Plant Physiology: Resource Acquisition & Transport PDF

Summary

These lecture notes cover plant physiology, focusing on resource acquisition and transport. They detail various structures and processes involved in plant function.

Full Transcript

Plant Physiology:
Resource Acquisition &
Transport
 Overview of Plant Evolution & Structures
Plants arose from algal ancestors
Water-based, non-vascular lacking

de
leaves and roots; minimal stomata
man and waxy cuticles reduced water
loss; materials primarily collected
from water via diffusion
Land plants grew taller (requiring
more structure & anchoring roots
for support & collecting water,
minerals), often with broader
leaves and extensive branching to
collect light more efficiently
·

dominant haploid =>
gameotype

·

vascular tissue arose =
roots/shorts develop ,
more specialization

3
flowers

seeds main
adaptation
pollen
General Vascular Plant Parts
Roots: anchor, collect water,
minerals
Taproot: main, vertical root
Lateral roots: branching roots
Root hairs: ‘fuzzy’ extensions
increasing surface area (mycorrhizae
help too) I

fungal symbiant
↳ help in exchange for sugar
collect
General Vascular Plant Parts Con’t
Shoots: support (stem) and
photosynthesis (leaves)
Stem: supports increased height (may
be woody); in some cases can
photosynthesize
Leaves: light capture, gas exchange
via stomata
Blade: ‘body’ of leaf
Petiole: ‘stem’ of leaf
Leaf Adaptations
·
diff pigments to broaden range of light

Size, shape, orientation of leaves varies
based on environment
If water loss is minimal or light is weak, broad
leaves
If water loss is high or light intensity harsh,
reduce leaves >
-
exposure less to sun

Modify into spines, orient vertically rather than
horizontally
Concentrate stomata on underside (shaded)
Orient leaves to minimize overlap; if lower leaves too
shaded self-prune

lots of light/H2 broad leaves

intense sun + min.

H2o => small leaves
 Vascular Tissue -

transport system

As plants increased in height
they needed more efficient
transport systems: a vascular
system of hollow tubes acting
Q as a circulatory system

Xylem: carry water, minerals ~
shorts
roots to

from roots to shoots; dead
-

, hollow

②
composed of dead tissue
Phloem: carry food (mainly -nutrients hormones ,

sugars) in both directions; alive ,
directly
-

can

composed of living tissue regulate
 Transport
want to avoid fransmem.
bc.
requires specialized proteins
General transport pathways to
move short distances: ↑
around the
Apoplastic: materials move via
Cells
extracellular spaces & cell walls
rapid , quick- Symplastic: materials move in between -

cytoplasm between cells via through cells

plasmodesmata gap junc
con : Cell
pathogens -. in
can
easily run
crossing
cells wo mem.
+ hm
Transmembrane: materials move cell
to cell through membranes & cell
walls for regulation purposes
-

Crossing membranes accomplished via
passive or active transport

active => [low] to
[high]

passive => [High] to
[low]
Transport Con’t
Diffusion & membrane transporters similar to animal cells, BUT
H+ rather than Na+ used in ions pumps and Ca2+ used for electrical signals passive
trems
(similar to action potentials).

↑
Osmosis occurs via aquaporins and driven by concentration gradient,
BUT ↓ due to
having
plant cells a cell wall

Osmosis harnessed as water potential: potential energy of water based on
where it will move
Water flows from regions of higher water potential to regions of lower water
potential
Influenced by solute concentration and physical pressure

osmosis moves towards soln.
hypertonic
 Water Potential gradient
concentration
Calculated as: Ψ = ΨS + ΨP
Ψ = water potential (measured in
megapascals, MPa)
only negative, Ψ S = solute potential (measure of

pulls H20 s
!
solute concentration)
lowers

Pure water value would be zero, so
,
H20
potential
any solute should give a negative F
value; more solute = lower water ↓
potential - ↑↓
D
ΨP = pressure potential (physical D -

N
pressure on the solution) W
+

Can be positive (‘pushing’) or Higher >
-
lower lower >
-
high
negative (‘pulling’)
 nigh
-

