesis relate to macropod herbivores in general and further detail regarding the
identity of herbivore species using the sites would need to be obtained before implementing
management actions that are targeted toward individual species.
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Summary of Outcomes
Paper I: The effects of large native herbivores on other animals
In Paper I, I conducted a systematic review and meta-analysis of the effects of large native
herbivores on other animals. I found that, on average, large herbivores had negative effects on
the abundance and diversity of other animal groups. However, most studies compared areas of
very high herbivore density (overabundance) with areas of very low density (exclusions), which
likely biased studies towards detecting negative effects. Most of the effects of large herbivores
on other animals were attributed to indirect effects, predominantly through changes in the
quantity and/or structure of vegetation, although mediating mechanisms were rarely
quantitatively tested.
I identified key knowledge gaps on the effects of large herbivores on other animals
including: (i) the prevalence of nonlinear responses to herbivore pressure, (ii) how responses
differ between different herbivores, (iii) the spatial and (iv) the temporal variation of responses,
(v) how the effects of herbivores interact with disturbance and land management activities and
(vi) the mechanisms driving cascading effects through ecosystems (including synthesis of multi-
taxa responses). This paper was the first quantitative synthesis of the effects of large native
herbivores on other animals, and provides important context for the growing literature on the
ecological effects of large herbivores.
Paper II: Herbivory and fire interact to affect forest understory habitat, but not its
use by small vertebrates.
In Paper II, I tested whether herbivory and fire interacted to affect understory vegetation and
small vertebrates. Fire and herbivore exclusion interacted to affect understorey habitat, with
vegetation cover, particularly of palatable vegetation, showing poor post-fire recovery on
browsed sites. However, despite these interactive effects on vegetation, small vertebrates
responded to the individual, not interactive effects of fire and herbivory. Small vertebrate
species had contrasting responses to disturbance. For example, the small mammal, brown
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antechinus (Antechinus stuartii) responded positively to herbivore exclusion, while the delicate
skink (Lampropholis delicata) showed the opposite trend.
These results suggest that it may be necessary to manage the macropod herbivore
population after fire to prevent the decline of palatable plants, and maintain the dense habitat
required by some small mammals. However, as the invasive European rabbit was most active in
macropod-free sites after fire, any management must consider both types of herbivores. As
different combinations of management benefited different species, and fauna responses were not
predictable from vegetation responses, a mix of management practices may be needed to ensure
suitable habitat is maintained for all species.
Paper III: Synergistic interactions between fire and browsing drive plant diversity
in a forest understory.
In Paper III, I tested the interactive effects of browsing and fire on understorey plant diversity. I
found browsing increased plant community dominance, and reduced evenness and diversity in
burnt, but not in unburnt sites. This fire–browsing interaction was driven by both numerically
mediated and functionally moderated pathways: Fire both increased local browsing intensity,
and amplified the per-unit effect of herbivores on the plant community. The altered competitive
environment after fire, combined with heavy post-fire browsing created a depauperate
understorey, dominated by an unpalatable, fire-resistant fern species (austral bracken, Pteridium
esculentum). Due to the ability of bracken to suppress the establishment of other plants, this
fern-dominated state may be difficult to reverse. Integrated management of fire and large
herbivores may therefore be necessary to prevent the development of a depauperate understorey
in areas where herbivores are abundant.
Paper IV: Interactive effects of fire and large herbivores on web-building
spiders.
In Paper IV, I tested for the interactive effects of fire and large herbivores on web-building
spiders, and the mechanisms by which these effects occurred. I found that fire had a strong
negative effect on the density of web-building spiders, which was partly mediated by effects on
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vegetation structure, while the negative effect of large herbivores on web density was not
related to changes in vegetation. Fire amplified the effects of large herbivores on spiders, both
by modifying herbivore effects on vegetation, and by increasing herbivore activity. The relative
importance of the different pathways driving the effects of disturbance differed between types
of web-building spiders, and led to potentially important changes in the composition of this
predator guild. This study is one of the first to quantitatively assess the role of vegetation in
mediating the effects of fire-browsing interactions on fauna, and highlights the importance of
considering the driving mechanisms both when investigating and managing disturbance
interactions.
Paper V: Integrating theory into disturbance interaction experiments to better
inform ecosystem management.
Theoretical studies have shown that developing efficient, novel solutions to managing multiple
stressors relies on a detailed, mechanistic understanding of their interactions. In Paper V, I used
a mini-review of the fire-grazing literature to demonstrate that few empirical studies of
disturbance interactions were designed to identify the mechanistic pathways driving interactive
effects, or to detect non-linear effects (key relationships highlighted in theoretical models as
being important for management). I then showed how these widespread limitations among
disturbance interaction studies can lead to management recommendations that are ineffective,
inefficient, or likely to have negative outcomes. To address this issue, I presented a series of
adjustments to the design and interpretation of empirical disturbance interaction studies that
would require minimal additional research effort, but would improve the contribution of such
investigations to both the theoretical understanding, and applied management of multiple
stressors.
Synthesis and Management Implications
My research tested the interactive effects of fire and large herbivores on forest flora and fauna. I
found that for vegetation, the effects of fire and browsing were strongly interactive: in the
absence of fire, the effects of browsing on vegetation structure and floristics were minimal, but
12
following fire, heavy browsing led to a depauperate understorey dominated by ferns (Papers II,
III). Surprisingly, these interactive effects only partially mediated fauna responses, and both
vertebrate and invertebrate fauna were most strongly influenced by the individual, rather than
the interactive effects of disturbance (Papers II, IV). These results indicate that at their current
densities, the native macropod herbivores may have minimal effects on an undisturbed forest
ecosystem, and that management of the herbivore population should be targeted towards post-
fire, or early successional vegetation.
While I observed strong interactive effects of fire and herbivory on vegetation, the
result that browsing had minimal effects on vegetation in the absence of fire will require further
investigation. This is because the experiments in this thesis were of short duration (two years)
compared with the lifespans of many understory plants in these forests (time to maturity > 5-8
years for many shrub species, Morrison et al. 1996, Morrison 2002). Herbivory can affect plant
communities through mechanisms that can take a number of years to become evident, such as
limiting reproductive output and preventing establishment of seedlings (Hester et al. 2006,
Mathisen et al. 2010, Tanentzap et al. 2012), and forest vegetation can be slow to recover after
release from chronic herbivory (Royo et al. 2010b, Tanentzap et al. 2011). Therefore, a longer-
term study may be needed to detect the full range of herbivory effects. Further, while the plant
community exhibited only limited responses to large herbivores in the absence of fire, some
fauna (brown antechinus, skinks, spiders) responded to herbivore exclusion regardless of
burning treatment. This suggests that some important effects of large herbivores on other fauna
were not vegetation-mediated, or, that subtle (undetected) changes in the vegetation in herbivore
exclusion sites played an important role in determining fauna occupancy.
Fire and herbivory had strong interactive effects on vegetation. However, it was not
possible to conclude whether post-fire herbivory had led the system to an alternate state that
would persist long-term, or had simply slowed the recovery of vegetation (Paper III). If post-
fire vegetation recovery was simply slowed by browsing, then in the long-term, the individual
effects of herbivory may prove to be more important than interactive effects in defining the
community structure and floristics. It will therefore be important that monitoring of the
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experimental plots continues, so that remaining questions regarding the longevity of interactive
effects, and herbivore effects on vegetation succession and recruitment can be answered.
My research has shown that small-scale prescribed fires can lead to focal browsing
(localised, high intensity browsing, Fuhlendorf and Engle 2001) by macropod herbivores in
burnt forest patches, which simplifies site-level vegetation structure and reduces floristic
diversity. Focal grazing (particularly of domestic herbivores) has been found to have net
benefits for biodiversity in many grasslands, despite reducing local vegetation structure
(Fuhlendorf et al., 2006; Fuhlendorf et al., 2009; Fuhlendorf et al., 2010; Winter et al., 2012). In
grasslands, focal grazing after patch burning can increase the diversity of flora and fauna,
because the concentration of herbivores in burnt patches releases vegetation elsewhere from
grazing pressure, the contrasting grazing pressures creating a heterogeneous mosaic of
vegetation structure, supporting a diversity of species (Fuhlendorf et al. 2010). However, focal
browsing following prescribed burning in forests is likely to have markedly different effects on
biodiversity.
The effects of focal browsing are likely to differ between grasslands and forests due to
general differences between herbivore populations, fire extent and frequency, and plant traits in
these ecosystems. Most herbivore populations in forested systems are wild, and free to move
across large areas of habitat. When the area of habitat that is burnt is small compared with the
total available habitat (which is often the case for prescribed fires in forests), focal browsing in
burnt patches is likely to do little to reduce browsing pressure in unburnt areas (Fuhlendorf et
al., 2009). Further, even if browsing pressure is reduced temporarily in unburnt areas, the slow-
growing nature of many forest plant species and the lack of an evolutionary history of heavy
grazing (Milchunas and Lauenroth 1993, Díaz et al. 2007), mean that forest vegetation is likely
to be slow to recover following release from browsing pressure (e.g. Royo et al. 2010b,
Tanentzap et al. 2011, Tanentzap et al. 2012). Supporting this reasoning, I found that in
Booderee National Park, the concentration of herbivores in burnt areas lasted only months, but
interactive effects on vegetation persisted throughout the study (Papers III, IV). Therefore,
small burns which initiate focal browsing of herbivores in forests may lead to the simplification
14
of vegetation of burnt patches, but not allow vegetation complexity or density to increase
elsewhere. Thus, focal browsing in forests could potentially lead to the overall decline of
vegetation complexity, rather than creating the heterogeneous vegetation structure that promotes
biodiversity in grassland systems.
The potential for focal browsing after prescribed fire to lead to simplification of
vegetation is of concern for the management of forests in south-eastern Australia for two
reasons. The first is that ongoing control of both native (dingoes) and introduced (European red
foxes) predators for livestock protection and threatened species conservation mean that some
species of macropod herbivores are highly abundant in many forests of south-eastern Australia
(Banks et al. 2000, Coates 2008, Coulson et al. 2008, Gowans et al. 2010, Nimmo et al. 2015).
Where predator control is ongoing, high densities of these herbivores, combined with limited
predation risk (predation risk can discourage some herbivores from browsing in open areas,
While and McArthur 2006, Cromsigt et al. 2013, McArthur et al. 2014), means that there is
strong potential for fire-browsing interactions such as those observed in this thesis. The second
reason for concern is that current fire management policies in south-eastern Australia aim to
increase the proportion of fire that occurs through prescribed burning (rather than wildfire)
(Attiwill and Adams 2013, NSW Office of Environment and Heritage 2013). Prescribed fires
are usually of lower intensity and severity than wildfire (and so less likely to directly reduce
macropod populations), and of smaller spatial extent (and so more likely than wildfire to lead to
focal browsing in burnt areas). Further, many plant species in south-eastern Australia are
already at risk from increasing fire frequencies, which do not allow sufficient time between
return fires for plant recruitment (Morrison et al. 1996). As I found in this thesis that macropod
browsing slowed the recovery of vegetation from fire (Paper III), focal browsing after fire may
slow plant maturity, and therefore increase the risk of plants being locally extirpated by return
fires. This combination of release of macropod herbivores from predation and changing fire
regimes is therefore of concern for the conservation of flora and fauna in south-eastern
Australian forests, and warrants further consideration from both researchers and managers.
15
In this thesis, I have recommended that the management of macropod herbivores be
integrated with fire management decisions in forests. Where fire-browsing interactions are
considered to be negatively affecting conservation values, forest managers may need to reduce
the occurrence or strength of these interactions. Two potential ways managers could reduce the
strength of fire-browsing interactions would be to: (i) manage fire to reduce the concentration of
herbivores in recently burnt areas (manage the chain interaction), or (ii) target management of
the herbivore population to post-fire environments (manage the interaction modification) (Paper
V). The choice between these two strategies will depend on whether the fire-herbivore
interaction is being driven by chain or modification effects. In cases such as Booderee National
Park, where fire and herbivory are interacting via both chain effects (fire-driven browsing) and
modification effects (herbivore effects being stronger after fire), effective management of the
interaction may require a combination of both strategies (see Paper V).
Managing the chain interaction may be an effective way to manage many fire-herbivore
interactions, particularly in reserves where high visitor use makes implementing broad-scale
macropod control programs difficult. To manage the chain interaction, it may be possible to
alter the size, shape or timing of prescribed burns to reduce the concentration of herbivores in
burnt patches. However, before this could be implemented effectively, further work is needed to
determine how fire influences macropod habitat selection in forests. Previous studies have
shown that some small macropods, such as the swamp wallaby, forage less in open areas, even
if they contain high quality forage (While and McArthur 2006, Di Stefano et al. 2009, Stutz et
al. 2015), and it has also been found that many small savannah herbivores select more strongly
for small, rather than large burns (Sensenig et al. 2010). It may therefore be possible to reduce
the extent to which small macropods concentrate in burnt areas by increasing the size of
individual fires (e.g. burning one larger area, rather than a number of small areas), or reducing
the edge:area ratio of burnt areas (so that more of the burnt area is at large distance from the
edge).
Another strategy that may be effective in reducing the concentration of herbivores in
burnt areas would be to alter the timing of burning, either ensuring that burns are conducted
16
when there is ample fresh pick available elsewhere in the system, or if a number of burns are
planned in the same season, ensuring burns are completed close in time, so that herbivores must
choose between patches, rather than moving from one freshly burnt patch to another as burns
are completed. However, the success of such strategies may be limited in areas such as
Booderee National Park, where terrestrial predators are largely absent, as it is unclear whether
swamp wallabies will avoid open areas without the ongoing threat of predation. Changes to
prescribed burning must also be considered in the context of broader fire history, as any
strategies that result in high fire frequency or short inter-fire intervals could have negative
effects on many species (Morrison et al. 1996, Enright and Fontaine 2014). Further study is
therefore needed to determine how the size, shape, intensity and/or timing of prescribed burns
affect the selection of different macropod species for burnt areas, and whether this varies with
the presence or absence of terrestrial predators.
When interaction modification effects are strong, managing for an interaction chain may
do little to mitigate interactive effects, and if the strategy includes increasing the size of burns,
such management may actually increase interactive effects (see Paper V). Therefore, fire-
browsing interactions that are driven by modification effects may be more effectively managed
by controlling the herbivore population in recently burnt areas. Targeted population control (e.g.
culling) to protect vegetation from browsing in the period immediately following fire may be
more efficient than broad scale population control as it may also encourage herbivores to avoid
burnt areas (i.e. reduce chain effects) (Cromsigt et al. 2013). Targeted control of macropods in
burnt areas may also more closely resemble historic processes in this region, as indigenous
Australians traditionally used fire to attract macropods to areas for easier hunting (Benson et al.
1997, Yibarbuk et al. 2001). Prior to implementing any population control, managers would
need to confirm the identity and relative abundance of the macropod species foraging in the
burnt habitat, and ensure that control was targeted towards the species contributing to vegetation
decline.
In Booderee National Park, management intervention may be required to prevent the
simplification of vegetation following prescribed burning. As Booderee National Park attracts
17
high numbers of visitors, managing the fire to reduce focal browsing in burnt areas (managing
the interaction chain) may be an effective and achievable alternative to broad scale lethal control
of macropods. In the long-term, effective management of the interaction chain requires a better
understanding of how the size, shape or intensity of prescribed fires affects site selection by
different herbivore species. Until such information is available, managers could consider a
number of measures to reduce the likelihood of vegetation simplification after burning:
- Avoid very small sized prescribed burns, particularly in areas of sensitive or high-value
vegetation.
- Consider the timing of burns, and where possible conduct burns when forage is readily
available and widespread within the park.
- Monitor the recovery of vegetation following prescribed burns. If, despite measures to
reduce chain effects, recovery of vegetation is limited (i.e. bracken dominance exceeds
60%, see Paper III), consider short-term measures to deter herbivores from feeding in
burnt areas.
Conclusion
My research has shown that fire and macropod herbivores can interact via both numerically
mediated (chain) and functionally moderated (modification) effects to simplify the structure and
diversity of forest vegetation, and alter the density and composition of some fauna groups.
Under current management and policy conditions, it is probable that such interactions occur in
many of the forests of south-eastern Australia. Large herbivore populations, particularly those
that are highly abundant, should therefore be an important consideration for prescribed burn
planning in these forests. Future research that determines how long interactive effects persist,
and how fire properties and the presence of predators affect macropod site selection should be
prioritised to support these management decisions. Overall, this thesis has highlighted the value
of a mechanistic understanding of how co-occurring disturbances interact for determining when,
where and how disturbance interactions can most effectively and efficiently be managed.
18
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Paper I: Effects of large native herbivores on other animals
Numerous studies have highlighted the strong role of large herbivores in shaping ecosystem
structure and function. However, there has been little quantitative synthesis of the effect of
native herbivores on other animals, despite wild herbivore populations being managed for
biodiversity conservation in many ecosystems. In this paper, I consolidated existing knowledge
of the effects of large herbivores on other animal groups, analysed the reasons behind current
gaps and limitations in the literature, and identified approaches for further research to better
inform the management of large herbivores for conservation objectives.
Foster, C.N., Barton, P.S. and D.B. Lindenmayer (2014) The effects of large native herbivores
on other animals. Journal of Applied Ecology. 51, 929-938.
26
Summary
1. Large mammalian herbivores are major drivers of the structure and function of
terrestrial ecosystems worldwide, and changes in their abundance have resulted in many
populations being actively managed. Many empirical studies have identified that
abundant mammalian herbivores can have negative impacts on biodiversity, but there
has been no specific review of the impacts of native mammalian herbivores.
2. We assessed the peer-reviewed literature on the effects of large native herbivores on
other animals. We aimed to quantitatively synthesise current knowledge, identify gaps
and limitations in the literature, and highlight priorities for future research.
3. Most empirical studies of herbivory effects compared only two levels of herbivory
(76%), and meta-analysis showed that very high densities of herbivores, when
compared with very low densities, had mostly negative effects on other animal species.
These negative effects were usually attributed to changes in the quantity and/or
structure of vegetation. Only 24% of papers studied animal responses across a gradient
of herbivore densities; and non-linear responses to herbivory, as well as responses to
low and moderate herbivore densities, remain poorly understood.
4. The literature also was dominated by short-term studies (76% sampled animal responses
for 2 years or less) and there was a high incidence of confounding factors among studies
(38% of studies). In addition, many studies used only coarse metrics to assess effects
(e.g. only 33% of studies assessed species composition) and few included community-
level synthesis (only 31% of studies reported results from more than one animal class).
5. Synthesis and applications. Critical questions remain for both basic ecology and the
management of large native herbivores for biodiversity. Key knowledge gaps include
(1) non-linear responses to herbivore pressure, (2) how responses differ between
different herbivores, (3) the spatial and (4) the temporal variation of responses, (5) how
the effects of herbivores interact with other land management activities, and (6) the
27
mechanisms driving cascading effects through ecosystems. We identify ways to address
these gaps and emphasise the need for studies which employ contrasts over a gradient of
ecologically relevant herbivore densities and biologically meaningful timeframes.
Keywords
Browsing, biodiversity, ecological cascades, deer, grazing, herbivory, indirect effects, over-
abundance, species interactions, ungulates
Introduction
Large mammalian herbivores play a central role in the structure and functioning of terrestrial
ecosystems (Côté et al. 2004; Danell et al. 2006). Loss of native predators, and changes in land
use have led to large herbivores becoming over-abundant in many ecosystems worldwide (Estes
et al. 2011; Ripple et al. 2014). In other locations, large herbivore populations are threatened by
over-hunting, habitat loss, and habitat fragmentation (Mallon & Zhigang 2009; Festa-Bianchet
et al. 2011). Consequently, many species of large herbivores are now actively managed
throughout much of their range (Gordon, Hester & Festa-Bianchet 2004). This has resulted in a
demand for empirical studies to quantify the effects of large herbivores on ecosystems and
biota, and for data to both inform and justify management decisions (e.g. Owen-Smith et al.
2006).
Knowledge of the effects of large herbivores is substantial. Effects include changes to
primary production (Frank & McNaughton 1993), nutrient cycling (Molvar, Bowyer &
Ballenberghe 1993), soil properties (Abdel-Magid, Schuman & Hart 1987), fire regimes (Hobbs
1996), plant and animal communities (Goheen et al. 2010), and possibly even climate (Doughty,
Wolf & Field 2010). In this study we focus on the effects of large native herbivores on other
animals. The effects of large herbivores on other animals can occur via a range of mechanisms,
many of which are indirect. These include consumption of vegetation, modification of the
physical environment, provision and re-distribution of resources (e.g. dung, carrion), and direct
interference (Schmitz 2008; Marquis 2010). These effects can vary in both temporal and spatial
28
scale, from short-term impacts on individuals, to landscape-scale shifts in ecosystem state that
can be difficult to reverse (Côté et al. 2004; Tanentzap, Kirby & Goldberg 2012). The effects of
herbivory on other animals cannot be easily predicted from effects on vegetation as animal
responses have been found to differ from plant responses both in shape and magnitude
(Milchunas, Lauenroth & Burke 1998; Wardle et al. 2001; Grandin, Lenoir & Glimskär 2013).
Previous reviews on the effects of large herbivores on other animals have attempted to
synthesise these complex effects but have been specific in taxonomic or geographic focus. They
include effects on birds (Gill & Fuller 2007), small mammals (Flowerdew & Ellwood 2001),
butterflies (Feber et al. 2001) and invertebrates (Stewart 2001), and effects on specific
ecosystems such as European heathlands (Rosa García et al. 2013) and the North American arid
zone (Jones 2000). Work by Suominen and Danell (2006) took a more holistic approach,
providing a qualitative summary of the effects of large herbivores on both invertebrate and
vertebrate groups and in a range of ecosystems. However, the volume of literature available on
this topic has more than doubled since 2006, which both warrants renewed attention to this
topic, and allows the application of quantitative approaches not previously possible.
Furthermore, previous reviews have not distinguished between the effects of native and
introduced herbivore species. This is important because the effects of native herbivores may
differ from those of introduced species due to their shared evolutionary history with their
environment (Milchunas, Sala & Lauenroth 1988; Hobbs 1996). The management goals for
native herbivores are also likely to differ, being focussed on establishing an ‘optimum’
herbivore density, rather than on damage limitation or eradication (Côté et al. 2004; Gordon,
Hester & Festa-Bianchet 2004).
We conducted a systematic review and meta-analysis of the published literature on the
effects of large native herbivores on other animals. Our review had four principal aims: (1) to
synthesise current knowledge on the effects of large native herbivores on other animals, (2) to
identify key knowledge gaps or inconsistencies within the literature, (3) to identify the problems
which have led to these gaps, and (4) to suggest priorities for future research. While our review
focusses on effects on animal assemblages, many of the knowledge gaps and barriers we
29
identify also will be applicable to the study of other effects of large herbivores. While the
definition of a ‘large herbivore’ varies between studies, to be consistent with the previous
review, we use the definition of Danell et al. (2006), where the term covers all terrestrial
mammalian herbivores with an average body mass exceeding 2 kg.
Our quantitative and systematic approach to this review reveals key gaps in our
understanding of the effects of large native herbivores, and identifies specific limitations in
study design that have led to these gaps. We identify approaches for future research to overcome
these limitations and address critical questions for basic ecology and management.
Materials and Methods
We used a systematic approach to obtain a representative sample of the literature on the effects
of large herbivores on other animals. Briefly, we used key search terms to identify potentially
relevant articles, and selected articles which quantified the effects of large native herbivores on
other animals (full details are outlined in Appendix S1 in Supporting Information). This process
yielded 96 different studies from 69 different study areas, published between 1983 and 2013.
For details of these papers see Appendix S2 in Supporting Information.
Systematic Review
We used data from these 96 papers to address six specific research questions. Below we briefly
outline the methods used to address each of these, for full details see Appendix S1.
1. Which ecosystems and animal response groups are most commonly studied?
To assess geographical and taxonomic differences in study effort, we sorted all papers into
categories by two location variables (continent and ecosystem), two focus herbivore variables
(taxonomic group and abundance (as described by authors)), and two animal response group
variables (number of groups studied, taxonomic group studied). For each variable, we then
tested whether there were differences in the frequency of papers in each category using a Chi-
squared analysis. We also sorted papers from the original search to assess whether studies of
native herbivores were more or less common than studies of domestic or wild exotic herbivores.
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2. Are there overall trends in the direction of effects of large herbivores on other
animals?
From each experimental study which was not strongly confounded (i.e. quality of evidence
score of iii or better as defined by Felton et al. 2010, see Appendix S1), we recorded the
abundance, species diversity and species composition responses of animal assemblages to
different levels of herbivory. We calculated the mean effect of herbivory for taxonomic groups
for which we could extract data from at least five studies. We selected species richness as the
measure of species diversity as it was the most commonly used metric. For each taxonomic
group in each study, we calculated a log response ratio (highest versus lowest herbivory
treatments in study) and its variance (Borenstein et al. 2009, p. 30). We then performed a
random effects meta-analysis to calculate mean log response ratios and 95% confidence
intervals for each taxonomic group (Borenstein et al. 2009, p. 69). Taxonomic groups were used
instead of functional groups as most studies used taxonomic divisions and the infrequent and
inconsistent use of functional groups between studies meant sample sizes were small. In
addition, where sample sizes were adequate, we found that taxonomic groups were able to
provide more detail than functional groups (e.g. Orthoptera and Lepidoptera versus leaf chewing
herbivores). We analysed Arthropoda overall, as well as arthropod orders individually, as
Arthropoda were often used as a measure of prey abundance for other taxa.
As species composition is not measurable on a continuous scale, we could not calculate
a mean response ratio for species composition. Instead, we assessed whether overall, results for
species composition differed from those for species diversity. We examined studies that
reported both species diversity (any measure of within-plot species diversity) and species
composition responses to herbivory, and compared the numbers of studies reporting a
significant effect or no effect for each of these measures. As some studies analysed data from
different animal groups separately, we included data from each analysis as a separate data point.
We also assessed whether the effects of large herbivores on other animals could be
attributed to any particular mechanism. To do this, for each study, and also for each animal
response group in each study, we recorded the mechanisms authors attributed to the observed
31
animal responses. For each response, we also recorded whether the importance of these
mechanisms was determined through an explicit test, or through author inference, and the
direction of the animal response (positive, negative or ‘other’).
Environmental factors can modify the way organisms respond to herbivory (Wisdom et
al. 2006), and the interactions can have stronger effects than the factors alone (Joern & Laws
2013). We therefore recorded the results of all studies investigating the interaction between
herbivory and another factor to identify patterns across studies.
3. What is the shape of the animal response to herbivory?
We defined the shape of the herbivory response as the relationship between the animal group
response variable (abundance, species diversity etc.) and increasing herbivore density. This
could be increasing or decreasing, linear or non-linear etc. We first quantified how many studies
were designed to test the shape of the herbivory response. To be counted, a study had to
measure the abundance or species diversity of an animal assemblage at a minimum of three
different levels of herbivory, and analyse these measurements against a continuous scale of
herbivory. Second, we quantified the frequency of non-linear responses to herbivory among the
reviewed studies. For each study which measured responses at three or more levels of
herbivory, we allocated the response of an animal group to one of the following four categories
for both abundance and diversity (any measure of within-plot diversity): (1) linear response, (2)
non-linear response, (3) no response/unable to tell from data or (4) no data. For studies which
used qualitative categories of herbivore pressure (e.g. low, medium and high) and reported a
monotonic response, it was not possible to differentiate between linear and non-linear
responses. Therefore, all monotonic responses from categorical studies were assigned to the
category ‘unable to tell from data’.
4. Has the design of herbivory studies changed over time?
We assessed the change in experimental approaches over time by examining the design, spatial
scale and ‘quality’ of experiments. To assess changes in design, we sorted papers by
experimental approach (herbivore exclusion, herbivore density manipulation, simulation of
32
herbivory or natural experiment) and herbivory treatments (binary – two levels of herbivory or
gradient – three or more levels of herbivory). We also sorted herbivore exclusion studies
according to whether they excluded all large herbivores or selectively excluded particular
groups of herbivores. We grouped studies by publication year into five year blocks, and used a
Chi-squared analysis to test whether the frequency of studies across experimental designs
differed among time periods.
To assess changes in scale over time, we used the experimental exclosure studies and
examined whether, for the same level of replication, the size of exclosures had changed over
time. To do this we calculated the mean exclosure size and the number of sampling plots (the
number of exclosures per treatment times the number of treatment combinations) in each paper.
We log-transformed both variables to improve linearity. To test for differences over time, we
performed a linear regression with groups (with five-year intervals as the groups).
To assess the ‘quality’ of studies over time, we used the quality of evidence categories
described by Felton et al. (2010) to classify studies as either not confounded (evidence quality
score of i or ii) or confounded (evidence quality score iii or iv). We also grouped studies
according to whether they used an experimental or non-experimental approach. We tested
whether the frequency of studies with confounding variables had changed over time using a
logistic regression in GenStat 15th Edition (VSN International 2012). We allowed interactions
between publication year and study approach to allow different slopes to be fitted to
experimental and non-experimental studies.
5. Do short-term studies provide a reliable representation of the effect of large
herbivores on other fauna?
We assessed whether the duration of sampling of animal responses affected the likelihood of the
study detecting a significant effect of herbivory. For each of three variables (abundance, within-
plot diversity and composition), we classified the response of each animal group in each study
as either ‘significant response to herbivory’ or ‘no response to herbivory’. We conducted a Chi-
squared analysis to test whether the frequency of studies detecting a significant result differed
33
between short-term studies (sampling for three years or less, = 1.56, n = 84) and long-term
studies (sampling over four or more years, = 6.25, n = 12). We also assessed the prevalence of
significant time × herbivory treatment interactions in long-term studies by recording whether or
not such an interaction was detected in each study.
6. What do authors recommend as priorities for future research?
One of the principal aims of our review was to identify ways to guide the direction of future
research. We therefore recorded research recommendations from each paper.
Results
Most commonly studied ecosystems and response groups
We found significant biases in the geographic location, ecosystem, types of herbivores and
animal response groups studied (all P < 0.001, Fig. S1 in Supporting Information). Studies in
forested systems of North America and Europe were the most common; with Arthropoda and
birds the most frequently studied animal response groups. Our search did not return any studies
of the effects of large herbivores on their predators. Only 31% of studies measured the
responses of more than one class of animal to herbivory. In 58% of studies, at least one native
herbivore was described as over-abundant or at higher than historical levels. In the initial search
of the literature, studies on the effects of introduced herbivores (n = 193, domestic = 167, wild =
27) on fauna were twice as common as studies on the effects of native herbivores (n = 99, P <
0.001, Fig. S2 in Supporting Information).
Effects of herbivory on other animals
Meta-analysis revealed significant overall responses to large herbivores for many animal taxa.
The abundance of small mammals, Arthropoda, Araneae, Hemiptera and Lepidoptera were all
negatively affected by high levels of herbivory (P < 0.05 for all groups, Fig. 1). The abundance
of birds, Coleoptera and Hymenoptera showed no significant overall response to herbivory.
Orthopteran abundance was the only variable showing a positive overall response to herbivory,
34
however this was not significant (P = 0.21). The effect of herbivory on species richness could
be calculated only for birds and Arthropoda and both groups were negatively affected by
herbivory (P < 0.001, Fig. 1). Arthropoda richness showed the strongest negative response of all
variables, with richness being 66% lower under high than low levels of herbivory.
Figure 1. Abundance (a) and richness (b) responses of animal groups to large native herbivores
(ln response ratio and 95% confidence limits). Arthropoda includes only data from
studies examining arthropods overall (i.e. not restricted to 2 or 3 focal groups). Data
from some studies are included in both Arthropoda and order-level analyses. Response
ratio equals abundance (or richness) at high herbivore density / abundance (or richness)
at low herbivore density. Values less than zero indicate that the animal group was more
abundant (or species rich) at low levels of herbivory. Values with error bars not
overlapping zero indicate a significant effect of herbivory (P < 0.05).
The effects of herbivory on the species composition of animal assemblages were
assessed in 32 papers (33 %) for 41 animal groups, and effects on both composition and species
diversity were analysed for 37 animal groups. Herbivory significantly affected the composition
but not the diversity of eight animal groups, while only two animal groups had the reverse
result.
35
Ninety of the 96 reviewed papers discussed mechanisms driving the effects of large
herbivores on other animals. Although 84 papers provided conclusions about which
mechanisms were likely to have caused the effects they observed, only 48 performed any test of
these mechanisms. Of these, 46 confirmed one or more mechanism as important, while only
eight reported evidence against a mechanism. Animal responses were most commonly attributed
to changes to vegetation biomass and structure (Fig. 2). Most mechanisms were associated with
negative effects of large herbivores on other animals, however changes to plant chemistry also
commonly associated with positive effects (Fig. 2). Vegetation structure and biomass were the
most commonly implicated mechanisms for effects on birds, small mammals, Arthropoda,
coleopterans and orthopterans (Table S1 in Supporting Information). Effect on coleopterans
were also associated with changes to the physical environment.
