Chapter 39 Plant
Responses to Internal and External Signals
Lecture Outline
Overview: Stimuli and a
Stationary Life
·
At
every stage in the life of a plant, sensitivity to the environment and
coordination of responses are evident.
°
One
part of a plant can send signals to other parts.
°
Plants
can sense gravity and the direction of light.
°
A
plant’s morphology and physiology are constantly tuned to its variable
surroundings by complex interactions between environmental stimuli and internal
signals.
·
At
the organismal level, plants and
animals respond to environmental stimuli by very different means.
°
Animals,
being mobile, respond mainly by behavioral mechanisms, moving toward positive
stimuli and away from negative stimuli.
°
Rooted
in one location for life, a plant generally responds to environmental cues by
adjusting its pattern of growth and development.
§
As
a result, plants of the same species vary in body form much more than do
animals of the same species.
°
At
the cellular level, plants and all other eukaryotes are surprisingly similar in
their signaling mechanisms.
Concept 39.1 Signal transduction pathways link signal reception to
response
·
All
organisms, including plants, have the ability to receive specific environmental
and internal signals and respond to them in ways that enhance survival and
reproductive success.
°
Like
animals, plants have cellular receptors that they use to detect important
changes in their environment.
§
These
changes may be an increase in the concentration of a growth hormone, an injury
from a caterpillar munching on leaves, or a decrease in day length as winter
approaches.
·
In
order for an internal or external stimulus to elicit a physiological response,
certain cells in the organism must possess an appropriate receptor, a molecule
that is sensitive to and affected by the specific stimulus.
°
Upon
receiving a stimulus, a receptor initiates a specific series of biochemical
steps, a signal transduction pathway.
§
This
couples reception of the stimulus to the response of the organism.
·
Plants
are sensitive to a wide range of internal and external stimuli, and each of
these initiates a specific signal transduction pathway.
·
Plant
growth patterns vary dramatically in the presence versus the absence of light.
°
For
example, a potato (a modified underground stem) can sprout shoots from its
“eyes” (axillary buds).
°
These
shoots are ghostly pale and have long, thin stems; unexpanded leaves; and
reduced roots.
·
These
morphological adaptations, called etiolation,
are seen also in seedlings germinated in the dark and make sense for plants
sprouting underground.
°
The
shoot is supported by the surrounding soil and does not need a thick stem.
°
Expanded
leaves would hinder soil penetration and be damaged as the shoot pushes upward.
°
Because
little water is lost in transpiration, an extensive root system is not
required.
°
The
production of chlorophyll is unnecessary in the absence of light.
°
A
plant growing in the dark allocates as much energy as possible to the
elongation of stems to break ground before the nutrient reserves in the tuber
are exhausted.
·
Once
a shoot reaches the sunlight, its morphology and biochemistry undergo profound
changes, collectively called de-etiolation,
or greening.
°
The
elongation rate of the stems slows.
°
The
leaves expand, and the roots start to elongate.
°
The
entire shoot begins to produce chlorophyll.
·
The
de-etiolation response is an example of how a plant receives a signal—in this
case, light—and how this reception is transduced into a response
(de-etiolation).
°
Studies
of mutants have provided valuable insights into the roles played by various
molecules in the three stages of cell-signal processing: reception,
transduction, and response.
·
Signals,
whether internal or external, are first detected by receptors, proteins that
change shape in response to a specific stimulus.
°
The
receptor for de-etiolation in plants is called a phytochrome, which consists of a light-absorbing pigment attached
to a specific protein.
§
Unlike
many receptors, which are in the plasma membrane, this phytochrome is in the
cytoplasm.
°
The
importance of this phytochrome was confirmed through investigations of a tomato
mutant, called aurea, which greens
less when exposed to light.
°
Injecting
additional phytochrome into aurea
leaf cells and exposing them to light produced a normal de-etiolation response.
·
Receptors
such as phytochrome are sensitive to very weak environmental and chemical
signals.
°
For
example, just a few seconds of moonlight slow stem elongation in dark-grown oak
seedlings.
