transport in vascular plants
DESCRIPTION
Transport in Vascular Plants. Overview: Pathways for Survival. For vascular plants, the evolutionary journey onto land involved differentiation into roots and shoots Vascular tissue transports nutrients in a plant; such transport may occur over long distances. - PowerPoint PPT PresentationTRANSCRIPT
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Transport in Vascular Plants
Transport in Vascular Plants
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Overview: Pathways for Survival
Overview: Pathways for Survival
For vascular plants, the evolutionary journey onto land involved differentiation into roots and shoots
Vascular tissue transports nutrients in a plant; such transport may occur over long distances
For vascular plants, the evolutionary journey onto land involved differentiation into roots and shoots
Vascular tissue transports nutrients in a plant; such transport may occur over long distances
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Physical forces drive the transport of materials in plants over a range of distances
Physical forces drive the transport of materials in plants over a range of distances
Transport in vascular plants occurs on three scales:Transport of water and solutes by
individual cells, such as root hairsShort-distance transport of substances
from cell to cell at the levels of tissues and organs
Long-distance transport within xylem and phloem at the level of the whole plant
Transport in vascular plants occurs on three scales:Transport of water and solutes by
individual cells, such as root hairsShort-distance transport of substances
from cell to cell at the levels of tissues and organs
Long-distance transport within xylem and phloem at the level of the whole plant
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Minerals
H2O
H2O
CO2 O2
Sugar
Light
CO2
O2
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Selective Permeability of Membranes: A Review
Selective Permeability of Membranes: A Review
The selective permeability of the plasma membrane controls movement of solutes into and out of the cell
Specific transport proteins enable plant cells to maintain an internal environment different from their surroundings
The selective permeability of the plasma membrane controls movement of solutes into and out of the cell
Specific transport proteins enable plant cells to maintain an internal environment different from their surroundings
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The Central Role of Proton Pumps
The Central Role of Proton Pumps
Proton pumps in plant cells create a hydrogen ion gradient that is a form of potential energy that can be harnessed to do work
They contribute to a voltage known as a membrane potential
Proton pumps in plant cells create a hydrogen ion gradient that is a form of potential energy that can be harnessed to do work
They contribute to a voltage known as a membrane potential
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LE 36-3LE 36-3
CYTOPLASM
ATP
EXTRACELLULAR FLUID
Proton pumpgenerates mem-brane potentialand gradient.
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Plant cells use energy stored in the proton gradient and membrane potential to drive the transport of many different solutes
Plant cells use energy stored in the proton gradient and membrane potential to drive the transport of many different solutes
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LE 36-4aLE 36-4a
CYTOPLASM EXTRACELLULAR FLUID
Cations ( , forexample) aredriven into the cellby the membranepotential.
Transport protein
Membrane potential and cation uptake
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In the mechanism called cotransport, a transport protein couples the passage of one solute to the passage of another
In the mechanism called cotransport, a transport protein couples the passage of one solute to the passage of another
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LE 36-4bLE 36-4b
Cell accumulatesanions ( , for example) by coupling their transport to; theinward diffusionof through a cotransporter.
Cotransport of anions
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The “coattail” effect of cotransport is also responsible for the uptake of the sugar sucrose by plant cells
The “coattail” effect of cotransport is also responsible for the uptake of the sugar sucrose by plant cells
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LE 36-4cLE 36-4c
Plant cells canalso accumulatea neutral solute, such as sucrose( ), bycotransporting down thesteep protongradient.