Figure 2. The mechanisms that authors considered to be driving the effects of large native
herbivores on the (a) abundance and (b) diversity of other animals, and the numbers of
animal responses associated with each mechanism. The animal response groups are
divided according to whether the mechanism was associated with a negative (black),
positive (white) or ‘other’ (grey) response to herbivory.
36
Nineteen studies (20%) considered how environmental or land management factors
interacted with herbivory effects. All three studies that investigated herbivory × productivity
interactions reported that herbivory effects were most strongly negative at low productivity
(Suominen et al. 2003; Pringle et al. 2007; Suominen et al. 2008). Recent fire (three papers),
addition of logs (two papers), vegetation age (two papers), vegetation density, tree thinning, soil
disturbance, nutrient input, rainfall and invasive plants were also found to modify the response
to herbivory of at least some animal groups. Studies of fire frequency (two papers) and predator
control identified no significant interaction with herbivory.
Shape of the response to herbivory
We found that 23 studies (24%) measured animal response variables at three or more levels of
herbivory, but only six of these performed their analyses using herbivore pressure as a
quantitative variable. We were able to assess the shape of the response to herbivory for only two
of these, and both linear and non-linear responses were reported. Among the 23 studies which
measured animal responses to a gradient of herbivore pressures, linear, exponential decay,
threshold, intermediate maximum and intermediate minimum response shapes were all reported
for at least one animal group. There was no significant difference in the number of animal
groups which showed linear and non-linear responses to herbivory for either abundance (P =
0.21) or diversity (P = 0.26).
Experimental approaches
The most common experimental approach was herbivore exclusion, followed by natural
experiments (Fig. S3a in Supporting Information). Chi-square comparisons indicated that there
was no difference in the distribution of papers across experiment types between time periods (P
= 0.29, Fig. S3b). In contrast, the number of papers using three or more levels of herbivory in
their comparisons tended to increase over time; from 10 % of pre-2003 papers to 30% of papers
published between 2004 and 2013 (P = 0.03, Fig. S3b). The number of papers including
selective exclusion of different herbivores in their design also increased over time (P = 0.017,
37
Fig. S3c). However, only seven of the 17 papers which had study designs including selective
exclusion actually included the selective treatments in their analysis of effects on animals.
The size of exclosures in herbivore exclusion studies varied greatly, from 0.1 m2 cages
surrounding individual shrubs to 2100 ha fences encompassing entire watersheds (median =
0.92 ha, IQR = 3.9 ha). There was a significant negative relationship between the log of mean
exclosure size and the log of the number of sample plots in a study, with studies employing
larger exclosures using lower levels of replication (Fig. 3). This relationship did not differ
between time periods, indicating that the scale of exclosure studies has not changed over time.
Figure 3. Relationship between mean exclosure size in a study and the number of study plots
(number of replicate exclosures per treatment combination times the number of
treatment combinations) in different time periods. The log of the number of sample
plots was negatively related to the log of exclosure size (r2 = -0.6, P < 0.001). This
relationship did not differ between time periods (P > 0.2).
We identified potential confounding effects in 38% of papers, with 13% of papers
confounded to the extent that their data were unusable for meta-analysis (data quality score iv,
see Felton et al. 2010). Logistic regression showed that there has been no change in the
incidence of confounded studies over time for either experimental or non-experimental studies
38
(P > 0.05). Experimental studies were far less likely to have problems with confounding factors
(20% of studies) than non-experimental studies (85% of studies, P < 0.001).
Effects of time
Most (76%) papers measured animal responses for two years or less, while only 12% measured
animal responses for four years or more. Chi-squared tests showed that there was no difference
in the proportion of animal groups showing significant responses to herbivory between short-
term (1–3 year) and longer-running studies (P > 0.5 for all variables). However, this analysis
had limited power due to studies being heavily skewed across both categories (only 12% ran for
more than three years and only 5% found no significant response to herbivory).
Among the 12 studies which measured animal responses for four or more years, five
reported a significant year × treatment interaction (Keesing 2000; McShea & Rappole 2000;
Gómez & González-Megías 2007; Mathisen et al. 2012; Parsons, Maron & Martin 2013), and
two found significant treatment effects in only some years (Neff, Fettig & VanOverbeke 2007;
Martin & Maron 2012). The remaining five studies did not contain any information on year–
treatment interactions.
Priorities for future research
Fifty-one of the 96 papers made explicit recommendations for future research.
Recommendations could be divided into two main categories; those relating to research topic
and those relating to study design (Table S2 in Supporting Information). The most frequently
suggested topic for future research was the possible cascade of observed herbivory effects to
other species or ecosystem processes. Other commonly identified research priorities included
studies of the mechanisms of effects, novel habitats or locations, and possible interacting
factors. Recommendations regarding the design of future studies were less common but
included: studies which measure responses at larger spatial scales and/or examine spatial
variation in responses; studies which can detect both direct and indirect relationships; studies
which can detect the shape of herbivory responses; and longer-term studies.
39
Discussion
Our review of the empirical literature has demonstrated that very high herbivore densities
usually have negative impacts on other animals. However, there remains only a limited
understanding of whether these effects are consistent across taxa (of both herbivores and
response animals) or ecosystems, and what factors modify these effects. We also have identified
key knowledge gaps around the shape of animal responses to herbivory, the consistency of
responses between herbivores, how responses vary with temporal and spatial scale and the
mechanisms driving the flow of effects through ecosystems. These gaps are, in part, due to
limitations in the design of studies. Below we discuss key findings and research gaps and
identify ways to advance future research in this area.
Effects of herbivory
Most animal groups showed a negative overall response to herbivory (Fig. 1). Small mammal
abundance and bird species richness were both negatively affected by high levels of herbivory,
mostly due to reduced biomass and structural complexity of vegetation and reduction in food
resources (Fig. 1, Table S1). This result is consistent with previous reviews (Flowerdew &
Ellwood 2001; Fuller 2001; Suominen & Danell 2006). Overall, bird abundance was not
affected by herbivory, which may be due to the small sample size in our analysis. However, the
effects of livestock grazing on birds are also mixed (e.g. Milchunas, Lauenroth & Burke 1998)
and the difference we found between abundance and diversity effects may reflect a
compensatory increase in generalist species under high herbivory (McKinney & Lockwood
1999). Arthropoda, Araneae, Hemiptera and Lepidoptera, also showed negative responses to
high herbivory, which was consistent with the summary of Suominen & Danell (2006), and was
again attributed to simplified vegetation structure and reduced plant biomass under high
herbivory.
Orthopterans (leaf-chewing herbivores), were the only group to show a positive overall
response to herbivory, although this effect was not significant. This result differed from the
other herbivorous analysed (Hemiptera - sap suckers and Lepidoptera - leaf chewers as larvae),
40
which responded negatively to the reduced vegetation biomass at high levels of herbivory. The
different responses may have occurred because studies of Orthoptera were predominantly from
grassland and savanna habitats. In these systems, although grazing reduces grass biomass, it
also can increase nutrient turnover and improve the nutritional quality of food available to
grasshoppers, while also increasing the heterogeneity of the grass canopy, which assists with
predator evasion and thermoregulation (Joern 2004).
We found that Arthropoda richness displayed the strongest negative response to
herbivory (Fig. 1), which differs from Suominen and Danell’s (2006) summary that richness is
often higher in grazed sites. As only three of the five studies in our analysis corrected richness
for abundance this strong negative response may be a slight over-estimate (Gotelli & Colwell
2001). However, it does indicate that effects on richness, at least at this coarse taxonomic level,
tended to be negative rather than positive. It is somewhat surprising that such an ecologically
diverse group as Arthropoda showed such a strong negative response, but this may partly be
explained by the nature of the comparisons in the studies we analysed. Most studies we
analysed were exclosure studies, where very high levels of herbivory were compared with very
low or no herbivory (Figs. S1, S3). As herbivore density increases, it will almost invariably
reach a point where effects on other species become negative, even if effects were positive or
negligible at lower densities (Milchunas, Sala & Lauenroth 1988; Suominen & Danell 2006).
By comparing two extreme (and unnatural) herbivore densities, exclosure studies in areas of
high herbivore density are therefore pre-positioned to detect negative effects of large herbivores
on other animals. At lower levels of herbivory, animal responses may be more varied, both
between sites and between animal groups.
Shape of animal responses to herbivory
A wide range of ‘shapes’ of animal responses to herbivory were reported, which reflects the
wide range of ecosystems, animal groups and herbivores included in this review. Both grazing
theory, and papers we reviewed, indicate that site-specific variables such as productivity
(Pringle et al. 2007; Vesterlund et al. 2012), history of herbivory (Milchunas, Sala & Lauenroth
41
1988), and the presence of other disturbances (Wisdom et al. 2006), can change the shape,
direction and magnitude of animal responses to herbivory. The variation caused by these factors
is in addition to the variation in responses between animal response groups and between
different herbivores (Pringle et al. 2011).
These variable results highlight the importance of not assuming a linear response to
herbivory and caution against extrapolation (or interpolation) from studies which include only
binary comparisons. If the relationship between herbivore pressure and an animal assemblage
were non-linear, a binary study could detect a positive, negative or no response to herbivory
simply depending on which two herbivore pressures were selected for comparison (Rooney &
Waller 2003)(Fig. 4). The use of binary studies to inform the management of large herbivore
populations could therefore lead to unexpected and undesirable outcomes. For example,
reduction of a highly abundant herbivore population intended to benefit other animals could
have no effect, or even a deleterious effect on the target animals, depending on the underlying
shape of the herbivory response (see Fig. 4).
42
Figure 4. The effect of non-linear responses to herbivory on the outcome of experiments
including only binary comparisons (74% of reviewed studies). If the ‘true’ response of
an animal group to increasing herbivore pressure was unimodal (bold line), a study
including only binary comparisons would fail to detect this, and depending on the two
herbivore pressures compared, could conclude that an animal was positively (e.g. a vs
b), negatively (e.g. b vs c) or not affected (e.g. a vs b) by increasing herbivore pressure.
A binary study would also fail to detect a threshold-shaped response (dotted line) and
might instead report no effect (e.g. i vs ii) or a negative effect (ii vs iii).
Experimental Approaches
The recent increase in the number of studies using a gradient of herbivore densities indicates
that researchers are recognising the limitations of simple binary designs. However, non-binary
studies are still in the minority, and animal responses are rarely analysed against a quantitative
gradient of herbivory. Studies of functional differences between herbivores are also increasing,
but many papers present data only from the two extreme treatments and therefore do not use
these studies to their full potential. Further progress in isolating the effects of herbivory from
43
confounding factors is also essential if studies are to detect the ‘true’ response of animals to
herbivory.
Due to logistical constraints, experimental studies were usually limited in either spatial
scale or replication (Fig. 3). A trade-off is made between gaining detailed information at small
spatial scales, or coarser information at large spatial scales. As a result, most studies did not
integrate considerations of spatial scale into their design, although a few notable studies found
important scale-dependent results (Jay-Robert et al. 2008; Barton et al. 2011). As the effects of
herbivory vary with spatial scale (Chaneton & Facelli 1991; Tahmasebi Kohyani et al. 2008),
contradictory results can simply be an artefact of the scale of measurements; small-scale
responses do not necessary multiply up to similar effects at larger spatial scales (Hester et al.
2006). While understandable, the bias of experimental studies towards low replication at large
scales and high replication at small scales means that they are unlikely to detect landscape-scale
changes in diversity such as biotic homogenisation (Olden 2006).
The need for long-term studies
Most studies measured animal responses to herbivory over short timeframes of two years or
less. However, such studies may give a poor estimate of the true response of an animal
assemblage to herbivory, even if herbivory treatments have been in place for a number of years.
Animal populations can fluctuate greatly within short time periods, particularly in short-lived
organisms or boom–bust ecosystems (Joern & Pruess 1986; Ernest, Brown & Parmenter 2000;
Ostfeld & Keesing 2000). Short-term studies, especially those with few sampling events, can
therefore not be reliably extrapolated to the multi-year times scales of interest to land managers
(Lindenmayer et al. 2012). This is demonstrated by the high incidence of significant time ×
herbivory interactions in long-running studies, where the effect of herbivory was significant
only in some years, and some studies even returned opposite results between years. Although
long-term studies are more costly and difficult to conduct, they are necessary if we are to detect
and distinguish between short-term populations fluctuations, which may require little
44
management intervention, and major shifts in ecosystem state which justify significant
investment of conservation resources (Andersen et al. 2009; Lindenmayer et al. 2012).
Implications for future work
We have identified key limitations in the design of existing studies that have led to knowledge
gaps in the effects of large herbivores on other animals. These gaps include; (1) the shape of
animal responses to increasing herbivore pressure, (2) how animal responses differ between
different herbivores and the (3) spatial and (4) temporal variation in animal responses (Table 1).
How these effects interact with other land management activities (5), and the mechanisms by
which effects cascade to other biota and ecosystem processes (6) also remain key areas for
future research. To address these gaps, study designs need to move beyond the traditional “lots
or none” herbivore exclusion approach, and employ collaborative and creative study designs
(see Table 1).
Table 1. Knowledge gaps surrounding the effects of large native herbivores on other animals and
suggested approaches to address these gaps.
To understand the shape of animal responses to herbivory, studies need to include a
gradient of ecologically relevant herbivore pressures and analyse animal responses against
herbivory as a continuous variable (Hester et al. 2000). In systems where more than one species
of large herbivore is active, studies which measure animal responses to different herbivores are
45
also critical for understanding the functioning of these systems (Wisdom et al. 2006; Pringle et
al. 2011). Combining experimental approaches with natural experiments (Hester et al. 2000),
and using experimental treatments to their full potential will go a long way to addressing these
gaps (Table 1). Considerable potential also lies in collaborations with land managers to measure
responses across different areas of active management and establish adaptive management
studies (Wisdom et al. 2006; Westgate, Likens & Lindenmayer 2013).
An understanding of the spatial and temporal variation in the effects of large herbivores
is essential for the efficient, targeted and timely management of large herbivore populations
(Gordon, Hester & Festa-Bianchet 2004; Wisdom et al. 2006). To detect this variation,
comparisons need to extend further than simple between-plot comparisons and employ sampling
regimes over biologically meaningful timeframes. Again, combining experimental approaches
with natural experiments and replicating experiments over different land management practices
or environmental gradients (e.g. Goheen et al. 2013) will be useful approaches (Table 1).
Metrics which examine changes in species composition and species turnover across landscapes
can also provide larger-scale insights (e.g. Newman, Mitchell & Kelly 2013), without great
increases in sampling effort above what is required for between-plot diversity comparisons. As
identified by previous authors (Table S2), multi-taxa studies able to test the mechanisms which
drive effects, and how effects cascade through ecosystems, are essential if we are to thoroughly
understand the processes underpinning the effects of large herbivores on other animals.
Conclusion
Studies of the effects of large native herbivores on other animals were biased towards short-
term, binary comparisons at limited spatial scales. These studies revealed mostly negative
effects of high densities of large native herbivores on bird, small mammal and arthropod
assemblages. To advance this field, future studies must address key knowledge gaps
surrounding non-linear effects, differences in effects between herbivores, spatial and temporal
variation, interacting factors and the mechanisms driving effects. These studies must give
46
careful consideration to study design if they are to give new insights for both basic ecology and
management.
Acknowledgements
We thank Peter Lane for statistical advice, Chloe Sato for assistance with figures and the
associate editor, Otso Suominen, Benjamin Scheele and an anonymous reviewer for comments
on earlier versions of this manuscript.
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Supporting Information
Additional Supporting Information may be found in the online version of this article:
Appendix S1. Detailed methods for literature search and meta-analysis.
Appendix S2. Details of the 96 papers included in the systematic review.
Table S1. Mechanisms driving the effects of large herbivores on other animals.
Table S2. Recommendations for future research given by authors.
Figure S1. Distribution of reviewed papers by study system and animal response groups.
Figure S2. Numbers of studies of effects of herbivores on other animals where herbivores are
native, wild exotic or domestic livestock.
Figure S3. The distribution of experimental approaches, contrasts and exclusion method used
by studies.
52
Appendix S1. Detailed methods for literature search and meta-analysis.
Literature Search and Paper Selection
We used a four stage systematic approach to obtain a representative sample of the literature on
the effects of large herbivores on other animals.
1. We searched the ISI Web of Knowledge Database with the following search string:
Topic=((Herbivor* OR graz* OR brows*) AND (Mammal* OR vertebrate* OR
overabundan* OR density OR deer OR ungulate*) AND (Fauna* OR reptil* OR herp*
OR frog* OR amphibian* OR bird* OR avifauna* OR “small mammal*” OR rodent*
OR invertebrate* OR insect*)). This search returned approximately 9500 results.
2. We reviewed the first 100 of these articles to identify additional key words that were
common to the titles of relevant papers. This enabled us to add an additional criteria
based on the article title: Title=(brows* OR herbivor* OR graz* OR deer OR cascade*
OR trophic). We performed the final search using both of these search strings on the
15th August 2013 and obtained 1453 unique matches.
3. We assessed each article for relevance using according to seven criteria. The criteria
were applied hierarchically, with articles only being assessed if they met all of the
preceding criteria.
4. Criteria:
i. Studied the effect of a native mammalian herbivore on fauna (268 articles)
ii. Empirical study published in English in peer reviewed journal (260 articles)
iii. At least one of the herbivores was native to the study system (91 articles)
iv. At least one of the native herbivores was large (> 2 kg) (85 articles)
v. Study was from a natural (or minimally modified) terrestrial ecosystem (76
articles).
vi. Study measured the impact of herbivory on native terrestrial fauna (70 articles)
vii. Study included contrasts (i.e. compared at least two levels of herbivory of
native herbivores) (67 articles).
53
5. Finally, we searched the reference list of the 67 articles identified above and located a
further 29 papers which met the seven inclusion criteria.
Classification of Studies
To assess biases in the literature we classified studies according to their study location and
herbivores and animal response groups. We classified studies by six variables, each with a
number of categories:
i. Continent: North America / South America / Asia / Europe / Africa / Oceania.
ii. Ecosystem: Forest or Woodland / Heath or Shrubland / Savanna or Grassland
iii. Taxonomic group of herbivores: at order level
iv. Abundance of herbivores (as described by author): over-abundant (or at higher than
historical levels) / not over-abundant
v. Number of animal response groups studied: single species / single taxonomic group
(class level) / multiple taxonomic groups
vi. Taxonomic group of animal response groups: class for vertebrates, order for
invertebrates.
We also returned to data collected in stage three of the paper selection process to assess whether
studies of the effects of native herbivores were less common than studies of introduced
herbivores. We sorted the 268 articles which studied the effects of herbivores on fauna
according to whether the herbivores studied were native, wild exotic or livestock (step 3iii). In
both of the above processes, if a paper fit into more than one category (e.g. studied both heath
and forest habitats) then it was counted in both categories. Multiple papers from the same study
site were included separately in this analysis as this was thought to summarise research effort
more accurately than if we pooled papers by study site.
54
Data Extraction and Conversion
For meta-analysis we extracted data from tables, figures and supplementary material on the
abundance and species richness of animal groups under different levels of herbivory. Animal
groups were taxonomic and grouped by class for vertebrates, order for invertebrates. As many
studies did not separate arthropods by order, we also analysed arthropods overall which
included any analysis of arthropods where data from three or more orders were combined. As
we were interested in community level effects, we excluded data which reported effects on only
one or two species (except for the effect of herbivory calculation for small mammals, where
studies of one or two species were the most common and so included in the analysis). Data in
figures were extracted using the web-based application Web Plot Digitiser V2.5 (Rohatgi 2012).
Papers reported data in a variety of formats and we converted all data to means and standard
deviations according to the methods in Table 1. If a study did not include all the information
needed to calculate a mean and standard deviation for each level of herbivory then the study
could not be included in the analysis. All data conversions were conducted before data were
combined. To reduce unexplained variation within the analysis we assessed studies according to
the quality of evidence criteria of Felton et al. (2010) and included only experimental studies
with a data quality score of iii or better (Table 2).
Studies with > 2 levels of herbivore pressure
In the calculation of mean response ratios we used data from the lowest and highest levels of
herbivory compared. This was thought to give the most consistent data across studies as most
studies with only two levels of herbivory compared absence (or very low) with very high
densities.
55
Combining Data
A number of studies had split data across years, sites, factorial treatments or taxonomic or
functional groups, however for our analysis we needed to generate a single data point per study.
For the purpose of analysis, a study was defined as “a project employing the same treatments at
the same geographical location measuring the same animal response group”. By this definition
some papers produced multiple data points while in other instances data from multiple papers
were combined to give a single data point. We used the following methods to combine data:
Data split by taxonomic or functional group:
Before calculating the response ratio and variation we summed the means to obtain an overall
mean. To calculate the summed standard deviation we used the rule: The variance of the sum =
the sum of the variances.
Data split by sites:
If the sites were split according to habitat type (e.g. both grassland and forest sites were studied
and each habitat was analysed separately), then each habitat type was included as its own data
point (as if they were separate studies). If sites were split by criteria other than broad habitat
types (e.g. landscape position) we combined data from the different categories using the
methods described by Borenstein et al. (2009) for ‘multiple outcomes or time points within a
study’, treating the categories as ‘outcomes’. As we did not know the level of correlation
between among categories, we took the conservative approach and assumed a correlation
coefficient of 1 (which overestimates the variance). As a trial of the same calculations with a
correlation coefficient of 0 and 0.5 had little effect on the variation estimates, we believe this
assumption had little effect on the final outcome of the analysis.
Data split by a factorial treatment (e.g. in a fire x herbivory factorial design):
We attempted to produce data which was as consistent as possible to studies without factorial
treatments. If the factorial treatments were with/without a second factor we used only data from
sites without the factor. If this was not possible we then assessed whether the factor affected
56
herbivore pressure. If it did, we treated the study as if it had > 2 levels of herbivore pressure (as
described above). Failing either of these methods we combined data from across factors using
the same approach outlines above for data split by sites.
Data split by year or sampling events:
We combined data across time periods using the methods described by Borenstein et al. (2009)
for ‘multiple outcomes or time points within a study’. We again assumed a correlation
coefficient between time points of 1.
Weighting of Studies within Meta-Analysis
Standard practice when conducting a random-effects meta-analysis is to weight each score by
the inverse of its variance, so that more precise scores are given more weight in the analysis
(Borenstein et al. 2009). In addition to this, we also weighted all data points by the square root
of the number of years of sampling so that long-running studies were given more weight.
References
Borenstein, M., Hedges, L.V., Higgins, J.P.T. & Rothstein, H.R. (2009) Introduction to Meta-
Analysis. John Wiley & Sons Ltd, West Sussex.
Felton, A., Knight, E., Wood, J., Zammit, C. & Lindenmayer, D. (2010) A meta-analysis of
fauna and flora species richness and abundance in plantations and pasture lands. Biological
Conservation, 143, 545-554.
Rohatgi, A. (2012) Web Plot Digitiser v2.5. Available from
[http://arohatgi.info/WebPlotDigitizer/app/].
57
Table 1. Methods used to convert different types of data to means and standard errors. Data formats not included below were unable to be converted to means and standard errors so
were not included in the analysis.
Original Format of Abundance or Richness Measure
Conversion to Mean Original Format of Variation Measure
Conversion to SD
Population estimate Taken as mean Standard Error (SE) SD = SE * sqrt (n)
95% Confidence Interval (CI) SE = CI (1.96*2)
Geometric mean Taken as mean Geometric 95% CI SE = CI (1.96*2)
Median Taken as mean Interquartile Range (IQR) SD = (IQR/1.34)
Median (log scale - ln(m)) Mean = exp((ln(m)+(s2/2)) IQR (ln scale) s(ln scale) = (IQR/1.34) SD = mean*sqrt(exp(s2)-1)
P value of t-test SE = (diff in means / t @ (p/2, df)) * (sqrt(n)/sqrt(2))
Raw data Calculate mean Raw data Calculate SD
Table 2. Categories used to assess quality of evidence in reviewed papers. From Felton et al. 2010.
Category Quality of evidence presented
i Randomized controlled trial with matched pairs of treatments and controls. Study conducted at an adequate scale for subject taxa
ii Controlled trial of adequate scale for study organism. Unpaired treatments and controls
iii Unpaired treatments and controls. Scale of study raises potential of confounding effects for the subject taxa considered
iv Evidence deemed inadequate due to inherent problems with experimental design
58
Appendix S2. Details of the 96 papers included in the systematic review.
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Bailey & Whitham
2002 North America
Forest / Woodland
Cervus canadensis
Herbivore Exclusion, Simulation of Herbivory
gradient i Fire 1 Single class Arthropods - Overall
Bailey & Whitham
2003 North America
Forest / Woodland
Cervus canadensis
Herbivore Exclusion, Simulation of Herbivory
binary i none 2 Multiple classes
Birds Arthropods - Overall, Phytophagous Insects
Bailey & Whitham
2006 North America
Forest / Woodland
Castor canadensis
Natural Experiment
binary iv none 2 Single class Phytophagous Insects
Baines 1996 Europe Shrubland / Heath
Cervus elaphus, Sheep
Natural Experiment
binary ii Predator Control
1 Multiple classes
Birds Araneae, Coleoptera, Diptera, Hymenoptera, Hemiptera, Lepidoptera
Baines, Sage & Baines
1994 Europe Mixed Habitats
Cervus elaphus
Herbivore Exclusion
binary i none 2 Multiple classes
Araneae, Coleoptera, Diptera, Hemiptera, Hymenoptera, Lepidoptera, Plecoptera
Barrett & Stiling
2007 North America
Forest / Woodland
Odocoileus virginianus
Natural Experiment
gradient iii Nutrients 1 Single class Phytophagous Insects
Barton et al.
2011 Oceania Grassland / Savanna
Macropus giganetus
Herbivore Exclusion
binary i Log Addition
2 Single class Coleoptera
Berger et al.
2001 North America
Forest / Woodland
Alces alces Natural Experiment
binary iii none 1 Single class Birds
Bergstrom, Skarpe & Danell
2000 Africa Grassland / Savanna
Mixed ungulate assemblage
Simulation of Herbivory
gradient i none 1 Single class Phytophagous Insects
Bonal & Munoz
2007 Europe Forest / Woodland
Cervus elaphus
Herbivore Exclusion
binary iii none 2 single species
Beetles
59
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Bressette, Beck & Beauchamp
2012 North America
Forest / Woodland
Odocoileus virginianus
Herbivore Exclusion
binary i none 1 Multiple classes
Birds Arthropods - Overall, Araneae, Chilopoda, Coleoptera, Diplopoda, Hymenoptera
Brooks 1999 North America
Forest / Woodland
Odocoileus virginianus
Manipulation of herbivore density
binary iii Disturbance
3 single species
Amphibians
Buesching et al.
2011 Europe Forest / Woodland
Capreolus capreolus, Dama dama, Muntiacus reevesi
Herbivore Exclusion
binary i none 1 Single class Small mammals
Bush et al. 2012 Europe Forest / Woodland
Capreolus capreolus, Dama dama, Muntiacus reevesi
Herbivore Exclusion
binary i none 1 Single class Small mammals
Casey & Hein
1983 North America
Forest / Woodland
Cervus elaphus, Odocoileus virginianus, Ovus musimon
Herbivore Exclusion
binary iii none 1 Single class Birds
Christopher & Cameron
2012 North America
Forest / Woodland
Odocoileus virginianus
Herbivore Exclusion
binary i Weeds 2 Multiple classes
Arthropods - Overall, Acari, Araneae, Coleoptera, Collembola, Hymenoptera
Cumming et al.
1997 Africa Forest / Woodland
Loxodonta africana
Herbivore Exclusion
binary iii none 1 Multiple classes
Bats, Birds Hymenoptera, Orthoptera
Danell & Huss-Danell
1985 Europe Forest / Woodland
Alces alces Simulation of herbivory
binary i none 1 Multiple classes
Hymenoptera, Phytophagous Insects
60
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Decalesta 1994 North America
Forest / Woodland
Odocoileus virginianus
Manipulation of herbivore density
gradient i none 1 Single class Birds
Degraaf, Healy & Brooks
1991 North America
Forest / Woodland
Odocoileus virginianus
Natural Experiment
binary iii Tree Thinning
3 Single class Birds
Den Herder, Virtanen & Roininen
2004 Europe Forest / Woodland
Rangifer tarandus
Herbivore Exclusion
binary i Vegetation Age
2 Single class Coleoptera, Phytophagous Insects
Deveny & Fox
2006 North America
Shrubland / Heath
Odocoileus hemionus columbianus
Herbivore Exclusion
binary i none 1 Single class Small mammals
Feeley & Terborgh
2006 South America
Forest / Woodland
Alouatta seniculus
Natural Experiment
gradient iii none 1 Single class Birds
Gebeyehu, S. & Samways, M.
2006 Africa Grassland / Savanna
Mixed native ungulate assemblage, cattle, sheep
Natural Experiment
gradient iv none 3 Single class Grasshoppers
Gill & Fuller 2007 Europe Forest / Woodland
Capreolus capreolus, Dama dama, Muntiacus reevesi
Herbivore Exclusion
binary i Disturbance
5 Single class Birds
Goheen et al.
2004 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 1 Multiple classes
Small mammals Coleoptera, Hemiptera, Orthoptera
Goheen et al.
2010 Africa Grassland / Savanna
Mixed ungulate assemblage, Cattle
Herbivore Exclusion
gradient i none 3 single species
Small mammals
Goheen et al.
2013 Africa Grassland / Savanna
Mixed native ungulate assemblage
Herbivore Exclusion
binary i Rainfall 3 Multiple classes
Small mammals
61
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Gomez & Gonzalez Megias
2002 Europe Shrubland / Heath
Capra pyrenaica,
Sheep
Herbivore Exclusion
binary i none 3 Single class Coleoptera
Gomez & Gonzalez-Megias
2007 Europe Shrubland / Heath
Capra pyrenaica
Herbivore Exclusion
binary i none 6 Single class Phytophagous Insects
González-Megías, Gómez &Sánchez-PiÑero
2004 Europe Shrubland / Heath
Capra pyrenaica, Sheep, Goats
Herbivore Exclusion
binary iii none 2 Multiple classes
Arthropods - Overall, Coleoptera, Hymenoptera
Gough et al.
2012 North America
Mixed Habitats
Rangifer tarandus, mixed rodents
Herbivore Exclusion
binary i Nutrient addition
1 Multiple classes
Soil Invertebrates
Greenwald, Petit & Waite
2008 North America
Mixed Habitats
Odocoileus virginianus
Herbivore Exclusion
binary iv none 2 Multiple classes
Amphibians, Reptiles Arthropods - Overall, Gastropoda, Isopoda, Myriapoda, Oligochaeta
Hagenah, Prins & Olff
2009 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
gradient i none 2 Single class Small mammals
Herremans 1995 Africa Forest / Woodland
Loxodonta africana
Natural Experiment
binary iv none 2 Single class Birds
Hino 2000 Asia Forest / Woodland
Cervus nippon
Natural Experiment
binary iv none 4 Single class Birds
Hino 2006 Asia Forest / Woodland
Cervus nippon
Natural Experiment
gradient iv none 1 Single class Birds
Holt, Fuller & Dolman
2010 Europe Forest / Woodland
Capreolus capreolus, Dama dama, Muntiacus reevesi
Herbivore Exclusion
binary i Disturbance
10 single species
Birds
62
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Holt, Fuller & Dolman
2011 Europe Forest / Woodland
Capreolus capreolus, Dama dama, Muntiacus reevesi
Herbivore Exclusion
binary i Disturbance
3 Multiple classes
Birds Flying Insects, Phytophagous Insects
Holt, Fuller & Dolman
2013 Europe Forest / Woodland
Dama dama, Capreolus capreolus, Muntiacus reevesi
Herbivore Exclusion
binary i none 3 single species
Birds
Huffman et al.
2009 North America
Forest / Woodland
Cervus elaphus, Odocoileus hemionus
Herbivore Exclusion
binary ii none 3 Single class Arthropods - Overall
Huntzinger, Karban & Cushman
2008 North America
Mixed Habitats
Lepus californicus, Odocoileus hemionus
Herbivore Exclusion
binary ii none 2 Multiple classes
Gastropoda, Lepidoptera, Orthoptera
Ims et al. 2007 Europe Grassland / Savanna
Rangifer tarandus
Manipulation of herbivore density
binary i none 1 Multiple classes
Birds, Small Mammals
Jay-Robert et al.