°
These
weak signals are amplified by second
messengers—small, internally produced chemicals that transfer and amplify
the signal from the receptor to proteins that cause the specific response.
°
In
the de-etiolation response, each activated phytochrome may give rise to
hundreds of molecules of a second messenger, each of which may lead to the
activation of hundreds of molecules of a specific enzyme.
·
Light
causes phytochrome to undergo a conformational change that leads to increases
in levels of the second messengers’ cyclic GMP (cGMP) and Ca2+.
·
Changes
in cGMP levels can lead to ionic changes within the cell by influencing
properties of ion channels.
°
Cyclic
GMP also activates specific protein kinases, enzymes that phosphorylate and
activate other proteins.
°
The
microinjection of cyclic GMP into aurea
tomato cells induces a partial de-etiolation response, even without the
addition of phytochrome.
·
Changes
in cytosolic Ca2+ levels also play an important role in phytochrome
signal transduction.
°
The
concentration of Ca2+ is generally very low in the cytoplasm.
°
Phytochrome
activation can open Ca2+ channels and lead to transient 100-fold
increases in cytosolic Ca2+.
·
Ultimately,
a signal transduction pathway leads to the regulation of one or more cellular
activities.
°
In
most cases, these responses to stimulation involve the increased activity of
certain enzymes.
°
This
occurs through two mechanisms: by stimulating transcription of mRNA for the
enzyme or by activating existing enzyme molecules (post-translational
modification).
·
In
transcriptional regulation, transcription factors bind directly to specific
regions of DNA and control the transcription of specific genes.
°
In
the case of phytochrome-induced de-etiolation, several transcription factors
are activated by phosphorylation, some through the cyclic GMP pathway, while
activation of others requires Ca2+.
°
The
mechanism by which a signal promotes a new developmental course may depend on
the activation of positive transcription factors (proteins that increase transcription of specific
genes) or negative transcription factors (proteins that decrease transcription).
·
During
post-translational modifications of proteins, the activities of existing
proteins are modified.
°
In
most cases, these modifications involve phosphorylation, the addition of a
phosphate group onto the protein by a protein kinase.
°
Many
second messengers, such as cyclic GMP, and some receptors, including some
phytochromes, activate protein kinases directly.
°
One
protein kinase can phosphorylate other protein kinases, creating a kinase
cascade, finally leading to phosphorylation of transcription factors and
impacting gene expression.
§
Thus,
they regulate the synthesis of new proteins, usually by turning specific genes
on and off.
·
Signal
pathways must also have a means for turning off once the initial signal is no
longer present.
°
Protein
phosphatases, enzymes that dephosphorylate specific proteins, are involved in
these “switch off” processes.
°
At
any given moment, the activities of a cell depend on the balance of activity of
many types of protein kinases and protein phosphatases.
·
During
the de-etiolation response, a variety of proteins are either synthesized or
activated.
°
These
include enzymes that function in photosynthesis directly or that supply the
chemical precursors for chlorophyll production.
°
Others
affect the levels of plant hormones that regulate growth.
§
For
example, the levels of two hormones (auxin and brassinosteroids) that enhance
stem elongation will decrease following phytochrome activation—hence, the
reduction in stem elongation that accompanies de-etiolation.
Concept 39.2 Plant hormones help coordinate growth, development, and
responses to stimuli
·
The
word hormone is derived from a Greek
verb meaning “to excite.”
·
Found
in all multicellular organisms, hormones
are chemical signals that are produced in one part of the body, transported to
other parts, bind to specific receptors, and trigger responses in target cells
and tissues.
°
Only
minute quantities of hormones are necessary to induce substantial change in an
organism.
°
Hormone
concentration or rate of transport can change in response to environmental
stimuli.
°
Often
the response of a plant is governed by the interaction of two or more hormones.
Research on how plants grow toward light led
to the discovery of plant hormones.
·
The
concept of chemical messengers in plants emerged from a series of classic
experiments on how stems respond to light.