Cotransport of a neutral solute
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Effects of Differences in Water Potential
Effects of Differences in Water Potential
To survive, plants must balance water uptake and loss
Osmosis determines the net uptake or water loss by a cell is affected by solute concentration and pressure
To survive, plants must balance water uptake and loss
Osmosis determines the net uptake or water loss by a cell is affected by solute concentration and pressure
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Water potential is a measurement that combines the effects of solute concentration and pressure
Water potential determines the direction of movement of water
Water flows from regions of higher water potential to regions of lower water potential
Water potential is a measurement that combines the effects of solute concentration and pressure
Water potential determines the direction of movement of water
Water flows from regions of higher water potential to regions of lower water potential
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How Solutes and Pressure Affect Water Potential
How Solutes and Pressure Affect Water Potential
Both pressure and solute concentration affect water potential
The solute potential of a solution is proportional to the number of dissolved molecules
Pressure potential is the physical pressure on a solution
Both pressure and solute concentration affect water potential
The solute potential of a solution is proportional to the number of dissolved molecules
Pressure potential is the physical pressure on a solution
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Quantitative Analysis of Water Potential
Quantitative Analysis of Water Potential
The addition of solutes reduces water potential
The addition of solutes reduces water potential
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Physical pressure increases water potential
Negative pressure decreases water potential
Physical pressure increases water potential
Negative pressure decreases water potential
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Water potential affects uptake and loss of water by plant cells
If a flaccid cell is placed in an environment with a higher solute concentration, the cell will lose water and become plasmolyzed
Water potential affects uptake and loss of water by plant cells
If a flaccid cell is placed in an environment with a higher solute concentration, the cell will lose water and become plasmolyzed
Video: Plasmolysis
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If the same flaccid cell is placed in a solution with a lower solute concentration, the cell will gain water and become turgid
If the same flaccid cell is placed in a solution with a lower solute concentration, the cell will gain water and become turgid
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Turgor loss in plants causes wilting, which can be reversed when the plant is watered
Turgor loss in plants causes wilting, which can be reversed when the plant is watered
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Aquaporin Proteins and Water Transport
Aquaporin Proteins and Water Transport
Aquaporins are transport proteins in the cell membrane that allow the passage of water
Aquaporins do not affect water potential
Aquaporins are transport proteins in the cell membrane that allow the passage of water
Aquaporins do not affect water potential
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Three Major Compartments of Vacuolated Plant Cells
Three Major Compartments of Vacuolated Plant Cells
Transport is also regulated by the compartmental structure of plant cells
The plasma membrane directly controls the traffic of molecules into and out of the protoplast
The plasma membrane is a barrier between two major compartments, the cell wall and the cytosol
Transport is also regulated by the compartmental structure of plant cells
The plasma membrane directly controls the traffic of molecules into and out of the protoplast
The plasma membrane is a barrier between two major compartments, the cell wall and the cytosol
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The third major compartment in most mature plant cells is the vacuole, a large organelle that occupies as much as 90% or more of the protoplast’s volume
The vacuolar membrane regulates transport between the cytosol and the vacuole
The third major compartment in most mature plant cells is the vacuole, a large organelle that occupies as much as 90% or more of the protoplast’s volume
The vacuolar membrane regulates transport between the cytosol and the vacuole
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LE 36-8aLE 36-8a
Cell compartments
Plasmodesma
Plasma membrane
Cell wallCytosol
Vacuole
Key
Symplast
Apoplast
Vacuolar membrane(tonoplast)
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In most plant tissues, the cell walls and cytosol are continuous from cell to cell
The cytoplasmic continuum is called the symplast
The apoplast is the continuum of cell walls and extracellular spaces
In most plant tissues, the cell walls and cytosol are continuous from cell to cell
The cytoplasmic continuum is called the symplast
The apoplast is the continuum of cell walls and extracellular spaces