2008 Europe Mixed Habitats
Cervus elaphus, sheep
Natural Experiment
binary iv none 2 Single class Coleoptera
Joern 2004 North America
Grassland / Savanna
Bos bison Manipulation of herbivore density
binary iii Fire 1 Single class Orthoptera
Joern 2005 North America
Grassland / Savanna
Bos bison Manipulation of herbivore density
binary iii Fire 1 Single class Orthoptera
Jonas & Joern
2007 North America
Grassland / Savanna
Bos bison Manipulation of herbivore density
binary iii Fire 1 Single class Orthoptera
63
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Jonsson et al.
2010 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
gradient iii none 1 Single class Araneae, Coleoptera, Hymenoptera, Orthoptera
Kanda et al. 2005 Asia Forest / Woodland
Cervus nippon
Natural Experiment
gradient iv none 1 Single class Coleoptera
Keesing 1998 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 2 Single class Small mammals
Keesing 2000 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 4 Single class Small mammals
Kuria et al. 2010 Africa Grassland / Savanna
Mixed ungulate assemblage, cattle
Herbivore Exclusion
gradient i none 1 Single class Coleoptera
Lessard et al.
2012 North America
Forest / Woodland
Odocoileus virginianus
Herbivore Exclusion
binary i none 1 Multiple classes
Arthropods - Overall, Acari, Araneae, Coleoptera, Collembola, Hymenoptera
Lind et al. 2012 North America
Forest / Woodland
Odocoileus virginianus
Herbivore Exclusion
binary i none 1 Single class Phytophagous Insects
Little, Hockey & Jansen
2013 Africa Grassland / Savanna
Mixed native ungulate assemblage
Herbivore Exclusion
binary iii Fire 2 Multiple classes
Birds Arthropods – Overall, Orthoptera
Manning, Cunningham & Lindenmayer
2013 Oceania Mixed Habitats
Macropus giganetus
Herbivore Exclusion
binary i Log Addition, Vegetation Density
4 Single class Reptiles
Martin & Maron
2012 North America
Forest / Woodland
Cervus canadensis
Herbivore Exclusion
binary i none 7 Single class Birds
Martin, Arcese & Scheerder
2011 North America
Forest / Woodland
Odocoileus hemionus
Natural Experiment
gradient ii none 1 Single class Birds
64
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Martinsen, Driebe & Whitham
1998 North America
Forest / Woodland
Castor canadensis
Natural Experiment
binary iv none 1 single species
Coleoptera
Mathisen & Skarpe
2011 Europe Forest / Woodland
Alces alces Manipulation of herbivore density
gradient iii Nutrient addition
1 Single class Birds
Mathisen et al.
2012 Europe Forest / Woodland
Alces alces Manipulation of herbivore density
gradient iii none 5 Single class Birds
Matlack, Kaufman & Kaufman
2001 North America
Grassland / Savanna
Bos bison, Cattle
Manipulation of herbivore density
binary iii Fire 2 single species
Small mammals
McCauley et al.
2006 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 3 Multiple classes
Reptiles, Small Mammals
McCauley et al.
2008 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 2 Multiple classes
Small mammals Parasitic Invertebrates
McShea & Rappole
2000 North America
Forest / Woodland
Odocoileus virginianus
Herbivore Exclusion
binary i none 9 Single class Birds
Melis et al. 2006 Europe Forest / Woodland
Cervus elaphus
Natural Experiment
gradient iv none 1 Single class Coleoptera
Melis et al. 2007 Europe Forest / Woodland
Alces alces Natural Experiment
gradient iv none 1 Single class Coleoptera
Mohr, Cohnstaedt & Topp
2005 Europe Forest / Woodland
Cervus elaphus
Herbivore Exclusion
binary iii Disturbance
2 Multiple classes
Arthropods - General, Araneae, Isopoda
Moser & Witmer
2000 North America
Grassland / Savanna
Cervus elaphus, Cattle
Herbivore Exclusion
binary i none 1 Multiple classes
Birds, Small Mammals
Neff, Fettig & VanOverbeke
2007 North America
Mixed Habitats
Cervus elaphus
Herbivore Exclusion
binary i none 4 Single class Lepidoptera
65
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Newson et al.
2012 Europe Forest / Woodland
Capreolus capreolus, Dama dama, Muntiacus reevesi
Natural Experiment
gradient i none 11 Single class Birds
Nkwabi et al.
2011 Africa Grassland / Savanna
Connochaetes sp.
Natural Experiment
binary iii Fire 1 Multiple classes
Birds Arthropods - Overall
Ogada et al.
2008 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
gradient i none 2 Multiple classes
Birds Arthropods - Overall
Olofsson & Strengbom
2000 Europe Grassland / Savanna
Rangifer tarandus
Herbivore Exclusion
binary ii none 2 Multiple classes
Phytophagous Insects
Palmer et al.
2008 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 1 Multiple classes
Arthropods Overall, Coleoptera, Hymenoptera
Parsons, Maron & Martin
2013 North America
Forest / Woodland
Odocoileus hemionus
Herbivore Exclusion
binary i none 6 Single class Small mammals
Pedersen, Nilsen & Andreassen
2007 Europe Forest / Woodland
Alces alces Manipulation of herbivore density
binary ii none 2 Multiple classes
Birds Arthropods - Overall
Pringle 2008 Africa Grassland / Savanna
Loxodonta africana
Simulation of herbivory
binary i none 3 single species
Reptiles
Pringle et al.
2007 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i Nutrients 2 Multiple classes
Reptiles Arthropods - Overall, Coleoptera
Rambo & Faeth
1999 North America
Grassland / Savanna
Cervus elaphus, Odocoileus hemionus, Cattle
Herbivore Exclusion
binary i none 1 Multiple classes
Arthropods - Overall
Roininen, Price & Bryant
1997 North America
Mixed Habitats
Alces alces, Lepus americanus
Herbivore Exclusion
binary i none 1 Single class Phytophagous Insects
66
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Saetnan & Skarpe
2006 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
binary i none 1 Single class Small mammals
Schwenk & Strong
2011 North America
Forest / Woodland
Alces alces Natural Experiment
gradient iii none 2 Single class Lepidoptera
Seki and Koganezawa
2013 Asia Forest / Woodland
Cervus nippon
Herbivore Exclusion
binary iv none 1 Multiple classes
Small mammals Coleoptera, earthworms
Shibata, Saito & Tanaka
2008 Asia Forest / Woodland
Cervus nippon
Herbivore Exclusion
binary iii none 1 Single class Small mammals
Shimazaki & Miyashita
2002 Asia Forest / Woodland
Cervus nippon
Herbivore Exclusion
binary iii none 2 Single class Phytophagous Insects
Smit et al. 2001 Europe Mixed Habitats
Capreolus capreolus, Cervus elaphus, Ovis ammon musimon
Herbivore Exclusion
binary i none 1 Single class Small mammals
Spalinger et al.
2012 Europe Grassland / Savanna
Cervus elaphus, Rupicapra rupicapra
Natural Experiment
binary iv none 1 Multiple classes
Orthoptera
Suominen 1999 Europe Forest / Woodland
Alces alces, Rangifer tarandus
Herbivore Exclusion
binary i none 1 Single class Gastropoda
Suominen et al.
2003 Europe Forest / Woodland
Rangifer tarandus
Herbivore Exclusion
binary i Nutrients 1 Single class Coleoptera
Suominen et al.
2008 Europe Forest / Woodland
Alces alces Simulation of herbivory
gradient i Nutrients 1 Multiple classes
Araneae, Hemiptera, Flying Insects
Suominen, Danell & Bryant
1999 North America
Mixed Habitats
Alces alces Herbivore Exclusion
binary i none 1 Multiple classes
Coleoptera, Orthoptera
67
Authors Year Pub.
Study Location (continent)
Study ecosystem
Herbivore(s) Studied*
Study Design Contrasts Data Quality Score
Interacting Factors
Study Duration (years)
# taxonomic groups studied
Animal Taxa Studied
Suominen, Danell & Bergström
1999 Europe Forest / Woodland
Alces alces Herbivore Exclusion
binary i none 1 Multiple classes
Arthropods - Overall, Acari, Araneae, Blattodea, Chilipoda, Coleoptera, Diplopoda, Diptera, Hemiptera, Hymenoptera, Isopoda, Gastropoda, Nemastomatidae, Psocoptera, Phalangiidae
Tabuchi, Ueda & Ozaki
2010 Asia Forest / Woodland
Cervus nippon
Herbivore Exclusion
binary ii none 1 single species
Phytophagous Insects
Takada et al.
2008 Asia Forest / Woodland
Cervus nippon
Natural Experiment
gradient iii none 1 Single class Araneae
Warui et al. 2005 Africa Grassland / Savanna
Mixed ungulate assemblage
Herbivore Exclusion
gradient i none 2 Single class Araneae
* Wild herbivores (native or exotic) denoted with scientific name. Domestic stock uses common name.
68
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Supplementary Tables
Table S1. Mechanisms driving the effects of large herbivores on other animals. Counts indicate the number of papers where authors conclude that mechanism to be important for
driving the effect of large herbivores on a particular animal group. The most common mechanism(s) for each taxonomic group appears in bold.
Mechanism
Number of papers concluding mechanism to be important
For any taxa
Birds Small mammals
Arthropoda Araneae Coleoptera Hemiptera Hymenoptera Lepidoptera Orthoptera
Vegetation biomass 48 14 12 6 1 6 1 1 1 4
Vegetation structure 47 21 9 5 3 5
2 4
Via changes in other animals (e.g. prey) 17 7 2 2 2 1
Vegetation chemistry / nutrient quality 13
1
2
1
Vegetation species composition 13 4
1 1 2 1 1 3
Physical environment 10
1 3 2 5 1 2
Direct interference 5
1
2
Nutrient input/cycling (e.g. dung) 2
2
Total number of papers giving any conclusions
84 26 14 11 5 17 2 4 1 6
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Table S2. Recommendations for future research given by authors. We sorted recommendations according to whether they were related to research topic or to the design of future
studies. Fifty one of the 96 papers contained specific recommendations for future research.
Recommendation Number of papers
Research Topic
Cascading effects on other species or ecosystem processes 19
Mechanisms of effects 11
Novel habitats or locations 7
Interacting factors 7
Study Design
Larger spatial scales / spatial variation in responses 6
Studies able to detect both direct and indirect relationships 5
Studies able to detect the shape of herbivory responses 3
Long-term studies to distinguish between state shifts and short-term fluctuations
3
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Supplementary Figures
Figure S1. Distribution of the 96 reviewed papers by (a) continent and study system, (b) focal
herbivores, (c) number of animal response groups studied, (d) animal response groups:
class of vertebrates and (e) animal response groups: most common invertebrate orders.
Studies which belonged to more than one category were counted in both.
a.
b. c.
d. e.
0
5
10
15
20
25
30
35
NorthAmerica
Europe Africa Asia Oceania SouthAmerica
Num
ber
of
papers
Study location
Multiple habitats
Heath / Shrubland
Grassland / Savanna
Forest / Woodland
0
10
20
30
40
50
60
Single sp. Single class Multipleclasses
Num
ber
of
papers
Number of taxa studied
Both
Vertebrates
Invertebrates
0
10
20
30
40
50
60
70
80
Num
ber
of
papers
Order of focal herbivores
Not over-abundant
Over-abundant
0
5
10
15
20
25
Num
ber
of
papers
Animal response groups: Invertebrate orders
0
5
10
15
20
25
Num
ber
of
papers
Animal response groups: Vertebrate classes
78
Figure S2. Studies returned by our initial search which studied the effects of terrestrial
mammalian herbivores on other animals, sorted by the status of the focal herbivores
(native, exotic or livestock). Not all studies included under ‘native’ were included in the
final review as a number did not meet all criteria due to factors such as size of
herbivores, absence of contrasts etc. (see Appendix S1 for full details).
Native
LivestockExotic
75
12
154114
12
0
79
Figure S3. The distribution of experimental approaches (a.), contrasts (b.) and exclusion
method (c.) used by studies published in each five year period. The frequency of studies
using each of the experimental approaches did not vary among time periods (P = 0.29).
The frequency of studies employing more than two levels of herbivory, and including
selective exclusion fences was higher among studies published since 2004 (P = 0.03
and P = 0.017).
a.
b.
c.
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Paper II: Herbivory and fire interact to affect forest understory habitat, but not its use by small vertebrates
In Paper I, I found that large herbivores can have substantial effects on the abundance and
diversity of other animal groups. However, I also found that few studies have investigated the
impacts of Australian native herbivores, and that knowledge of how large herbivores interact
with episodic disturbances remains limited. In this paper, I experimentally tested for the
interactive effects of prescribed fire and macropod herbivores (kangaroos and wallabies) on
forest understorey vegetation and small vertebrate fauna.
Foster, C.N., Barton, P.S., Sato, C.F., Wood, J.T., Macgregor, C.I., and D.B. Lindenmayer
(2016) Herbivory and fire interact to affect forest understory habitat, but not its use by small
vertebrates. Animal Conservation. 19, 15-25.
82
Abstract
Herbivory and fire are two disturbances which often co-occur, but studies of their interactive
effects are rare outside of grassland ecosystems. We experimentally tested the interactive effects
of prescribed fire and macropod herbivory on forest understory vegetation and its vertebrate
fauna. Fire and herbivory interacted synergistically to affect forest understory vegetation, with
palatable plants showing poor post-fire recovery in un-fenced sites compared with herbivore
exclusion sites. Despite this strong interactive effect on vegetation, small vertebrates responded
to the individual, and not the interactive effects of disturbance. The native insectivorous
mammal Antechinus stuartii was more frequently encountered on large herbivore exclusion
sites, as was the introduced European rabbit. In contrast, the small skink Lampropholis delicata
was more common on sites with high densities of large herbivores. Skinks, snakes and
European rabbits were also more active on burnt than unburnt sites. Our results suggest that it
may be necessary to manage the macropod herbivore population after fire to prevent the decline
of palatable plants, and maintain the dense habitat required by some small mammals. However,
as the invasive rabbit was most active in macropod-free sites after fire, any management must
include control of both types of herbivores. A mix of understory densities may also need to be
maintained to ensure the persistence of species preferring more open habitats. Our study
demonstrates that interactive effects of disturbance on vegetation communities may not lead to
predictable effects on animals, and highlights the importance of considering both multiple
stressors, and multiple species, in the management of disturbance regimes.
Keywords
Disturbance interaction, browsing, grazing, indirect effects, kangaroo, synergistic effects
Introduction
Disturbance regimes play a central role in ecosystem dynamics (Willig and Walker, 1999).
However, in many parts of the world, natural disturbance regimes have been disrupted, with
unwanted outcomes for biodiversity (Hobbs and Huenneke, 1992, Sinclair and Byrom, 2006).
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Thus, many biodiversity conservation programs aim to reinstate natural disturbance regimes
(Fuhlendorf et al., 2010, Noss et al., 2006), but achieving this in systems where multiple
disturbances co-occur may be difficult. Co-occurring disturbances can interact to produce
distinctly different outcomes from what would be expected based on individual effects (Didham
et al., 2007, Tylianakis et al., 2008) and a poor understanding of these interactions can lead to
unexpected and undesirable management outcomes (Lindenmayer et al., 2010, Tylianakis et al.,
2008).
The importance of disturbance interactions for structuring grasslands and heathlands has
been widely recognised, and re-establishing fire-grazing interactions is identified as a priority
for maintaining biodiversity in these habitats (Fuhlendorf et al., 2010, Van Langevelde et al.,
2003). However, understanding of how fire and herbivory interact to affect species in forested
habitats remains limited (Foster, Barton and Lindenmayer, 2014, Royo et al., 2010, Wisdom et
al., 2006). As the interactive effects of fire and herbivory depend on the scale, intensity and
timing of these disturbances, the outcome of interactions can be highly variable (Fuhlendorf et
al., 2010, Wisdom et al., 2006). For example, at a local-scale, deer browsing after fire supressed
dominant shrub species, increasing herbaceous plant richness in a forest understory (Royo et al.,
2010). Conversely, heavy macropod herbivory following fire limited grass and forb recovery
(Tuft, Crowther and McArthur, 2012). At a larger scale, Bailey and Whitham (2002) found that
elk (Cervus canadensis) browsed more heavily in areas of aspen (Populus tremuloides) that
burned at high intensity, compared with moderate intensity. This heavy browsing reversed the
positive effect of browsing on arthropod richness that occurred after moderate intensity fire.
While such studies indicate that fire-herbivory interactions are likely to be prevalent in forested
ecosystems (Royo and Carson, 2006), investigations of animal responses to the combined
effects of these disturbances remain rare (Foster et al., 2014, Wisdom et al., 2006).
We combined prescribed fire and large herbivore exclusion treatments to test the
interactive effects of fire and herbivory on understory vegetation and small vertebrates in a
temperate forest ecosystem. As the management of disturbances is often targeted at plants, with
the assumption that this will also cater for the needs of animals (Clarke, 2008), it is important to
84
understand whether such assumptions are valid, and whether fauna respond in a predicable way
to disturbances. Our study addressed the following questions: (1) How do fire, herbivory and
their interaction affect understory habitat structure at the site level? (2) How do these
disturbances affect site occupancy by small vertebrate fauna? We expected that vertebrate
species would respond differently to the experimental treatments due to differences in their
habitat and dietary preferences, and that these responses would be mediated by changes in
vegetation structure. For example, we expected that both fire and herbivory would reduce
understory cover, and lead to negative effects on site occupancy by vertebrates preferring dense
understory habitats (Table 1). We provide recommendations for biodiversity conservation based
on our findings.
Table 1. Predicted effects of fire and large herbivores on habitat and food resources for vertebrates and
the corresponding predicted responses of two small mammal and two reptile species, based on
their diet and habitat preferences. Habitat preferences are attributes which have been associated
with higher abundance in forest habitat for that species.
Response group Habitat preference Diet Predicted response
Fire Herbivores
Habitat and food resources
Understory cover - -
Understory height - -
Leaf litter depth - None
Fresh plant growth + -
Invertebrate prey - -
Vertebrates
European rabbit (Oryctolagus cuniculus)
Open understory a Forbs and grasses b
+ -
Brown antechinus (Antechinus stuartii)
Dense, complex understory a,c
Tall understory d
Abundant logs d
Invertebrates c - -
Delicate skink (Lampropholis delicata)
High canopy cover e Deep litter f,g Tall understory g
Invertebrates e - ?
Eastern small-eyed snake (Cryptophis nigrescens)
Warm diurnal refuge h Skinks h + ?
aCatling and Burt (1995), b Davis, Coulson and Forsyth (2008), c Bennett (1993), d Knight and Fox (2000), e Bragg, Taylor and Fox (2005), f Taylor and Fox (2001), g Howard, Williamson and Mather (2003), h Webb et al. (2004)
85
Materials and methods
Study site
We conducted our study in Booderee National Park (BNP); a ~ 65 km2 peninsula in south-
eastern Australia (35°10′S, 150°40′E). We established sites within Eucalyptus pilularis forest,
which is the most widespread vegetation type in BNP (Taws, 1998). An intensive fox (Vulpes
vulpes) baiting program has been conducted in BNP since 1999 to protect native species from
predation (Dexter et al., 2012). Over the last decade, there has been a tenfold increase in native
herbivores in BNP (predominantly swamp wallaby, Wallabia bicolor, and eastern grey
kangaroo, Macropus giganteus), which is attributed to reduced predation by foxes
(Lindenmayer et al., 2014). Small-scale exclosure trials indicate that this high abundance of
herbivores could be driving changes in vegetation composition (Dexter et al., 2013), and there is
concern about flow-on effects for smaller vertebrates, which include a number of threatened
species (Dexter et al., 2012). As fire is a naturally occurring disturbance within BNP, occurring
both as wildfire and low-intensity prescribed burning (Lindenmayer et al., 2008), it is important
to understand how native herbivores interact with fire regimes.
Study design
We quantified the interactive effects of fire and herbivory on vegetation and small vertebrates
using a randomised blocked experiment. We combined three levels of large herbivore exclosure
and two levels of burning treatment in a factorial design (Appendix 1). We replicated each
treatment combination across four blocks to give 24 sites. For the exclosure treatments, we
excluded macropod herbivores from 25 × 25 m sites, using 1.1 m tall wire fencing, in June
2012. We created three levels of herbivore exclosure treatment: high activity (open treatment –
no fence), intermediate activity (partial treatment – sites were fenced but gates opened and
closed at two month intervals to simulate lower herbivore pressure), and no large herbivores
(exclosure treatment). For the burnt treatments, we conducted 50 × 50 m burns in August 2012,
with the 25 x 25 m site in the centre of the burnt area. Fire was low-intensity, removing
86
approximately 95% of understory vegetation and did not reach the canopy (scorch height 1.5 - 4
m) or burn large logs.
Data collection
We surveyed understorey vegetation prior to treatment in April/May 2012 and repeated surveys
biannually until May 2014. We sampled four 3 × 3 m quadrats in each site, with each quadrat at
least 1.5 m from the fence. We recorded four vegetation variables, representing important
attributes of fauna habitat; total understorey projective cover (%), projective cover of bracken
(Pteridium escelentum) (%), understorey height (averaged across 10 locations per quadrat using
the stick-and-disc method of Smit et al. (2001); disc 100 mm diameter, 4.7 g weight) and litter
depth (averaged across 10 locations per quadrat).
We surveyed macropod herbivore activity by counting scats along two 25 × 2 m
transects (100 m-2) per site, summing counts to give one count per site. As macropods defecate
more while feeding than resting (Johnson, Jarman and Southwell, 1987), pellet counts can give
a comparative measure of macropod feeding pressure between sites (Howland et al., 2014). We
surveyed transects every two months from August 2012 to May 2014, removing scats after each
survey to avoid re-counting. We also monitored European rabbit (Oryctolagus cuniculus)
activity using these transects, counting the number of rabbit diggings every two months from
June 2013 to May 2014.
We surveyed site use by small mammals through live trapping in April/May 2012 and
then every six months until May 2014. For each survey, we set eight Elliott traps per site for
four consecutive nights. We ear marked animals with a permanent marker to identify recaptures
within a survey.
We monitored reptiles using iron sheeting as artificial substrates. We set out four 1 × 1
m sheets per site in July 2012, and checked them on two consecutive mornings approximately
every two months from October 2012 to May 2014. To minimise biases due to time of day, we
rotated the order of site checking so that each site had one early morning and one late morning
check per sampling period. To address non-independence of counts within a survey, we used the
87
maximum value of the two consecutive counts for each species. Weather conditions meant that
some surveys returned few individuals. Therefore, for data analysis, we excluded surveys with
fewer than three detections for that species.
To measure arthropod prey availability, we sampled ground-dwelling beetles and
spiders using pitfall traps, counting the total captures per trap. We deployed four 250ml (100
mm diameter) traps per site (2/3 filled with non-toxic polyethylene glycol solution) for two
weeks in November 2012 and 2013.
Data analysis
To assess how fire-herbivory interactions affected habitat structure (question 1), and fauna
occupancy (question 2) we tested treatment effects on dependent variables using linear mixed
models (LMMs) for vegetation variables and generalised linear mixed models (GLMMs) with
Poisson errors for animal counts. Vegetation variables were understory cover (%), understory
cover excluding bracken (%, total understory cover minus cover of bracken), understory height
(m), and leaf litter depth (mm). We analysed understory cover excluding bracken because
bracken is a dominant, unpalatable species which could mask responses of other plants. Bracken
also provides little of the ground-level structure important for small vertebrates (Bennett, 1993).
Animal count variables were macropod scats, rabbit diggings, antechinus captures, delicate
skink (Lampropholis delicata) and eastern small-eyed snake sightings (Cryptophis nigrescens),
and spider and beetle captures.
We fitted each dependent variable with the full fixed effects model of herbivores ×
burning × time, and random effects of block/site/quadrat for vegetation and block/site for
animal variables to account for the repeated measures. A first-order auto-regressive covariance
structure on the random effects was trialled for the vegetation LMMs but was not used as it did
not improve model fit (ΔAIC < 2, Pinheiro and Bates, 2000). We did not define a covariance
structure for animal responses as inspection of residuals indicated little evidence of temporal
autocorrelation, and methods for fitting such structures with GLMMs are not well developed
(Zuur et al., 2009). We used Akaike information criterion, corrected for small sample size
88
(AICc), to select the most parsimonious model from all possible subsets of the full model (19
models) (Burnham and Anderson, 2002). If models within two AICc of the top ranked model
included predictors not included in the top model, we also discussed these alternate models. We
excluded pre-treatment surveys from analyses to avoid spurious time × treatment interactions.
The properties of some animal variables meant that adjustments to the full model were
necessary. Specifically, to adjust for over-dispersion of macropod scat data (φ = 6.9), rabbit
digging data (φ = 2.7) and arthropod data (φ = 3.1), we added an observation-level random
effect to the models for these variables (Harrison, 2014). Further, for the macropod model, we
divided the partial herbivore treatment into two categories: partial – open months, and partial –
closed months, to better describe this treatment. As there were low numbers of macropod scats
in exclosure and partial – closed month treatments, they were excluded from this analysis. For
the GLMM of antechinus captures, we ran model selection on all subsets of the full model of
herbivores × burning × time, plus an alternate model with ‘season’ substituted for ‘time’ (giving
33 different models for comparison). This accounted for the strong seasonal variation in
antechinus abundance (Lazenby-Cohen and Cockburn, 1991). Finally, as low mean counts for
the two reptile species meant some models including the burn × time fixed effect did not
converge, we excluded five models for the delicate skink and three models for the small-eyed
snake from model comparisons. LMMs were performed using the lme function in the package
MASS, GLMMs using the glmer function in the package lme4 and AICc model ranking using
the package AICcmodavg, within R version 3.0.1 (R Core Team, 2013).
Results
Vegetation structure
Vegetation structure responded both to the burning and herbivore exclosure treatments, as well
as their interaction (Table 2). Understory vegetation cover at unburnt sites declined in open and
partial treatments over time, but remained stable in exclosure sites (Fig. 1a). After an initial
reduction after fire, a similar decline was observed for burnt, open sites. However, burnt partial
89
and exclosure sites remained stable. (Fig. 1a, Appendix 2). When bracken was excluded from
understory cover, there was a strong exclosure × time interaction, as cover on open and partial
exclosure sites declined or remained low, while on full exclosure sites cover increased through
time (Fig. 1b, Appendix 2). The burning × time interaction was also important, as non-bracken
vegetation increased over time on all burnt sites. Compared with other treatments, burnt, open
sites had a high proportion of bracken, with very little non-bracken vegetation present across all
time periods (Fig. 1b). Both understory height and leaf litter depth responded to the burning ×
time interaction, but not to any other interaction terms (Table 2). Understory height was reduced
by fire but had recovered after 21 months (Fig. 2a). Litter depth recovered more slowly,
remaining lower in burnt than unburnt sites across all time periods (Fig. 2b). The second ranked
model for understory height also included an exclosure main effect, where vegetation was
slightly taller on exclosure than on open sites (Appendix 2).
90
Table 2. Model rankings for linear mixed models (LMMs, vegetation) and generalised linear mixed
models (GLMMs, animals), testing the fixed effects of burning (B - burnt or unburnt), exclosure
(E - open, partial or full exclosure), time (T - sampling event - categorical), and their interactions
on vegetation structure and animal occurrence. For brown antechinus, we also ran model ranking
on all subsets of a model with season (S - autumn or spring) substituted for time (i.e. B*E*S), to
account for the strong seasonal variation in the abundance of this species. K is the number of
parameters estimated in the model, Δ AICc is the change in Aikaike’s Information Criterion
(corrected for small sample size) from the best-ranked model. AICcWt is the Aikine Weight of
the model, LL is the Log-likelihood.
Data Model terms K Δ AICc AICcWt LL
LMMs
Understory cover B + E + T + B:T + E:T + B:E + B:E:T 28 0 0.97 -1454.7
Cover excluding bracken B + E + T + B:T + E:T 20 0 0.74 -1389.6
Vegetation height B + T + B:T 12 0 0.61 266.5
B + E + T + B:T 14 1.59 0.28 267.8
Litter depth B + T + B:T 12 0 0.82 -429.5
GLMMs
Macropod scats B + Ea + T 15 0 0.6 -500.6
Rabbit diggings T 9 0 0.37 -441.0
E + T 11 1.09 0.21 -439.2
B + T 10 1.64 0.16 -440.7
Brown antechinus E + season 6 0 0.36 -172.0
B + E + season 7 1.4 0.18 -171.5
Delicate skink B + E + T 13 1.01 0.46 -162.8
B + T 11 1.35 0.39 -165.3
Eastern small-eyed snake B 4 0 0.67 -60.4
Beetles and spiders T 5 0 0.61 -187.4
B + T 6 1.85 0.24 -187.0
a Compares only partial-open months with open treatment (see methods)
91
Figure 1. Vegetation structural responses to exclosure and burning treatments across sampling
periods, (a) total understory percent cover, and (b) understory percent cover, excluding
bracken (Pteridium esculentum). Values post-treatment are predicted means and
estimated SE from the top-ranked models. Pre-treatment data (May 2012) were not
included in the LMM, but are presented here (mean and SE) to allow comparison with
post-treatment data. Arrows indicate timing of prescribed burning.
Co
ver
exc
l. b
racke
n (%
)U
nd
ers
tory
co
ver
(%)
Aut'12 Spr'12 Aut'13 Spr'13 Aut'14
0
10
20
30
40
50
60(a)
(b)
Time period
Open Partial Exclosure
Aut'12 Spr'12 Aut'13 Spr'13 Aut'14
Burnt
Unburnt
0
10
20
30
40
50
60
Aut'12 Spr'12 Aut'13 Spr'13 Aut'14
92
Figure 2. Response of understory height (a) and leaf litter depth (b) to burning treatment across
time periods. Values post-treatment are predicted means and SE from the top-ranked
models. Pre-treatment data (May 2012) were not included in the LMM, but are
presented here (mean and SE) to allow comparison with post-treatment data. Arrows
indicate timing of prescribed burning.
Vertebrate responses
Exclosure treatments successfully excluded macropod herbivores, with very low scat counts in
exclosure treatments (�̅� = 0.71 ± 0.52). When partial treatment gates were open, scat counts
were 56% lower in partial than in open treatments (Fig. 3a). Macropods also responded to
burning, showing higher activity in burnt than unburnt sites (Table 2, Fig 3). There were three
competing models for rabbit diggings, with models including time, time plus exclosure and time
plus burning all explaining similar levels of variation in the data (Table 2). Rabbit activity
peaked in summer and tended to be higher in sites without macropods (partial and full exclosure
treatments) and in burnt sites (Fig. 4, Appendix 2).
0
0.1
0.2
0.3
0.4
0.5
0.6
BurntUnburnt
0
10
20
30
40
50
60
(a)
(b)
Time period
Un
de
rsto
ry h
eig
ht (
m)
Litte
r d
ep
th (m
m)
May '12 Nov '12 May '13 Nov '13 May '14
93
Figure 3. Number of macropod scats in burnt and unburnt sites through time in open (a) and
partial exclosure sites (b). Note that closed months of the partial exclosures (Nov 2012,
Apr 2013 etc.), and full exclosure sites were not included in the analysis as means for
this group were too low to allow model fit. Values for open sites and partial-open
months are predicted means and estimated SE from the top-ranked model. Arrows
indicate timing of prescribed burning (note Aug ’12 counts were after implementation
of herbivory treatments but before burning treatment).
Brown antechinus captures were highest in herbivore exclusion sites, and in Autumn
(May) surveys (Table 2, Fig. 5). The second ranked model also included burning as a fixed
effect (Table 2), where antechinus captures were slightly lower in burnt than unburnt sites
(Appendix 2). Both the delicate skink and the eastern small-eyed snake were encountered more
frequently in burnt sites than unburnt sites (Table 2, Fig. 6, Appendix 2). Delicate skink
numbers also tended to be higher in open and partial than in full exclosure sites and were higher
in the first survey (three months post-fire), than at any other time (Table 3, Fig, 6). Beetles and
spiders captures were 65% higher in the first year (2012, �̅� = 31.3 ± 3.1) than the second (2013,
�̅� = 18.9 ± 1.96), and the second ranked model indicated that captures were also slightly higher
in burnt than in unburnt sites (Table 2, Appendix 2).
94
Figure 4. Number of rabbit (Oryctolagus cuniculus) diggings per site in the different exclosure
treatments (a) and burning treatments (b) over time. Values are predicted means and
estimated SE from the 2nd (a) and 3rd (b) ranked models respectively. The effect of time
alone (first-ranked model) can be clearly seen in both plots.
Figure 5. Number of individual brown antechinus (Antechinus stuartii) captured per site in
different seasons and herbivory treatments. Values post-treatment are predicted means
and SE from the top-ranked model based on two years of data (November 2012 to May
2014). Pre-treatment data (May 2012) were not included in the GLMM, but are
presented here (mean and SE) to allow comparison with post-treatment data.