°
Plants
grow toward light, and if you rotate a plant, it will reorient its growth until
its leaves again face the light.
°
Any
growth response that results in curvature of whole plant organs toward or away
from stimuli is called a tropism.
°
The
growth of a shoot toward light is called positive phototropism; growth away from light is negative phototropism.
·
Much
of what is known about phototropism has been learned from studies of grass
seedlings, particularly oats.
°
The
shoot of a grass seedling is enclosed in a sheath called the coleoptile, which
grows straight upward if kept in the dark or illuminated uniformly from all
sides.
°
If
it is illuminated from one side, it will curve toward the light as a result of
differential growth of cells on opposite sides of the coleoptile.
§
The
cells on the darker side elongate faster than the cells on the brighter side.
·
In
the late 19th century, Charles Darwin and his son Francis observed that a grass
seedling bent toward light only if the tip of the coleoptile was present.
°
This
response stopped if the tip was removed or covered with an opaque cap (but not
a transparent cap).
°
While
the tip was responsible for sensing light, the actual growth response occurred
some distance below the tip, leading the
·
Later,
Peter Boysen-Jensen demonstrated that the signal was a mobile chemical
substance.
°
He
separated the tip from the remainder of the coleoptile by a block of gelatin,
preventing cellular contact, but allowing chemicals to pass.
§
These
seedlings were phototropic.
°
However,
if the tip was segregated from the lower coleoptile by an impermeable barrier,
no phototropic response occurred.
·
In
1926, Frits Went extracted the chemical messenger for phototropism, naming it
auxin.
·
Modifying
the Boysen-Jensen experiment, he placed excised tips on agar blocks, collecting
the hormone.
°
If
an agar block with this substance was centered on a coleoptile without a tip,
the plant grew straight upward.
°
If
the block was placed on one side, the plant began to bend away from the agar
block.
·
The
classical hypothesis for what causes grass coleoptiles to grow toward light,
based on the previous research, is that an asymmetrical distribution of auxin
moving down from the coleoptile tip causes cells on the dark side to elongate
faster than cells on the brighter side.
°
However,
studies of phototropism by organs other than grass coleoptiles provide less
support for this idea.
°
There
is, however, an asymmetrical
distribution of certain substances that may act as growth inhibitors, with these substances more concentrated on the lighted
side of a stem.
Plant hormones help coordinate growth,
development, and responses to environmental stimuli.
·
In
general, plant hormones control plant growth and development by affecting the
division, elongation, and differentiation of cells.
°
Some
hormones also mediate shorter-term physiological responses of plants to
environmental stimuli.
°
Each
hormone has multiple effects, depending on its site of action, its
concentration, and the developmental stage of the plant.
·
Some
of the major classes of plant hormones include auxin, cytokinins, gibberellins,
brassinosteroids, abscisic acid, and ethylene.
°
Many
molecules that function in plant defenses against pathogens are probably plant
hormones as well.
°
Plant
hormones tend to be relatively small molecules that are transported from cell
to cell across cell walls, a pathway that blocks the movement of large
molecules.
·
Plant
hormones are produced at very low concentrations.
°
Signal
transduction pathways amplify the hormonal signal many-fold and connect it to a
cell’s specific responses.
°
These
include altering the expression of genes, affecting the activity of existing
enzymes, or changing the properties of membranes.
·
Response
to a hormone usually depends not so much on its absolute concentration as on
its relative concentration compared to other hormones.
°
It
is hormonal balance, rather than hormones acting in isolation, that control
growth and development of the plants.
·
The
term auxin is used for any chemical
substance that promotes the elongation of coleoptiles, although auxins actually
have multiple functions in both monocots and dicots.
°
The
natural auxin occurring in plants is indoleacetic acid, or IAA.
·
In
growing shoots, auxin is transported unidirectionally, from the shoot apex down
to the base.
°
The
speed at which auxin is transported down the stem from the shoot apex is about
10 mm/hr, a rate that is too fast for diffusion, but slower than translocation
in the phloem.