I
In I
physical pressure
Heo wants to into cell
go prevents osmosis

structure
plants like this gives
,
& stability
Water Potential Con’t
Movement of water causes cells to
become:
Flaccid (wilted) if water is lost, reducing
pressure (ΨP) can lead to plasmolysis
(shriveling of cell within cell wall)
Turgid (firm) if water is gained, adding
pressure (ΨP)
Unlike animal cells this doesn’t lead to cells
bursting as the cell wall prevents over-expansion
 Long-Distance Transport this is what
bryophies do
~
Diffusion only works efficiently over
very short distances; bulk flow carries
materials over longer distances
Movement of liquid in response to a
pressure gradient (higher -> lower
pressure)
Independent of solute concentration -main
is
focus

physical
Operates in xylem and phloem pressure

diffusion cannot help w/taller plants
 Xylem
Transports water and minerals from roots to leaves
Diffuse into apoplast (everything external to cytoplasm: cell
walls, extracellular spaces, interior of dead cells) mostly at root
hairs
Some minerals actively transported across plasma membrane
H20 follows a

solute
into the symplast (entire mass of cytosol and plasmodesmata)
Apoplast materials move into xylem by crossing endodermis;
symplastic enter via plasmodesmata
Direct entrance to xylem from apoplast prevented by Casparian strip
(waxy barrier) to force all materials to cross the semi-permeable
membrane
 * explain process

~ cross min..
Of I mem.

no cuticle :
dissolve in cell wall

(
active transport
Transpiration
more 20 potential #yo
·
>
at roots -
less at the

top
·

using20 potential

One water/minerals are in xylem, how to transport long distances
against gravity?
> pulling
ofco
-
Bulk transit accomplished via transpiration: loss of water from shoots
Evaporation of water ‘pulls’ a string of water molecules (and dissolved
materials) up the thin xylem tubing system
Addition of solutes in roots draws water in (osmosis), increasing pressure
(root pressure) to ‘push’ solution up
Can lead to guttation: pushing excess water out of ‘escape valves’ in leaves (NOT
stomata) if insufficient transpiration occurs short plants few erap ,
-

,

Note that root pressure is not a major transport force; most movement is due to
transpiration evaporation occurs
=> at the
top

0 advesion
- -
H-bonds
-It both
-

-

cohesion o

I

H
low H20 pot
Transpiration Con’t
Transpiration relies on cohesion and adhesion of water molecules (H-
bonding due to the polar nature of water)
Xylem must be strong enough not to collapse under the powerful
negative pressure (sucking force); in large plants that may be 100+
feet tall reinforced with lignin (not just cellulose), aka wood
Rate of transpiration largely controlled by stomata: ·
where

gas
Heo escapes

exchange
·

Located on underside of leaves to minimize water loss
site
trade off
~
In arid environments reduced leaf size also reduces stomata (but this reduces
surface area for light-capture/photosynthesis too)
Stomata density varies (lower in desert-adapted plants; also varies within
plants due to environmental conditions such as CO2 levels)
open too long in not conditions >
-
water loss for plants
 Stomata
Stomata open/close due to turgidity of guard
cells, controlled by ion channels that
influence osmosis controlled by

Stomata open/close in response to: -
solute concent.

Light: exposure to light opens stomata CO2
03 -
-
needs remove
O for too much o -
>
photorespiration
photosynthesis
CO2 levels: lowered CO2 opens stomata to collect
more
Circadian cycles: even without light, stomata
open during “daylight” hours and close at “night”
[not in CAM plants]
Signals: stress conditions such as drought will
lead to more stomata closing to conserve water
Note: water isn’t primarily for photosynthesis
reaction, but rather to transport minerals
Also thermoregulates the leaf (evaporative cooling) >
Eurose
(
/water flows in water

↳Close
flows out
 [low]
Phloem
tissue
living
moves nutrients
[High] ↑
E
Bidirectional flow of nutrients
=
Hop

(translocation) through living tissues;
phloem into
it
to dilute

controlled/powered by pressure
Transports from source to sink; not always
shoots to roots
Clow] since
Early growth may transfer nutrients from solutes are sucked
storage in roots to growing buds into companion cell
Leaves may transport nutrients to other shoots -
regions undergoing growth (ex: fruits)
Phloem also transports communication
molecules, non-sugar biomolecules, and
even electrical signals