0
5
10
15
20
25
Jun '13 Aug '13 Oct '13 Dec '13 Feb '14 Apr '14Nu
mb
er o
f ra
bb
it d
igg
ing
s BurntUnburnt
0
5
10
15
20
25
Nu
mb
er o
f ra
bb
it d
igg
ing
s OpenPartialExclosure
(a)
(b)
Time period
0
1
2
3
4
5
May May November
Nu
mb
er o
f in
div
idu
als Open
PartialExclosure
Pre-treatment Post-treatment
Season
95
Figure 6. Number of delicate skinks (Lampropholis delicata) detected under artificial substrates
in the different burning and exclosure treatments across time. Values are predicted
means and SE from the top-ranked model.
Discussion
Fire and herbivory can interact strongly in space and time to shape the structure of vegetation
communities (Koerner and Collins, 2014, Royo and Carson, 2006, Van Langevelde et al.,
2003). However, animal responses to the fire × herbivory interaction are rarely studied (but see
Fuhlendorf et al., 2010, Kimuyu et al., 2014, Kutt and Woinarski, 2007). In our experimental
test of the interactive effects of fire and large herbivores, we found that forest understory
structure responded to the fire × herbivore exclosure interaction, but vertebrate site occupancy
was affected only by the individual effects of disturbance. This suggests that local changes in
vegetation structure may not be an adequate predictor of animal responses to disturbance and
that animals warrant individual consideration for the management of ecosystems that are subject
to both recurring fire and herbivory.
Question 1: Changes to habitat structure
As expected, fire and herbivory both affected habitat structure, and effects differed with
disturbance type. The limited recovery of non-bracken vegetation on burnt sites with high
densities of large herbivores (Fig. 1), was consistent with previous studies (Meers and Adams,
0.0
0.5
1.0
1.5
2.0
2.5
3.0
Nov'12
Feb'13
Apr'13
Jun'13
Aug'13
Oct'13
Dec'13
Apr'14
Nov'12
Feb'13
Apr'13
Jun'13
Aug'13
Oct'13
Dec'13
Apr'14
Nov'12
Feb'13
Apr'13
Jun'13
Aug'13
Oct'13
Dec'13
Apr'14
Burnt
Unburnt
Nu
mb
er o
f skin
ks
Time period
Open Partial Exclosure
96
2003, Tuft et al., 2012). Both of these previous studies attributed the stronger effect of
herbivory on burnt sites to greater herbivore pressure, driven by the attraction of herbivores to
the fresh plant growth following fire. This is a commonly reported mechanism explaining fire ×
herbivore interactions (Klop, van Goethem and de Iongh, 2007), for which we also found
evidence, as indicated by macropod activity being greatest on recently burnt sites (Fig. 2b).
In contrast to the non-bracken vegetation, bracken recovered well in burnt, open sites,
and made up a large proportion of the vegetation in these sites (Fig. 1). Bracken can regenerate
rapidly following fire and suppress other plants. However, after an initial post-fire pulse,
bracken cover usually declines over time, as other plants become dominant (Tolhurst and
Turvey, 1992). Our results indicate that abundant macropod herbivores may be disrupting this
successional process by selectively feeding on more palatable vegetation, maintaining the
bracken-dominated understory. As prescribed fire is commonly used in this system to reduce
forest fuel loads and promote vegetation heterogeneity and floristic diversity (Morrison et al.,
1996), our results suggest that herbivore management following fire may be important to
maintain a heterogeneous forest flora.
Question 2: Habitat use by vertebrates
Despite the strong effect of the fire × herbivory interaction on vegetation, habitat use by
vertebrates was affected only by the individual effects of disturbances and not their interaction.
The increased rabbit activity we observed on herbivore exclusion and recently burnt sites was
consistent with previous studies of small herbivore responses to large herbivore removal
(Keesing, 1998) and fire (Leigh et al., 1987, Moreno and Villafuerte, 1995). Competitive
release of small herbivores following a reduction in large herbivore densities can result in
increased herbivory by small herbivores, with subsequent impacts on vegetation communities
(Lagendijk, Page and Slotow, 2012). Our results suggest that control of native macropod
herbivores may favour introduced rabbits, particularly after fire when fresh plant growth is
abundant. Therefore, management of the native herbivore population should carefully consider
97
the potential for competitive release of the European rabbit, which is a destructive pest species
in Australia (Davey et al., 2006).
Antechinus responded positively to large herbivore exclusion, with more individuals
captured in sites without macropod herbivores, regardless of burning treatment. Despite the
small size of our exclosures, this response likely indicates a preference for herbivore exclusion
areas, as antechinus have small foraging ranges (approximately 0.4 ha for females and 0.9 ha for
males, Lazenby-Cohen and Cockburn, 1991). Further, our result is consistent with Pedersen et
al. (2014), who found that antechinus captures were negatively correlated with wallaby density.
The preference of antechinus for sites without large herbivores may have been due to the dense
understory cover in exclosure sites (Bennett, 1993, Knight and Fox, 2000), providing increased
foraging habitat (antechinus are scansorial) and/or greater protection from predators (e.g. Stokes
et al., 2004). Other studies have found that some small mammal species prefer habitats with
lower densities of large herbivores (Bush et al., 2012, Keesing, 1998, Kutt and Gordon, 2012),
but our study is the first to experimentally demonstrate this response to macropod herbivores.
Contrary to other studies from south-eastern Australia (Fox, 1982, Lindenmayer et al.,
2008), we found only weak support for a negative response of antechinus to fire. This was likely
due to the low intensity, small-scale fires used in our study. The availability of arthropod prey
(Table 2, Appendix 2), combined with the persistence of logs and the proximity of unburnt
vegetation to burnt areas in our study, may have sufficiently maintained habitat quality for
antechinus. It is likely that antechinus may have responded more strongly to a larger-scale, or
higher intensity burn (Lindenmayer et al., 2008, Penn et al., 2003).
Delicate skinks were more common in open than in herbivore exclusion sites, and both
delicate skinks and small-eyed snakes were more common in burnt than unburnt sites. The
negative response of delicate skinks to herbivore exclusion was likely due to increased shading
from recovering vegetation, which could have reduced the thermal suitability of the
environment for this heliothermic species (Howard et al., 2003). The positive response of the
delicate skink to burning was contrary to our expectation for this species, which generally
98
recovers slowly from fire, in response to the slow accumulation of leaf litter (Taylor and Fox,
2001). Our result may therefore reflect a change in micro-habitat use following burning, rather
than a change in site occupancy. Burning reduced litter depth, and in the absence of suitable
leaf-litter habitat, the delicate skink may have increased its use of the artificial survey substrates
for shelter, basking and foraging, as found by Croft, Reid and Hunter (2010).
A lack of alternative refuges also may explain the higher numbers of small-eyed snakes
under the artificial substrates in burnt sites. However, there are two other possible explanations
for this response: First is that the small-eyed snake was more common after burning as a result
of reduced shading of substrates, which provided warmer, more desirable diurnal refuges (Webb
et al., 2004). Second, the density of skinks, a key prey item for small-eyed snakes (Shine, 1984),
may have attracted snakes to the substrates in burnt sites. Previous studies of small-eyed snakes
show that reduced shading after fire can improve the thermal properties of diurnal refuges
(Webb et al., 2005), but large wildfire can lead to population declines, possibly due to increased
predation (Webb and Shine, 2008). While the possible biases in our reptile sampling technique
mean results should be interpreted with caution, the greater numbers of reptiles in burnt sites
and skinks in the open treatments, indicate that maintaining areas of open understory may be
important for the persistence of reptiles in these forests (Webb et al., 2005).
Conservation implications
Our results have four key implications relevant to the conservation of ecosystems subject to
both recurrent fire and herbivory. First, the dominance of bracken and limited recovery of other
vegetation in burnt, open sites indicates that short-term management of abundant macropod
herbivores following prescribed fire may be useful for the conservation of structurally and
floristically complex vegetation. Second, the preference of antechinus for herbivore exclusion
sites suggests that management of native herbivores to promote dense understory habitat is also
likely to benefit small mammals dependent on such habitats. Third, the increased rabbit activity
we observed on recently burnt sites, and sites without macropods, suggests that any plan to
improve the post-fire recovery of vegetation by controlling native herbivores also should
99
include management of rabbits. Fourth, the positive response of reptiles to the open understory
of burnt sites and sites with more macropods differed from the antechinus response, and
suggests that a mixed management scenario might be more appropriate.
While our experiments were small-scale, the contrasting responses of different species
to herbivory and fire indicate that a mixed management strategy promoting a heterogeneous
understory may be important for the persistence of all species in our study. Heterogeneous
landscapes have commonly been suggested as a desired goal of land management, as such
landscapes are more likely to allow the co-existence of species with different niches, as well as
species that require a mix of habitats (Law and Dickman, 1998, Stein, Gerstner and Kreft,
2014). In Australian landscapes, fire patch-mosaics have been recommended to promote fauna
diversity, although key questions around the appropriate spatial and temporal scales of such
mosaics remain unanswered (Allouche et al., 2012, Clarke, 2008, Driscoll et al., 2010). While
not designed to address questions of spatial scale, our study suggests that maintaining a mix of
habitat types and conditions may be important for fauna in forested systems.
Although both fire and herbivory are often actively managed in forested systems
(Gordon, Hester and Festa-Bianchet, 2004, Morrison et al., 1996), these processes are usually
considered independently (Royo and Carson, 2006, Wisdom et al., 2006). However, the
interactive effects of fire and herbivory observed in our study indicate that integrating large
herbivore management with fire management practices is likely to be important for achieving
vegetation heterogeneity in forests. This could be through the fire-dependent management of
herbivores (e.g. controlling large herbivores across only part of a burn or after only some
prescribed burns), or through planning fires to consider large herbivore behaviour (e.g. reducing
the edge-area ratio of prescribed burns, as macropods can be reluctant to enter open areas and so
feed more heavily at the edge (While and McArthur, 2006)). Our study shows the value of
experimental studies that quantify disturbance responses both individually and collectively, and
highlights the importance of considering both multiple stressors, and multiple species, in the
management of disturbance regimes.
100
Acknowledgments
Staff of BNP conducted prescribed burns. We thank the Department of Environment and the
landowners and co-managers of BNP - the Wreck Bay Aboriginal Community. The Margaret
Middleton Fund, The Norman Wettenhall Foundation and the Long Term Ecological Research
Network provided financial support.
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Appendices
Appendix 1. Spatial scale and construction of experimental treatments.
Figure 1. Schematic diagram of blocked design showing types and site dimensions of the six
treatment combinations (not to scale). Exact spatial arrangement varies between blocks
Figure 2. Example of a recently burnt herbivore exclusion site (3 months post-fire), showing
fence design and forest type.
106
Appendix 2. Full model rankings for LMMs and GLMMs, and parameter
estimates for fixed-effect terms in top-ranked models.
Table 1. Full model rankings for linear mixed models testing the fixed effects of burning (B - burnt or
unburnt), exclosure (E - open, partial or full exclosure), time (T - sampling event - categorical),
and their interactions on vegetation structure. K is the number of parameters estimated in the
model, Δ AICc is the change in Aikaike’s Information Criterion (corrected for small sample
size) from the best-ranked model. AICcWt is the Aikine Weight of the model, LL is the Log-
likelihood.
Data Model terms K AICc ΔAICc AICcWt Cum.Wt LL
Understory cover
Full model (BxExT) 28 2970.0 0 0.97 0.97 -1454.7
B + E + T + B:T + H:T 20 2977.2 7.22 0.03 1 -1467.4
B + E + T + B:E: + B:T + E:T 22 2980.9 10.92 0 1 -1467.0
B + T + B:T 12 2985.8 15.81 0 1 -1480.5
B + E + T + B:T 14 2987.1 17.14 0 1 -1479.0
B + E + T + B:E: + B:T 16 2990.7 20.69 0 1 -1478.6
B + E + T + E:T 17 3088.1 118.14 0 1 -1526.2
B + T 9 3089.4 119.48 0 1 -1535.5
B + E + T 11 3090.7 120.74 0 1 -1534.0
B + E + T + B:E: + E:T 19 3091.7 121.77 0 1 -1525.8
B + E + T + B:E 13 3094.2 124.22 0 1 -1533.6
E + T + E:T 16 3095.8 125.83 0 1 -1531.2
E + T 8 3096.2 126.2 0 1 -1539.9
E + T 10 3098.5 128.5 0 1 -1538.9
B 6 3206.4 236.39 0 1 -1597.1
B + E 8 3207.6 237.58 0 1 -1595.6
B + E + B:E 10 3211.0 241 0 1 -1595.2
intercept 5 3213.1 243.14 0 1 -1601.5
E 7 3215.4 245.38 0 1 -1600.5
Cover excluding bracken
B + E + T + B:T + E:T 20 2821.4 0 0.74 0.74 -1389.6
Full model (BxExT) 28 2824.5 3.02 0.16 0.9 -1381.9
B + E + T + B:E: + B:T + E:T 22 2825.4 3.94 0.1 1 -1389.3
B + E + T + B:T 14 2854.7 33.23 0 1 -1412.8
B + T + B:T 12 2855.9 34.47 0 1 -1415.5
B + E + T + B:E + B:T 16 2858.5 37.02 0 1 -1412.5
B + E + T + E:T 17 2902.1 80.7 0 1 -1433.2
B + E + T + B:E: + E:T 19 2906.0 84.56 0 1 -1433.0
E + T + E:T 16 2917.6 96.13 0 1 -1442.0
B + E + T 11 2924.2 102.71 0 1 -1450.7
B + T 9 2925.5 104.02 0 1 -1453.5
B + E + T + B:E 13 2927.9 106.43 0 1 -1450.4
B + E 8 2933.3 111.85 0 1 -1458.5
107
Data Model terms K AICc ΔAICc AICcWt Cum.Wt LL
B 6 2934.7 113.23 0 1 -1461.2
B + E + B:E 10 2936.9 115.5 0 1 -1458.2
T 8 2937.9 116.49 0 1 -1460.8
E + T 10 2939.7 118.21 0 1 -1459.5
intercept 5 2947.2 125.73 0 1 -1468.5
E 7 2948.8 127.38 0 1 -1467.3
Vegetation height
B + T + B:T 12 -508.1 0 0.61 0.61 266.5
B + E + T + B:T 14 -506.5 1.59 0.28 0.89 267.8
B + E + T + B:E + B:T 16 -504.4 3.71 0.1 0.98 268.9
B + E + T + B:T + H:T 20 -500.0 8.03 0.01 1 271.2
B + E + T + B:E: + B:T + E:T 22 -497.8 10.29 0 1 272.3
Full model (BxExT) 28 -494.3 13.77 0 1 277.4
B + T 9 -448.4 59.67 0 1 233.4
B + E + T 11 -446.9 61.2 0 1 234.8
B + E + T + B:E 13 -444.8 63.24 0 1 235.9
B + E + T + E:T 17 -439.3 68.81 0 1 237.5
T 8 -438.7 69.37 0 1 227.5
B + E + T + B:E: + E:T 19 -437.1 71 0 1 238.6
E + T 10 -435.9 72.12 0 1 228.3
E + T + E:T 16 -428.4 79.66 0 1 230.9
B 6 -331.4 176.68 0 1 171.8
B + E 8 -329.9 178.14 0 1 173.2
B + E + B:E 10 -328.0 180.11 0 1 174.3
intercept 5 -321.7 186.41 0 1 165.9
E 7 -319.0 189.09 0 1 166.6
Litter depth
B + T + B:T 12 883.9 0 0.82 0.82 -429.51
B + E + T + B:T 14 887.6 3.7 0.13 0.95 -429.21
B + E + T + B:E + B:T 16 890.4 6.55 0.03 0.99 -428.46
B + E + T + B:T + H:T 20 892.4 8.53 0.01 1 -425.03
B + E + T + B:E: + B:T + E:T 22 895.4 11.52 0 1 -424.29
Full model (BxExT) 28 904.4 20.49 0 1 -421.89
B + T 9 942.8 58.94 0 1 -462.16
B + E + T 11 946.4 62.57 0 1 -461.86
B + E + T + B:E 13 949.2 65.35 0 1 -461.11
B + E + T + E:T 17 952.8 68.9 0 1 -458.54
B + E + T + B:E: + E:T 19 955.7 71.82 0 1 -457.8
T 8 989.9 106.06 0 1 -486.77
E + T 10 994.1 110.21 0 1 -486.74
E + T + E:T 16 1000.3 116.47 0 1 -483.42
B 6 1023.8 139.9 0 1 -505.77
B + E 8 1027.3 143.46 0 1 -505.47
B + E + B:E 10 1030.0 146.18 0 1 -504.72
intercept 5 1070.9 187.05 0 1 -530.38
E 7 1075 191.14 0 1 -530.35
108
Table 2. Parameter estimates (best), standard errors (SE), degrees of freedom (df) and marginal
probabilities (P) of fixed-effect terms for linear mixed models within two AICc of the top-ranked
model for the vegetation variables.
Model Model fixed effects Factor levels best SE df P
a. Understory cover
Top ranked model: full model (BxHxT)
Burn burnt -31.71 6.78 15 <0.001
Exclosure partial 3.94 6.78 15 0.570
full exclosure -6.25 6.78 15 0.371
Time May'13 2.69 3.14 270 0.392
Nov'13 -10.44 3.14 270 0.001
May'14 -8.75 3.14 270 0.006
Burn x Exclosure burnt.partial -1.66 9.59 15 0.865
burnt.full 4.68 9.59 15 0.632
Burn x Time burnt.May'13 21.65 4.43 270 <0.001
burnt.Nov'13 31.03 4.43 270 <0.001
burnt.May'14 25.03 4.43 270 <0.001
Exclosure x Time partial.May'13 4.63 4.43 270 0.298
full.May'13 19.88 4.43 270 <0.001
partial.Nov'13 7.75 4.43 270 0.082
full.Nov'13 18.44 4.43 270 <0.001
partial.May'14 -3.94 4.43 270 0.375
full.May'14 14.63 4.43 270 0.001
Burn x Exclosure x Time burnt.partial.May'13 7.35 6.27 270 0.242
burnt.full.May'13 -16.68 6.27 270 0.008
burnt.partial.Nov'13 -2.65 6.27 270 0.673
burnt.full.Nov'13 -14.81 6.27 270 0.019
burnt.partial.May'14 14.98 6.27 270 0.018
burnt.full.May'14 -4.62 6.27 270 0.462
b. Understory cover excluding bracken Top ranked model: B + E + T + B:T + E:T
Burn burnt -26.60 3.05 17 <0.001
Exclosure partial 3.67 3.73 17 0.340
full exclosure -3.14 3.73 17 0.412
Time May'13 -9.21 2.13 276 <0.001
Nov'13 -13.00 2.13 276 <0.001
May'14 -12.99 2.13 276 <0.001
Burn x Time burnt.May'13 12.83 2.13 276 <0.001
burnt.Nov'13 16.98 2.13 276 <0.001
burnt.May'14 19.24 2.13 276 <0.001
Exclosure x Time partial.May'13 9.93 2.61 276 <0.001
full.May'13 12.61 2.61 276 <0.001
partial.Nov'13 3.71 2.61 276 0.156
full.Nov'13 11.83 2.61 276 <0.001
partial.May'14 3.06 2.61 276 0.241
full.May'14 13.68 2.61 276 <0.001
109
Model Model fixed effects Factor levels best SE df P
c. Vegetation height Top ranked model: B + T + B:T
Burn burnt -0.301 0.046 19 <0.001
Time May'13 0.047 0.020 282 0.021
Nov'13 0.030 0.020 282 0.132
May'14 0.084 0.020 282 <0.001
Burn x Time burnt.May'13 0.114 0.028 282 <0.001
burnt.Nov'13 0.200 0.028 282 <0.001
burnt.May'14 0.216 0.028 282 <0.001
2nd ranked model: B + E + T + B:T
Burn burnt -0.301 0.043 17 <0.001
Exclosure partial 0.036 0.049 17 0.476
full exclosure 0.082 0.049 17 0.112
Time May'13 0.047 0.020 282 0.021
Nov'13 0.030 0.020 282 0.133
May'14 0.084 0.020 282 <0.001
Burn x Time burnt.May'13 0.114 0.029 282 <0.001
burnt.Nov'13 0.200 0.029 282 <0.001
burnt.May'14 0.216 0.029 282 <0.001
d. Litter Depth Top ranked model: B + T + B:T
Burn burnt -2.837 0.197 19 <0.001
Time May'13 0.496 0.126 282 <0.001
Nov'13 0.498 0.126 282 <0.001
May'14 0.240 0.126 282 0.059
Burn x Time burnt.May'13 -0.008 0.179 282 0.964
burnt.Nov'13 0.692 0.179 282 <0.001
burnt.May'14 1.275 0.179 282 <0.001
110
Table 3. Full model rankings for generalised linear mixed models testing the fixed effects of burning (B -
burnt or unburnt), exclosure (E - open, partial or full exclosure), time (T - sampling event -
categorical), and their interactions on animal occurrence. For brown antechinus, we also ran
model ranking on all subsets of a model with season (S - autumn or spring) substituted for time
(i.e. B*E*S), to account for the strong seasonal variation in the abundance of this species. K is
the number of parameters estimated in the model, Δ AICc is the change in Aikaike’s Information
Criterion (corrected for small sample size) from the best-ranked model. AICcWt is the Aikine
Weight of the model, LL is the Log-likelihood.
Data Model terms K AICc Δ AICc AICcWt Cum.Wt LL
Macropod scats
B + E + T 15 1035.9 0 0.6 0.6 -500.6
B + E + T 15 1035.9 0 0.6 0.6 -500.6
B + E + T + B:E 16 1038.4 2.52 0.17 0.77 -500.6
E + T 14 1038.7 2.8 0.15 0.92 -503.3
B + E + T + E :T 19 1041.1 5.21 0.04 0.96 -497.7
E + T + E :T 18 1043.8 7.9 0.01 0.98 -500.5
B + E + T + B:E : + E :T 20 1043.8 7.93 0.01 0.99 -497.7
B + T 14 1045.7 9.81 0 0.99 -506.8
T 13 1046.0 10.16 0 1 -508.3
B + E + T + B:T 24 1046.1 10.23 0 1 -492.7
B + E + T + B:E + B:T 25 1049.0 13.17 0 1 -492.6
B + E + T + B:T + H:T 28 1052.6 16.74 0 1 -489.4
B + E + T + B:E : + B:T + E :T 29 1055.8 19.91 0 1 -489.2
B + T + B:T 23 1056.0 20.16 0 1 -499.3
B + E 6 1056.4 20.49 0 1 -521.8
B + E + B:E 7 1058.4 22.57 0 1 -521.7
E 5 1059.3 23.41 0 1 -524.4
Full model (BxE xT) 33 1062.2 26.36 0 1 -485.1
B 5 1066.3 30.43 0 1 -527.9
intercept 4 1066.9 31.02 0 1 -529.3
Rabbit diggings
T 9 901.4 0 0.37 0.37 -441.0
E + T 11 902.4 1.09 0.21 0.58 -439.2
B + T 10 903.0 1.64 0.16 0.74 -440.7
B + E + T 12 903.9 2.59 0.1 0.84 -438.8
B + T + B:T 15 904.0 2.69 0.1 0.94 -435.1
B + E + T + B:T 17 905.4 4.03 0.05 0.98 -433.3
B + E + T + B:E 14 908.3 6.96 0.01 1 -438.5
B + E + T + B:E + B:T 19 910.1 8.73 0 1 -433.0
E + T + E:T 21 920.8 19.48 0 1 -435.6
B + E + T + E:T 22 922.7 21.38 0 1 -435.2
B + E + T + B:T + H:T 27 925.0 23.62 0 1 -429.0
B + E + T + B:E: + E:T 24 927.9 26.56 0 1 -434.9
B + E + T + B:E: + B:T + E:T 29 930.5 29.16 0 1 -428.6
intercept 4 939.6 38.29 0 1 -465.7
E 6 940.3 38.98 0 1 -463.9
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Data Model terms K AICc Δ AICc AICcWt Cum.Wt LL
B 5 941.2 39.82 0 1 -465.4
B + E 7 941.7 40.37 0 1 -463.5
B + E + B:E 9 945.7 44.37 0 1 -463.2
Full model (BxExT) 39 958.8 57.4 0 1 -425.4
Brown antechinus
E + S 6 356.9 0 0.36 0.36 -172.0
B + E + S 7 358.3 1.4 0.18 0.54 -171.5
S 4 359.8 2.92 0.08 0.62 -175.7
E + T 8 360.4 3.47 0.06 0.68 -171.4
E + S+ E:S 8 360.4 3.49 0.06 0.74 -171.4
B + E + S + B:S 8 360.5 3.65 0.06 0.8 -171.4
B + S 5 361.4 4.52 0.04 0.84 -175.4
B + E + S + B:E 9 361.5 4.6 0.04 0.87 -170.7
B + E + T 9 361.9 4.99 0.03 0.9 -170.9
B + E + S + E:S 9 361.9 5 0.03 0.93 -170.9
T 6 363.1 6.18 0.02 0.95 -175.1
B + S + B:S 6 363.5 6.66 0.01 0.96 -175.3
B + E + S + B:E + B:S 10 363.8 6.96 0.01 0.97 -170.6
B + E + S + B:S + E:S 10 364.2 7.36 0.01 0.98 -170.8
B + T 7 364.8 7.89 0.01 0.99 -174.7
B + E + T + B:E 11 365.3 8.41 0.01 0.99 -170.1
B + E + S + B:E + E:S 11 365.3 8.43 0.01 1 -170.1
B + E + S + B:E + B:S + E:S 12 367.8 10.97 0 1 -170.0
B + E + T + B:T 12 369.3 12.4 0 1 -170.8
Full model (BxExS) 14 371.1 14.21 0 1 -169.0
B + T + B:T 10 371.8 14.95 0 1 -174.6
B + E + T + B:E + B:T 14 373.1 16.2 0 1 -169.9
E + T + E:T 14 373.9 17 0 1 -170.3
B + E + T + E:T 15 375.8 18.89 0 1 -169.9
B + E + T + B:E + E:T 17 380.0 23.11 0 1 -169.1
E 5 382.5 25.58 0 1 -185.9
B + E 6 383.8 26.94 0 1 -185.4
B + E + T + B:T + E:T 18 384.4 27.52 0 1 -169.8
intercept 3 385.5 28.6 0 1 -189.6
B + E + B:E 8 386.9 30.02 0 1 -184.6
B 4 387.0 30.15 0 1 -189.3
B + E + T + B:E + B:T + E:T 20 389.1 32.22 0 1 -168.9
Full model (BxExT) 26 402.4 45.57 0 1 -165.1
Delicate skink
B + E + T 13 353.7 0 0.46 0.46 -162.8
B + T 11 354.1 0.34 0.39 0.85 -165.3
B + E + T + B:E 15 356.0 2.24 0.15 1 -161.6
T 10 364.5 10.75 0 1 -171.6
E + T 12 366.7 12.96 0 1 -170.5
B + E 6 376.5 22.82 0 1 -182.0
B 4 377.2 23.5 0 1 -184.5
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Data Model terms K AICc Δ AICc AICcWt Cum.Wt LL
B + E + B:E 8 378.4 24.71 0 1 -180.8
B + E + T + E:T 27 380.7 26.97 0 1 -158.7
B + E + T + B:T + H:T 34 382.7 28.96 0 1 -149.8
B + E + T + B:E: + E:T 29 383.8 30.05 0 1 -157.5
intercept 3 387.8 34.07 0 1 -190.8
E 5 389.7 35.95 0 1 -189.7
E + T + E:T 26 393.2 39.52 0 1 -166.4
Eastern small-eyed snake
B 4 129.2 0 0.67 0.67 -60.4
B + E 6 132.8 3.59 0.11 0.78 -59.9
intercept 3 133.5 4.32 0.08 0.86 -63.6
B + T 7 133.7 4.55 0.07 0.93 -59.2
B + T + B:T 10 136.3 7.19 0.02 0.95 -56.9
B + E + B:E 8 136.4 7.28 0.02 0.97 -59.4
E 5 137.3 8.12 0.01 0.98 -63.3
B + E + T 9 137.6 8.46 0.01 0.99 -58.8
T 6 137.9 8.72 0.01 1 -62.5
B + E + T + B:T 12 140.6 11.44 0 1 -56.4
B + E + T + B:E 11 141.7 12.49 0 1 -58.3
E + T 8 142.0 12.83 0 1 -62.2
B + E + T + E:T 15 146.5 17.29 0 1 -55.2
E + T + E:T 14 150.4 21.29 0 1 -58.6
B + E + T + B:T + H:T 18 150.6 21.4 0 1 -52.8
B + E + T + B:E: + E:T 17 151.3 22.12 0 1 -54.7
Beetles and spiders
T 5 386.2 0 0.61 0.61 -187.4
B + T 6 388.1 1.85 0.24 0.85 -187.0
B + T + B:T 7 390.8 4.53 0.06 0.92 -187.0
E + T 7 391.5 5.29 0.04 0.96 -187.4
B + E + T 8 393.6 7.4 0.02 0.98 -187.0
intercept 4 395.2 8.97 0.01 0.98 -193.1
E + T + E:T 9 396.0 9.72 0 0.99 -186.6
B + E + T + B:T 9 396.6 10.38 0 0.99 -186.9
B 5 397.0 10.8 0 0.99 -192.8
B + E + T + B:E 10 397.4 11.21 0 1 -185.7
B + E + T + E:T 10 398.4 12.15 0 1 -186.2
E 6 400.2 14.01 0 1 -193.1
B + E + T + B:E + B:T 11 400.8 14.52 0 1 -185.7
B + E + T + B:T + H:T 11 401.7 15.45 0 1 -186.2
B + E 7 402.3 16.08 0 1 -192.8
B + E + T + B:E: + E:T 12 402.9 16.7 0 1 -185.0
B + E + B:E 9 406.1 19.83 0 1 -191.7
B + E + T + B:E: + B:T + E:T 13 406.6 20.39 0 1 -185.0
Full model (BxExT) 15 414.5 28.26 0 1 -184.7
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Table 4. Parameter estimates (best), standard errors (SE) and marginal probabilities (P) of fixed-effect
terms in the generalised linear mixed models within two AICc of the top-ranked model for
animal occurrence variables.
Model Model fixed effects Factor levels best SE P
a. Macropod scats
Top ranked model: B + Ea + T
Burn burnt 0.481 0.192 0.012
Exclosure partial (open months) -0.858 0.209 <0.001
Time Nov '12 0.558 0.294 0.058
Feb '13 -0.544 0.246 0.027
Apr '13 -0.016 0.298 0.956
Jun '13 0.443 0.238 0.062
Aug '13 -0.084 0.298 0.777
Oct '13 -0.153 0.242 0.527
Dec '13 -0.819 0.307 0.008
Feb '14 -0.675 0.245 0.006
Apr '14 -0.840 0.308 0.006
b. Rabbit diggings Top ranked model: T
Time Aug '13 -0.372 0.195 0.057
Oct '13 -0.340 0.194 0.080
Dec '13 0.316 0.185 0.087
Feb '14 0.717 0.181 <0.001
Apr '14 -0.420 0.196 0.032
2nd ranked model: E + T
Exclosure partial 0.5116 0.314 0.104
full exclosure 0.5716 0.315 0.069
Time Aug '13 -0.3712 0.195 0.057
Oct '13 -0.3393 0.194 0.080
Dec '13 0.3155 0.185 0.088
Feb '14 0.7175 0.181 <0.001
Apr '14 -0.4188 0.196 0.033
3rd ranked model: B + T
Burn burnt 0.230 0.278 0.408
Time Aug '13 -0.372 0.195 0.056
Oct '13 -0.341 0.194 0.079
Dec '13 0.316 0.185 0.087
Feb '14 0.718 0.181 <0.001
Apr '14 -0.420 0.196 0.032
c. Brown antechinus Top ranked model: E + season
Exclosure partial -0.116 0.182 0.524
full exclosure 0.352 0.163 0.031
Season spring -0.750 0.147 <0.001
2nd ranked model: B + E + season
Burn burnt -0.132 0.137 0.336
Exclosure partial -0.116 0.182 0.524
full exclosure 0.352 0.163 0.031
Season spring -0.750 0.147 <0.001
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Model Model fixed effects Factor levels best SE P
d. Delicate skink Top ranked model: B + E + T
Burn burnt 1.085 0.228 <0.001
Exclosure partial 0.002 0.246 0.995
full exclosure -0.553 0.265 0.037
Time Feb '13 -1.068 0.348 0.002
Apr '13 -2.080 0.528 <0.001
Jun '13 -1.163 0.360 0.001
Aug '13 -1.386 0.393 <0.001
Oct '13 -1.520 0.415 <0.001
Dec '13 -0.470 0.284 0.097
Apr '14 -1.068 0.348 0.002
2nd ranked model: B + T
Burn burnt 1.077 0.260 <0.001
Time Feb '13 -1.068 0.345 0.002
Apr '13 -2.080 0.524 <0.001
Jun '13 -1.163 0.358 0.001
Aug '13 -1.386 0.390 <0.001
Oct '13 -1.520 0.412 <0.001
Dec '13 -0.470 0.281 0.095
Apr '14 -1.068 0.345 0.002
e. Eastern Small-eyed snake Top ranked model: B
Burn burnt 1.551 0.600 0.010
f. Beetles and Spiders Top ranked model: T Time Nov'13 -0.505 0.131 0.000
2nd ranked model: B + T Burn burnt 0.135 0.152 0.376
Time Nov'13 -0.505 0.131 0.000 a Compares only partial-open months with open treatment (see methods)
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Paper III: Synergistic interactions between fire and browsing drive plant diversity in a forest understory
In Paper II, I found that fire and herbivory interacted strongly to affect vegetation, with herbivory
limiting the recovery of understorey vegetation from fire. In this paper, I focussed more closely
on the mechanisms driving the interactive effects of fire and herbivory on plant diversity, and
investigated whether these effects occurred via numerically mediated (interaction chain) or
functionally moderated (interaction modification) pathways.