°
Auxin
seems to be transported directly through parenchyma tissue, from one cell to
the next.
°
This
unidirectional transport of auxin is called polar transport, and has nothing to
do with gravity.
§
Auxin
travels upward if a stem or coleoptile is placed upside down.
°
The
polarity of auxin transport is due to the polar distribution of auxin transport
protein in the cells.
°
Concentrated
at the basal end of the cells, auxin transporters move the hormone out of the
cell and into the apical end of the neighboring cell.
·
Although
auxin affects several aspects of plant development, one of its chief functions
is to stimulate the elongation of cells in young shoots.
°
The
apical meristem of a shoot is a major site of auxin synthesis.
°
As
auxin moves from the apex down to the region of cell elongation, the hormone
stimulates cell growth, binding to a receptor in the plasma membrane.
°
Auxin
stimulates cell growth only over a certain concentration range, from about 10−8
to 10−4 M.
°
At
higher concentrations, auxins may inhibit cell elongation, probably by inducing
production of ethylene, a hormone that generally acts as an inhibitor of
elongation.
·
According
to the acid growth hypothesis, in a shoot’s region of elongation, auxin
stimulates plasma membrane proton pumps, increasing the voltage across the
membrane and lowering the pH in the cell wall.
°
Lowering
the pH activates expansin enzymes
that break the cross-links between cellulose microfibrils and other cell wall
constituents, loosening the wall.
°
Increasing
the membrane potential enhances ion uptake into the cell, which causes the
osmotic uptake of water.
°
Uptake
of water increases turgor and elongates the loose-walled cell.
·
Auxin
also alters gene expression rapidly, causing cells in the region of elongation
to produce new proteins within minutes.
°
Some
of these proteins are short-lived transcription factors that repress or
activate the expression of other genes.
°
Auxin
stimulates a sustained growth response of making the additional cytoplasm and
wall material required by elongation.
·
Auxins
are used commercially in the vegetative propagation of plants by cuttings.
°
Treating
a detached leaf or stem with rooting powder containing auxin often causes
adventitious roots to form near the cut surface.
°
Auxin
is also involved in the branching of roots.
§
One
Arabidopsis mutant that exhibits
extreme proliferation of lateral roots has an auxin concentration 17-fold
higher than normal.
·
Synthetic
auxins, such as 2,4-dinitrophenol (2,4-D), are widely used as selective
herbicides.
°
Monocots,
such as maize or turfgrass, can rapidly inactivate these synthetic auxins.
°
However,
dicots cannot and die from a hormonal overdose.
§
Spraying
cereal fields or turf with 2,4-D eliminates dicot (broadleaf) weeds such as
dandelions.
·
Auxin
also affects secondary growth by inducing cell division in the vascular cambium
and by influencing the growth of secondary xylem.
·
Developing
seeds synthesize auxin, which promotes the growth of fruit.
°
Synthetic
auxins sprayed on tomato vines induce development of seedless tomatoes because
the synthetic auxins substitute for the auxin normally synthesized by the
developing seeds.
·
Cytokinins stimulate cytokinesis, or
cell division.
°
They
were originally discovered in the 1940s by Johannes van Overbeek, who found
that he could stimulate the growth of plant embryos by adding coconut milk to
his culture medium.
°
A
decade later, Folke Skoog and Carlos O. Miller induced cultured tobacco cells
to divide by adding degraded samples of DNA.
°
The
active ingredients in both were modified forms of adenine, one of the
components of nucleic acids.
°
These
growth regulators were named cytokinins because they stimulate cytokinesis.
·
The
most common naturally occurring cytokinin is zeatin, named from the maize (Zea mays) in which it was found.
·
Much
remains to be learned about cytokinin synthesis and signal transduction.
·
Cytokinins
are produced in actively growing tissues, particularly in roots, embryos, and
fruits.
°
Cytokinins
produced in the root reach their target tissues by moving up the plant in the
xylem sap.
·
Cytokinins
interact with auxins to stimulate cell division and differentiation.
