determining the pollination mechanism of a problematic
TRANSCRIPT
University of New Orleans University of New Orleans
ScholarWorks@UNO ScholarWorks@UNO
University of New Orleans Theses and Dissertations Dissertations and Theses
Spring 5-13-2016
Determining the pollination mechanism of a problematic invasive Determining the pollination mechanism of a problematic invasive
species in the Gulf South: Triadica sebifera species in the Gulf South: Triadica sebifera
Jennifer Wester Clark University of New Orleans, [email protected]
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Recommended Citation Recommended Citation Clark, Jennifer Wester, "Determining the pollination mechanism of a problematic invasive species in the Gulf South: Triadica sebifera" (2016). University of New Orleans Theses and Dissertations. 2134. https://scholarworks.uno.edu/td/2134
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Determining the pollination mechanism of a problematic invasive species in the Gulf South:
Triadica sebifera
A Thesis
Submitted to the Graduate Faculty of the
University of New Orleans
in partial fulfillment of the
requirements for the degree of
Master of Science
in
Biological Sciences
by
Jennifer Wester Clark
B.S. University of New Orleans, 2011
May 2016
ii
Acknowledgement
I would like to thank my advisor, Dr. Jerome Howard, for his inspiration, advice, and
encouragement throughout my project. I would also like to thank my committee members, Dr.
Charles Bell and Dr. Philip DeVries, for their guidance and assistance.
Thank you to Scott Hereford and staff at the Mississippi Sandhill Crane National Wildlife
Refuge and staff at Tulane University’s F. Edward Hebert Riverside Research Center for
assisting me when needed. Many thanks to Dr. Mary Clancy for her microscope expertise and to
the undergraduate research assistants I had out in the field, Crista, Brittany, and Becky.
Special thanks to my lab mates Cara Nighohossian, Lizzie Ruffman, and Robinson Sudan,
and fellow graduate students Lauren Gonzalez, Catie Policastro, and Trent Santonastaso for all
of their knowledge and encouragement.
Lastly, thank you to my wonderful family for their love and encouragement, especially
my husband for his support and patience.
iii
Table of Contents
List of Figures ................................................................................................................................ iv
List of Tables .................................................................................................................................. v
Abstract .......................................................................................................................................... vi
Introduction ..................................................................................................................................... 1
Invasive Species .......................................................................................................................... 1
Triadica sebifera characteristics .................................................................................................. 2
Triadica sebifera as an invasive species in the U.S. ................................................................... 4
Methods........................................................................................................................................... 7
Study sites ................................................................................................................................... 7
Sampling design .......................................................................................................................... 9
Self-fertilization survey .............................................................................................................. 9
Receptivity survey .................................................................................................................... 10
Airborne pollen count ............................................................................................................... 11
Insect pollination survey ........................................................................................................... 11
Insect identification ................................................................................................................... 12
Pollen identification .................................................................................................................. 12
Statistical analysis ..................................................................................................................... 12
Results ........................................................................................................................................... 14
Self-fertilization survey ............................................................................................................ 14
Receptivity survey .................................................................................................................... 14
Airborne pollen count ............................................................................................................... 15
Insect pollination survey and identification .............................................................................. 16
Pollen identification .................................................................................................................. 18
Discussion ..................................................................................................................................... 19
References ..................................................................................................................................... 22
Appendix ....................................................................................................................................... 30
Receptivity Data........................................................................................................................ 30
Insect Identification .................................................................................................................. 30
Vita ................................................................................................................................................ 34
iv
List of Figures
Figure 1: Range of T. sebifera in the U.S. ...................................................................................... 4
Figure 2: Map of Tulane University's F. Edward Hebert Riverside Research Center .................... 8
Figure 3: Map of Mississippi Sandhill Crane National Wildlife Refuge........................................ 9
Figure 4: Bagged inflorescence .................................................................................................... 10
Figure 5: Tagged inflorescence post- exposure ............................................................................ 11
Figure 6: Pollen trap...................................................................................................................... 11
Figure 7: Pollen grains vs. distance from source tree ................................................................... 16
v
List of Tables
Table 1: Proportion of fruits developed per test tree in self-fertilization survey .......................... 14
Table 2: Repeated measured ANOVA of fruit set among trees over time ................................... 15
Table 3: Number of pollen grains per microscope field for two trees at varying distances ......... 15
Table 4: Comparison of abundance of taxa visiting at two sites. ................................................. 17
Table 5: Species diversity by order and bee family at both sites .................................................. 18
Table 6: Mean and standard deviation of 5 field views of pollen loads per group ....................... 18
Table 7: Numbers of fruits developed in receptivity exclusion experiment ................................. 30
Table 8: Arthropods collected (ms stands for morphospecies) ..................................................... 30
vi
Abstract
Understanding the ecology of invasive species is vital to curb the homogenizing of ecosystems,
yet the pollination mechanisms of the Chinese tallow tree (Triadica sebifera) in its introduced
habitat remain ambiguous. This study examines self-pollination, wind pollination, and flower-
visiting insects of tallow in a bottomland hardwood forest and Longleaf pine savannah in the U.S.
Gulf South. These data suggest that self-pollination and airborne pollination are possible, but
likely rare occurrences, although the possibility of apoxisis was not investigated. Seed
production in exclusion experiments was significantly less than in open-pollinated flowers, and
wind dispersal of tallow pollen dropped to essentially zero 8 meters from the source. Results
show that tallow is primarily bee pollinated, with external pollen loads of Apis, Melissodes, and
halictids visiting at similar rates, and Xylocopa species visiting less frequently. The researchers
believe that to date, this is the first study of the pollination mechanisms of T. sebifera in its
introduced range and recommend further study to understand the ecology of this destructive
invasive species.