Foster, C.N, Barton, P.S, Sato, C.F, Macgregor, C.I, and D.B. Lindenmayer (2015) Synergistic
interactions between fire and browsing drive plant diversity in a forest understory. Journal of
Vegetation Science. 26, 1112-1123.
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Abstract
Questions: Does browsing by large herbivores affect forest understory diversity by modifying
assemblage dominance? Does fire interact with browsing to affect forest understory diversity?
Does this interaction occur via a numerically-mediated or functionally-moderated pathway?
Location: Booderee National Park, Jervis Bay Territory, south-eastern Australia
Methods: We tested the interactive effects of fire and browsing by native herbivores on
understory plant diversity using a randomised blocked experiment in an open eucalypt forest.
We monitored the percentage cover of every vascular plant species in 24 sites over four
experimental blocks. We applied a different treatment to each of the six sites in the four blocks.
Treatments were a factorial combination of three levels of herbivory treatment (open, partial
exclosure, full exclosure) and two levels of prescribed fire treatment (burnt, unburnt).
Results: Browsing increased plant community dominance and reduced evenness and diversity,
but only in burnt sites. Heavy browsing following fire created an understory dominated by an
unpalatable, fire resistant fern species (bracken, Pteridium esculentum). This fire-browsing
interaction was driven by both numerically-mediated and functionally-moderated pathways:
Fire both increased local browsing intensity, and amplified the per-unit effect of herbivores on
the plant community.
Conclusions: The altered competitive environment after fire, combined with heavy post-fire
browsing created a depauperate understory, dominated by bracken fern. The ability of bracken
to supress the establishment of other plants means that, once established, this fern-dominated
understory may be difficult to reverse. Our results demonstrate the key role of fire-browsing
interactions in forest vegetation dynamics and highlight the importance of integrating large
herbivore management with fire planning in forest ecosystems.
Keywords
Alternate stable states; Browsing; Community structure; Dominance; Disturbance interaction;
Eucalyptus forest; Herbivory; Macropod; Plant diversity; Pteridium esculentum; Understory
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Nomenclature
Robinson (1991)
Introduction
Herbivory is a core process driving the structure and diversity of plant communities in many
ecosystems worldwide (Milchunas et al. 1988; Hester et al. 2006; Borer et al. 2014). In forested
systems, selective browsing by large herbivores can have transformative effects, altering canopy
tree species dominance and driving cascading effects through the rest of the ecosystem (Royo &
Carson 2006; Holm et al. 2013; Côté et al. 2014). Browsing has also been shown to exert strong
effects on forest understory vegetation. However, there is little agreement among studies about
whether browsing enhances or reduces the diversity of forest understory plants. Positive effects
(Royo et al. 2010a), negative effects (Rooney & Waller 2003; Jenkins et al. 2014), and no effect
(Kerns et al. 2011) of browsing on understory plant diversity have all been reported, with
discrepancies between studies attributed to differences in herbivore densities, ecosystem
productivity, disturbance history and other site-dependent variables (Hester et al. 2006; Royo et
al. 2010a).
While the net effects of herbivory on plant diversity are variable, it has been suggested
that most responses can be explained by effects on plant species dominance (Hester et al. 2006).
In systems where herbivores selectively feed on dominant plant species, they will reduce
assemblage dominance, and increase resource availability for competitively inferior plants,
thereby increasing diversity (Côté et al. 2004; Hester et al. 2006). However, when the dominant
species are unpalatable, herbivores will have the opposite effect. A number of recent studies
from grassland systems have supported this hypothesis, finding that the effects of herbivory on
ground-level light availability (which is driven by the abundance of dominant species),
consistently explained herbivory effects on plant diversity, despite the sites having a wide range
of abiotic conditions and disturbance histories (Borer et al. 2014; Eby et al. 2014; Koerner et al.
2014).
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Understanding the effects of grazing and browsing can be useful for predicting the
outcomes of management interventions (Hester et al. 2000). Such predictions, however, are
complicated by the fact that herbivory can interact strongly with other episodic disturbance
events (e.g. fire, timber harvest, drought; Royo & Carson 2006; Wisdom et al. 2006). These
interactions can produce vastly different outcomes than would be predicted from studies of
individual effects, and can lead to unintended management outcomes (Tylianakis et al. 2008).
Ecological disturbances can interact via two main pathways: an interaction chain (a
numerically-mediated process), and an interaction modification (a functionally-moderated
process) (Didham et al. 2007). In the context of disturbance-grazing interactions, a numerically-
mediated interaction could occur through disturbance changing the local abundance of
herbivores, in turn affecting vegetation. A functionally-moderated interaction would occur if
disturbance modified the per unit effect of herbivores on vegetation.
Both these interaction pathways are commonly described in studies of fire-grazing
interactions, although they are not often explicitly identified as such. For example, patch
burning of grasslands can initiate a numerically-mediated fire-grazing interaction; fire
stimulates fresh growth which attracts large herbivores (Allred et al. 2011). The resulting
concentration of herbivores increases local grazing intensity, while reducing it elsewhere, which
increases vegetation heterogeneity (Fuhlendorf et al. 2006). By modifying the competitive
interactions among plant species, or selectively acting on some plant traits, fire can also have a
functionally-moderated effect on plant responses to herbivory. For example, in a North
American mesic grassland, annual burning amplified the negative effect of grazing exclusion on
plant diversity (Eby et al. 2014). This was due to the dominant grass species in the system being
both a post-fire increaser and highly palatable. These two functional traits gave this grass
species a competitive advantage following fire and allowed it to dominate the plant community
in the absence of large herbivores (Eby et al. 2014).
As disturbances can interact with the life history traits of organisms, as well as with
each other, predicting the outcomes of disturbance interactions is problematic, even if plant
traits are well understood (Royo & Carson 2006). Therefore, understanding such interactions
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requires manipulative experiments that are able to test the non-additive effects of these
processes (Didham et al. 2007; Tylianakis et al. 2008). Manipulative tests of the interactive
effects of herbivory and disturbance have become reasonably common in grassland systems
(e.g. Fuhlendorf et al. 2006; Collins & Calabrese 2012; Koerner & Collins 2014), but remain
rare in forested systems (Wisdom et al. 2006; Royo et al. 2010a). The high densities of large
herbivores in many forests worldwide (Côté et al. 2004), and the prevalence of active fire
management in forest ecosystems (Stephens & Ruth 2005; Boer et al. 2009), mean that
improving our understanding of the effects of fire-browsing interactions on vegetation dynamics
is of high importance for the management of forest ecosystems (Wisdom et al. 2006).
We studied the effects of fire × browsing interactions on plant diversity in a temperate
forest understory, testing the hypothesis that effects on plant diversity would be similar to those
described for grassland ecosystems. Our study had three main predictions: (1) browsing by large
herbivores would affect plant diversity by modifying assemblage dominance. Specifically, as
the dominant understory species in our study system was of low palatability (Pteridium
esculentum, Di Stefano & Newell 2008; Fletcher et al. 2011), we predicted that browsing would
increase assemblage dominance and reduce diversity. We also predicted that: (2) fire would
amplify the effects of browsing on plant diversity, and that (3) this interaction would occur via
both numerically-mediated and functionally-moderated pathways. The numerically-mediated
effect would be driven by more herbivores browsing in burnt sites, while the functionally-
moderated effect would be driven by fire amplifying the effects of herbivory on P. esculentum
dominance.
Methods
Study site
We conducted this study in Booderee National Park (BNP); a ~6 500 ha peninsula in south-
eastern Australia (35°10′S, 150°40′E, Fig. 1). The most widespread vegetation type in the park
is open eucalypt forest (Taws 1998). This forest type is dominated by Eucalyptus pilularis,
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Corymbia gummifera and E. botryoides in the overstory (> 10 m), Banksia serrata, Acacia
longifolia and Monotoca elliptica in the midstory (2 – 10 m) and Lomandra longifolia and P.
esculentum in the understory (< 2 m) (Taws 1998; Lindenmayer et al. 2008).
An intensive baiting program targeting the introduced red fox (Vulpes vulpes) has been
in place within the park since 1999 to protect native small mammal species from predation
(Dexter et al. 2012). As hunting has been long discontinued and dingoes (Canis lupus dingo)
now occur only rarely in the park, the removal of foxes means that predation pressure on
herbivores is low (Lindenmayer et al. 2014). Since the removal of foxes, there has been a
tenfold increase in the numbers of native macropod herbivores within the park (Dexter et al.
2012; Lindenmayer et al. 2014). The most common of these macropods are the swamp wallaby,
Wallabia bicolor, a generalist browser, and the eastern grey kangaroo, Macropus giganteus, a
grazer (Davis et al. 2008; Dexter et al. 2013). Small-scale exclosure trials have indicated that
the current high abundance of these herbivores could be driving a decline in some plant species
(Dexter et al. 2013).
Study design
We quantified the interactive effects of fire and large herbivores on understory plant diversity
using a randomised, blocked experiment. We examined three levels of herbivory treatment and
two levels of burning treatment in a factorial design (Fig. 1). We replicated each of these six
treatment combinations across four experimental blocks to give a total of 24 sites. For the
herbivory treatments, we manipulated the density of macropods within 25 × 25 m plots using
exclosure fences to produce three levels of herbivory: full herbivory (open treatment),
intermediate herbivory (partial treatment – plots were fenced but gates opened and closed at two
month intervals to simulate lower browsing pressure), and no herbivory (exclosure treatment).
We constructed exclosure fences in June 2012 using 1.1 m tall feral-proof stock fencing, which
we found to be effective at excluding macropods (see results). For the burning treatments, we
conducted 50 × 50 m, low severity burns across half of the herbivore treatment sites in August
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2012. Burns removed approximately 95% of understory vegetation from the site and did not
reach canopy foliage (tree scorch height 1.5 - 4 m).
Figure 1. Study location and design showing (a) location of Booderee National Park in south-
eastern Australia, (b) location of the four experimental blocks (A-D) within Booderee
National Park, and (c) a schematic diagram of the factorial design showing the
experimental treatments and their arrangement within the four experimental blocks (not
to scale, exact spatial arrangement of sites varies between blocks). Dark grey shaded
area in (b) shows the extent of the Eucalyptus pilularis forest type within BNP, black
outline indicates park boundary, light grey shading depicts ocean.
Data collection
We surveyed understorey vegetation prior to treatment implementation in April/May 2012
(austral autumn) and repeated surveys three months after burning, and then every six months
until May 2014. To capture variation within each site, we sampled vegetation using four small
quadrats, rather than one large quadrat in each site. We placed four 3 x 3 m quadrats at fixed
locations in each site, with one quadrat in each of the four quarters of the site, ensuring each
was at least 1.5 m from the fence. For each quadrat, we visually estimated the projective cover
of each vascular plant species, using the same observer for all estimates. Prior to any data
processing, we averaged the cover values of each plant species across the four quadrats to give
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one value for the 36 m2 area sampled in each site. We used these site-level data to calculate four
standard metrics of community diversity: species richness (species/ 36 m2), species diversity
(Simpson’s reciprocal index - 1/D), evenness (Simpson’s evenness – E1/D), and assemblage
dominance (Berger-Parker index – d) (Magurran 2004).
We surveyed site use by macropod herbivores by counting their scats along two 25 × 2
m transects (100 m2) in each site, summing counts to give one overall count per site. We
surveyed transects every two months from August 2012 to May 2014. We removed scats from
transects after each survey to avoid double counting. For analysis, we summed the two scat
counts preceding each vegetation survey to give an estimate of the average level of herbivore
activity in a site leading up to each sampling event.
Data analysis
We tested the effects of herbivory, fire and their interaction on plant species richness, diversity,
evenness and dominance using linear mixed-models (LMMs) in R (R Core Team 2013). The
full model for these analyses included the fixed effects of herbivory × fire × time, plus the pre-
treatment value (to account for any pre-existing differences between sites), and random effects
of block/site. Instead of the categorical herbivory treatments, we used the scat counts at each
site as our measure of herbivory. This allowed us to account for variation in herbivore pressure
both between and within levels of the herbivore exclosure treatments, and also to test whether
the relationship between herbivore pressure and plant diversity metrics differed between burnt
and unburnt sites (i.e. whether there was a functionally moderated interaction). Prior to
inclusion in the model as a fixed effect, scat count data were natural log (ln) transformed to
reduce skew, and standardised by centring, and dividing by two standard deviations to allow
comparison of the main effects of fire and herbivory and aid in interpretation of interaction
terms (Gelman & Hill 2007). After checking the fit of the full models by inspecting residual
plots (Zuur et al. 2009), we used the “dredge” function in the package “MuMIn” (Barton 2014)
to rank all possible subsets of the full model, based on minimising Akaike’s Information
Criterion, corrected for small sample sized (AICc) (Burnham & Anderson 2002).
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As our study included repeated measures at sites, we tested for temporal autocorrelation
between repeated measures at sites using the “acf” function in R (R Core Team 2013).
Autocorrelation for all variables was low, and including a first-order autoregressive correlation
structure on the random effects did not improve the fit of the LMMs. Therefore, we did not
include correlation structures in our final models (Pinheiro & Bates 2000). We also considered
fitting the species richness data with a generalised linear mixed-model (GLMM), with Poisson
errors, which is often used for count data. However, this was not used in the final analysis as the
characteristics of a Poisson distribution (skewed distribution and heteroscedasticity) were not
evident in our data (Zuur et al. 2009), and a trial GLMM showed poor fit at the extremities
when compared with the LMM.
To assess whether fire also interacted with herbivory via a numerically-mediated
pathway, we tested whether fire increased herbivore activity (as measured from scat counts)
within the different exclosure treatments. We used GLMM with a Poisson error distribution and
a log-link function for this analysis, with exclosure treatment × fire × time as fixed effects and
block/site as random effects. As very low scat counts in exclosure treatments ( = 1.78 ± 0.53,
59% of counts = 0) led to complete separation of factor combinations (Gelman & Hill 2007),
the exclosure treatment was excluded from this analysis. Scat count data were found to be over-
dispersed, which we accounted for by including an observation-level random effect in our
model (Harrison 2014).
We tested for differences in community composition among the six treatment
combinations both pre- (May 2012) and post-treatment (May 2014), using nonparametric
blocked multi-response permutation procedures (MRBP, McCune & Grace 2002) in PC-ORD
(McCune & Mefford 2006). We excluded rare species (those occurring at 2 or fewer sites) from
the site × species matrix and relativized abundances within sites, prior to analysis (McCune &
Grace 2002). If MRBP indicated significant differences in species composition among
treatments, we then used indicator species analysis (Dufrene & Legendre 1997) to identify
individual species associated with the different treatments. We used the function “multipatt” in
the R package “indicspecies” (De Cáceres & Legendre 2009), which allows the identification of
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species associations with combinations of groups (treatments) rather than just a single group
(De Cáceres et al. 2010). We set the maximum number of groups (treatment combinations) to
be combined to three as this allowed us to identify associations with both individual treatment
combinations, as well as with complete factors in the factorial design. We accounted for the
blocked structure of sites by constraining permutations within, rather than among blocks.
Significance was determined from 9999 permutations of the data.
Results
Effect of browsing and fire on plant diversity metrics
We detected 111 understory plant species over five surveys in the two-year study period
(Appendix S1). In the top-ranked LMMs, fire modified the effect of herbivory on plant
community diversity, evenness, and dominance and this interaction was consistent across time
(Table 1, Fig. 2, Appendix S2). Plant species diversity, evenness and dominance were not
related to herbivore activity on unburnt sites, but burnt sites had lower community diversity and
evenness and higher assemblage dominance as herbivore activity increased (Table 1, Fig. 2).
This indicates a functionally moderated interaction. The difference in community diversity and
evenness between burnt and unburnt sites varied through time and was highest 15 months post-
fire. In contrast, the highest-ranked model for assemblage dominance indicated that the effect of
fire was consistent across time; at high levels of herbivory, the relative abundance of the
dominant species was 30 % higher in burnt than unburnt sites (Fig. 2). This increase in
assemblage dominance was driven by P. esculentum, which comprised approximately 70 % of
the vegetation cover in burnt-open sites, but less than 40 % in burnt and unburnt exclosure sites
(Fig. 3). In contrast to the other diversity metrics, none of the models for species richness with
ΔAICc < 2 included the herbivory × fire interaction (Appendix S2), and the effects of fire were
short-term, with species richness of burnt sites returning to the level of unburnt sites within 15
months (Table 1).
125
Table 1. Estimates of coefficients (Est.), their standard errors (SE) and probabilities for the top-ranked
linear mixed model testing the effects of fire (burnt or unburnt), large herbivore activity (scats
per 100m2, ln transformed), time since fire (3, 9, 15 or 21 months) on plant species richness
(species / 36 m2), diversity (Simpson’s reciprocal index, 1/D), evenness (Simpson’s evenness,
E1/D) and dominance (Berger-Parker, d). Pre-treatment values were included as a fixed effect to
account for pre-existing differences between sites. Reference states for comparisons were
unburnt sites three months post-fire. Random terms for each model were block/site.
Species richness Diversity (1/D) Evenness (E1/D) Dominance (d)
Fixed effects Est. SE df P
Est. SE df P
Est. SE df P
Est. SE df P
Intercept 6.15 5.33 66 0.253 2.25 0.72 64 0.003 0.075 0.024 64 0.002 0.266 0.078 67 0.001
Pre-treatment value 0.85 0.19 18 <0.001 0.39 0.20 18 0.060 0.373 0.168 18 0.040 0.296 0.126 18 0.030
Fire -9.40 1.45 18 <0.001 1.04 0.53 18 0.066 0.095 0.020 18 <0.001 0.107 0.031 18 0.003
Herbivores (ln trans.) 0.28 0.48 64 0.558 0.012 0.016 64 0.455 -0.022 0.046 67 0.636
Time since fire 9 mo 0.50 0.78 66 0.523 -0.43 0.48 64 0.378 -0.016 0.020 64 0.410 0.115 0.038 67 0.003
15 mo -0.25 0.78 66 0.749 -0.02 0.48 64 0.973 0.001 0.020 64 0.975 0.063 0.038 67 0.100
21 mo 1.17 0.78 66 0.139 0.13 0.49 64 0.785 0.001 0.020 64 0.973 0.053 0.039 67 0.177
Fire:Herbivores(ln) -1.68 0.64 64 0.011 -0.059 0.021 64 0.006 0.209 0.061 67 0.001
Fire:Time B:9mo 6.67 1.10 66 <0.001 -1.69 0.67 64 0.014 -0.110 0.028 64 <0.001
B:15mo 10.33 1.10 66 <0.001 -1.88 0.67 64 0.007 -0.126 0.028 64 <0.001
B:21mo 10.92 1.10 66 <0.001 -1.67 0.69 64 0.018 -0.122 0.028 64 <0.001
126
Figure 2. Response of plant community diversity (Simpson’s reciprocal index, 1/D, a-d),
evenness (Simpson’s evenness, E1/D, e-h) and dominance (Berger-Parker, d, i-l) to fire
(burnt or unburnt) and herbivore activity through time. Values are predicted means and
95 % confidence intervals from the top-ranked model for each metric. Pre-treatment
values were fixed at the mean for all predictions (3.15 for diversity, 0.106 for evenness
and 0.53 for dominance).
127
Figure 3. Species rank-abundance curves for burnt and unburnt sites under each of the
herbivory treatments in the final survey period (May 2014). Species with relative
abundances > 0.1 are identified on each plot.
Effect of fire on herbivore activity
Fire affected herbivore activity levels, with both the first and second ranked models (ΔAICc =
0.46) showing that scat counts were higher on burnt than unburnt sites (Table 2), indicating a
numerically-mediated interaction between fire and herbivory. In the first-ranked model, this
effect was consistent across time, but in the second-ranked model, this difference was
significant only in the period from three to nine months post-fire, where counts in burnt sites
were more than double those in unburnt sites (Table 2, Fig. 4).
128
Table 2. Results of generalised linear mixed models testing whether fire affected the level of herbivore
activity (scats per 100m2) in the different exclosure treatments (open or partial exclosure)
through time (3, 9, 15 or 21 months post-fire). Full exclosure treatments were not included in
this analysis due to very low values ( = 1.78 ± 0.53). Reference states for comparisons were
unburnt, open sites three months post-fire.
Top ranked model Second ranked model
Fixed effects Est. SE Z P
Est. SE Z P
Intercept 4.26 0.23 18.8 <0.001
4.36 0.25 17.2 <0.001
Fire 0.46 0.20 2.2 0.025
0.27 0.33 0.8 0.408
Exclosure (partial) -1.63 0.20 -8.0 <0.001
-1.63 0.20 -8.1 <0.001
Time since fire 9 months -0.51 0.24 -2.1 0.038
-1.04 0.32 -3.2 0.001
15 months -0.25 0.24 -1.0 0.306
-0.20 0.31 -0.7 0.515
21 months -0.89 0.24 -3.6 <0.001
-0.81 0.31 -2.6 0.010
Fire:Time B:9m
1.01 0.44 2.3 0.022
B:15m
-0.09 0.43 -0.2 0.831
B:21m -0.18 0.44 -0.4 0.690
Figure 4. Herbivore activity in each of the experimental treatment combinations over time.
Values are the predicted mean scat count and 95 % confidence intervals (a-d) based on
the second-ranked generalised linear model. Full exclosure treatments were not
included in this analysis due to very low values ( = 1.78 ± 0.53).
Effect of browsing and fire on plant species composition
Species composition did not differ among experimental treatments prior to treatment
implementation in May 2012 (MRBP, P = 0.15). However, by May 2014, species composition
differed significantly among treatments (MRBP, P = 0.004). Pairwise comparisons revealed that
burnt-open sites had significantly different species composition to all other treatment
129
combinations (all P < 0.05). Burnt partial and burnt exclosure sites also differed significantly in
composition (P = 0.03).
Indicator species analysis identified six individual species that were associated with the
experimental treatments, each of which was positively associated with three of the treatment
combinations (all P < 0.05, Appendix S1). The fern P. esculentum was positively associated
with both burnt and unburnt open sites, as well as burnt partial sites. Conversely, the grass
Themeda australis and the herb Galium propinquum were associated with both burnt and
unburnt exclosure treatments, as well as unburnt partial treatments. A further three species were
associated with burnt exclosure treatments but differed in their other associations; the small tree
Synoum glandulosum was also associated with burnt partial and unburnt exclosure sites, the
sub-shrub Marsdenia suavolens was also associated with unburnt exclosure sites and burnt open
sites, and another small tree Persoonia linearis was associated with all burnt treatments.
Discussion
We tested plant diversity responses to browsing and the fire-browsing interaction using a
manipulative experiment in a temperate forest understory. As predicted, where browsing
increased plant community dominance, it reduced plant diversity and evenness. Prescribed fire
interacted strongly with browsing, with herbivore activity affecting these measures of plant
diversity only in burnt sites. This fire-browsing interaction was generated through a
combination of numerically-mediated and functionally-moderated pathways; fire both increased
herbivore activity levels, and increased the per-unit effect of herbivores on the plant
community.
Effect of browsing and fire
Browsing had little effect on the plant community in the absence of fire, but browsing in burnt
environments increased community dominance, reduced plant community evenness and
diversity, and altered species composition. Specifically, browsing in burnt environments
increased the dominance of the fern P. esculentum and reduced the abundance of a number of
130
palatable grasses and herbs. This pattern was consistent with previous studies where plant
diversity responses to grazing depended on the effect of grazing on the dominant plant species
(Mathisen et al. 2010; Royo et al. 2010a; Borer et al. 2014). As suggested by Royo et al.
(2010a), the variable effect of browsing on the dominant plant species can potentially explain
the wide range of reported effects of large herbivores on forest plant diversity. In systems where
large herbivores have been at high abundances for extended periods, understories are largely
dominated by a few unpalatable species; this is the case in many forested systems of North-
America (Tremblay et al. 2006; Rooney 2009) and Europe (Kirby 2001) where deer are highly
abundant. In such systems, continued browsing maintains the dominance of unpalatable species,
while herbivore exclusion can allow palatable species to recover, thereby increasing plant
species richness and evenness. In systems where large herbivores are not highly abundant,
browsing may help to maintain understory diversity by reducing the dominance of fast-growing
palatable species, particularly following disturbance (Royo et al. 2010a).
Despite having strong effects on plant community diversity and evenness after fire, we
found that browsing did not affect plant species richness, either with or without burning.
Mathisen et al. (2010) reported a similar result for moose browsing in Swedish pine forest. This
may be because much of the vegetation in both the study by Mathisen et al. (2010) and in our
study was comprised of shrubs (Appendix S1). Browsing is often not lethal for established
individuals of woody plant species (Hester et al. 2006). Thus, in forest systems with woody
understories, browsing will affect the relative cover of different species more strongly than the
relative number of individuals. In addition, as shrubs are slow-growing and long-lived
compared with many herbs and grasses (McFarland 1998), the two-year time frame of our study
may have been insufficient for differences in colonisation and extinction rates to become
apparent.
Interaction pathways
The stronger effect of herbivory on vegetation after burning occurred both via numerically-
mediated and functionally-moderated pathways. Burning both increased the herbivore activity
131
at a site (Fig. 4), and increased the per unit effect of herbivore activity on the vegetation (Fig.
2). The attraction of large herbivores to recently burnt patches has been well documented in
grassland ecosystems (Allred et al. 2011), and has also been shown for some forest-dwelling
ungulates (Fisher & Wilkinson 2005). However, previous studies of macropod herbivores
following fire have found little effect of large wildfires on macropod densities (Garvey et al.
2010; Arthur et al. 2012). These contrasting results indicate that fire-browsing interactions
driven by the attraction of herbivores to burnt areas may be more likely to occur following
small, patchy fires (as occurs with prescribed burns), than following large-scale wildfires. The
effects of prescribed fire on browsing intensity should therefore be considered in fire planning
in these systems, especially where herbivores are particularly abundant.
The greater per-unit effect of herbivores on vegetation in burnt than in unburnt sites was
likely due to the competitive release of P. esculentum following fire. After fire (and other
disturbances), Pteridium species can rapidly regenerate from below-ground rhizomes and
dominate recently disturbed environments (Skre et al. 1998; Spencer & Baxter 2006). However,
in the absence of further disturbance, the dominance of P. esculentum usually declines with time
since fire, as other plants become more established (Spencer & Baxter 2006). In our study,
browsing maintained assemblage dominance two years after fire, with P. esculentum
comprising almost 70 % of understory vegetation cover in burnt, browsed (open) sites,
compared with less than 40 % in burnt, un-browsed sites (Fig. 3). The dominance of P.
esculentum could have important consequences for the ability of the vegetation to recover to its
pre-fire state, as P. esculentum can form a shade canopy which supresses the establishment of
other plants (Tolhurst & Turvey 1992). Therefore, our results suggest that heavy browsing after
prescribed fire may lead to an understory dominated by a few fire- and browsing-resistant
species, which could be difficult to reverse.
An understory dominated by browse- and fire-resistant plants was suggested by Wisdom
et al. (2006) as a likely outcome of low severity forest fires under moderate or high herbivory.
Previous studies of the individual effects of chronic herbivory (Rooney 2001) and reoccurring
fire (Spencer & Baxter 2006) have documented transitions towards depauperate understories
132
dominated by ferns (Dennestaedtia and Pteridium respectively). Our study, and an earlier pilot
study (Dexter et al. 2013), show that, in concert, fire and herbivory can have synergistic effects,
creating a depauperate, fern-dominated understory over a relatively short time period. Our
results also show that at low levels of herbivory, differences in vegetation diversity between
burnt and unburnt sites are small. Therefore, in forests where predation by foxes and dingoes
keeps macropod herbivores at low densities, fire-browsing interactions may have limited effects
on vegetation diversity.
Although the timeframe of our study means we cannot predict whether the effects of
these fire-browsing interactions will persist in the long-term, alternate stable states driven by
chronic herbivory have been documented from a range of forest ecosystems worldwide (Royo
& Carson 2006; Raffaele et al. 2011; Tanentzap et al. 2011; Hidding et al. 2013). These systems
are characterised by understories with low floristic diversity which are dominated by a few,
unpalatable species (de la Cretaz & Kelty 1999; Horsley et al. 2003). Once such states have
developed, legacy effects can prevent the recovery of plant diversity, even if herbivore densities
are reduced (Royo et al. 2010g). Preventing the development of such states through the
integrated management of disturbances such as herbivory and fire is therefore of key
importance for the conservation of diverse forest understory flora (Royo & Carson 2006;
Wisdom et al. 2006).
Can effects on dominance always be used to predict the outcome of fire-
browsing interactions?
We were able to predict the outcome of the fire-browsing interaction in our study. However,
this was most likely due to the particularities of our study system rather than a predictability of
fire-browsing interactions in general. In our study system, the most dominant and widespread
understory species is P. esculentum, which is of low palatability (Di Stefano & Newell 2008)
and responds positively to fire (Spencer & Baxter 2006). Therefore, both fire and browsing
acted to increase the dominance of P. esculentum, and their functionally-moderated effects were
synergistic. In addition, fire increased browsing activity, meaning that the numerically-mediated
interaction between fire and browsing also had positive synergistic effects.
133
By contrast, in many other systems, the outcomes of fire-browsing interactions will be
far less predictable. For example, in a system where fire and browsing act antagonistically (e.g.
fire increases dominance, but browsing has the opposite effect, as in Eby et al. 2014), where
more than one species is dominant (and fire or browsing responses differ between these species)
and/or where functionally-moderated effects are in opposition to numerically-mediated effects,
the outcome will depend on the balance of these opposing effects. Further, fire and browsing
may interact in more subtle ways, such as modifying the strength of each other’s effects on
dominant species. For example, the tissues of plants regenerating after fire often lack the
physical and chemical defences of mature plants, meaning generally unpalatable plants can be
highly palatable after burning (Augustine & McNaughton 1998). If differences in palatability
between species are reduced, herbivores feed less selectively, so the strength of browsing
effects on assemblage dominance can be reduced or even eliminated (Augustine & McNaughton
1998). In addition, low severity fires, such as prescribed burns can have different effects on the
plant community than high severity fires that often occur as wildfire (Morrison 2002). Different
fire severities may therefore have differing effects on dominant species, and so the outcomes of
fire-browsing interactions are likely to vary with fire severity. Therefore, predicting the
outcome of fire-browsing interactions will only be possible in some ecosystems, and where
there is detailed knowledge of the palatability and functional traits of plant species. Outside of
these systems, manipulative experiments will continue to be critical to improving understanding
of the dynamics of fire-browsing interactions.
Conclusion
In forested systems that are dominated by unpalatable, fire-resistant plant species, prescribed
fire and browsing are likely to interact synergistically to increase assemblage dominance and
reduce plant community diversity. In such systems, integrated management of fire and large
herbivores will be necessary to prevent the development of an understory dominated by a
narrow set of fire tolerant, unpalatable species. In forested ecosystems where unpalatable, fire
resistant species are not dominant, the outcome of fire-browsing interactions will not be so easy
to predict. Therefore manipulative studies which can examine both the individual and
134
interactive effects of these disturbances, and their interaction pathways, will continue to play a
central role in developing our understanding of fire-browsing interactions in forest ecosystems.
Acknowledgements
Staff of BNP conducted prescribed burns. We thank the Department of Environment and the
landowners and co-managers of BNP - the Wreck Bay Aboriginal Community for supporting
this project. The Margaret Middleton Fund, The Norman Wettenhall Foundation and the Long
Term Ecological Research Network provided financial support.