°
In
the absence of cytokinins, a piece of parenchyma tissue grows large, but the
cells do not divide.
°
In
the presence of cytokinins and auxins, the cells divide, while cytokinins alone
have no effect.
§
If
the ratio of cytokinins and auxins is at a specific level, then the mass of
growing cells, called a callus, remains undifferentiated.
§
If
cytokinin levels are raised, shoot buds form from the callus.
§
If
auxin levels are raised, roots form.
·
Cytokinins,
auxins, and other factors interact in the control of apical dominance, the
ability of the terminal bud to suppress the development of axillary buds.
°
Until
recently, the leading hypothesis for the role of hormones in apical
dominance—the direct inhibition hypothesis—proposed that auxin and cytokinin
act antagonistically in regulating axillary bud growth.
°
Auxin
levels would inhibit axillary bud growth, while cytokinins would stimulate
growth.
·
Many
observations are consistent with the direct inhibition hypothesis.
°
If
the terminal bud, the primary source of auxin, is removed, the inhibition of
axillary buds is removed and the plant becomes bushier.
§
This
can be inhibited by adding auxins to the cut surface.
·
The
direct inhibition hypothesis predicts that removing the primary source of auxin
should lead to a decrease in auxin levels in the axillary buds.
·
However,
experimental removal of the terminal shoot (decapitation) has not demonstrated
this.
°
In
fact, auxin levels actually increase
in the axillary buds of decapitated plants.
°
Further
research is necessary to uncover all pieces of this puzzle.
·
Cytokinins
retard the aging of some plant organs.
°
They
inhibit protein breakdown by stimulating RNA and protein synthesis and by
mobilizing nutrients from surrounding tissues.
°
Leaves
removed from a plant and dipped in a cytokinin solution stay green much longer
than otherwise.
°
Cytokinins
also slow deterioration of leaves on intact plants.
°
Florists
use cytokinin sprays to keep cut flowers fresh.
·
A
century ago, farmers in
°
In
1926, E. Kurosawa discovered that a fungus in the genus Gibberella causes this “foolish seedling disease.”
°
The
fungus induced hyperelongation of rice stems by secreting a chemical, given the
name gibberellin.
·
In
the 1950s, researchers discovered that plants also make gibberellins.
Researchers have identified more than 100 different natural gibberellins.
°
Typically
each plant produces a much smaller number.
°
Foolish
rice seedlings, it seems, suffer from an overdose of growth regulators normally
found in lower concentrations.
·
Roots
and leaves are major sites of gibberellin production.
°
Gibberellins
stimulate growth in both leaves and stems but have little effect on root
growth.
°
In
stems, gibberellins stimulate cell elongation and cell division.
°
One
hypothesis proposes that gibberellins stimulate cell wall–loosening enzymes
that facilitate the penetration of expansin proteins into the cell well.
°
Thus,
in a growing stem, auxin, by acidifying the cell wall and activating expansins,
and gibberellins, by facilitating the penetration of expansins, act in concert
to promote elongation.
·
The
effects of gibberellins in enhancing stem elongation are evident when certain
dwarf varieties of plants are treated with gibberellins.
°
After
treatment with gibberellins, dwarf pea plants grow to normal height.
°
However,
if gibberellins are applied to normal plants, there is often no response,
perhaps because these plants are already producing the optimal dose of the
hormone.
·
The
most dramatic example of gibberellin-induced stem elongation is bolting, the
rapid formation of the floral stalk.
°
In
their vegetative state, some plants develop in a rosette form with a body low
to the ground with short internodes.
°
As
the plant switches to reproductive growth, a surge of gibberellins induces
internodes to elongate rapidly, which elevates the floral buds that develop at
the tips of the stems.
·
In
many plants, both auxin and gibberellins must be present for fruit to set.
°
Spraying
of gibberellin during fruit development is used to make the individual grapes
grow larger and to make the internodes of the grape bunch elongate.
§
This
enhances air circulation between the grapes and makes it harder for yeast and
other microorganisms to infect the fruits.