Triadica sebifera, Chinese tallow, invasive species, pollination, arthropods, Longleaf pine
savannah, bottomland hardwood forest
1
Introduction
Invasive Species
It has been known for decades that invasive species have negative effects on native
species, communities, and ecosystems (Elton 1958, Simberloff 1996). Invasive species are found
in almost every habitat on earth (Mack et al. 2000) and considered second only to habitat loss
and fragmentation as a threat to global biodiversity (Sakai et al. 2001, Walker and Steffen 1997).
Not only do invasive species alter ecosystem structure and processes, reduce native diversity,
and contribute to extinction of native organisms (Cleland et al. 2004, Mack et al. 2000, Mooney
and Hobbs 2000, Wilcove et al. 1998), but they also have significant economic impacts, costing
over $120 billion annually (Pimentel et al. 2005).
Human activity is a major cause of long-distance introductions of nonindigenous species.
Exotic flora has been introduced into new areas for ornamentation, agriculture, and erosion
control, amongst other reasons (Wilcove et al. 1998). In the U.S. alone, an estimated 5,000
invasive species introduced for agricultural, textile, and horticultural purposes have escaped
domestication (Morse et al. 1995).
For many introduced species, biotic interactions rather than the physical environment
may determine the persistence of introduced populations, the degree to which they become
invasive, and the geographic distribution in the introduced range. While competition from native
species and escape from natural enemies has been investigated in many systems (Levine et al.
2004, Maron and Vila 2001, Mitchell and Power 2003), until recently mutualistic interactions
facilitating the spread of invasive species has received less attention. Mutualistic interactions
involving both pollination and seed dispersal appear to be common and important factors in the
2
success of invasive plant species (Richardson et al. 2000). In most cases there appears to be
adequate service to introduced species by generalist mutualists to permit successful
establishment and spread. However, this does not appear to always be the case.
In some habitats, non-native pollinators more closely associate with non-native plant
species (Morales and Aizen 2006). Studies in Argentina, Australia, Canada, and New Zealand
demonstrated the existence of invasive pollination mutualisms, where introduced bees visit
exotic plant species over native flora (Donovan 1980, Morales and Aizen 2006, Pearson and
Braiden 1990, Stimec et al. 1997, Woodward 1996). In some cases, invasive mutualisms between
introduced plants and pollinators appear to be a crucial factor in the establishment and spread of
invasive plant species. In North America, introduced honeybees (Apis mellifera) are the main
pollinators of two important non-native weeds, purple loosestrife (Lythrum salicaria, Mai et al.
1992), and wild radish (Raphanus sativus, Stanton 1987), and have been shown to increase seed
set of yellow star thistle (Centaurea solstitialis, Barthell et al. 2001). The role of mutualisms in
the establishment and spread of invasive plant species deserves greater attention.
Triadica sebifera characteristics
Triadica sebifera, commonly known as the Chinese tallow tree, popcorn tree, Florida
aspen, and chicken tree, belongs to the large and diverse family Euphorbiaceae (Jubinsky and
Anderson 1996). Chinese tallow is a subtropical, deciduous tree. Its flowers are monoecious, and
the tree is polycarpic. The tree has greyish-brown fissured bark and exhibits plasticity in growth
form, ranging from shrubby with lateral branches to tall trees with pendent branches (Jubinsky
and Anderson 1996). It can grow to heights of 10 to 15 meters (Bruce et al. 1997, Duke 1983).
Leaves are alternately whorled and distinctively heart-shaped with blades 5-8 cm long
and 4-6 cm wide. They are dark green with light green veins and turn yellow to red in the fall.
3
Flowers are yellow-green in terminal spike-like inflorescences 5-20 cm long. Staminate flowers
are in clusters along the spike. Pistillate flowers are clustered at the base of the spike and are
reduced with a three-lobed ovary, three styles, and no petals. Trilocular capsule fruits are 9-19
mm across and split to reveal three white, wax-coated seeds 6-10 mm in diameter that remain
attached until winter (Bogler 2000, McCormick 2005, Meyer 2011, Miller 2003).
Chinese tallow exhibits r-strategist life history traits. Generation time is short, with
maturity reached in as little as three years (Duke 1983, Scheld et al. 1984). Fecundity is high due
to prolific seed production (Renne et al. 2000, Scheld and Cowles 1981). A mature stand of trees
can produce seeds in excess of 4,500 kg per acre per year (Conway et al. 2000), and trees remain
sexually viable to 60 years (USGS/NWRC 2000). Growth is rapid (Lin et al. 2004) and is equal
or greater than numerous native seedlings in most conditions (Jones and McLeod 1989, 1990).
Trees reach a maximum height of 10-15 meters in 10-12 years (Duke 1983). Other r-selected
traits of Chinese tallow include widespread seed dispersal by birds and moving water (Jubinsky
1995, McCormick 2005, Meyer 2011, Renne et al. 2002), and its ability to survive in disturbed
and unstable environments (Jubinsky 1995, McCormick 2005, Meyer 2011).
Chinese tallow is native to southeastern China and Japan. It has been introduced to the
Korean Peninsula, Vietnam, Singapore, Sri Lanka, India, Sudan, South Africa, Algeria, Italy,
France, Brazil, Martinique, Jamaica, Cuba, Mexico, and the U.S. (Duke 1983, ISSG 2005,
McCormick 2005). Its range in the U.S. extends from North Carolina south to Florida, west into
Texas, and north to Oklahoma, Arkansas, Tennessee, and Kentucky. It has also been found in
Wisconsin, California, and Hawaii (Fig. 1) (CISEH 2010, McCormick 2005, Siemann and
Rogers 2003).
4
Figure 1: Range of T. sebifera in the contiguous U.S.
Triadica sebifera as an invasive species in the U.S.