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Supporting Information
Additional supporting information may be found in the online version of this article:
Appendix S1. Plant species list
Appendix S2. Tables of model rankings
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Appendix S1. Plant species list
Appendix S1. List of species sampled in experimental plots and treatment associations of individual
species that were identified by indicator species analysis as having a significant association with
one or more treatments. Nomenclature follows Robinson (1991). Letter codes for treatment
associations are as follows: BO – burnt, open; BP – burnt, partial exclosure; BE – burnt,
exclosure; UO – unburnt open; UP – unburnt partial exclosure; UE – unburnt exclosure.
Life-form Species Treatment associations P
Ferns
Calochlaena dubia
Pteridium esculentum BO, BP, UO 0.019
Palms
Livistona australis
Grasses
Austrostipa pubescens
Entolasia marginata
Entolasia stricta
Imperata cylindrica
Microlaena stipoides
Oplismenus aemulus
Oplismenus imbecillis
Poa labillardierei
Themeda australis BE, UE, UP 0.024
Sedges / Rhizomatous Perennials
Ficinia nodosa
Hypolaena fastigiata
Lepidosperma concavum
Lomandra cylindrica
Lomandra filiformis
Lomandra glauca
Lomandra gracilis
Lomandra longifolia
Lomandra micrantha
Lomandra multiflora
Restio fastigiatus
Xanthorrhoea resinifera
Herbs and Forbs
Acianthus sp.
Actinotus helianthi
Caladenia catenata
Commelina cyanea
Corybas sp.
Dianella caerulea
Dichondra repens
Galium gaudichaudii
Galium propinquum BE, UE, UP 0.042
Gastrodia sesamoides
Lagenifera stipitata
Patersonia sericea
Poranthera microphylla
Pratia purpurascens
Pterostylis sp.
Scaevola ramosissima
Schelhammera undulata
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Life-form Species Treatment associations P
Selaginella uliginosa
Viola hederacea
Climbing / Scrambling Herbs
Cassytha pubescens
Comesperma volubile
Desmodium brachypodum
Desmodium rhytidophyllum
Desmodium varians
Glycine clandestina
Glycine microphylla
Glycine tabacina
Sub-shrubs
Billardiera scandens
Coronidium elatum
Dampiera purpurea
Dampiera stricta
Gonocarpus teucriodes
Hardenbergia violacea
Opercularia aspera
Marsdenia suaveolens BE, BP, UE 0.017
Shrubs
Acacia suaveolens
Acacia terminalis
Acacia ulicifolia
Bossiaea ensata
Bossiaea heterophylla
Breynia oblongifolia
Correa reflexa
Dillwynia sp.
Epacris pulchella
Glochidion ferdinandi
Hibbertia aspera
Hibbertia empetrifolia
Hibbertia linearis
Hibbertia obtusifolia
Hovea linearis
Leptomeria acida
Leucopogon lanceolatus
Melichrus sp.
Monotoca elliptica
Monotoca scoparia
Petrophile pulchella
Phyllanthus hirtellus
Pimelea linifolia
Platylobium formosum
Platysace lanceolata
Pultenaea paleacea
Pultenaea rosmarinifolia
Ricinocarpos pinifolius
Styphelia triflora
Xanthosia pilosa
Zieria smithii
Vines
Cissus hypoglauca
Clematis aristata
Eustrephus latifolius
Hibbertia dentata
Hibbertia scandens
Marsdenia rostrata
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Life-form Species Treatment associations P
Parsonsia straminea
Sarcopetalum harveyanum
Smilax glyciphylla
Trees / Tree Seedlings
Acacia longifolia
Allocasuarina seedling
Banksia serrata
Ceratopetalum gummiferum
Corymbia gummifera
Elaeocarpus reticulatus
Eucalyptus seedling
Notelaea longifolia
Persoonia linearis BE, BO, BP 0.012
Pittosporum undulatum
Syncarpia glomulifera
Synoum glandulosum
BE, BP, UE
0.047
References
Robinson, L. 1991. Field guide to the native plants of Sydney. Kangaroo Press, Kenthurst,
NSW, Australia.
142
Appendix S2. Model rankings for linear mixed models (LMMs) and generalised
linear mixed models (GLMMs).
Table S1. Model rankings for linear mixed models (LMMs) testing the fixed effects of fire (B, burnt or
unburnt), herbivory (H, number of scats per 100m2) and time since fire (T, 3, 9, 15 or 21
months) and their interactions, plus the starting condition (Pre), on plant community diversity
metrics (species richness, Simpson‘s reciprocal diversity index, Simpson’s evenness, and
Berger-Parker dominance). All models included the random effects of block/site. Details are
provided for all models with ΔAICc < 4.
Data Model Terms K LL AICc ΔAICc AICcWt
Species richness
Pre + B + T + B:T 12 -222.09 471.9 0 0.498
Pre + B + H + T + B:T 13 -221.23 472.9 0.96 0.309
Pre + B + H + T + B:H + B:T 14 -221.15 475.5 3.54 0.085
Simpson’s reciprocal diversity (1/D)
Pre + B + H + T + B:H + B:T 14 -150.94 335.1 0 0.158
Pre + T 8 -159.14 335.9 0.87 0.103
H + T 8 -159.19 336 0.96 0.098
Pre + H + T 9 -157.99 336.1 1.01 0.095
B + H + T + B:H + B:T 13 -153.05 336.5 1.47 0.076
T 7 -161.00 337.3 2.21 0.052
Pre + B + H + T + B:H 11 -156.19 337.5 2.46 0.046
B + H + T 9 -158.80 337.7 2.63 0.043
Pre + B + T 9 -158.84 337.8 2.71 0.041
Pre + B + H + T 10 -157.70 338 2.92 0.037
Pre + B + T + B:T 12 -155.14 338 2.97 0.036
B + H + T + B:T 12 -155.32 338.4 3.33 0.03
B + H + T + B:H 10 -157.91 338.4 3.35 0.03
Pre + B + H + T + B:T 13 -154.16 338.8 3.69 0.025
B + T 8 -160.59 338.8 3.78 0.024
B + T + B:T 11 -156.89 338.9 3.85 0.023
Evenness (E 1/D)
Pre + B + H + T + B:H + B:T 14 161.53 -289.9 0 0.534
B + H + T + B:H + B:T 13 158.98 -287.5 2.35 0.165
Pre + B + H + T + B:H + B:T + H: T 17 163.92 -286 3.89 0.076
Dominance (d)
Pre + B + H + T + B:H 11 58.75 -92.4 0 0.302
Pre + B + H + T + B:H + B:T 14 62.52 -91.9 0.51 0.234
Pre + B + H + B:H 8 53.94 -90.2 2.13 0.104
B + H + T + B:H 10 56.09 -89.6 2.77 0.076
B + H + T + B:H + B:T 13 59.58 -88.7 3.65 0.049
143
Table S2. Model rankings for generalised linear mixed models (GLMMs) testing the fixed effects of fire
(B, burnt or unburnt), exclosure treatment (E, open or partial), and time since fire (T, 3, 9, 15, or
21 months) on site-level herbivore activity (number of scats per 100m2). All models included
the random effects of block/site. Details are provided for all models with ΔAICc < 4.
Model terms K LL AICc ΔAICc AICcWt
B + Ep + T 9 -281.81 584.9 0 0.330
B + Ep+ T + B:T 12 -277.65 585.4 0.46 0.262
Ep + T 8 -284.02 586.7 1.71 0.141
B + E + T + B:Ep 10 -281.69 587.5 2.58 0.091
B + Ep + T + B:Ep+ B:T 13 -277.50 588.3 3.33 0.062
145
Paper IV: Interactive effects of fire and large herbivores on web-building spiders
Understanding of how the effects of large herbivores cascade through ecosystems is limited
(see Paper I), but is important for both detecting and managing impacts. The effects of large
herbivores on other animals are often attributed to changes in vegetation (Paper I). However, in
Papers II and III, I found that plants and animals differed in their responses to the fire-herbivory
interaction. In this paper, I examined the extent to which vegetation mediated the effects of fire
and herbivory on web-building spiders – a group that is usually sensitive to changes in habitat
structure.
Foster, C.N, Barton, P.S., Wood, J.T. and D.B. Lindenmayer (2015) Interactive effects of fire
and large herbivores on web-building spiders. Oecologia. 179, 237-248.
146
Abstract
Altered disturbance regimes are a major driver of biodiversity loss worldwide. Maintaining or
recreating natural disturbance regimes is therefore the focus of many conservation programs. A
key challenge, however, is to understand how co-occurring disturbances interact to affect
biodiversity. We experimentally tested for the interactive effects of prescribed fire and large
macropod herbivores on the web-building spider assemblage of a eucalypt forest understorey,
and investigated the role of vegetation in mediating these effects using path analysis. Fire had
strong negative effects on the density of web-building spiders, which were partly mediated by
effects on vegetation structure, while negative effects of large herbivores on web density were
not related to changes in vegetation. Fire amplified the effects of large herbivores on spiders,
both via vegetation-mediated pathways, and by increasing herbivore activity. The importance of
vegetation-mediated pathways and fire-herbivore interactions differed for web density and
richness, and also differed between web types. Our results demonstrate that for some groups of
web building spiders, the effects of co-occurring disturbance drivers may be mostly additive,
whereas for other groups, interactions between drivers can amplify disturbance effects. In our
study system, the use of prescribed fire in the presence of high densities of herbivores could
lead to reduced densities and altered composition of web-building spiders, with potential
cascading effects through the arthropod food web. Our study highlights the importance of
considering both the independent and interactive effects of disturbances, as well as the
mechanisms driving their effects, in the management of disturbance regimes.
Keywords
Araneae, browsing, disturbance interaction, grazing, synergistic effects
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Introduction
Disturbance regimes drive the structure and function of ecosystems worldwide, and altered
disturbance regimes are an important cause of biodiversity loss (Sinclair and Byrom 2006).
Maintaining or recreating appropriate disturbance regimes is therefore the focus of many
conservation and restoration programs (Hobbs and Huenneke 1992; Halme et al. 2013).
Two of the most common and widely studied disturbance drivers in terrestrial systems
are herbivory and fire (Bond and Keeley 2005; Danell et al. 2006). Browsing or grazing by
large mammalian herbivores has been shown to shape the structure and function of ecosystems,
from plant and animal communities, through to nutrient cycles and even climate (Côté et al.
2004; Danell et al. 2006; Foster et al. 2014). Fire is an episodic disturbance, and the frequency,
intensity and spatial extent of fires also drives the structure and function of ecosystems
(Thonicke et al. 2001; Bond and Keeley 2005). Both of these disturbances can affect biota
either directly (e.g. through direct mortality), or indirectly (e.g. by modifying habitat), or both
(Thonicke et al. 2001; Côté et al. 2004). A key mechanism linking both large herbivores and
fire to effects on biological communities is altered vegetation structure and complexity (Bond
and Keeley 2005; Foster et al. 2014).
As disturbances rarely occur in isolation, understanding how disturbance drivers
interact to affect biota is critical for effective conservation management (Wisdom et al. 2006;
Didham et al. 2007; Mantyka-pringle et al. 2012). Although the ecological effects of
disturbance have been widely studied, investigations of the interactive effects of disturbance
drivers are much less common (Wisdom et al. 2006; Didham et al. 2007; Foster et al. 2014).
Interactions between fire and herbivory have been reported in a range of ecosystems, and can
occur in a number of ways. For example, patterns and intensity of herbivory can affect fuel
loads and hence modify the spatial extent or intensity of fire (Wisdom et al. 2006; Kimuyu et al.
2014). Similarly, as many herbivores are attracted to the new growth available in recently burnt
areas, fire can affect the spatial distribution and intensity of herbivory (Allred et al. 2011). Fire
and herbivory also can interact via what is termed an interaction modification, where fire
changes the mode of action or per-unit effect of herbivory on organisms (sensu Didham et al.
148
2007). For example, Royo et al. (2010) found that moderate levels of deer browsing increased
understorey plant richness in burnt deciduous forest, but not in unburnt forest. Interactions
between disturbance drivers can be synergistic (i.e. effects magnified, e.g. Barton et al. 2011) or
antagonistic (i.e. effects diminished or reversed, e.g. Matlack et al. 2001), and by definition,
differ from what would be predicted from the additive effects of each driver occurring in
isolation (Didham et al. 2007; Crain et al. 2008).
Most studies of fire × large herbivore interactions have investigated effects on
vegetation (e.g. Royo et al. 2010; Kerns et al. 2011), and to date only a small number of studies
have investigated how these interactions affect animal assemblages. Among these studies, there
appears to be a consistency between vegetation and animal responses; most studies which report
interactive effects on animals also report interactive effects on vegetation (e.g. Matlack et al.
2001, deer mice; Bailey and Whitham 2002, arthropods), while studies which find no interactive
effects on animals also find no interactive effects on vegetation (e.g. Jonas and Joern 2007,
grasshoppers; Underwood and Christian 2009, ants).
Web-building spiders are a group of animals that have been found to respond to both
fire (Buddle et al. 2000) and large herbivores (Miyashita et al. 2004; Warui et al. 2005), but the
responses of these spiders to fire-herbivore interactions have not previously been studied. Web-
building spiders respond strongly to changes in vegetation structure (Langellotto and Denno
2004), and are the dominant invertebrate predators in terrestrial food webs (Riechert and
Lockley 1984; Carter and Rypstra 1995). Therefore, disturbance-induced changes in vegetation
structure may modify spider densities, which could have important consequences for trophic
dynamics (Schmitz 2008). In addition, different types of web-builders may differ in their
response to habitat complexity, for example, Halaj et al. (2000) found that sheet weaving
spiders, which build complex three-dimensional webs, responded more negatively to habitat
simplification than orb-weaving spiders. As different types of web-builders target different prey
items (Nyffeler 1999), changes in vegetation structure also may affect food web structure by
altering the composition of the predator guild. As disturbance effects can cascade through
ecosystems via both trophic and non-trophic pathways (Ohgushi 2005), it is important to
149
understand the extent to which disturbance effects are mediated by changes in vegetation, and
whether managing disturbances to maintain vegetation condition will also cater for the
requirements of fauna (Clarke 2008).
In this study, we tested for the effects of fire, large macropod herbivores and their
interaction on the web-building spider assemblage of a eucalypt forest understory. We used a
randomised, blocked experiment, combining prescribed fire and herbivore exclusion treatments,
to address three questions: (1) Do large herbivores and fire interact to affect the density or
richness of web-building spiders? (2) To what extent are the effects of these disturbances
mediated by changes in vegetation? And (3) Do these effects differ between different types of
web-builders? We predicted that both fire and large herbivores would reduce web-building
spider density and richness by reducing the structural complexity of vegetation, with sheet web-
builders responding most strongly to vegetation simplification.
Materials and methods
Study site
We conducted our study in Booderee National Park (BNP); a ~6 500 ha peninsula in south-
eastern Australia (35°10′S, 150°40′E, see Online Resource 1). We established sites within the
Eucalyptus pilularis forest of BNP, which is the most widespread vegetation type in the park
(Barton et al. 2014). An intensive baiting program targeting the introduced red fox (Vulpes
vulpes) has been in place in BNP since 1999 to protect native small and medium-sized mammal
species from predation (Dexter et al. 2012). Loss of native predators and a lack of human
hunting mean that without foxes, predation pressure on native macropod herbivores is low
(Lindenmayer et al. 2014). Over the last decade, there has been a tenfold increase in the
numbers of these herbivores in BNP (predominantly Wallabia bicolor, a generalist browser and
Macropus giganteus, a grazer, Family Macropodidae) (Dexter et al. 2012; Lindenmayer et al.
2014). A short-term exclosure trial has indicated that this high abundance of native herbivores
could be driving a shift in vegetation composition (Dexter et al. 2013). As prescribed fire is
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commonly used in eucalypt forests to reduce the risk of high intensity wildfire, promote
regeneration of senescing vegetation, and/or increase habitat heterogeneity (Williams et al.
1994), it is important to understand how fire interacts with high abundances of herbivores to
affect biodiversity.
Study design
We tested the interactive effects of prescribed fire and large herbivores on understorey
vegetation and web-building spiders using a randomised blocked experiment. We combined
three levels of herbivore treatment (open, partial and exclosure) and two levels of burning
treatment (burnt and unburnt) in a factorial design. We replicated each of these six treatment
combinations across four experimental blocks to give a total of 24 sites (Online Resource 1).
We created the herbivore treatments by using exclosure fences to reduce the density of
macropods within 0.125 ha (25 m × 25 m) plots, to produce three treatments: full herbivory
(open treatment), intermediate herbivory (partial treatment – plots were fenced but gates opened
and closed at two month intervals to create a lower browsing pressure) and no herbivory
(exclosure treatment). Exclosure fences were constructed in June 2012 using 1.1 m tall wire
fencing, which we found to be effective at excluding macropods (see Results). Smaller animals
were observed to move freely through the fence, and other large animals are rare in the park, so
effects of exclosure fences were assumed to occur primarily via their effect on macropods. For
the burning treatments, small (50 × 50 m), low-intensity burns were conducted across half of the
herbivory treatment sites in August 2012.
Data collection
We sampled spider webs and vegetation within four 3 × 3 m plots within each site (one in each
of the four quarters of the site). Data were collected three months post-fire (November 2012)
and 15 months post-fire (November 2013). Plots were established at least 1.5 m from the edge
of the site.
We counted spider webs as a surrogate measure for the web-building spider
assemblage. This method was described and tested by Gollan et al. (2010), who found that the
151
diversity of web-types (based on web architecture) was strongly correlated with the diversity of
spider genera in a site. As the richness of spider genera can be a viable surrogate for the species
richness of spiders (Foord et al. 2013), this method allowed us to assess compositional and
diversity responses of spiders, in addition to density responses. We used vaporised water,
applied with a pressurised spray mister, to assist in locating webs, and counted and identified all
spider webs within each of the four plots in each site. Each web was assigned to one of 32 web
types based on their architecture, according to the key of Smith (2008) (see Fig. 1 for
examples). From this, we generated measures of web density (number of webs per 3 x 3 m plot),
web richness (the number of different web types per plot) and web composition (the assemblage
composition of web types) for each plot. To minimise variation due to weather conditions,
surveys were delayed for 48 hours following strong wind or rain to allow spiders to rebuild
damaged webs.
We recorded the following vegetation variables from each plot; total understorey
foliage projective cover (the proportion of ground area covered by foliage held vertically above
it, Specht and Morgan 1981), foliage projective cover of vascular plants by life-form,
understorey height (measured at 10 evenly spaced locations per plot using the stick and foam
disc method of Smit et al. (2001), disc 100 mm diameter, 4.7 g weight), litter depth (measured
at 10 evenly spaced locations per plot) and stem density (number of live woody stems at ground
level within a 1 × 1 m sub-plot). Life-forms were grouped into the broad structural categories of
ferns, grasses (Poaceae), herbs (including forbs and climbers), sedges (which included grass-
like perennial herbs) and shrubs (including sub-shrubs and tree seedlings).
We measured the effects of burning and the herbivory treatments on herbivore activity
using scat (pellet) counts. Scat counts are a commonly used method to assess the comparative
density of macropod herbivores between sites (e.g. Howland et al. 2014; Pedersen et al. 2014).
We counted the number of macropod scats along two 25 × 2 m transects (100 m-2) in each site
approximately every two months from August 2012 to December 2013. Counts from the two
transects were summed to give one count per site. We removed scats from transect lines on each
sampling event to avoid double counting. For each site, we summed the count preceding and
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that following the spider web counts to give an approximate index of herbivore activity in each
site at the time of the web count.
Figure 1. Examples of web types encountered in surveys. One example of each of the four
groups of web types is shown: (a) web 9, an orb web, (b) web 28, a sheet web, (c) web
23, a lace web and (d) web 32, a tangle web.
Data analysis
Effects of fire and large herbivores on web density and richness
We used generalised multi-level path models (Shipley 2009) to test the effects of fire and large
herbivores on spider web density and richness, and the extent to which these effects were
153
mediated by vegetation changes. Generalised multi-level path analysis uses directional-
separation (d-sep) tests to assess the goodness of fit of a hypothesised causal diagram to the
patterns of dependence and independence within a dataset (Shipley 2002). This analysis is based
on a structural equation modelling (SEM) framework, but has been generalised to accommodate
hierarchical designs and non-normal response variables (Shipley 2009).
We hypothesised that the effects of fire, herbivores and their interaction on spiders
would be largely vegetation-mediated, but would also occur via other mechanisms that operate
independently of vegetation structure (Fig. 2). Our rationale for the construction of this causal
model was as follows: Fire can affect spiders through changes in vegetation structure (Brennan
et al. 2006), or via other mechanisms that operate independently of vegetation (the direct fire-
spider pathway in Fig. 2), such as fire-induced mortality (Bell et al. 2001), or changes in prey
availability (York 1999). Similarly, large herbivores have been found to affect spiders by
modifying vegetation structure (Miyashita et al. 2004), but could also affect spiders through
other mechanisms (the direct herbivore-spider pathway in Fig. 2) such as physical disturbance
of webs (Chmiel et al. 2000), or changes to key resources such as arthropod prey (Foster et al.
2014). We also identified three possible pathways by which fire could interact with large
herbivores to affect spiders; (1) a chain effect, where fire attracts herbivores to burnt areas,
increasing the level of herbivore activity in burnt sites (Allred et al. 2011), (2) an interaction
modification, where fire alters plant traits, modifying the effect of herbivores on vegetation
(Augustine and McNaughton 1998), or (3) an interaction modification where fire increases the
vulnerability of web spiders to other impacts of large herbivores (e.g. by reducing prey
availability, increasing the likelihood of spiders abandoning webs after physical disturbance,
Chmiel et al. 2000).
Confirmatory path analysis does not allow for reciprocal effects among variables
(Shipley 2009), but a number of vegetation variables we measured were likely to be reciprocally
related (for example, high grass cover would lead to low average understory height and low
stem density in a site). Therefore, we selected three vegetation variables that were not correlated
with each other, but made up a large component of the vegetation and were correlated with
154
other vegetation variables, to include in the path analysis (cover of shrubs, sedges and ferns).
While this approach avoided reciprocity between variables, in excluding some vegetation
variables, we potentially omitted variation in vegetation structure that could explain spider
responses to disturbance. Therefore, we also conducted a sensitivity analysis (sensu Ruffell et
al. 2014) to test whether including additional vegetation variables in our path model would
increase the extent to which disturbance effects were mediated by vegetation (Online Resource
2). To do this, we used principal components analysis to reduce our nine vegetation variables to
seven orthogonal components, and used these as the measures of vegetation structure in our
path analysis. We did not use principal components in the main analysis as principal
components are less correlated than would be expected by chance, and including them in the
path analysis would reduce our chance of rejecting an incorrectly specified path model (Ruffell
et al. 2014).
Figure 2. Hypothesised causal diagram of the effects of fire and large herbivores on web-
building spiders. We predicted that the effects of fire and herbivores on spiders would
be largely vegetation-mediated, but may also occur via other mechanisms that operate
independently of vegetation structure. We also predicted that fire may potentially
interact with large herbivores by increasing herbivore activity (an interaction chain), or
by modifying the effects of large herbivores (an interaction modification).
For each of web density and web richness, we constructed two causal diagrams, one for
each year of the study, with the cover of shrubs, sedges and ferns as measures of vegetation
structure (each with their own node). For each of these diagrams, we tested goodness of fit
using d-sep tests (Shipley 2009). Once we had tested the goodness of fit of the full path model,
Fire Herbivores
Vegetation
Structure
Spiders
Vegetation-mediated
effects
Other effects
Interaction modification
Interaction chain
155
we simplified the model to a more parsimonious one using a backward selection approach
(sensu Ruffell et al. 2014). Backward selection based on minimising AIC was used to simplify
each sub-model within the full model (Zuur et al. 2009). Each sub-model was a mixed-effects
model fitted with maximum likelihood estimation, and included an endogenous variable as the
response and its direct causal parents as predictors. Once all sub-models had been simplified,
they were grouped back into a single path model and the fit of this model was tested using
generalised multilevel path analysis and d-sep tests as described above.
All analyses were completed using R (R Core Team 2013). For GLMMs we used the
glmer function in the package lme4, using a Poisson distribution and log-link function (Bates et
al. 2014), while for LMMs we used the lme function in the package nlme (Pinheiro et al. 2014).
Random effects for all GLMMs and LMMs were sites within blocks (block/site). When used as
predictors, count variables were ln-transformed and continuous variables were centred on their
means. Response variables were checked for over-dispersion and model residuals were
inspected to verify that the data met model assumptions (Zuur et al. 2009). After deciding on the
final model for both web abundance and richness, we calculated path coefficients as the
estimated slopes of the variables within each of the sub-models (Shipley 2009). Unstandardized
path coefficients can be interpreted as the change in the response variable for a one unit change
in the predictor variable (Aiken and West 1991). However, in the presence of an interaction,
these path coefficients are conditional effects. Because all predictors were centred, the
conditional effects can be interpreted as the effect of the predictor on the response variable
when the interacting predictor is held at its mean value, or in the case of categorical predictors
(fire and herbivore exclosure treatments) at the control value (unburnt and open treatments
respectively). The interaction term indicates the amount of change in the slope of the regression
of the response on the predictor with a one-unit change in the value of the interacting predictor.
Effects of fire and large herbivores on different web types
To test whether different types of webs responded differently to large herbivores and fire, we
estimated unstandardized regression coefficients when the density of that web type was
156
substituted for overall web density in the full path diagram. Each of the individual web types
was assigned to one of four groups based on similarity of web characteristics - orb webs, sheet
webs, lace webs and tangle webs (Fig. 1, Online Resource 3). Such groupings are commonly
used in studies of web-building spiders, and while there is some overlap, these categories
broadly sort spiders into groups of families (e.g. Halaj et al. 2000). Orb weavers are generally in
the families Araneidae, Tetragnathidae, and Uloboridae, sheet weavers in the families
Linyphiidae, Theridiidae and Stiphidiidae, lace weavers belong to Desidae, and tangle web
spinners are generally in the family Theridiidae (Online Resource 3). We used a separate
GLMM for each web type grouping in each year with a Poisson distribution and log-link
function and random effects of block/site. We used backward selection as described above to
simplify the model for each web type in each year.
We also analysed the effect of our treatments on the composition of individual web types
using partial (or conditioned) canonical correspondence analysis in R (R Core Team 2013),
using the “cca” function in the package “vegan” (Oksanen et al. 2013), and using the Bray-
Curtis dissimilarity measure. This analysis allowed us to partial out the spatial variation
associated with the experimental blocks, before analysing the variation in web type composition
that was associated with our experimental treatments (herbivory × fire × year) (Borcard et al.
1992). We then ran permutation tests using the function “anova.cca” to test the significance of
our constraints (treatment combinations) using 10 000 permutations of the data. To reduce the
incidence of zero values in the data caused by rare web types, we pooled web counts to the site
level for this analysis and excluded web types occurring at two or fewer sites.
Results
Density and richness of spider webs
We counted 3687 spider webs, representing 28 different web types, across the two sampling
periods (Online Resource 3). Generalised multilevel path analysis indicated that herbivores and
157
fire affected spider web density via both vegetation-mediated and other pathways, but effects on
web type richness were of short duration and not mediated by changes in vegetation.
For web density, the simplified path models (2012: χ2 = 34.7, df = 30, P = 0.25, 2013: χ2
= 29.0, df = 28, P = 0.41) gave as good fit as the full models (2012: χ2 = 25.9, df = 22, P = 0.26,
2013: (χ2 = 28.5, df = 22, P = 0.16) in both years. The simplified model for web density in 2012
indicated that fire had a strong negative effect on web density, which was partly mediated by
negative effects of fire on vegetation cover (Fig. 3a). In contrast, the small, but significant,
negative effect of large herbivores on web density was not mediated by changes in vegetation
structure. By 2013, the effects of fire on vegetation variables were weaker, which was
associated with a recovery in vegetation (Fig. 3b). Both the vegetation-mediated effects, and the
other effects, of fire on web-density were reduced in 2013 compared with 2012. While the
effect of fire on shrub cover was reduced in 2013, shrub cover remained a strong determinant of
web density in 2013. In 2013 there also was a marginally significant interaction between fire
and herbivores, where herbivore activity was positively associated with fern cover in burnt, but
not in unburnt sites (Fig. 3b, Online Resource 2 - Figs. OR3a,b). High fern cover was associated
with higher web density in the path model (Fig. 3a). As in 2012, in 2013 there was a small
negative effect of herbivores on web density which was not explained by vegetation structure.
Sensitivity analysis indicated that including all vegetation variables in the path model did not
increase the amount of variation in web density that was explained by vegetation-mediated
pathways (Online Resource 2).
Model fits for web type richness were similar to those for web density, where our
simplified model (2012: χ2 = 35.6, df = 34, P = 0.39, 2013: χ2 = 30.2, df = 34, P = 0.65) gave as
good a fit as the full model (2012: χ2 = 23.8, df = 22, P = 0.35, 2013: χ2 = 25.0, df = 22, P =
0.30) in both years of the study. The simplified path models indicated that the effects of
disturbance on web-type richness were not mediated by changes in vegetation structure (Fig.
3c,d). Fire had a short-term negative effect on web-type richness which was no longer evident
in 2013 (15 months after fire). Large herbivores had a small negative effect on web-type
richness in both years, and this effect was strongest in 2012, when herbivore activity was
158
elevated in burnt sites (Fig. 3c,d). As with web density, including all vegetation variables in the
path analysis did not increase the strength of vegetation-mediated effects on web type richness
(Online Resource 2).
Figure 3. The effects of fire, herbivores and their interaction on web-building spider density
(a,b) and richness (c,d), and the extent to which these effects were mediated by
vegetation. Arrows represent causal paths between the experimental treatments (square
boxes) and plant and animal responses (rounded boxes). Path coefficients are
unstandardized partial regression coefficients. Dashed arrows indicate non-significant
relationships, significance levels of path coefficients: ^ P ≤ 0.1, * P ≤ 0.05, ** P ≤ 0.01,
*** P ≤ 0.001. Herbivore activity was ln transformed when used as a predictor.
Fire Herbivores
Shrub Fern
Web density
Partial Exclosure
-1.7 *** -3.4***
0.62***
Sedge
-0.61*** -0.13*
0.96**1.13***
-0.08*** -0.15*** -0.04*
Fire Herbivores
Shrub Fern
Web density
Partial Exclosure
-1.0 *** -4.0***
-0.14^
Sedge
-0.46*** -0.09*
1.8*** 0.43^
-0.03^ -0.06* 0.03
0.03^
-0.004
Fire Herbivores
Shrub Fern
Web type richness
Partial Exclosure
-1.7 *** -3.4***
0.62***
Sedge
-0.08*** -0.15*** -0.04*
-0.46*** -0.06*
Fire Herbivores
Shrub Fern
Web type richness
Partial Exclosure
-1.0 *** -4.0***
-0.14^
Sedge
-0.03^ -0.06* 0.03
0.03^
-0.004
-0.03
(a) Web density
2012
(c) Web type richness
2012
(b) Web density
2013
(d) Web type richness
2013
Positive effect Negative effectDriver makes effect
more negative
Driver makes effect
more positive
159
Responses of different web types
Substituting different web type groupings into the full model in place of web density revealed
key differences in the factors affecting different types of webs. Orb web density was higher on
sites with higher shrub cover, a relationship which mediated the negative effects of fire on orb
webs in both years (Table 1). In 2013, orb webs also were positively associated with higher fern
cover. In contrast, while some of the effects of fire on sheet webs were vegetation-mediated,
there was a strong negative effect of fire on sheet webs in both 2012 and 2013, which was not
vegetation mediated (Table 1). Sheet webs also responded negatively to herbivore activity on
both years, a response which was also not explained by changes in vegetation. Tangle webs and
lace webs showed only weak or inconsistent responses to the experimental treatments, with
tangle webs showing a shrub-mediated negative response to fire and a negative response to
herbivore activity in 2012, but no responses to disturbance in 2013 (Table 1).