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Transmembrane route
Key
Symplast
Apoplast
Symplastic route
Transport routes between cells
Apoplastic route
Apoplast
Symplast
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Functions of the Symplast and Apoplast in TransportFunctions of the Symplast and Apoplast in Transport
Water and minerals can travel through a plant by three routes:Transmembrane route: out of one cell,
across a cell wall, and into another cellSymplastic route: via the continuum of
cytosolApoplastic route: via the the cell walls and
extracellular spaces
Water and minerals can travel through a plant by three routes:Transmembrane route: out of one cell,
across a cell wall, and into another cellSymplastic route: via the continuum of
cytosolApoplastic route: via the the cell walls and
extracellular spaces
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Bulk Flow in Long-Distance Transport
Bulk Flow in Long-Distance Transport
In bulk flow, movement of fluid in the xylem and phloem is driven by pressure differences at opposite ends of the xylem vessels and sieve tubes
In bulk flow, movement of fluid in the xylem and phloem is driven by pressure differences at opposite ends of the xylem vessels and sieve tubes
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Roots absorb water and minerals from the soil
Roots absorb water and minerals from the soil
Water and mineral salts from the soil enter the plant through the epidermis of roots and ultimately flow to the shoot system
Water and mineral salts from the soil enter the plant through the epidermis of roots and ultimately flow to the shoot system
Animation: Transport in Roots
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Casparian strip
Endodermal cellPathway alongapoplast
Pathway throughsymplast
Casparian strip
Plasmamembrane
Apoplasticroute
Symplasticroute
Roothair
Vessels(xylem)
Cortex
EndodermisEpidermis Vascular cylinder
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Much of the absorption of water and minerals occurs near root tips, where the epidermis is permeable to water and root hairs are located
Root hairs account for much of the surface area of roots
After soil solution enters the roots, the extensive surface area of cortical cell membranes enhances uptake of water and selected minerals
Much of the absorption of water and minerals occurs near root tips, where the epidermis is permeable to water and root hairs are located
Root hairs account for much of the surface area of roots
After soil solution enters the roots, the extensive surface area of cortical cell membranes enhances uptake of water and selected minerals
The Roles of Root Hairs, Mycorrhizae, and Cortical Cells
The Roles of Root Hairs, Mycorrhizae, and Cortical Cells
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Most plants form mutually beneficial relationships with fungi, which facilitate absorption of water and minerals from the soil
Roots and fungi form mycorrhizae, symbiotic structures consisting of plant roots united with fungal hyphae
Most plants form mutually beneficial relationships with fungi, which facilitate absorption of water and minerals from the soil
Roots and fungi form mycorrhizae, symbiotic structures consisting of plant roots united with fungal hyphae
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2.5 mm
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The Endodermis: A Selective Sentry
The Endodermis: A Selective Sentry
The endodermis is the innermost layer of cells in the root cortex
It surrounds the vascular cylinder and is the last checkpoint for selective passage of minerals from the cortex into the vascular tissue
The endodermis is the innermost layer of cells in the root cortex
It surrounds the vascular cylinder and is the last checkpoint for selective passage of minerals from the cortex into the vascular tissue
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Water can cross the cortex via the symplast or apoplast
The waxy Casparian strip of the endodermal wall blocks apoplastic transfer of minerals from the cortex to the vascular cylinder
Water can cross the cortex via the symplast or apoplast
The waxy Casparian strip of the endodermal wall blocks apoplastic transfer of minerals from the cortex to the vascular cylinder
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Water and minerals ascend from roots to shoots through
the xylem
Water and minerals ascend from roots to shoots through
the xylem
Plants lose an enormous amount of water through transpiration, the loss of water vapor from leaves and other aerial parts of the plant
The transpired water must be replaced by water transported up from the roots
Plants lose an enormous amount of water through transpiration, the loss of water vapor from leaves and other aerial parts of the plant
The transpired water must be replaced by water transported up from the roots
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Factors Affecting the Ascent of Xylem SapFactors Affecting the Ascent of Xylem Sap
Xylem sap rises to heights of more than 100 m in the tallest plants
Is the sap pushed upward from the roots, or is it pulled upward by the leaves?
Xylem sap rises to heights of more than 100 m in the tallest plants
Is the sap pushed upward from the roots, or is it pulled upward by the leaves?