The first documentation of the intentional introduction of Chinese tallow to the U.S. is in
a letter from Benjamin Franklin in 1772. Franklin, while visiting Asia, sent a few seeds to his
friend and gentleman farmer, Noble Wimberly Jones, in Darien, Georgia (Bell 1966). The first
botanical reference to the plant in the U.S. was in 1803 by Andreas Michaux, who observed its
cultivation in Charleston, South Carolina and Savannah, Georgia, and noted its unaided spread
into coastal forests (McCormick 2005). In 1906, Chinese tallow was brought to Texas and
Louisiana by the USDA’s Foreign Plant Introduction Division to establish a commercial soap
industry (Flack and Furrow 1996, Siemann and Rogers 2001). It is favored in the horticulture
industry as an ornamental due to its fall foliage (Maddox et al. [date unknown], McCormick
2005).
Since its introduction to the U.S., Chinese tallow has aggressively displaced native flora and
formed monospecific stands. It can invade both intact and disturbed habitats (Conner et al. 2002,
Neyland and Meyer 1997, Varner and Kush 2004). Chinese tallow readily invades grassland
communities and does especially well in coastal prairies, where it has been shown to convert to
closed-canopy forests within 10 years of establishment (Bruce et al. 1995, Grace 1998, Meyer
2011). It invades numerous woodland habitats, including bottomland hardwood, pine, floodplain,
5
riparian, and mixed (Harcombe et al. 1998, Ramsey et al. 2005, Renne et al. 2000, Varner and
Kush 2004), and is successful in wet habitats, along lake and river shores, in floodplains, and in
wetlands, including floating marsh thickets (Bruce et al. 1997, Meyer 2011, Miller 2003, Nolfo-
Clements 2006). It invades disturbed sites such as agricultural lands, roadsides, spoilbanks,
storm-damaged habitats, utility rights-of-way, and urban areas (Loewenstein and Loewenstein
2005, Maddox et al. [date unknown], Mann 2006, Ramsey et al. 2005, Varner and Kush 2004).
The competitive dominance of Chinese tallow is due to multiple factors, including its r-
strategist life history traits. These traits include rapid growth, high fecundity, short generation
time, generalized avian seed dispersal, and tolerance to a wide range of environmental conditions,
including acid to alkaline soils, wet to droughty landscapes, deep shade to full sun, and saline to
freshwater flooding (Conner et al. 1997, McCormick 2005, Meyer 2011). Adding to its success is
a low herbivore load in its introduced range (Bruce et al. 1997), and the ease at which roots
develop shoots and stumps resprout (Urbatsch 2000).
Understanding the ecology of invasive species is vital to curbing impacts on native
species and the homogenization of ecosystems (Mack at al. 2000, Sakai et al. 2001). Despite the
threats that Chinese tallow poses, some characteristics of this invasive plant remain unknown.
Surprisingly, the mechanisms of pollination of this plant in its introduced habitat remain
ambiguous (Meyer 2011). A fact sheet produced by the University of Georgia’s Center for
Invasive Species and Ecosystem Health states that Chinese tallow is wind pollinated (Evans et al.
2006). While this is generally consistent with the tendency of the Euphorbiaceae to produce
spicate inflorescences containing many reduced flowers, entomophily is common in the family
and consistent with this floral morphology (Webster 1994). The United States Department of
Agriculture notes Chinese tallow being used by beekeepers (Miller 2003), and was apparently
6
aggressively planted throughout the Gulf Coast as a nectar source for honeybees and the quality
of its honey (Hayes 1979). The close association between Chinese tallow and the introduced
honeybee may comprise an invasive mutualism that could have been important to the spread of
tallow in North America, but there is no information on tallow visitation by native or introduced
pollinators. The pollination mechanisms of Chinese tallow have not been explored in sufficient
detail to determine the dominant mode of pollination and whether this may influence its success
as an introduced species. In this study I aim to evaluate pollination mechanisms in Chinese
tallow on the central Gulf Coast.
7
Methods
Study sites
The study was conducted at two sites invaded by Chinese tallow. The Tulane
University’s F. Edward Hebert Riverside Research Center (HRRC) in Belle Chasse, Louisiana
was chosen as an invaded bottomland hardwood forest (Fig. 2). The site is approximately 100
hectares in size and 1.22m above sea level (Wunderground 2015). The area bears evidence of
drainage canals and most likely functioned as a cotton or sugar cane plantation during the 18th
and 19th centuries due to its location along the Mississippi River (S. Darwin, personal
communication). During World War II, The United States government owned the property and
altered it to assist in wartime efforts. Tulane University acquired the property at the end of World
War II, and it has been allowed to grow unmanaged since then (Whitrock 2013). The overstory is
comprised of native hardwood species including: Acer negundo, Acer rubrum, Carya
illinoinensis, Celtis laevigata, Cornus, Liquidambar styraciflua, Prunus serotina, Quercus nigra,
Quercus texana, Quercus virginiana, Sambucus nigra, and Ulmus americana. Some areas
include invasive Ligustrum lucidum and Triadica sebifera. Other notable species include Ilex
vomitoria and Sabal minor. The understory is mostly comprised of invasive Ligustrum sinense
(Whitrock 2013).
