36 Transport
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Transcript 36 Transport
Chapter 36:
Transport in Plants
Plants
Leaves roots
may be 100m apart.
Question ?
How do plants move
materials from one
organ to the other ?
Levels of Plant Transport
1. Cellular
2. Short Distance
3. Long Distance
3 Levels of Plant Transport
A) Cellular Transport
The transport of solutes and
water across cell
membranes.
Problem: very slow
Mechanisms
Types of transport:
1.
Passive Transport
Diffusion and Osmosis.
Requires no cellular energy.
Materials diffuse down
concentration gradients.
Transport Proteins
Ex: Carrier Proteins
Selective Channels
Potassium Channel
Found in most plant cell
membranes.
Allow K+ but not Na+ to pass.
Often “gated” to respond to
environmental stimuli.
B. Active Transport
C. Water Transport
2. Active Transport
Requires cell energy.
Moves solutes against a concentration gradient.
Ex: Proton Pump (another example of Chemiosmosis)
Membrane Potentials
Uses ATP to move H+ out of cells.
H+ creates a membrane potential.
H+ allows cotransport.
Allow cations to moved into the cell.
Ex: Ca+2, Mg+2
Cotransport
Couples H+ with anions to move both into cell.
Ex: NO3-
Summary
3. Water Transport
Osmosis - water moves from high concentration to low
concentration.
Water Potential
The potential energy of water to move from one location to another.
Abbreviated as
y
Has two components:
yr
yp
Pressure potential:
Solute potential:
y = yr + yp
Problem
Cell wall creates a pressure in the cells.
Water potential must account for this pressure.
Pressure counteracts the tendency for water to
move into plant cells.
Bulk Flow
The movement of water between two
locations due to pressure.
Much faster than osmosis.
Tension (negative pressure).
May cause bulk flow against the diffusion
gradient.
Tension
Is a very important force to "pull" water from
one location to another.
Plant Vacuoles
Create Turgor Pressure against the cell wall.
Affect water potential by controlling water
concentrations inside cells.
Tonoplast
Name for the vacuole membrane.
Has proton pumps.
Comment – genetic modification of these
pumps gives plants salt tolerance.
Proton Pumps
Drives solutes inside the vacuole.
Lowers water potential (yp ) inside the
vacuole.
Result
Water moves into the vacuole.
Vacuole swells.
Turgor pressure increases.
Turgor Pressure
Important for non-woody plant support.
Wilting:
Loss of turgor pressure.
Loss of water from cells.
Turgid
Flaccid
Aquaporins
Water specific facilitated diffusion transport
channels.
Help water move more rapidly through lipid
bilayers.
Short Distance Transport
1. Transmembrane route
2. Symplast route
3. Apoplast route
1. Transmembrane
Materials cross from cell
to cell by crossing each
cell's membranes and cell
walls.
2. Symplast
The continuum of
cytoplasm by
plasmodesmata bridges
between cells.
3. Apoplast
Extracellular pathway
around and between
cell walls.
Point
Movement of materials can take place by all 3
routes.
Long Distance Transport
Problem: diffusion is too slow for long
distances.
Answer: tension and bulk flow methods.
Start - Roots
Absorb water.
Take up minerals.
Root Hairs
Main site of absorption.
Comment - older roots
have cork and are not very
permeable to water.
Root Cortex
Very spongy.
Apoplast route very
common.
Problem
Can't control uptake
of materials if the
apoplast route is
used.
Solution
Endodermis with its
Casparian Strip.
Casparian Strip
Waxy layer of suberin.
Creates a barrier between the cortex and the
stele.
Forces materials from apoplast into
endodermis symplast.
Result
Plant can now control movement of materials into
the stele.
Casparian Strip
Endodermis
Mycorrhizae
Symbiotic association of fungi with roots of
plants.
Help with water and mineral absorption
(replaces root hairs in some plants).
May also prevent toxins from entering the
plant.
Mycorrhizae
Xylem Sap
Solution of water and minerals loaded into the
xylem by the endodermis.
Endodermis - also prevents back flow of
water and minerals out of the stele.
Xylem Sap Transport Methods
1. Root Pressure
2. Transpiration (Ts)
Root Pressure
Root cells load minerals into xylem.