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Pushing Xylem Sap: Root Pressure
Pushing Xylem Sap: Root Pressure
At night, when transpiration is very low, root cells continue pumping mineral ions into the xylem of the vascular cylinder, lowering the water potential
Water flows in from the root cortex, generating root pressure Root pressure sometimes results in guttation, the exudation of water droplets on tips of grass blades
At night, when transpiration is very low, root cells continue pumping mineral ions into the xylem of the vascular cylinder, lowering the water potential
Water flows in from the root cortex, generating root pressure Root pressure sometimes results in guttation, the exudation of water droplets on tips of grass blades
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Pulling Xylem Sap: The Transpiration-Cohesion Tension Mechanism
Pulling Xylem Sap: The Transpiration-Cohesion Tension Mechanism
Water vapor in the airspaces of a leaf diffuses down its water potential gradient and exits the leaf via stomata
Transpiration produces negative pressure (tension) in the leaf, which exerts a pulling force on water in the xylem, pulling water into the leaf
Water is pulled upward by negative pressure in the xylem
Water vapor in the airspaces of a leaf diffuses down its water potential gradient and exits the leaf via stomata
Transpiration produces negative pressure (tension) in the leaf, which exerts a pulling force on water in the xylem, pulling water into the leaf
Water is pulled upward by negative pressure in the xylem
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Upperepidermis
MesophyllAir
space
Cuticle
Lowerepidermis
Cuticle CO2 O2 CO2Xylem
O2
Stoma
Evaporation
EvaporationWater film
Airspace
Cytoplasm
Cell wall
Vacuole
Air-waterinterface
High rate of transpiration
Low rate of transpiration
Y = –10.00 MPaY = –0.15 MPa
Cell wall
Airspace
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Cohesion and Adhesion in the Ascent of Xylem Sap
Cohesion and Adhesion in the Ascent of Xylem Sap
The transpirational pull on xylem sap is transmitted all the way from the leaves to the root tips and even into the soil solution
Transpirational pull is facilitated by cohesion and adhesion
The transpirational pull on xylem sap is transmitted all the way from the leaves to the root tips and even into the soil solution
Transpirational pull is facilitated by cohesion and adhesion
Animation: Transpiration
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Xylemsap
Mesophyllcells
Stoma
Watermolecule
AtmosphereTranspiration
Xylemcells
Adhesion Cellwall
Cohesion,byhydrogenbonding
Cohesion andadhesion inthe xylem
Watermolecule
Wat
er p
ote
nti
al g
rad
ien
t
Roothair
Soilparticle
WaterWater uptakefrom soil
Trunk xylem = –0.8 Mpa
Root xylem = –0.6 MPa
Leaf (air spaces)= –7.0 MPa
Outside air = –100.0 MPa
Leaf (cell walls) = –1.0 MPa
Soil = –0.3 MPa
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Xylem Sap Ascent by Bulk Flow: A Review
Xylem Sap Ascent by Bulk Flow: A Review
The movement of xylem sap against gravity is maintained by the transpiration-cohesion-tension mechanism
The movement of xylem sap against gravity is maintained by the transpiration-cohesion-tension mechanism
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Stomata help regulate the rate of transpiration
Stomata help regulate the rate of transpiration
Leaves generally have broad surface areas and high surface-to-volume ratios
These characteristics increase photosynthesis and increase water loss through stomata
Leaves generally have broad surface areas and high surface-to-volume ratios
These characteristics increase photosynthesis and increase water loss through stomata
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LE 36-14LE 36-14
20 µm
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Effects of Transpiration on Wilting and Leaf Temperature
Effects of Transpiration on Wilting and Leaf Temperature
Plants lose a large amount of water by transpiration
If the lost water is not replaced by absorption through the roots, the plant will lose water and wilt
Plants lose a large amount of water by transpiration
If the lost water is not replaced by absorption through the roots, the plant will lose water and wilt
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Transpiration also results in evaporative cooling, which can lower the temperature of a leaf and prevent denaturation of various enzymes involved in photosynthesis and other metabolic processes
Transpiration also results in evaporative cooling, which can lower the temperature of a leaf and prevent denaturation of various enzymes involved in photosynthesis and other metabolic processes
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Stomata: Major Pathways for Water Loss
Stomata: Major Pathways for Water Loss
About 90% of the water a plant loses escapes through stomata
Each stoma is flanked by a pair of guard cells, which control the diameter of the stoma by changing shape
About 90% of the water a plant loses escapes through stomata
Each stoma is flanked by a pair of guard cells, which control the diameter of the stoma by changing shape