8
Figure 2: Map of Tulane University's F. Edward Hebert Riverside Research Center
The Mississippi Sandhill Crane National Wildlife Refuge (MSCNWR) in Jackson County,
Mississippi, was chosen as the second sampling site and is representative of invaded longleaf
pine savannah. The refuge encompasses 7,800 hectares over three separate units, divided into
smaller management compartments (Fig. 3). The refuge was established in 1975 to protect the
endangered Mississippi sandhill crane (Grus canadensis pulla) and restore the unique and
disappearing habitat (USFWS 2007). The understory is species-rich and consists of grasses:
Aristida, Ctenium, Dicanthelium, Muhlenbergia, Schiazachyrium; sedges: Dichromena, Fuirena,
Rhynchospora, Scleria; rushes: Juncus; forbs: Aletris, Aster, Balduina, Bigelowia, Calopogon,
Carphephorus, Coreopsis, Eriocaulon, Eryngium, Eupatorium, Helianthus, Hypoxis,
Lachnanthes, Ludwigia, Lobelia, Lophiola, Phlox, Polygala, Rhexia, Sabatia, Solidago, Tofieldia,
Viola, Xyris, Zigadenus; and insectivorous plants: Drosera, Pinguicula, Sarracenia, Utricularia.
Larger plants include shrubs: Gaylussacia, Hypericum, and Vaccinium, and taller-growing
species: Ilex, Clethra, Cyrilla, Lyonia, MyricaI, Pinus, and Taxodium (USFWS 2007).
9
Figure 3: Map of Mississippi Sandhill Crane National Wildlife Refuge units and compartments
Sampling design
To assess pollination mechanisms of Chinese tallow, exclusion experiments to test for
self-fertilization and receptivity were performed at HRRC. Pollen traps were constructed to test
for wind pollination in compartment G-02 of MSCNWR, and aerial netting of flower visitors
was conducted at both sites. Experiments were performed in May and June of 2012 and 2013.
Self-fertilization survey
Chinese tallow is protogynous (McCormick 2005), which may reduce self-pollination. To
determine if self-pollination occurs under natural conditions, I bagged 20 unopened buds on four
trees at HRRC in late May 2012. Fine nylon mesh was secured around twigs approximately 4 cm
below from the base of the inflorescence and sealed with wire (Fig. 4). The bags remained on
10
inflorescences the entire flowering season, and when removed, the peduncle was examined for
capsules.
Figure 4: Bagged inflorescence
Receptivity survey
To test daily stigmatic receptivity, 20 immature inflorescences were bagged on three test
trees at HRRC as described in the self-fertilization survey. Four bags from each tree were
systematically removed for two days and then replaced and tagged with exposure dates,
beginning on the day of anthesis and ending at 10 days post-anthesis (Fig. 5). The bags were
visually inspected for fruit development every 10 days after the exposure trial and removed at the
end of the flowering season.
11
Figure 5: Tagged inflorescence post- exposure
Figure 6: Pollen trap
Airborne pollen count
To determine if Chinese tallow is capable of wind pollination, we surveyed for wind-born
pollen using pollen traps made of standard microscope slides coated in petroleum jelly as
outlined by Kearns and Inouye (1993). Slides were mounted on rings made from PVC pipe 7.5
cm in diameter and cut one cm thick, which attached to a length of PVC pipe 2.5 cm in diameter
secured approximately 30 cm from the ground (Fig. 6). In June 2013, at the height of flowering,
we placed traps around two trees at MSCNWR at 1, 4, and 8-meter intervals in the four cardinal
directions. Traps were open for 24 hours, and subsequently the slides were removed and placed
in individual plastic bags for transportation to the lab for analysis.
Insect pollination survey
Insect pollination was assessed using aerial netting of flower visiting insects. A flower-
visiting insect was defined as any insect that made contact with an inflorescence in anthesis. We
sampled trees for five minutes each, sweeping at all flower visiting insects within reach. In May
and June 2012, we sampled 7 trees at HRRC. We revisited three trees that exhibited an extended
flowering period, for a total of 10 samples. In June 2013, we sampled 6 trees at HRRC,
12
revisiting one, for a total of 7 samples, and at MSCNWR, we sampled 8 trees, revisiting 2, for a
total of 10 samples. Insects were stored in vials containing 70% ethyl alcohol as collected.
Insect identification
Insects were identified morphologically to the lowest taxonomic level possible; all were
identified to family, 80% to genus and 54% to species. Key references included Arnett et al.
2000; Arnett and Thomas 2002; Buck et al. 2008; McAlpine et al. 1981, 1987; Mitchell 1960,
1962; and Slater and Baranowski 1978.
Pollen identification
Pollen was identified morphologically using light microscopy at 400x and compared to
images from Lieux (1975) and Trigg at al. (2013). For flower visitor pollen samples, I gently
removed external pollen from insects using insect pins. Pollen was put onto glass slides, and I
sealed cover slips using clear nail polish. Flower visitor slides and pollen trap slides were
inspected methodically as outlined by Jones (2012). Chinese tallow pollen was identified by its
tricolporate shape and large 32-43μm diameter (Dustmann and Von Der Ohe 1993, Lieux 1975).
I recorded the number of Chinese tallow versus other pollen grains in five field views of each
slide.
Statistical analysis
All statistical analysis was performed in SYSTAT version 13, except Chi-squared tests,
which were run in R version 2.13.1. Receptivity data was analyzed using a repeated measured
ANOVA of fruit set among trees over time. Airborne pollen was analyzed with regression
analysis on the number of tallow and non-tallow pollen grains collected on pollen traps at
13
varying distances. External pollen loads were analyzed using an ANOVA on the arcsine-square
root transformed proportions with Tukey’s HSD post hoc analysis. To investigate if site,
particularly the floral communities invaded, affected the presence of orders, families, or genera
of insects, we ran Pearson’s Chi-squared tests (𝑥2) using Monte Carlo simulations with p-values
based on 999 replicates.
14
Results
Self-fertilization survey
Of the 80 inflorescences bagged in the self-fertilization survey, 73 retained their bags
throughout the duration of the study and were surveyed for fruit set. Although self-fertilized
fruits were rare, at least one flower on each tree set fruit. An average of 9.8 ± 4.8% of
inflorescences set fruit. Inflorescences bore an average of three trilocular flowers capable of
producing three seeds, and the mean seed set of the four trees was 1.38 ± 0.70% (Table 1).