Water potential (yp) is lowered.
Water flows into xylem.
Result
Volume of water in xylem increases
Xylem sap is pushed up the xylem tissues creating root
pressure.
Comments
Root Pressure: limited way
to move xylem sap.
Most apparent at night.
Excess water may leave
plant through Guttation.
Transpiration (Ts)
Evaporation of water from aerial plant parts.
Major force to pull xylem sap up tall trees.
TCTM Theory
Transpiration
Cohesion
Tension
Mechanism
How does TCTM work?
Water evaporates from leaves, especially from
the cell walls of the spongy mesophyll.
Reason: water potential of the air is usually
much less than that of the cells.
As water evaporates:
Cohesion: water molecules sticking together
by H bonds.
Adhesion: water molecules sticking to other
materials (cell walls etc.).
Result
The loss of water from the leaves creates
“tension” or negative pressure between the air
and the water in the plant.
Tension causes:
Xylem sap to move to replace the water lost
from the mesophyll cells.
Xylem Sap
Is “pulled” by the resulting tension all the way
down the plant to the roots and soil.
Summary
Xylem sap moves along a continual chain of
water potential from:
air leaf stem roots soil
Comments
Tension is a negative pressure which causes a
decreased in the size of xylem cells.
Xylem cells would collapse without
secondary cell walls.
Factors that Affect Transpiration Rate
1. Environmental
2. Plant Structures
Stomatal Crypt
Multiple Layer Epidermis
Environmental Factors
1. Humidity
2. Temperature
3. Light
4. Soil Water Content
5. Wind
Plant Structure Factors
1. Cuticle
2. Stomate Number
3. Hairs
Stomates
Openings in the epidermis that allow water
and gas exchange.
Controlled by Guard Cells.
Control rate of Ts and Ps.
Guard Cells
Turgid: Swell - open stomata.
Flaccid: Shrink - close stomata.
Size of the cells is a result of turgor pressure
changes.
Turgid - Open
Flaccid - Closed
Turgor Pressure of Guard cells
Controlled by K+ concentrations.
To Open Stomata:
1. K+ enters the guard cells.
2. Water potential lowered.
3. Water enters guard cells.
4. Turgor pressure increases.
5. Guard cells swell and Stomata opens.
To Close Stomata:
1. K+ leaves guard cells.
2. Water leaves guard cells.
3. Turgor pressure decreases.
4. Guard cells shrink and Stomata close.
K+ Movement
Regulated by proton pumps and K+ channels.
Controlled by:
Light (Blue)
CO2 concentrations
Abscisic Acid (water stress)
Comment
Plant must balance loss of water by
transpiration with CO2 uptake for Ps.
Adaptations for Balance
C4 Ps
CAM Ps
Phloem Transport
Moves sugars (food).
Transported in live cells.
Ex: Sieve & Companion Cells
Source - Sink Transport
Model for movement of phloem sap from a
Source to a Sink.
Source
Sugar production site
Ex: Ps
Starch breakdown in a
storage area.
Sink
Sugar uptake site.
Ex: Growing areas
Storage areas
Fruits and seeds
Comment
The same organ can serve as a source or a
sink depending on the season.
Result
Phloem transport can go in two directions
even in the same vascular bundle.
Xylem Transport: In Contrast to Phloem
Usually unidirectional.
Endodermis prevents back flow.
Dead cells.
Phloem Loading at the Source:
1. Diffusion
2. Transfer Cells
3. Active Transport
Phloem Loading
Transfer Cells
Modified cell with ingrowths of cell wall to
provide more surface area for sugar diffusion.
Result
Sugar loaded into phloem.
Water potential (yp) decreases.
Bulk flow is created.
Bulk Flow
Movement of water into phloem.
Pressure forces phloem sap to move toward
the sink.
At the Sink:
Sugar is removed.
Water potential is raised.
Water moves out of phloem over to xylem.
Phloem: summary
Source - builds pressure.
Sink - reduces pressure.
Pressure caused by:
Sugar content changes
Water potential changes
Comment
Plants move materials without "moving"
parts, unlike animals.
Summary
Know various ways plants use to move
materials.
Know how Ts works and the factors that
affect Ts.
Know how phloem transport works.