Table 1. Estimated coefficients (and SE) of parameters for the four different types of webs, when
substituted for overall web density in the path diagrams for 2012 and 2013. All models included
the blocking structure of block/site as a random effect. Significance levels: ^ P ≤ 0.1, * P ≤ 0.05,
** P ≤ 0.01, *** P ≤ 0.001
Model term Estimate (se)
Orb webs Sheet webs Tangle webs Lace webs
2012 2013 2012 2013 2012 2013 2012 2013
Shrub cover
1.23 (0.64)^
2.87 (0.63)***
- - 2.18 (0.77)**
- - -11.1 (4.0)**
Sedge cover
- - 2.11 (0.37)***
-1.34 (0.49)**
- - - -2.9 (1.9)
Fern Cover -1.42 (0.90)
1.55 (0.41)***
- -1.25 (0.45)**
- - - -
Fire -0.76 (0.24)**
- -1.6 (0.23)***
-1.84 (0.29)***
- -0.07 (0.12)
- -
Herbivores -0.13 (0.08)^
- -0.19 (0.07)**
-0.19 (0.08)*
-0.17 (0.05)***
0.02 (0.05)
- -
Fire * herbivores
- - - - - -0.12 (0.07)
- -
160
Compositional differences in web-types reflected the strongest effects in the analysis of
web types. The first two axes of the partial CCA analysis accounted for 14.8 % and 12.4 % of
the variation in web type composition, respectively. There was a significant interaction between
year and burning treatment (P = 0.03, Fig. 4). There were also significant differences in web
type composition between burning treatments (P < 0.01), and years (P < 0. 01), but not between
herbivory treatments or any of its interaction terms (all P > 0.05). The composition of burnt
sites appeared to be a sub-set of unburnt sites, with the two most common sheet webs (web 25
and 27, belonging to the families Theridiidae and Linyphiidae respectively), strongly associated
with unburnt sites (Fig. 4).
Figure 4. Site scores (linear combinations of variable scores) for axis 1 and 2 of the partial
canonical correspondence analysis on the distribution of individual web types with
respect to the experimental treatments (burning × herbivory × year), after blocking
effects had been partialed out. Ellipses indicate one standard deviation from the
centroid of each burning × year treatment combination. Numbers identify individual
web types: 1-20 – orb webs, 21-24 lace webs, 25-29 sheet webs, 30-32 tangle webs (see
Online Resource 3 for individual descriptions). Overlapping web numbers are replaced
with points (+).
161
Discussion
We used a combination of burning and herbivore exclusion treatments to test the combined
effects of fire and large herbivores on web-building spiders in a forest understory. Fire and large
herbivores interacted via a chain effect, where fire increased herbivore activity, which in turn
affected the web-building spider assemblage. Fire and large herbivores also interacted via
vegetation-mediated pathways to affect spiders, although this interaction was only marginally
significant. The extent to which vegetation structure mediated disturbance effects and the
importance of interactive effects differed for web density and richness, and also between web
types. Strong effects of disturbance on web-building spiders that were not mediated by
vegetation indicate that managing disturbances to maintain vegetation structure is unlikely to
adequately address the needs of fauna in this system.
Fire, but not herbivore effects on web density were vegetation-mediated
Web density was most strongly affected by fire, and much of this effect was mediated by
changes in vegetation structure. The loss and subsequent recovery of vegetation after fire (Fig.
3) was mirrored by a loss and partial recovery of spider web density, with spiders likely
responding to changes in web-site availability and litter accumulation that occurred with
changes in vegetation cover (Brennan et al. 2006; Podgaiski et al. 2013). However, fire also had
strong effects on web density that were not explained by vegetation responses, and these effects
persisted in the second year of the study (Fig. 3a,b). As our experimental burns were small (50 x
50 m), and many spiders are able to rapidly disperse via aerial ballooning (Bell et al. 2005;
Langlands et al. 2011), this strong residual effect of fire is unlikely to be limited by
recolonization ability. We suggest that other changes that can occur after fire, but were not
measured this study, such as reduced soil/litter moisture, or reduced abundances of arthropod
prey, may have limited the re-establishment of high densities of spiders following fire
(Neumann and Tolhurst 1991; York 1999).
Fire and large herbivores interacted to increase the cover of ferns, which had a weak
positive effect on web density. This interaction likely occurred due to selective browsing by
162
herbivores allowing the less palatable bracken to dominate in burnt, browsed environments
(Augustine and McNaughton 1998). This increased cover of ferns was positively associated
with web density, with fern cover likely providing suitable web sites in an environment where
cover of other lifeforms remained low (Online Resource 4). Overall, very little of the effect of
large herbivores on spiders was mediated by vegetation, which contrasts with a number of
previous studies, which have attributed negative effects of large herbivores on spiders to
changes in vegetation structure (e.g. Miyashita et al. 2004; Warui et al. 2005).
Path analysis revealed that large herbivores negatively affected web density (and also
web type richness) via non-vegetation-mediated pathways, likely through the physical
disturbance of webs. Web damage is one of the main triggers for a spider to abandon a web site
(Chmiel et al. 2000). Repeated web disturbance may therefore have reduced web density by
causing spiders to move out of sites with high herbivore activity, or by reducing spider fitness,
as spiders which move web sites must expend considerable energy in web reconstruction
(Rypstra 1983; Chmiel et al. 2000), and are more vulnerable to predation when moving between
sites (Lubin et al. 1993). The effect of herbivores on web density was greatest in 2012 (Fig. 3a)
and this was likely due to the chain interaction between fire and herbivores, where herbivore
activity was higher in burnt sites. This type of interaction has been reported by many previous
studies, where burning focusses herbivore activity in burnt patches (Klop et al. 2007; Allred et
al. 2011). This greater level of herbivore activity in recently burnt sites would have led to
greater rates of web disturbance, and hence the stronger negative effects on spiders.
Disturbance effects on web type richness were not vegetation-mediated
In contrast to web density, the effects of disturbance on web type richness were of short
duration and were not mediated by effects on vegetation structure (Fig. 3c,d). The short-lived
effect of fire suggests that spiders were able to rapidly re-colonise sites as the vegetation
recovered from fire, a result that is not surprising given the small scale of the burns in our study
(50 x 50 m) and the high capacity of spiders to disperse via both ground movement and aerial
ballooning (Bell et al. 2005; Langlands et al. 2011). Such short-term effects of fire on spider
163
richness are consistent with previous studies from fire-prone environments, where post-fire
recovery of spiders can be rapid (e.g. Brennan et al. 2006; Podgaiski et al. 2013). Spider
richness also was directly affected by herbivore activity, where sites with higher herbivore
activity had slightly (but significantly) lower web richness (Fig. 3a). This is likely due to a few
web types being particularly vulnerable to physical disturbance, causing them to occur only
rarely on sites with high herbivore activity.
Responses differed between web types
Different web types showed clear differences in their response to fire, large herbivores, and
their interaction. Orb web weavers showed a strong post-fire recovery which was largely
mediated by vegetation, while sheet web weavers showed a strong negative response to fire,
with little recovery after 15 months. These differences are attributable to key differences in the
ecology of these different types of web spinners. Firstly, orb weavers tend to build their webs in
higher strata of the vegetation than sheet weavers (Janetos 1982), and so are more likely to be
able to escape being killed by a low intensity fire. Second, orb weavers tend to have high
dispersal capabilities, allowing them to re-colonise rapidly following disturbance (Bell et al.
2005). Third, sheet weavers often have a high proportion of litter arthropods in their diets,
compared with orb weavers which target aerial prey (Harwood et al. 2003). Therefore, the dry
litter conditions which usually occur after fire may have supported low abundances of the
decomposers which are key prey items for sheet weavers (Neumann and Tolhurst 1991; York
1999). Fourth, orb webs are more efficient at prey capture than sheet webs (Zschokke et al.
2006), and so orb-web weavers may be able to persist with low post-fire prey densities than
sheet web builders. Finally, orb web builders may be better able to use the post-fire vegetation
than sheet web builders. Orb weavers responded positively to the recovery of fern cover in burnt
sites in 2013, which likely allowed their rapid recovery after fire. In contrast sheet web density
was negatively related to the cover of ferns. An abundance of ferns may provide suitable
structure for orb weavers to build webs spanning open spaces (Rypstra 1983; Halaj et al. 2000),
but may not provide sufficient ground-level structure for sheet webs (Janetos 1982, pers. obs.).
164
While orb weavers, sheet weavers and tangle weavers all responded negatively to the
high level of herbivore activity in burnt sites in 2012, sheet weavers were the only group to
show a consistent negative response in 2013, when herbivore activity was lower. Many sheet
webs are larger than tangle and lace webs, are constructed between, rather than within, plants,
and are built close to the ground (e.g. web 28, Fig. 1b), all of which would make them
vulnerable to trampling and physical disturbance by herbivores. Further, sheet webs have lower
rates of prey capture than orb webs, as well as greater costs of initial web construction
(Zschokke et al. 2006), which may cause sheet weavers to be more likely to abandon a site after
web disturbance (Chmiel et al. 2000). As sheet web building spiders were more strongly
affected by disturbance and were slower to recover than other types of web builders,
disturbance caused a shift in the composition of this important predator guild. As different types
of webs target different types of arthropod prey (Nyffeler 1999; Harwood et al. 2003), these
compositional changes to the spider assemblage could have important cascading effects through
the arthropod food web. Understanding how the effects we observed for spiders affect the rest
of the arthropod community therefore remains a key area for future research.
Conclusions
Our study has shown that fire and large herbivores can interact both via vegetation-mediated
pathways, and via chain effects, to affect web-building spiders, an important component of the
forest understory fauna. In our study system, the use of prescribed fire in areas with high
densities of native herbivores could lead to reduced densities and altered composition of web-
building spiders, with potential cascading effects through arthropod food webs (Riechert and
Lockley 1984; Carter and Rypstra 1995). Managing the ecosystem to reduce the effects of
herbivores on vegetation post-fire (i.e. managing the interaction modification) may be
ineffective in mitigating the combined effects of disturbance, as the chain effect of fire on
herbivore activity also had important short-term effects on spiders. Our results reinforce the
importance of considering both independent and interactive effects, as well as the different
types of interactions, when managing disturbance regimes (Wisdom et al. 2006; Didham et al.
2007; Crain et al. 2008).
165
The differing strength of vegetation-mediated pathways between web types observed in our
study revealed the importance of understanding the mechanisms driving effects for both
predicting interactions and managing disturbance effects (Didham et al. 2007; Crain et al.
2008). In this system, monitoring and managing the effects of disturbance on vegetation (a
common approach to management of disturbances such as fire (Clarke 2008)), is unlikely to
detect or prevent important changes in the spider assemblage. Understanding of mechanistic
pathways is also essential if studies are to be used to inform management in un-studied
locations (Ruffell et al. 2014). To identify the mechanisms driving disturbance interactions,
long-term, multi-taxon studies, which simultaneously address multiple stressors, will be needed
(Tylianakis et al. 2008; Foster et al. 2014). When applied to such studies, analytical approaches
such as path analysis will give valuable insights into the importance of different interaction
pathways. This mechanistic understanding will be useful, not only in predicting the outcomes of
interacting disturbance drivers, but also in identifying appropriate actions to manage their
effects on biodiversity (Didham et al. 2007; Crain et al. 2008).
Acknowledgements
Staff at Booderee National Park conducted prescribed burns. Chris Macgregor assisted with
fence construction and plant identification. Many volunteers assisted with data collection. Chloe
Sato provided valuable feedback on the manuscript. The Margaret Middleton Fund, The
Norman Wettenhall Foundation and the Long Term Ecological Research Network provided
financial support. The experiments comply with the current laws of Australia where the research
was performed (ANU Animal Ethics protocol A2012/24 and Booderee National Park Research
Permit BDR12/00005).
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Supplementary Material
Online Resource 1 – Study location and experimental design
Site Description
This study was conducted within the Eucalyptus pilularis forest of BNP (Fig. OR1). We
selected this vegetation type as it is the most widespread vegetation type in BNP and it occurs
widely through coastal areas of Eastern Australia. In BNP this vegetation is dominated by an
overstorey of Eucalyptus pilularis, Corymbia gummifera and E. botryoides (Taws 1998;
Lindenmayer et al. 2008). The midstorey is comprised predominantly of Banksia serrata,
Acacia longifolia and Monotoca elliptica, with Synoum glandulosum and Ziera arborescens
becoming more prevalent in moist areas. The understorey is dominated by Lomandra longifolia
and Pterideum esculentum.
Figure OR1. Location of study site within the Eucalyptus pilularis forest type (grey) within
Booderee National Park (bold line). Map shows the arrangement of the 24 study sites
into four blocks with one replicate of each of the six treatment combinations in each
block. Abbreviations for levels of herbivory and burning treatments: E = exclosure, P =
partial, O = open, B = burnt, U = unburnt.
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Site selection
Sites were selected using a three step process. (1) We selected the four experimental blocks by
using vegetation maps of BNP to identify areas of continuous Eucalyptus pilularis forest which
had not been recently burnt (>8 years since fire) and which were large enough to contain six
experimental plots (approx. 12ha), and then maximising the distance between selected blocks
(minimum of 2 km between blocks, see Fig OR1). (2) We selected six sites within each block
which both minimised the total distance between plots (to reduce variation between plots) and
maintained a minimum distance of 150 m between plots (to reduce the chances of interference
between treatments, See Fig. OR2). (3) We then randomly allocated the six treatments to the six
sites within the following logistical constraints: burnt sites could not be > 50 m from an access
trail (due to operational requirements) and fenced sites could not be adjacent to an existing
long-term monitoring sites (to avoid interfering with other studies). Pre-treatment vegetation
surveys indicated there were no significant differences in vegetation structure between
treatments prior to commencement of the study.
Figure OR2. Schematic diagram of blocked design showing types and site dimensions of the
six treatment combinations (not to scale). Exact spatial arrangement varies between blocks (see
Fig. OR1).
173
References
Lindenmayer DB et al. (2008) Contrasting mammal responses to vegetation type and fire.
Wildl. Res. 35:395-408
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Australia, Canberra
174
Online Resource 2 – Reanalysis of path model including all vegetation
variables
In our main path analysis, we included only three of our nine vegetation variables in the
hypothesised causal diagram (cover of shrubs, sedges and ferns). This was because many of the
nine vegetation variables were highly correlated and potentially reciprocally related. However,
Generalised Multilevel Path Analysis is unable to handle reciprocal relationships between
variables (Shipley 2009). By including only three vegetation variables in the path analysis, we
were omitting a large amount of the measured variation in vegetation structure. Therefore, any
significant effects of vegetation structure on spiders that were not captured by the three selected
variables, would be attributed to “direct” rather than vegetation-mediated effects of disturbance
on spiders. To test whether the significant main effects of disturbance that were not explained
by vegetation in our main analysis were in fact due to additional variation in vegetation
structure, we conducted a ‘sensitivity analysis’ including all of the nine vegetation variables in
the analysis.
This sensitivity analysis involved re-running the path analysis to include all of the
vegetation variables we measured. However, to avoid the issue of reciprocity between variables,
we first had to generate a set of uncorrelated vegetation variables (which we did using principal
components analysis), and then use these as the vegetation structural variables in the path
analysis. We did not use this approach in the main analysis, as principal components are less
correlated than would be expected by chance. Including principal components in the path
analysis, could therefore compensate for unacceptably high levels of correlation among other
independence claims, and reduce our chances of rejecting an incorrectly specified causal model.
As traditional PCA does not allow for hierarchically structured data, we used the
“phyl.pca” function in the “phytools” package in R to conduct a hierarchically structured
phylogenetic PCA of the vegetation data, where plots were nested within sites, within blocks
(see Ruffell et al. 2014 for a more detailed description of this method). We conducted a separate
PCA for each year of data, and based the PCA on the correlation (rather than the covariance)
matrix as vegetation variables were measured on different scales. We used the first seven of the
175
principal components in the path analysis, which accounted for 96% of the variation in
vegetation variables in each year (Table OR1).
Table OR1. Details of the seven principal components of the vegetation variables used in the path
analysis.
PC1 PC2 PC3 PC4 PC5 PC6 PC7
2012 Variation explained (cum. %) 33.9% 49.5% 62.3% 74.0% 83.3% 91.2% 96.0%
Variable Loadings
Total understory cover -0.95 -0.06 -0.05 0.12 -0.06 -0.03 -0.18
Stem density -0.56 0.15 0.14 -0.35 -0.03 0.70 0.14
Understory height -0.77 -0.31 0.28 0.08 0.13 -0.16 -0.05
Litter depth -0.59 0.50 -0.19 0.09 0.31 -0.24 0.45
Fern cover -0.51 -0.58 0.44 -0.29 0.01 -0.19 0.11
Grass cover 0.10 -0.53 -0.18 0.55 0.53 0.30 0.03
Sedge cover -0.54 0.41 0.20 0.61 -0.29 0.07 -0.14
Shrub cover -0.55 0.06 -0.65 -0.35 0.22 -0.06 -0.29
Herb cover -0.21 -0.50 -0.57 0.13 -0.55 0.03 0.24
2013 Variation explained (cum. %) 28.2% 44.8% 58.0% 70.3% 80.7% 89.3% 96.0%
Variable Loadings
Total understory cover 0.91 -0.05 0.21 -0.09 -0.14 -0.22 -0.03
Stem density 0.56 -0.07 0.05 0.15 -0.09 0.80 0.11
Understory height 0.83 0.10 -0.19 -0.11 0.00 -0.08 -0.12
Litter depth 0.24 0.68 -0.16 0.30 0.23 -0.13 0.54
Fern cover 0.58 -0.58 0.42 -0.11 0.21 -0.18 0.24
Grass cover 0.01 -0.35 -0.23 0.51 -0.71 -0.17 0.16
Sedge cover 0.25 0.73 0.45 0.06 -0.33 -0.04 -0.27
Shrub cover 0.42 0.06 -0.79 -0.36 -0.05 -0.03 -0.09
Herb cover 0.27 -0.12 -0.15 0.76 0.43 -0.07 -0.35
The full path model including all seven principal components had a high level of support for
web density in 2012 (χ2 = 54.9, df = 74, P = 0.95), and in 2013 (χ2 = 50.88, df = 74, P = 0.98),
and also had a high level of support when claims among principal components were excluded
(2012: χ2 = 29.6, df = 32, P = 0.59; 2013: χ2 = 30.8, df = 32, P = 0.53). Similarly, models for
web-type richness were well supported in both years (2012: χ2 = 54.9, df = 74, P = 0.95; 2013:
χ2 = 46.5, df = 74, P = 0.99), and when independence claims among principal components were
excluded (2012: χ2 = 29.6, df = 32, P = 0.58; 2013: χ2 = 26.4, df = 32, P = 0.75).
176
The models including the seven principal components gave qualitatively similar results
to our main path analysis. The negative effects of fire on web density were largely mediated by
vegetation, but also occurred via the “direct” pathway, while negative effects of herbivores on
web density occurred mostly via the “direct” pathway (Fig. OR3a,b). The negative effects of
fire and herbivores on web type richness were not mediated by changes in vegetation structure
(Fig. OR3c,d). The strength of “direct” pathways in the analysis including all vegetation
variables was not reduced compared with our main analysis. This indicates that our main
analysis captured sufficient variation in vegetation structure to provide a reliable estimate of the
strength of vegetation-mediated versus other effects of disturbance.
References
Ruffell J et al. (2014) Discriminating the drivers of edge effects on nest predation: Forest edges
reduce capture rates of ship rats Rattus rattus, a globally invasive nest predator, by altering
vegetation structure. PLoS ONE 9:e113098
Shipley B (2009) Confirmatory path analysis in a generalized multilevel context. Ecology
90:363-368
177
Figure OR3. Effects of fire, herbivores and their interaction on web-building spider density
(a,b) and richness (c,d), and the extent that effects were mediated by vegetation. Arrows
represent causal paths between the experimental treatments (square boxes) and
plant/animal responses (rounded boxes). Path coefficients are unstandardized partial
regression coefficients. Grey arrows are negative effects, black arrows positive effects,
and blue connectors are interactions. Dashed arrows indicate non-significant
relationships, significance levels of path coefficients: ^ P ≤ 0.1, * P ≤ 0.05, ** P ≤ 0.01,
*** P ≤ 0.001. Herbivore activity was ln transformed when used as a predictor.
178
Figure OR3 cont.
179
Online Resource 3 – Functional group and associated taxa of the recorded
web types
Table OR2. Functional group of web types recorded in surveys, and the taxa constructing each type in
the region of the study (adapted from Smith 2008).
Functional group
Web number
Brief description Taxa commonly constructing web
Sites present
Individuals recorded
2012 2013 2012 2013
Orb webs
W1§ Decorated - silk X
Araneidae: Argiope keyserlingi & some other Argiope spp.
0 2 0 2
W2
Decorated - silk vertical line
Araneidae: Araneus eburnus and Araneus bradleyi
4 1 4 1
W3§ Decorated, sloping Uloboridae: Zosis & other genera 0 1 0 2
W4§
Decorated - line of prey and eggs
Araneidae: Cyclosa 0 1 0 1
W5 Decorated with doily
Araneidae: Argiope keyserlingi (juv.) & some other Argiope spp.
3 0 5 0
W9 Leaf at web centre
Araneidae: Phonognatha graeffei & other Phonognatha
15 23 43 314
W10
Leaf away from web centre
Araneidae: Araneus dimidiatus 8 8 15 11
W12§ Sloping, missing sector Araneidae: Arachnura higginsi 1 2 1 2
W13
Pie slice, vertical, retreat at hub
Araneidae: Phonognatha graeffei (juv.) & other Phonognatha
22 24 180 303
W14
Pie slice, signal line to retreat
Araneidae: Metepeira 22 17 221 155
W15 Offset hub, horizontal Uloboridae: Philoponella & other genera 5 1 9 1
W16§ Plain, many radial lines
Nephilidae: Nephila plumipes and Nephila edulis (juveniles)
1 0 1 0
W17 Plain, web hub filled Araneidae: juveniles of many genera 10 18 25 47
W18 Plain, hole at hub
Araneidae: Eriophora & other genera Tetragnathidae: Tetragnatha & Leucauge
4 10 6 13
W19 Horizontal, hole at hub Tetragnathidae: Tetragnatha & Leucauge 10 7 23 12
W20§
Horizontal, v. small, cone
Theridiosomatidae 1 0 1 0
Lace webs
W21
On bark, funnel-like entrance
Desidae: Badumna longinqua, Badumna insignis
1 3 1 3
W22
Radiates from hole in twig
Desidae: Paramatachia 11 17 19 51
W23
Fans out from silk retreat
Desidae: Badumna 23 4 169 6
W24 Web around nest Desidae: Phryganoporus candidus 7 7 10 8
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Functional group
Web number
Brief description Taxa commonly constructing web
Sites present
Individuals recorded
2012 2013 2012 2013
Sheet webs
W25
"Witch's hat", irregular weave
Theridiidae: Achaearanea mundula & related spp.
20 22 492 475
W26
"Witch's hat", regular weave
Araneidae: Cyrtophora 3 0 7 0
W27
Small sheet in low vegetation
Linyphiidae 20 21 127 119
W28
Platform, burrow top of sheet
Stiphidiidae: Corasoides australis 14 7 41 27
W29
Sloping sheet, retreat below sheet
Stiphidiidae: Therlinya, Pillara, Couranga, Stiphidion & Jamberoo Theridiidae: Steatoda
7 13 13 17
Tangle webs
W30
Silk retreat, web between leaves
Theridiidae: Achaearanea, Theridion & others
20 24 83 169
W31§
Silk retreat, lines to firm surface
Theridiidae: Latrodectus, Achaearanea & Steatoda
1 0 1
W32 No silk retreat
Theridiidae: Achaearanea, Theridion & other genera
24 24 220 231
§ These rare web types were excluded from the CCA analysis.
References
Smith H (2008) BugWise Web2Spider supplement, Available at
http://publications.australianmuseum.net.au/pdf/1561_complete.pdf. Accessed 15 October
2012
181
Online Resource 4 – Response of vegetation to disturbance treatments
Figure OR4. Vegetation response to burning and herbivory treatments (selection of ‘typical’
sites).
183
Paper V: Integrating theory into disturbance interaction experiments to better inform ecosystem management
Theoretical studies of ecological disturbance have highlighted the value of understanding
interaction pathways for both predicting and managing the effects of co-occurring disturbances.
In this paper, I synthesised the findings from my experiments (Papers II, III and IV), and critically
evaluated related literature on fire-grazing interactions, to assess the ability of studies to test the
key relationships and mechanisms that are important for ecological management. Based on this
evaluation, I identified several ways that future studies can be improved to better inform the
management of disturbance interactions.
Foster, C.N, Sato, C.F., Lindenmayer, D.B., and P.S. Barton (Accepted) Integrating theory into
disturbance interaction experiments to better inform ecosystem management. Global Change
Biology, doi:10.1111/gcb.13155.
184
Abstract
Managing multiple, interacting disturbances is a key challenge to biodiversity conservation, and
one that will only increase as global change drivers continue to alter disturbance regimes.
Theoretical studies have highlighted the importance of a mechanistic understanding of stressor
interactions for improving the prediction and management of interactive effects. However,
many conservation studies are not designed or interpreted in the context of theory, and instead
focus on case-specific management questions. This is a problem as it means that few studies test
the relationships highlighted in theoretical models as being important for ecological
management. We explore the extent of this problem among studies of interacting disturbances
by reviewing recent experimental studies of the interaction between fire and grazing in
terrestrial ecosystems. Interactions between fire and grazing can occur via a number of
pathways; one disturbance can modify the other’s likelihood, intensity or spatial distribution, or
one disturbance can alter the other’s impacts on individual organisms. The strength of such
interactions will vary depending on disturbance attributes (e.g. size or intensity), and this
variation is likely to be non-linear. We show that few experiments testing fire-grazing
interactions are able to identify the mechanistic pathway driving an observed interaction, and
most are unable to detect non-linear effects. We demonstrate how these limitations compromise
the ability of experimental studies to effectively inform ecological management. We propose a
series of adjustments to the design of disturbance interaction experiments that would enable
tests of key theoretical pathways, and provide the deeper ecological understanding necessary for
effective management. Such considerations are relevant to studies of a broad range of ecological
interactions, and are critical to informing the management of disturbance regimes in the context
of accelerating global change.
Keywords
Antagonisms, compound effects, disturbance ecology, fire, grazing, higher order effects,
multiple stressors, terrestrial ecosystems, synergisms
185
Introduction
Disturbance is a major driver of change in ecosystems, and is central to both fundamental and
applied ecology. As climate change and anthropogenic pressures are driving substantial changes
to disturbance regimes such as fire, severe weather and biological invasions, understanding the
factors affecting disturbances and their ecological impacts will be essential to the effective
future management of terrestrial ecosystems (Dale et al., 2001; Turner, 2010). Recent advances
in disturbance theory include improved understanding of the spatial variability of disturbance
effects (Turner, 2010), and the potential for cross-scale effects (Peters et al., 2007), and legacy
effects (Essl et al., 2015) to produce unanticipated changes in ecosystems. Another key
advancement, and one with strong management applications, is the acknowledgement of the
prevalence of disturbance interactions (Wisdom et al., 2006; Turner, 2010), their ability to
produce ecological surprises (Lindenmayer et al., 2010; Doherty et al., 2015), and the range of
mechanistic pathways by which these interactions can occur (Didham et al., 2007; Buma,
2015). An important question, however, is whether empirical studies have kept pace with
theoretical advances, and the implications this has for informing effective ecological
management.
As theoretical models are widely used in conservation decision making, advances in
disturbance theory have the potential to guide substantial improvements in the management of
disturbance regimes (Driscoll & Lindenmayer, 2012). For example, several recent papers have
demonstrated how a disaggregated, mechanistic understanding of the effects of disturbance and
land use change on ecosystems could lead to more effective, and potentially novel, solutions for
ecological management (Didham et al., 2007; Fuhlendorf et al., 2009; Peters et al., 2011). For
theory to effectively inform management, however, it needs to be paired with empirical studies
that test its applicability to the local context (Driscoll & Lindenmayer, 2012). Yet, while there
are many excellent examples of such studies (e.g. Mandle & Ticktin, 2012; Kimuyu et al.,
2014), the majority of empirical conservation studies are not well integrated with theory, and
this potentially limits both theory development and management applications (Belovsky et al.,
2004; Fazey et al., 2005; Barot et al., 2015).
186
Here, we examine how well the experimental literature has integrated recent theoretical
developments on disturbance interactions, and how this affects management implications. We
focus on examples from studies of fire-grazing interactions as they are among the most
commonly studied disturbance interactions in terrestrial ecosystems, and as fire and grazing are
both commonly managed in terrestrial ecosystems, much research has focussed on how
prescribed fire (e.g. burn frequency) and grazing regimes (e.g. stocking density) can best be
managed for biodiversity conservation. We use a mini-review of recent fire-grazing interaction
experiments to highlight the gaps between theoretical and experimental studies, and the effect
this has on the ability of experimental studies to inform management decisions. We then discuss
how relatively simple changes to the way interaction experiments are designed and interpreted
will strengthen their links with the theoretical literature, and in doing so, will improve the
ability of experimental studies to provide useful information for the management of multiple
disturbances.
Recent advances in disturbance interaction theory
The study of disturbance interactions has evolved largely from work on multiple stressor effects
in marine systems, which is based on the ‘additive’ model of interactions (Folt et al., 1999;
Crain et al., 2008). Under this model, interactive effects occur when the combined effects of
two environmental stressors is greater than (synergism) or less than (antagonism) the sum of
their individual effects (Folt et al., 1999). Although the additive model has formed the basis of
countless experimental studies of the effects of multiple stressors (reviewed by Brook et al.,
2008; Crain et al., 2008; Darling & Côté, 2008; Jackson et al., 2015; Przeslawski et al., 2015),
current theory recognises disturbance interactions as complex, spatially and temporally variable
processes (Peters et al., 2004; Wisdom et al., 2006; Turner, 2010; Buma, 2015). This theory
includes two recent advances which have the potential to dramatically improve our ability to
predict and manage the outcomes of disturbance interactions; (1) characterisation of the
different mechanistic pathways driving interactions, and (2) increasing acknowledgement of the
likelihood of non-linear interactive effects.
187
Several recent syntheses have focussed on the mechanistic pathways by which multiple
disturbances (or stressors) interact, and the value of identifying interaction pathways for
designing effective and novel management interventions (Didham et al., 2007; Tylianakis et al.,
2008; Oliver & Morecroft, 2014; Boyd & Brown, 2015; Buma, 2015; Doherty et al., 2015). A
variety of terms have been used to describe these different interaction pathways, but despite
differences in the stressors discussed, most studies separate interactions into two broadly similar
“types” (Table 1). We adopt the terminology of Didham et al. (2007), who separate interactions
into (1) interaction chain effects, where one disturbance affects the occurrence or magnitude of
a second disturbance, and both disturbances have a direct effect on the response variable, and
(2) interaction modification effects, where the per-unit effect of one disturbance on the response
variable depends on the environmental context of a second disturbance (Fig. 1). We use the
definitions of Didham et al. (2007), as they are among the first presented in the literature, and
while originally developed in the context of habitat modification and invasive species
interactions, have been successfully adapted to characterise interactions between other stressors,
both biotic and abiotic (e.g. Mandle & Ticktin, 2012; Oliver & Morecroft, 2014). Regardless of
the terminology and definitions used, a focus on identifying the mechanistic pathways driving
disturbance interactions has the potential to provide valuable insights for ecological
management, and potentially lead to novel solutions for processes that may be difficult to
manage directly (Didham et al., 2007; Peters et al., 2011; Boyd & Brown, 2015; Doherty et al.,
2015). For example, feral predators have substantial impacts on many native species, but broad-
scale control is often unfeasible. However, as predation success is modified by habitat
complexity, it may be possible to conserve native species by improving fire management to
maintain complex habitats (i.e. managing the interaction modification) (Doherty et al., 2015).
The theoretical literature also acknowledges the likelihood that many interactions will
have non-linear effects on ecosystems, potentially leading to alternate states (Peters et al., 2004;
Wisdom et al., 2006; Oliver & Morecroft, 2014; Kayler et al., 2015). These non-linear effects
can occur both in chain (Didham et al., 2007) and modification interactions (Dunne, 2010).
Further, when chain and modification interactions both occur, their net effects may become
188
non-linear through cross-scale interactions (Peters et al., 2007). When the effects of
disturbances and their interactions are non-linear, knowledge of key points, such as when a
small change in disturbance intensity has a large effect on biodiversity (or vice versa), are
potentially invaluable for informing targeted and effective management (Peters et al., 2004;
Huggett, 2005; Groffman et al., 2006; Didham et al., 2007). For example, the effect of fire on
the susceptibility of forests to pine-beetle attacks is non-linear: low severity fire can increase the
susceptibility of forests to pine beetle outbreaks (Kulakowski & Jarvis, 2013), while high-
severity, stand-replacing fires can reduce forest susceptibility to the same pests (Kulakowski et
al., 2003). Knowledge of these non-linear effects, and estimates of the threshold at which
effects switch from negative to positive would allow managers to adjust fire management
practices, and/or conduct target management of local beetle outbreaks, to minimise the risk of
widespread pine-beetle infestations.
189
Table 1. Summary of the terms and definitions used to distinguish interaction “types” in recent reviews
of ecological interactions. Types are sorted according to how they align with the definitions of
interaction chains and interaction modifications provided by Didham et al. (2007).