Table 1: Proportion of fruits developed per test tree in self-fertilization survey
No Fruit 1 Fruit 2 Fruits % Fruits % Seeds
Tree 1 15 2 0 11.8 1.3
Tree 2 19 0 1 5.0 1.1
Tree 3 15 2 1 16.7 2.5
Tree 4 17 1 0 5.6 0.6
Average 9.8 ± 4.8 1.38 ± 0.70
Receptivity survey
In the receptivity experiment all test inflorescences set at least one fruit. Average fruit set
of the three test trees was 28.9 ± 6.5% and varied from a high of 36.1 to a low of 23.3%. Number
of fruits set differed significantly among trees (F2,9 = 8.123, p = 0.010), with tree #2 (36.1%) out-
producing the others (Table 2). Receptivity of flowers did not vary over time (Day effect, F4,36 =
0.841, p = 0.509), and was similar over time for all trees (Day x Tree interaction; F8,36 = 0.380, p
= 0.924).
15
Table 2: Repeated measured ANOVA of fruit set among trees over time
Between Subjects Within Subjects
Source Tree Day exposed Day x Tree
F-ratio 8.123 1 0.841 2 0.380 3
P value 0.010 0.509 0.924
1: df = 2,9 2: df = 4,36 3 df = 8,36
Airborne pollen count
While Chinese tallow pollen was found on pollen traps, it comprised a small fraction of
all pollen. Only 1% of pollen on slides was attributed to Chinese tallow (Table 3), while the rest
was from other species. Regression analysis showed that abundance of Chinese tallow pollen in
microscope fields decreased significantly with distance from the tree (Y = -0.11X + 0.79; r2 =
0.59; p < 0.001) (Fig. 7). In contrast, abundance of other pollen types did not vary significantly
with distance from the target tree (Y = 0.05X + 24.1; r2 = 0.003; p = 0.817) (Fig. 7).
Table 3: Number of tallow and non-tallow pollen grains per microscope field for two trees,
collected on pollen traps at varying distances
Tree 1 Tree 2
Distance (m) Tallow Non-tallow Tallow Non-tallow
1 0.6 ± 0.24 23 ± 2.5 0.9 ± 0.36 25 ± 2.7
4 0.2 ± 0.14 25.8 ± 1.9 0.3 ± 0.22 23.6 ± 3.9
8 0 24.2 ± 1.2 0 25.2 ± 3.3
16
Figure 7: Number of pollen grains per microscope field vs. distance from source tree.
Tallow pollen regression: Y = -0.11X + 0.79; r2 = 0.59; p < 0.001.
Non-tallow pollen regression: Y = 0.05X + 24.1; r2 = 0.003; p = 0.817
Insect pollination survey and identification
178 individual insects were collected on tallow trees; 35 were removed from the data set
as either too degraded to identify, or incidental visitors unlikely to pollinate tallow flowers (4
Lepidoptera) and non-pollinating arthropods (arachnids). Of the remaining 143 individuals, 94
were collected at HRRC and 49 at MSCNWR. The majority were Hymenoptera (71%), with the
others being Diptera (13%), Coleoptera (10%), and Hemiptera (6%). Within the order
Hymenoptera, 5 families were represented with the majority being Apidae at 70%. The other
families included Vespidae (14%), Formicidae (10%), Halictidae (6%), and Ichneumonidae
(<1%). Apidae was represented by 5 species: Apis mellifera (51), Melissodes bimaculata (13),
17
Xylocopa virginica (5), X. micans (1), and a single undetermined Xylocopa species. Halictids
were represented by the species Augochloropsis metallica (4) and Augochlora pura (2).
Using Pearson’s Chi-squared test with a simulated p-value (based on 999 replicates) we
analyzed whether the difference in ecosystem, particularly the floral communities that were
invaded, affected the presence of particular orders, families, or genera of insects. We then
analyzed if site affected the families found in each of the four orders found in our study (Table 4).
Each variable showed a significant difference between sites except when families of
Hymenoptera were compared (p = 0.467).
Table 4: Comparison of abundance of taxa visiting Chinese tallow flowers at two sites on the central Gulf Coast. P-
values are of Pearson's Chi-squared test with Monte Carlo simulations.
p-value p-value
Orders 0.001 Hemiptera 0.004
Families 0.001 Hymenoptera 0.467
Genera 0.001 Hymenoptera without Apis 0.001
Coleoptera 0.003 Apidae 0.087
Diptera 0.001 Apidae without Apis 0.001
33 species were collected at the HRRC, 15 being from the order Hymenoptera and
making up the bulk of the samples. More than half of the Hymenoptera collected (62%) were
bees from 6 species across 2 families; 82% were Apidae and 18% Halictidea. M. bimaculata
represented 46%, A. mellifera 32%, X. virginica 18%, and X. micans 3.6% of Apidae collected. A.
metallica made up 66% of the Halictids, with A. pura completing the other 33%. The 39 non-
Hymenopteran individuals came from 18 different species.
The MSCNWR only produced 7 species; 5 from the order Hymenoptera, with the
majority being A. mellifera (42). Other Hymenopterans included 3 vespids, 1 Formicidae, and 1
unknown species of Xylocopa. The other 2 species were from the order Diptera.
18
Table 5: Species diversity by order and bee family at both sites
HRRC MSCNWR
Order No. of Species Order No. of Species
Hymenoptera 15 Hymenoptera 5
Coleoptera 7 Diptera 2
Hemiptera 6
Diptera 5
Bee Family No. of Species Bee Family No. of Species
Apidae 4 Apidae 2
Halicidae 2
Pollen identification
We analyzed external pollen loads of Apis, Melissodes, both Xylocopa species, and both
genera of Halictids combined. Chinese tallow pollen dominated loads of Apis (86%), Melissodes
(85%), and Halictids (79%), but made up only 14% of loads carried by Xylocopa (Table 5). An
ANOVA on the arcsine-square root transformed proportions showed the four groups carried
significantly different proportions of tallow pollen in their pollen loads (F3, 31 = 11.8, p < 0.001).