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Cells turgid/Stoma open
Changes in guard cell shape and stomatal opening and closing(surface view)
Radially orientedcellulose microfibrils
Vacuole
Cell wall
Guard cell
Cells flaccid/Stoma closed
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Changes in turgor pressure that open and close stomata result primarily from the reversible uptake and loss of potassium ions by the guard cells
Changes in turgor pressure that open and close stomata result primarily from the reversible uptake and loss of potassium ions by the guard cells
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Cells turgid/Stoma open
Role of potassium in stomatal opening and closing
Cells flaccid/Stoma closed
H2O
H2O
H2OH2O
H2O H2O
H2O
H2O
H2O
H2O
K+
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Xerophyte Adaptations That Reduce Transpiration
Xerophyte Adaptations That Reduce Transpiration
Xerophytes are plants adapted to arid climates
They have leaf modifications that reduce the rate of transpiration
Their stomata are concentrated on the lower leaf surface, often in depressions that provide shelter from dry wind
Xerophytes are plants adapted to arid climates
They have leaf modifications that reduce the rate of transpiration
Their stomata are concentrated on the lower leaf surface, often in depressions that provide shelter from dry wind
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Cuticle Upper epidermal tissue
Lower epidermaltissue
Trichomes(“hairs”)
Stomata 100 µm
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Organic nutrients are translocated through the
phloem
Organic nutrients are translocated through the
phloem
Translocation is the transport of organic nutrients in a plant
Translocation is the transport of organic nutrients in a plant
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Movement from Sugar Sources to Sugar Sinks Movement from Sugar Sources to Sugar Sinks
Phloem sap is an aqueous solution that is mostly sucrose
It travels from a sugar source to a sugar sink A sugar source is an organ that is a net
producer of sugar, such as mature leaves A sugar sink is an organ that is a net
consumer or storer of sugar, such as a tuber or bulb
Phloem sap is an aqueous solution that is mostly sucrose
It travels from a sugar source to a sugar sink A sugar source is an organ that is a net
producer of sugar, such as mature leaves A sugar sink is an organ that is a net
consumer or storer of sugar, such as a tuber or bulb
![Page 61: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/61.jpg)
Sugar must be loaded into sieve-tube members before being exposed to sinks
In many plant species, sugar moves by symplastic and apoplastic pathways
Sugar must be loaded into sieve-tube members before being exposed to sinks
In many plant species, sugar moves by symplastic and apoplastic pathways
![Page 62: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/62.jpg)
Mesophyll cell
Cell walls (apoplast)
Plasma membrane
Plasmodesmata
Companion(transfer) cell
Mesophyll cellBundle-sheath cell
Phloemparenchyma cell
Sieve-tubemember
Protonpump
Low H+ concentration
Sucrose
High H+ concentrationCotransporter
Key
Apoplast
Symplast
![Page 63: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/63.jpg)
In many plants, phloem loading requires active transport
Proton pumping and cotransport of sucrose and H+ enable the cells to accumulate sucrose
In many plants, phloem loading requires active transport
Proton pumping and cotransport of sucrose and H+ enable the cells to accumulate sucrose
![Page 64: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/64.jpg)
Pressure Flow: The Mechanism of Translocation
in Angiosperms
Pressure Flow: The Mechanism of Translocation
in Angiosperms
In studying angiosperms, researchers have concluded that sap moves through a sieve tube by bulk flow driven by positive pressure
In studying angiosperms, researchers have concluded that sap moves through a sieve tube by bulk flow driven by positive pressure
Animation: Translocation of Phloem Sap in Summer
Animation: Translocation of Phloem Sap in Spring
![Page 65: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/65.jpg)
Vessel(xylem)
Sieve tube(phloem)
Sucrose
Source cell(leaf)
H2O
H2O
Sucrose
Sink cell(storageroot)
H2O
Pre
ssu
refl
ow
Tran
spir
a tio
nst
ream
![Page 66: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/66.jpg)
The pressure flow hypothesis explains why phloem sap always flows from source to sink
Experiments have built a strong case for pressure flow as the mechanism of translocation in angiosperms
The pressure flow hypothesis explains why phloem sap always flows from source to sink
Experiments have built a strong case for pressure flow as the mechanism of translocation in angiosperms
![Page 67: Transport in Vascular Plants](https://reader037.vdocuments.us/reader037/viewer/2022102500/5681434b550346895dafc804/html5/thumbnails/67.jpg)
LE 36-19LE 36-19
Sapdroplet
Aphid feeding Stylet in sieve-tubemember (LM)
Stylet
Severed stylet exuding sap
Sap droplet
Sieve-tubemember
25 µm