Paper Context Interaction "types" and their definitions
Ecosystem
Disturbances/ stressors
Interaction chain Interaction modification
Didham et al. (2007)
Broad range of both terrestrial and marine ecosystems
Invasive species and habitat modification
Interaction chain (numerically mediated): Total impact changes because of a numerically scaled response (of the first driver) to a second driver variable
Interaction modification (functionally moderated): the per capita impact of one driver is dependent on the level of effect of a second driver
Oliver and Morecroft (2014)
Terrestrial ecosystems
Climate change and land use change
Interaction chain: one driver changes the magnitude of another driver and both drivers have a direct effect on the response variable.
Interaction modification: the per capita effect of one driver changes depending on the level of another driver
Ban et al. (2014)
Coral reefs Multiple stressors, both biotic and abiotic
Stressor interactions: where one stressor directly influences another
Synergistic effects: where two stressors interact to produce an effect on a response variable that is greater than purely additive
Doherty et al. (2015)
Terrestrial ecosystems
Invasive predators and disturbance
Numerical impact: where a disturbance increases the abundance of the invasive species
Functional impact: where a disturbance changes the per-capita impact of an invasive species
Compounding impacts: where the effect of disturbance on a population changes its ability to cope with invasion
Boyd and Brown (2015)
Marine ecosystems
Environmental drivers, focussing on warming and ocean acidification
Physiochemical interactions: interactions that occur directly between drivers, outside of organisms
Physiological interactions: where an organism’s physiological response to one driver changes with the level of another driver
Food web interactions: where interactive effects on organisms occur indirectly, via changes in food webs or ecosystem functioning
Buma (2015)
Broad range of both terrestrial and marine ecosystems
Wide range of disturbances
Linked interactions: one disturbance increases or decreases the likelihood, spatial extent, intensity or severity of a second disturbance
Compound disturbance: Recovery from a second disturbance is more or less likely, or at altered speed, due to the initial disturbance
Jackson (2015)
Marine, terrestrial and freshwater ecosystems
Multiple invasive animals
Interactions among invaders: where the presence of one invader influences the performance of a second invader
Combined impacts: where the presence of one invader influences another's impact on the ecosystem
190
Figure 1. The two major pathways by which fire and grazing can interact to affect biota
(adapted from Didham et al. 2007). (a) An interaction chain effect, where fire affects
the spatial distribution or intensity of grazing, which in turn has a direct effect on the
response variable (e.g. plant or animal abundance), but the per-unit effect of grazing on
the response variable remains unchanged. A chain interaction also can occur in the
opposite direction, with grazing affecting the spatial location, spread, and intensity of
fire. (b) An interaction modification, where the per-unit effect of grazing on the
response variable is modified by the occurrence of fire. This interaction can also occur
where grazing modifies the effect of fire on the response variable. The response curves
shown are only one example of many possible relationships. The slope and direction of
responses, and the direction and strength of interactions will vary depending on the
ecosystem, disturbances and organisms (response variables) studied.
Where are the gaps between theory and experimental studies?
Many experimental studies of disturbance interactions aim to inform management decisions,
citing conservation challenges as motivation for the study, or providing management
recommendations based on their findings. However, few studies focussing on conservation
problems are well integrated with theory (Fazey et al., 2005; Barot et al., 2015), despite the
acknowledged value of using a strong conceptual framework to guide empirical research
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(Driscoll & Lindenmayer, 2012; Barot et al., 2015), and the popularity of conceptual models for
guiding management decisions (Williams, 2011). To assess the extent of this problem among
studies of disturbance interactions, we focussed on the two recent conceptual advancements
highlighted previously: (1) the mechanisms driving interactions and (2) non-linear interactive
effects on ecosystems or biota, and quantified the extent to which these concepts have been
addressed in recent studies of fire-grazing interactions. To do this, we reviewed 50 recent papers
that focussed on fire-grazing interactions and were published between 2011 and 2015
(Supporting Information, Appendix S1). This mini-review was conducted to obtain a
representative sample of recent studies of fire-grazing interactions (most of which were
experimental) which we could use to answer specific questions about the current literature, and
is not intended as a comprehensive literature review. The 2011 cut-off was selected as a number
of key conceptual studies were published in the years 2007-2008 (e.g. Didham et al., 2007;
Peters et al., 2007; Brook et al., 2008; Crain et al., 2008; Darling & Côté, 2008), and the 2011
cut-off allowed some lag time for these ideas to become integrated into experimental studies.
Mechanisms driving interactions
Do experimental studies identify interaction pathways?
Fire and grazing can interact via a number of different pathways. For example, fire can affect
the intensity and spatial distribution of grazing as many herbivores preferentially graze in burnt
areas (a chain interaction often referred to as fire-driven grazing or pyric herbivory) (e.g. Allred
et al., 2011). Similarly, grazing can affect the location and intensity of fires by modifying the
distribution of fine fuels (also a chain interaction) (e.g. Kimuyu et al., 2014). At a more local
scale, fire and grazing, by altering the composition, traits or condition of biological
communities or individual organisms, can alter each other’s effects on those organisms (an
interaction modification) (e.g. Eby et al., 2014). However, few of the studies we reviewed
identified the mechanistic pathways driving the fire-grazing interaction, despite 80% of these
papers citing management applications as a motivation for the study. Of the 50 studies
reviewed, only one quantified the relative contributions of both chain and modification effects
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in the interaction (Mandle & Ticktin, 2012), and 30 did not quantify any pathway, reporting
only net effects of the interaction (Fig. 2). Of these 30 studies, five included description of more
than one potential pathway driving the observed effects, 15 described only one potential
pathway, and 10 did not provide any ecological definition of how the “interaction” might be
occurring (Fig. 2).
Overall, 30% of the fire-grazing studies we reviewed discussed only one interaction
type, but did not provide evidence that this interaction type was driving the observed effects.
For example, 13 of the 22 studies that defined only chain interactions (mostly fire-driven
grazing) actually tested for net interactive effects, and did not quantify the extent to which fire
affected herbivory (Fig. 2). As it has been demonstrated that burning does not always affect
herbivore site selection (McGranahan et al., 2012), the interaction detected by such studies may
be caused by a chain, or a modification, or both. By defining only one interaction type, but
testing for net effects, these studies make the implicit assumption that the defined interaction is
driving the fire-grazing interaction, which may or may not be true.
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Figure 2. A comparison of the interaction pathways described or defined by studies of fire-
grazing interactions, versus the pathways actually tested in the study (chain =
interaction chain, mod. = interaction modification, net = tests for interactions that do
not isolate interaction pathways, and hence may result from chain, or modification
effects or a combination of the two). Numbers are based on a review of 50 fire-grazing
interaction studies published between 2011 and 2015. * Indicates combinations where
the definition used was appropriate for the interactions tested (n = 13).
How does not identifying the interaction pathway affect management applications?
Studies which make untested assumptions about interaction pathways could potentially be
harmful, rather than useful for land management. We illustrate this with an example, based on a
recent study by Foster et al. (2015), who found that fire and herbivory by native macropods
interacted via both an interaction chain, and an interaction modification, to reduce the diversity
of forest understory vegetation. If the authors had measured the net effect of the interaction, and
based their management recommendations on an assumption about the interaction pathway,
then these recommendations would be likely to lead to little improvement, or even deterioration
of biodiversity (Fig. 3). For example, if the authors had assumed that the interaction occurred
through an interaction chain, they may have recommended changing fire management to
prevent herbivores concentrating in burnt areas (e.g. by increasing the area burnt). However,
due to the presence of an interaction modification, reducing grazing pressure in burnt sites by
194
increasing burn size is unlikely to mitigate all interactive effects, and may actually increase
negative effects on plants by increasing the proportion of the population that is exposed to the
interactive effects (Fig. 3).
Similarly, the converse assumption (that the interaction occurred solely through an
interaction modification) also could lead to ineffective management recommendations. If an
interaction modification was assumed, the authors may have recommended control measures to
reduce the abundance of macropod herbivores. However, due to the presence of an interaction
chain, where herbivores were attracted to burnt areas, general population control may do little to
reduce grazing pressure in burnt areas, and therefore not mitigate negative interactive effects
(Fig. 3). As population control of native herbivores is both resource-intensive and socially
unpopular (Nugent et al., 2011), a control program that does not achieve the desired benefits for
biodiversity is not only a waste of resources, but could compromise the ability of managers to
implement similar programs in the future. This example demonstrates how failure to integrate
theoretical concepts on interaction pathways into the design and interpretation of experimental
studies could limit their ability to effectively inform the management of multiple disturbances.
195
Figure 3. Schematic diagram illustrating how incorrect assumptions about interaction pathways
can lead to ineffective, or even damaging, management interventions. In the presence of
an interaction chain herbivores congregate in burnt areas (grey shading), while in the
presence of an interaction modification the per-herbivore impact is greater in burnt than
unburnt areas (larger size of herbivore indicates larger per-herbivore impact). Managing
for one interaction (e.g. an interaction chain), when the observed effects are
predominantly driven by a different interaction pathway (e.g. an interaction
modification), can result in unexpected outcomes. Note that the ‘outcomes’ in this
example are based on the study of Foster et al. (2015), where fire and grazing interacted
to negatively affect plant diversity, and so the aim of management interventions would
be to maintain plant diversity by reducing interactive effects.
Non-linear interactive effects on ecosystems and organisms
How well do experimental studies test for nonlinear effects?
Among the 50 papers we reviewed, there were two common study designs used to investigate
fire-grazing interactions; patch burning experiments (15 papers) and factorial experiments (27
papers). Few studies (12%) of either type were able to detect nonlinear effects. Most patch-
burning studies compared “homogenous” grazed areas with “heterogeneous” patch burnt and
grazed areas, under constant grazing intensity and burn size. Only two of the 15 studies using a
196
patch-burning design varied any characteristics of the burns (e.g. size of the burnt area), and
none tested the how interaction strength was affected by grazer density or species. While not
testing for non-linear interactions, a further three studies did test the consistency of interactive
effects across sites with different management histories.
All of the studies that identified an interaction modification (nine studies), and many
studies which tested net effects (18 studies), used a factorial study design, combining different
levels of fire (most often burnt/unburnt) and grazing (most often grazed/un-grazed) at the plot
level. To detect non-linear interactive effects, factorial studies must use more than two
treatment levels for at least one disturbance (i.e. include treatment levels in addition to
grazed/un-grazed and burnt/un-burnt, or measure natural variation within these levels), and
ideally include that factor as a continuous variable in analyses. However, of the 27 factorial
studies we reviewed, only nine used more than two levels for either fire or grazing, and only
three of these used either factor as a continuous variable in analyses. Thus, only three of 27
factorial studies and two of 15 patch-burning studies were of a design that could detect non-
linear interactive effects.
How does not identifying non-linear effects affect management applications?
The management implications of failing to detect non-linear effects differ slightly between
chain and modification interactions, but most relate to the ability to extrapolate (or interpolate)
results to untested situations or locations. Studies using patch-burn designs are testing for the
ecological effects of a chain interaction (“pyric herbivory”), where herbivores are attracted to
the fresh growth after fire, resulting in high grazing intensity in burnt patches (Fuhlendorf et al.,
2009). However, although it is acknowledged that the extent to which fire drives grazing
patterns may vary with the intensity, duration and timing of grazing, as well as with the size,
shape, intensity and timing of fire (Fuhlendorf et al., 2009; Sensenig et al., 2010; Allred et al.,
2011) (Fig. 4), most patch-burning studies did not test whether any of these factors affected the
strength of the fire-grazing interaction (but see McGranahan et al., 2013; Hovick et al., 2014),
and the consistency of such relationships remains poorly understood. Most patch-burning
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studies are therefore able to detect the presence of an interaction at the levels of burning and
grazing selected for that experiment, but cannot reliably be used for inference beyond this
specific combination of conditions. A manager who is faced with different conditions from
those tested in a study is therefore provided with little useful information about whether
changing stocking rates, harvest quotas or prescribed burns will improve biodiversity outcomes.
By comparison, studies that tested effects over a gradient of fire sizes, or a range of stocking
densities, would be able to give insights into the probable outcomes of changing management
practices, as well as improve our fundamental understanding of the fire-grazing interaction.
Figure 4. Generalised relationships between burn size, and the extent to which herbivores select
for the burnt area, demonstrating how chain interactions may vary with disturbance
properties such as spatial scale, and between ecosystems (Fuhlendorf et al., 2009).
Selection for burnt areas also varies between herbivore species (Sensenig et al., 2010),
and under certain conditions, herbivores may select against burnt areas (e.g. if dense
post-fire regrowth hinders herbivore movements, Wan et al., 2014).
Studies of interaction modifications are also often limited in their ability to inform
changes to management practices. This is because most studies are based on factorial
experiments using binary treatments (i.e. 2 × 2 factorial designs). When the effects of
disturbances, and their interactions, are non-linear, the key points of interest from a
management perspective are the points at which changes in one disturbance will have very large
(e.g. points of inflection), or very small (e.g. beyond thresholds), effects on the variable of
interest (Groffman et al., 2006)(Fig. 5a). Knowledge of the existence of these points, and their
198
approximate values, would allow managers to identify: when management is most likely, or
least likely to be successful; what level of management is required to achieve an outcome; or
how management should differ in the presence of other disturbances (Groffman et al., 2006).
However, factorial studies employing binary contrasts cannot detect these points (Fig. 5), and
cannot be generalised beyond the levels chosen for study (Inouye, 2001), and hence are of
limited use for predicting the outcome of changes to management.
Factorial experiments employing binary comparisons are also problematic because
whether they detect synergisms or antagonisms can be entirely dependent on the levels chosen
for study (Fig. 5)(Dunne, 2010), but the management implications of synergisms and
antagonisms are very different. Synergistic interactions can accelerate biodiversity decline, but
synergisms may be more likely to respond to management, as managing one disturbance can
mitigate the effects of both (Brown et al., 2013; Piggott et al., 2015). By contrast, mitigating the
effects of antagonistic interactions usually requires both disturbances to be managed
concurrently (Didham et al., 2007; Brown et al., 2013). Therefore, if the results of factorial
studies are used to inform management, but the underlying relationships are nonlinear,
unintended outcomes are likely to result.
As an example, Figure 5a presents a hypothetical non-linear interaction between fire
and herbivory. In this example, a factorial study would detect; (1) a synergism if the herbivore
densities compared were low and moderate; (2) no interaction if herbivore densities were low
and high; and (3) an antagonism if herbivore densities were moderate and high (Fig. 5). If a
factorial study compared low and high herbivore densities, the authors would likely conclude
that fire and grazing were not interacting, and that reducing grazing intensity is likely to be the
most effective action to increase the response variable. As can be seen in Fig. 5a, even if
herbivore density were halved in this situation, there would be little change in the response
variable in burnt environments, resulting in a waste of limited conservation resources. As field
experiments tend to employ extreme treatments, with large effect sizes (Foster et al., 2014), and
synergisms are more likely to be detected when individual effect sizes are small (Folt et al.,
1999; Piggott et al., 2015), factorial experiments may also under-estimate the occurrence of
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synergisms in natural ecosystems. Clearly, single-level factorial studies can miss a large (and
potentially important) part of the picture if used to study non-linear interactions. Therefore,
researchers who aim to inform more efficient and effective management of terrestrial
ecosystems through disturbance interaction studies should consider whether non-linear effects
are likely, and if so, explore alternatives to factorial designs which include a gradient of
biologically and management-relevant treatment levels.
Figure 5. When interactive effects are non-linear, differences in interpretation can occur when
examining disturbances as continuous or factorial treatments. (a) An hypothetical, non-
linear, interaction modification between fire and herbivory, showing the key points of
management interest (turning points, shifts in marginal rates, and limits; open circles)
and how these vary across different levels of fire and herbivore density (low density =
L, moderate density = M, high density = H). (b) The likely results of factorial studies in
the same study system, showing how the experimental results will vary depending on
the treatment levels chosen for comparison (L v M => synergism, L v H => additive
effects, M v H => antagonism).
Bridging the gap to improve management applications
There is a lack of integration of theory into the design and interpretation of disturbance
interaction experiments. We have demonstrated this by reviewing recent studies of fire-grazing
interactions. We have also shown that this lack of integration means that interaction
experiments, despite often being motivated by management problems, fall short of their
potential in effectively informing the management of multiple disturbances. Land managers,
faced with complex systems, competing demands, and a mandate for transparent decision
200
making, often rely on system and management models to inform management practices
(Underwood, 1995; Williams, 2011). A core role of experimental studies should therefore be to
improve our understanding of the relationships on which such models are based (Underwood,
1995). As we have argued in this paper, to do this requires experimental studies of disturbance
interactions to more effectively, and broadly, engage with the theoretical literature. Closing the
gap between the theoretical and experimental literature on disturbance interactions is not
straightforward – interactions are complex, multiscale processes which can be difficult to
manipulate experimentally. However, there are some adjustments that could be made to the
design and interpretation of disturbance interaction studies which would both improve links
with theory, and generate more useful information for the management of multiple disturbances.
While we have focussed on studies of terrestrial disturbance interactions in this paper, similar
experimental designs are used to study many other types of interactions, in a range of
ecosystems. The problems and solutions presented below will therefore be relevant to the study
of many kinds of ecological interactions.
Study design
1. Focus on testing the key relationships and interaction pathways identified in theoretical
models as important for management. Most studies report the net effects of an
experimentally manipulated interaction (Fig. 2), but it is difficult to generalise the
results of such studies, and they often do not test the key relationships that make up
management models. It is not always feasible, or desirable, to test all interaction
pathways in a single study. However, future studies of disturbance interactions should
explicitly identify the interaction pathway(s) being tested, and ensure that the study is
conducted at an appropriate spatial and temporal scale. Such experimental tests of
theoretically important relationships and pathways would allow theoretical models to be
verified, which could then be used to inform decisions at management-relevant scales
(Inouye, 2001; Belovsky et al., 2004; Cottingham et al., 2005; Denny & Benedetti-
Cecchi, 2012).
201
2. Quantify variation in disturbances/stressors, as well as their ecological effects. Few
experimental studies measure or analyse disturbances as continuous variables.
However, environmental variation, and/or chain interactions mean that even if
disturbance treatments are experimentally imposed, disturbance intensity/extent is
likely to vary within treatments (i.e. between replicates). If measured, this variation can
be used to a researchers’ advantage, as by pairing this quantitative measure of
disturbance directly with responses, researchers will be able to separately quantify chain
and modification effects, and test for non-linear effects (Oliver & Morecroft, 2014).
3. Spread replicates across gradients, rather than pooling within treatments. Many studies
are based on the additive model of interactions, and employ factorial designs, where
single levels are replicated multiple times. However, as demonstrated in Fig. 5, factorial
designs are inappropriate if interactions are non-linear, as the results may be subjective
(dependent on the treatment levels selected by researchers), and therefore misleading.
Alternative regression-based study designs, where replicates are instead spread across a
gradient of levels of a factor (e.g. stocking densities / fire sizes), would be better able to
detect and describe nonlinear effects (Cottingham et al., 2005). It would not be feasible,
or even desirable, to test all combinations of two disturbance gradients in a single study.
However, a gradient could be achieved for a single disturbance without a substantial
increase in research effort compared with a factorial design. For example, a study with
24 sites in a factorial design would have 6 replicates for each of four treatment
combinations (i.e. a 2 × 2 design). The same number of sites, if employed a regression-
based design, could be spread across 12 different levels of one disturbance, and the two
levels of the second disturbance (i.e. a 12 × 2 design).
4. Extend gradients outside their current “natural” range. Most of the reviewed studies
used binary comparisons of treatments in their experiments (e.g. burnt/unburnt or patch
burnt/uniformly burnt), which are usually at “moderate” or average levels of
disturbance size or intensity. However, chain interactions with other disturbances, or
with external global change drivers such as climate, have the potential to generate
conditions, and levels of variation, that are outside the current natural range (Thornton
202
et al., 2014; Kayler et al., 2015). Studies which test responses to conditions both within,
and beyond current natural limits are therefore necessary to highlight potential
thresholds or state-changes that are currently unlikely, but that may occur with these
novel combinations of conditions (Belovsky et al., 2004; Kayler et al., 2015). For such
studies, simulation and modelling tools will be useful for informing how far outside
current ranges treatment gradients should extend (Kayler et al., 2015).
Interpretation
1. Clearly define the interaction being tested. Many studies do not clearly define which
aspect of an interaction they are testing (see Fig. 2). This makes it difficult for readers
to interpret results. Clearly defining which pathway/aspect of an interaction is being
tested, and ensuring that the design and analyses used actually test this component of
the interaction, will allow the study to be interpreted within a broader context.
2. Frame and interpret studies in a broad theoretical context. Many studies of disturbance
interactions focus their discussion and interpretation solely on the specific interaction
being studied (e.g. most of the reviewed papers focussed exclusively on the fire-grazing
literature in framing their studies). However, theoretical studies of interactions are often
more generalised, or are focussed on other interactions or ecosystems, and so go
unacknowledged in studies that are very specific in approach. Exploring and testing
ideas developed from studies of different types of interactions and different systems is
key to bridging the gap between theory and experimental studies (Peters et al., 2011;
Buma, 2015).
3. Discuss results in the context of existing theoretical models. System models and
management models are frequently used to inform management decisions. Yet many
relationships in such models have not been experimentally verified (Knapp et al.,
2011). Interpreting results in the context of existing theoretical models, and discussing
whether results support theoretical pathways is key to improving these models, and
hence management decisions.
203
Conclusions
Managing ecological interactions is a key challenge to biodiversity conservation, and one that is
becoming increasingly important as global change drives rapid shifts in threats, abiotic
conditions, and disturbance regimes (Brook et al., 2008; Turner, 2010). This challenge also
presents an opportunity, through which a detailed, mechanistic understanding of ecological
interactions can be used to develop novel solutions for biodiversity conservation. For example,
failure to account for interactions between habitat modification and invasive species can cause
invasive control programs to be ineffective, or even harmful for native species (e.g. Norbury et
al., 2013). However, a mechanistic understanding of habitat-predator interactions is now being
used to develop management interventions that may be both more efficient and effective than
lethal control for protecting wildlife from introduced predators (Didham et al., 2007; Doherty et
al., 2015).
Carefully executed empirical studies, which are well integrated with theory, are
essential for developing the detailed understanding that these novel solutions require. For
example, novel strategies to conserve frogs that are threatened by the disease Chytridiomycosis
have been identified, not from solution-focussed studies, but from well-designed empirical
studies, grounded in theory, that investigated the multiple interacting processes affecting disease
prevalence and impacts (Scheele et al., 2014; Heard et al., 2015). The suggestions we have
presented for the design and interpretation of disturbance interaction studies aim to guide
research that will provide a similar understanding for managing multiple stressors. By gaining a
deeper, mechanistic understanding of interactions, such studies will be able to provide context-
specific information to guide management while also testing and refining theoretical models,
which can then be translated to other processes and ecosystems.
Many studies of disturbance interactions aim to improve the management of
ecosystems. However, studies which focus on specific management problems and fail to
integrate relevant theory are often limited in their broader management applications. There are
many studies of ecological interactions that are well integrated with the theoretical literature
(e.g. Mandle & Ticktin, 2012; Kimuyu et al., 2014), but such studies remain the exception,
204
rather than the rule. Until this trend is reversed, disturbance interaction experiments will
continue to fall short of their potential in informing effective ecological management.
Acknowledgements
Ben Scheele provided valuable feedback on the manuscript. This research was financially
supported by The Margaret Middleton Fund, The Norman Wettenhall Foundation and the Long
Term Ecological Research Network. P.S.B. was supported by an ARC DECRA Fellowship,
D.B.L. was supported by an ARC Laureate Fellowship.
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Supporting Information
Appendix S1. List of the 50 fire-grazing studies reviewed.
Studies were identified by searching the ISI Web of Knowledge Database for articles including
the terms fire AND (grazing or browsing), and which were published between 2011 and the date
of the search. This search was performed on the 17th April 2015 and returned 268 results, 50 of
which were empirical studies that focussed at least in part on the interaction between fire and
large herbivores.
Allred BW, Fuhlendorf SD, Engle DM, Elmore RD (2011) Ungulate preference for burned
patches reveals strength of fire-grazing interaction. Ecology and Evolution, 1, 132-144.
Allred BW, Scasta JD, Hovick TJ, Fuhlendorf SD, Hamilton RG (2014) Spatial heterogeneity
stabilizes livestock productivity in a changing climate. Agriculture Ecosystems &
Environment, 193, 37-41.
Augustine DJ, Derner JD (2012) Disturbance regimes and mountain plover habitat in shortgrass
steppe: Large herbivore grazing does not substitute for prairie dog grazing or fire. Journal
of Wildlife Management, 76, 721-728.
Augustine DJ, Derner JD (2014) Controls over the strength and timing of fire-grazer
interactions in a semi-arid rangeland. Journal of Applied Ecology, 51, 242-250.
Blackhall M, Veblen TT, Raffaele E (2015) Recent fire and cattle herbivory enhance plant-level
fuel flammability in shrublands. Journal of Vegetation Science, 26, 123-133.
Bock CE, Jones ZF, Kennedy LJ, Bock JH (2011) Response of rodents to wildfire and livestock
grazing in an Arizona desert grassland. American Midland Naturalist, 166, 126-138.
Dalldorf KN, Swanson SR, Kozlowski DE, Schmidt KM, Shane RS, Fernandez G (2013)
Influence of livestock grazing strategies on riparian response to wildfire in northern
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Doxon ED, Davis CA, Fuhlendorf SD, Winter SL (2011) Aboveground macroinvertebrate
diversity and abundance in sand sagebrush prairie managed with the use of pyric herbivory.
Rangeland Ecology & Management, 64, 394-403.
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Eby SL, Anderson TM, Mayemba EP, Ritchie ME (2014b) The effect of fire on habitat
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Journal of Animal Ecology, 83, 1196-1205.
210
Endress BA, Wisdom MJ, Vavra M, Parks CG, Dick BL, Naylor BJ, Boyd JM (2012) Effects of
ungulate herbivory on aspen, cottonwood, and willow development under forest fuels
treatment regimes. Forest Ecology and Management, 276, 33-40.
Field JP, Breshears DD, Whicker JJ, Zou CB (2011) Interactive effects of grazing and burning
on wind- and water-driven sediment fluxes: rangeland management implications.
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Hierro JL, Clark KL, Branch LC, Villarreal D (2011) Native herbivore exerts contrasting effects
on fire regime and vegetation structure. Oecologia, 166, 1121-1129.
Hovick TJ, Elmore RD, Fuhlendorf SD (2014) Structural heterogeneity increases diversity of
non-breeding grassland birds. Ecosphere, 5, art62.
Hovick TJ, Elmore RD, Fuhlendorf SD, Engle DM, Hamilton RG (2015) Spatial heterogeneity
increases diversity and stability in grassland bird communities. Ecological Applications,
25, 662-672.
Hovick TJ, Elmore RD, Wallred B, Fuhlendorf SD, Dahlgren DK (2014) Landscapes as a
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Johansson MU, Granstrom A (2014) Fuel, fire and cattle in African highlands: traditional
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Kimuyu DM, Sensenig RL, Riginos C, Veblen KE, Young TP (2014) Native and domestic
browsers and grazers reduce fuels, fire temperatures, and acacia ant mortality in an African
savanna. Ecological Applications, 24, 741-749.
Koerner SE, Collins SL (2013) Small-scale patch structure in North American and South
African grasslands responds differently to fire and grazing. Landscape Ecology, 28, 1293-
1306.
Koerner SE, Collins SL (2014) Interactive effects of grazing, drought, and fire on grassland
plant communities in North America and South Africa. Ecology, 95, 98-109.
Limb RF, Fuhlendorf SD, Engle DM, Kerby JD (2011) Growing-season disturbance in tallgrass
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Lunt ID, Zimmer HC, Cheal DC (2011) The tortoise and the hare? Post-fire regeneration in
mixed Eucalyptus-Callitris forest. Australian Journal of Botany, 59, 575-581.
Mandle L, Ticktin T (2012) Interactions among fire, grazing, harvest and abiotic conditions
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Masunga GS, Moe SR, Pelekekae B (2013) Fire and grazing change herbaceous species
composition and reduce beta diversity in the Kalahari sand system. Ecosystems, 16, 252-
268.
211
McGranahan DA, Engle DM, Fuhlendorf SD, Winter SJ, Miller JR, Debinski DM (2012)
Spatial heterogeneity across five rangelands managed with pyric-herbivory. Journal of
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McGranahan DA, Engle DM, Fuhlendorf SD, Winter SL, Miller JR, Debinski DM (2013)
Inconsistent outcomes of heterogeneity-based management underscore importance of
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60.
McGregor HW, Legge S, Jones ME, Johnson CN (2014) Landscape management of fire and
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Management, 76, 38-47.
Monroe AP, O'Connell TJ (2014) Winter bird habitat use in a heterogeneous tallgrass prairie.
American Midland Naturalist, 171, 97-115.
Moranz RA, Fuhlendorf SD, Engle DM (2014) Making sense of a prairie butterfly paradox: The
effects of grazing, time since fire, and sampling period on regal fritillary abundance.
Biological Conservation, 173, 32-41.
Nayak RR, Vaidyanathan S, Krishnaswamy J (2014) Fire and grazing modify grass community
response to environmental determinants in savannas: Implications for sustainable use.
Agriculture Ecosystems & Environment, 185, 197-207.
Nield AP, Monaco S, Birnbaum C, Enright NJ (2015) Regeneration failure threatens persistence
of Persoonia elliptica (Proteaceae) in Western Australian jarrah forests. Plant Ecology,
216, 189-198.
Osem Y, Lavi A, Rosenfeld A (2011) Colonization of Pinus halepensis in Mediterranean
habitats: consequences of afforestation, grazing and fire. Biological Invasions, 13, 485-498.
Pekin BK, Wisdom MJ, Endress BA, Naylor BJ, Parks CG (2014) Ungulate browsing maintains
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Pillsbury FC, Miller JR, Debinski DM, Engle DM (2011) Another tool in the toolbox? Using
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Radloff FGT, Mucina L, Snyman D (2014) The impact of native large herbivores and fire on the
vegetation dynamics in the Cape renosterveld shrublands of South Africa: insights from a
six-yr field experiment. Applied Vegetation Science, 17, 456-469.
212
Ramirez AR, Pratt RB, Jacobsen AL, Davis SD (2012) Exotic deer diminish post-fire resilience
of native shrub communities on Santa Catalina Island, southern California. Plant Ecology,
213, 1037-1047.
Richardson AN, Koper N, White KA (2014) Interactions between ecological disturbances:
burning and grazing and their effects on songbird communities in northern mixed-grass
prairies. Avian Conservation and Ecology, 9, 5.
Scasta JD, Engle DM, Talley JL, Weir JR, Stansberry JC, Fuhlendorf SD, Harr RN (2012)
Pyric-herbivory to manage horn flies (Diptera: Muscidae) on cattle. Southwestern
Entomologist, 37, 325-334.
Schutz AEN, Bond WJ, Cramer MD (2011) Defoliation depletes the carbohydrate reserves of
resprouting Acacia saplings in an African savanna. Plant Ecology, 212, 2047-2055.
te Beest M, Mpandza NJ, Olff H (2015) Fire and simulated herbivory have antagonistic effects
on resistance of savanna grasslands to alien shrub invasion. Journal of Vegetation Science,
26, 114-122.
Thomas-Van Gundy M, Rentch J, Adams MB, Carson W (2014) Reversing legacy effects in the
understory of an oak-dominated forest. Canadian Journal of Forest Research, 44, 350-364.
Traore S, Tigabu M, Jouquet P, Ouedraogo SJ, Guinko S, Lepage M (2015) Long-term effects
of Macroternies termites, herbivores and annual early fire on woody undergrowth
community in Sudanian woodland, Burkina Faso. Flora, 211, 40-50.
Tuft KD, Crowther MS, McArthur C (2012) Fire and grazing influence food resources of an
endangered rock-wallaby. Wildlife Research, 39, 436-445.
Wan HY, Rhodes AC, St Clair SB (2014) Fire severity alters plant regeneration patterns and
defense against herbivores in mixed aspen forests. Oikos, 123, 1479-1488.
Winter SL, Fuhlendorf SD, Goad CL, Davis CA, Hickman KR (2011) Topoedaphic variability
and patch burning in sand sagebrush shrubland. Rangeland Ecology & Management, 64,
633-640.
Winter SL, Fuhlendorf SD, Goad CL, Davis CA, Hickman KR, Leslie DM, Jr. (2012)
Restoration of the fire-grazing interaction in Artemisia filifolia shrubland. Journal of
Applied Ecology, 49, 242-250.
Winter SL, Hickman KR, Goad CL, Fuhlendorf SD, Gregory MS (2013) Seasonal fires, bison
grazing, and the tallgrass prairie forb Arnoglossum plantagineum raf. Natural Areas
Journal, 33, 327-338.
213