Post-hoc comparisons showed no significant differences in the proportion of Chinese tallow
pollen in pollen loads between Apis, Melissodes, and the Halictid species. The two Xylocopa
species carried a significantly lower proportion of tallow pollen than all other groups (Tukey’s
HSD test p < 0.001 for all comparisons).
Table 6: Mean and standard deviation of 5 field views of pollen loads per group
n Tallow Non-tallow
Apis 12 7.233 ± 3.994 1.100 ± 1.864
Halictidae 6 2.400 ± 0.657 0.833 ± 2.041
Melissodes 12 6.583 ± 4.324 1.517 ± 1.478
Xylocopa 6 0.833 ± 0.612 6.000 ± 5.238
19
Discussion
My results suggest that Triadica sebifera on the Gulf Coast is strongly outcrossing and
primarily bee pollinated. Seed production in pollinator exclusion experiments was only 5% of
that in open-pollinated flowers, indicating the possibility of self fertilization if not considering
the possibility of apomixis. The mean seed set of 29% in open-pollinated flowers was somewhat
surprising given that flowers were receptive for up to 10 days after opening, and suggests that the
study plants may have been pollinator-limited. Seed production in some populations has been
estimated at over 100,000 per tree (Renne et al. 2000) and this level of production appears to be
inconsistent with pollinator limitation. It is possible that visitation rates vary significantly among
locations with pollinator community composition and abundance, or are strongly influenced by
the density of flowering tallow trees. Our pollinator collections were intermittent and aimed
primarily at establishing the identity of flower visitors rather than assessing rates of visitation.
Further studies comparing visitation rates in populations of different densities and in different
locations would be of significant interest.
Chinese tallow pollen appears to be poorly dispersed by wind and unlikely to produce
significant seed set under most conditions. Deposition of tallow pollen on sampling slides was
low relative to that of other plant species, and dropped to essentially zero at 8 meters from the
source. Wind dispersal of pollen could potentially produce significant seed set in dense stands of
tallow, but its importance is likely to be minor compared to insect pollination in most
populations.
External pollen loads of bee species show Apis, Melissodes, and Halictids visiting tallow
with similar fidelity. Xylocopa pollen loads had greater diversity, showing more generalized
20
visitation. Our collection of bee species from the HRRC is consistent with common species
previously found in bottomland hardwood forests (Hanula and Horn 2011, Ulyshen 2010), and
suggests that common, native generalist flower visitors in this habitat can and do frequently visit
Chinese tallow. Although collection effort was greater at the HRRC, we collected fewer
individual bees than at the MSCNWR. Despite lower numbers, bee species richness was higher
at the HRRC.
The relatively low bee species diversity and the dominance of Apis among visitors to
tallow trees at the MSCNWR is not consistent with bee assemblages previously found in longleaf
pine savannah by Bartholomew (2004). Apis mellifera is known to have strong preferences for
plants producing large amounts of pollen (Aronne et al. 2012), and may be preferentially
foraging on Chinese tallow in this habitat to the exclusion of small, scattered native plants that
produce only limited amounts of pollen. It is possible that interference competition from Apis
reduced visitation rates of native bees to tallow trees at MSCNWR, as has been found in
previous studies (Goulson 2003). Alternatively, solitary native bees such as Melissodes and
Augochlora are likely to have restricted flight distances compared to Apis mellifera (Gathmann
and Tscharntke 2002) and may find it more profitable to exploit native herbaceous plants in
longleaf pine savannahs near their nest sites (Peet and Allard 1993) than to fly long distances to
exploit scattered Chinese tallow patches.
Our results do not support the idea that Triadica sebifera and Apis mellifera comprise an
invasive mutualism that facilitated the spread of Chinese tallow in North America. While Apis
dominated at MSCNWR, comprising 98% of all bee visitors, it made up only 26% of bee visitors
at HRRC. In addition, Apis, Melissodes and Augochlora visitors all carried pollen loads equally
dominated by tallow pollen, indicating that native bees visit tallow extensively. Because
21
Melissodes and Augochlora are comparable in size to Apis, we could not carry out pollinator
exclusion experiments that might have determined if Apis was a more effective pollinator than
native bees. However, the simple, open structure of Triadica flowers (Webster 1994) suggests
that a wide variety of visitors, including native bees, should be effective pollinators.
Our results show that the pollination system of Triadica sebifera is well suited to a
successful invader capable of at least a small amount of self-fertilization under natural conditions,
and can potentially produce seed even under severe pollinator limitation. This would allow
newly established populations to reproduce and potentially gain a foothold in a novel
environment, even if insect visitation is low. Its ability to attract native pollinators suggests that,
once established, this species would not be pollen limited, and this is consistent with the copious
seed sets noted in other studies (Renne et al. 2000, Scheld and Cowles 1981). Overall, this
species is far more likely to be limited by the physical environment, natural enemies, or
competition from native plant species than by pollination services.
22
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Appendix
Receptivity Data
Table 7: Numbers of fruits developed in receptivity exclusion experiment
Day of Bag Removal Tree # 1 Tree # 2 Tree # 3
5/26/12 2 4 2 1 4 5 4 3 1 3 3 2
5/28/12 3 4 5 2 3 5 3 2 3 3 1 2
5/30/12 4 1 1 2 2 4 1 5 2 3 1 1
6/1/12 3 1 2 3 5 4 4 1 2 1 5 2
6/3/12 1 4 2 2 1 2 2 5 3 1 2 1
Insect Identification
Table 8: Arthropods collected (ms stands for morphospecies)
Date Time Capture # Order Family Genus Species
5/24/12 10:00 1 Hymenoptera Apidae Xylocopa virginica
5/24/12 10:00 2 Hymenoptera Apidae Xylocopa micans
5/24/12 10:00 3 Hymenoptera Apidae Apis mellifera
5/24/12 10:00 4 Hymenoptera Ichneumonidae – –
5/24/12 10:00 5 Coleoptera Oedemeridae Oxacis –
5/24/12 10:00 6 Coleoptera Coccinellidae Harmonia –
6/4/12 13:00 1 Hymenoptera Apidae Melissodes bimaculata
6/4/12 13:00 2 Hymenoptera Apidae Melissodes bimaculata
6/4/12 13:00 3 Hymenoptera Apidae Melissodes bimaculata
6/4/12 13:00 4 Hymenoptera Apidae Melissodes bimaculata
6/4/12 13:00 5 Diptera Syrphidae Palpada –
6/4/12 13:00 6 Diptera Syrphidae Palpada –
6/4/12 13:00 7 Hymenoptera Vespidae Polistes ms1
6/4/12 13:00 8 Hymenoptera Apidae Apis mellifera
6/4/12 13:00 9 Hymenoptera Apidae Apis mellifera
6/6/12 12:00 5 Hymenoptera Apidae Apis mellifera
6/6/12 12:00 7 Coleoptera Scarabaeidae Euphoria –
6/6/12 12:00 8 Hemiptera Pentatomidae Euschistus –
6/6/12 12:00 9 Coleoptera Oedemeridae Oxacis –
6/6/12 12:00 10 Hymenoptera Apidae Apis mellifera
6/6/12 12:00 11 Hemiptera Pentatomidae Euschistus –
31
(table continued)
6/6/12 12:00 14 Coleoptera Coccinellidae Harmonia –
6/6/12 12:00 15 Coleoptera Oedemeridae Oxacis –
6/6/12 13:00 1 Hymenoptera Halictidae Augochloropsis metallica
6/6/12 13:00 2 Coleoptera Chrysomelidae Paria –
6/6/12 13:00 3 Hymenoptera Apidae Apis mellifera
6/6/12 13:00 5 Hymenoptera Apidae Apis mellifera
6/6/12 13:00 8 Coleoptera Histeridae Paromalus –
6/6/12 13:00 9 Hymenoptera Apidae Apis mellifera
6/13/12 13:00 3 Hymenoptera Vespidae – ms2
6/13/12 13:00 4 Coleoptera Elateridae Glyphonyx –
6/13/12 13:00 5 Hymenoptera Vespidae – ms3
6/13/12 13:00 6 Hymenoptera Apidae Melissodes bimaculata
6/13/12 13:00 7 Hymenoptera Apidae Melissodes bimaculata
6/15/12 13:00 2 Hymenoptera Vespidae Zethus ms2
6/15/12 13:00 4 Hymenoptera Apidae Apis mellifera
6/15/12 13:00 6 Diptera Syrphidae Palpada –
6/15/12 13:00 7 Hemiptera Largidae Largus –
6/15/12 13:00 8 Hemiptera Largidae Largus –
6/15/12 13:00 9 Coleoptera Elateridae Glyphonyx –
6/15/12 14:00 1 Hemiptera Reduviidae Zelus –
6/15/12 14:00 2 Diptera Sarcophagidae Tylomyia –
6/15/12 14:00 3 Diptera Dolichopodidae Chrysotus –
6/15/12 14:00 4 Diptera Sarcophagidae Tylomyia –
6/15/12 14:00 5 Diptera Sarcophagidae Tylomyia –
6/15/12 14:00 7 Diptera Sarcophagidae Tylomyia –
6/15/12 14:00 8 Diptera Sarcophagidae Tylomyia –
6/15/12 14:00 9 Diptera Dolichopodidae Chrysotus –
6/15/12 14:00 10 Hymenoptera Formicidae – ms1
6/15/12 14:00 11 Hemiptera Rhopalidae Arhyssus –
6/15/12 14:00 12 Hymenoptera Formicidae – ms1
6/15/12 14:00 13 Hymenoptera Vespidae – ms3
6/18/12 15:00 1 Hymenoptera Apidae Melissodes bimaculata
6/18/12 15:00 2 Diptera Tachinidae – –
6/18/12 15:00 3 Hymenoptera Vespidae – ms4
6/18/12 15:00 4 Diptera Tachinidae – –
6/18/12 15:00 5 Hymenoptera Vespidae – ms5
6/18/12 15:00 6 Coleoptera Elateridae Glyphonyx –
6/18/12 15:00 7 Hymenoptera Vespidae – ms6
6/18/12 15:00 8 Diptera Syrphidae Palpada –
6/18/12 15:00 9 Coleoptera Scarabaeidae Trigonopeltastes –
6/18/12 15:00 13 Diptera Syrphidae Palpada –
6/24/12 18:00 1 Diptera Asilidae Ommatius –
32
(table continued)
6/24/12 18:00 2 Hymenoptera Formicidae – ms1
6/24/12 18:00 3 Diptera Tachinidae – –
6/27/12 11:00 1 Hymenoptera Formicidae – ms2
6/12/13 11:00 1 Hymenoptera Halictidae Augochloropsis metallica
6/12/13 11:00 2 Hymenoptera Halictidae Augochloropsis metallica
6/12/13 11:00 3 Hymenoptera Halictidae Augochloropsis metallica
6/12/13 11:00 4 Hymenoptera Vespidae – ms6
6/12/13 11:00 5 Hymenoptera Apidae Melissodes bimaculata
6/12/13 12:00 1 Hymenoptera Formicidae – ms1
6/12/13 12:00 2 Hemiptera Miridae Eustictus –
6/12/13 12:00 3 Hymenoptera Formicidae – ms1
6/14/13 12:00 1 Hymenoptera Apidae Xylocopa ms1
6/14/13 12:00 2 Hymenoptera Apidae Apis mellifera
6/14/13 12:00 3 Hymenoptera Apidae Apis mellifera
6/14/13 12:00 4 Hymenoptera Apidae Apis mellifera
6/14/13 12:00 5 Hymenoptera Apidae Apis mellifera
6/14/13 12:30 1 Hymenoptera Apidae Apis mellifera
6/14/13 12:30 2 Hymenoptera Apidae Apis mellifera
6/14/13 12:30 3 Hymenoptera Apidae Apis mellifera
6/14/13 12:30 4 Hymenoptera Apidae Apis mellifera
6/14/13 12:30 5 Hymenoptera Apidae Apis mellifera
6/14/13 12:30 6 Hymenoptera Apidae Apis mellifera
6/14/13 13:00 1 Hymenoptera Vespidae – ms6
6/14/13 13:00 2 Hymenoptera Apidae Apis mellifera
6/14/13 13:00 3 Hymenoptera Apidae Apis mellifera
6/14/13 13:00 4 Hymenoptera Apidae Apis mellifera
6/14/13 13:00 5 Hymenoptera Apidae Apis mellifera
6/19/13 12:00 1 Hemiptera Miridae Eustictus –
6/19/13 12:00 2 Hymenoptera Formicidae – ms2
6/19/13 12:00 8 Hymenoptera Vespidae – ms6
6/19/13 12:00 9 Hymenoptera Apidae Xylocopa virginica
6/19/13 12:00 10 Hymenoptera Apidae Melissodes bimaculata
6/19/13 12:00 11 Hymenoptera Apidae Melissodes bimaculata
6/19/13 12:00 12 Hymenoptera Apidae Melissodes bimaculata
6/19/13 12:00 13 Hymenoptera Apidae Melissodes bimaculata
6/19/13 12:00 14 Coleoptera Coccinellidae Harmonia –
6/19/13 12:00 15 Hemiptera Pentatomidae Cosmopepla –
6/19/13 12:00 16 Hymenoptera Apidae Xylocopa virginica
6/19/13 13:00 1 Hymenoptera Formicidae – ms2
6/19/13 13:00 3 Hymenoptera Apidae Xylocopa virginica
6/21/13 10:00 1 Hymenoptera Apidae Apis mellifera
6/21/13 10:00 2 Hymenoptera Apidae Apis mellifera
33
(table continued)
6/21/13 10:00 3 Hymenoptera Apidae Apis mellifera
6/21/13 10:00 4 Hymenoptera Apidae Apis mellifera
6/21/13 10:00 5 Hymenoptera Apidae Apis mellifera
6/21/13 10:00 6 Hymenoptera Apidae Apis mellifera
6/21/13 10:00 7 Hymenoptera Apidae Apis mellifera
6/21/13 10:00 8 Hymenoptera Apidae Apis mellifera
6/21/13 10:15 1 Hymenoptera Apidae Apis mellifera
6/21/13 10:15 2 Hymenoptera Apidae Apis mellifera
6/21/13 10:15 3 Hymenoptera Apidae Apis mellifera
6/21/13 10:15 4 Hymenoptera Apidae Apis mellifera
6/21/13 10:15 5 Hymenoptera Apidae Apis mellifera
6/21/13 10:30 1 Hymenoptera Apidae Apis mellifera
6/21/13 10:30 2 Hymenoptera Apidae Apis mellifera
6/21/13 10:30 3 Hymenoptera Apidae Apis mellifera
6/21/13 10:30 4 Hymenoptera Apidae Apis mellifera
6/21/13 10:30 5 Hymenoptera Vespidae – ms7
6/21/13 10:30 6 Hymenoptera Apidae Apis mellifera
6/21/13 11:00 1 Hymenoptera Formicidae – ms2
6/21/13 11:00 2 Hymenoptera Vespidae – ms7
6/21/13 11:00 4 Hymenoptera Apidae Apis mellifera
6/21/13 11:00 5 Diptera Syrphidae Toxomerus –
6/21/13 11:15 6 Hymenoptera Apidae Apis mellifera
6/21/13 11:15 7 Hymenoptera Apidae Apis mellifera
6/21/13 11:15 8 Hymenoptera Apidae Apis mellifera
6/21/13 11:15 9 Hymenoptera Apidae Apis mellifera
6/21/13 11:30 1 Hymenoptera Apidae Apis mellifera
6/21/13 11:30 2 Diptera – – –
6/21/13 11:30 3 Hymenoptera Apidae Apis mellifera
6/21/13 11:30 5 Hymenoptera Apidae Apis mellifera
6/21/13 11:30 6 Hymenoptera Apidae Apis mellifera
6/21/13 11:30 7 Hymenoptera Apidae Apis mellifera
6/25/13 14:00 1 Hymenoptera Halictidae Augochlora pura
6/25/13 14:00 3 Hymenoptera Formicidae – ms2
6/25/13 14:00 4 Hymenoptera Halictidae Augochlora pura
6/26/13 9:00 2 Coleoptera Scarabaeidae Trigonopeltastes –
6/26/13 9:00 3 Hymenoptera Apidae Melissodes bimaculata
6/26/13 9:00 4 Hymenoptera Vespidae – ms6
6/26/13 9:00 5 Hymenoptera Apidae Xylocopa virginica
34
Vita
The author was born in New Orleans, Louisiana. She obtained her Bachelor of Science from the
University of New Orleans in 2011. She joined the graduate program to pursue a Master of
Science in Biological Sciences under the advisement of Dr. Jerome Howard, which she
completed in 2016.