·
The
embryo of a seed is a rich source of gibberellins.
°
After
hydration of the seed, the release of gibberellins from the embryo signals the
seed to break dormancy and germinate.
°
Some
seeds that require special environmental conditions to germinate, such as
exposure to light or cold temperatures, will break dormancy if they are treated
with gibberellins.
°
Gibberellins
support the growth of cereal seedlings by stimulating the synthesis of
digestive enzymes that mobilize stored nutrients.
·
First
isolated from Brassica pollen in
1979, brassinosteroids are steroids
chemically similar to cholesterol and the sex hormones of animals.
°
Brassinosteroids
induce cell elongation and division in stem segments and seedlings at
concentrations as low as 10−12 M.
°
They
also retard leaf abscission and promote xylem differentiation.
°
Their
effects are so qualitatively similar to those of auxin that it took several
years for plant physiologists to accept brassinosteroids as nonauxin hormones.
·
Joann
Chory and her colleagues provided evidence from molecular biology that
brassinosteroids were plant hormones.
°
An
Arabidopsis mutant that has
morphological features similar to light-grown plants even when grown in the
dark lacks brassinosteroids.
°
This
mutation affects a gene that normally codes for an enzyme similar to one
involved in steroid synthesis in mammalian cells.
·
Abscisic acid (
°
Ironically,
°
°
Often
°
It
is the ratio of
·
One
major affect of
°
The
levels of
°
Seed
dormancy has great survival value because it ensures that the seed will
germinate only when there are optimal conditions of light, temperature, and
moisture.
·
Many
types of dormant seeds will germinate when
°
For
example, the seeds of some desert plants break dormancy only when heavy rains wash
°
Other
seeds require light or prolonged exposure to cold to trigger the inactivation
of
°
A
maize mutant that has seeds that germinate while still on the cob lacks a
functional transcription factor required for
·
°
When
a plant begins to wilt,
°
°
The
accompanying osmotic loss of water leads to a reduction in guard cell turgor,
and the stomata close.
°
In
some cases, water shortages in the root system can lead to the transport of
°
Mutants
that are prone to wilting are often deficient in
·
In
1901, Dimitry Neljubow demonstrated that the gas ethylene was the active factor that caused leaves to drop from
trees that were near leaking gas mains.
°
Plants
produce ethylene in response to stresses such as drought, flooding, mechanical
pressure, injury, and infection.
°
Ethylene
production also occurs during fruit ripening and during programmed cell death.
°
Ethylene
is also produced in response to high concentrations of externally applied
auxins.
·
Ethylene
instigates a seedling to perform a growth maneuver called the triple response that enables a seedling
to circumvent an obstacle as it grows through soil.
·
Ethylene
production is induced by mechanical stress on the stem tip.
·
In
the triple response, stem elongation slows, the stem thickens, and curvature
causes the stem to start growing horizontally.
·
As
the stem continues to grow horizontally, its tip touches upward intermittently.
°
If
the probes continue to detect a solid object above, then another pulse of
ethylene is generated, and the stem continues its horizontal progress.
°
If
upward probes detect no solid object, then ethylene production decreases, and
the stem resumes its normal upward growth.
·
It
is ethylene, not the physical obstruction per
se, that induces the stem to grow horizontally.
°
Normal
seedlings growing free of all physical impediments will undergo the triple
response if ethylene is applied.
·
Arabidopsis mutants with abnormal
triple responses have been used to investigate the signal transduction pathways
leading to this response.
°
Ethylene-insensitive
(ein) mutants fail to undergo the
triple response after exposure to ethylene.
§
Some
lack a functional ethylene receptor.
·
Other
mutants undergo the triple response in the absence of physical obstacles.
°
Some
mutants (eto) produce ethylene at 20
times the normal rate.
°
Other
mutants, called constitutive triple-response (ctr) mutants, undergo the triple response in air but do not respond
to inhibitors of ethylene synthesis.
§
Ethylene
signal transduction is permanently turned on even though there is no ethylene
present.
·
The
various ethylene signal-transduction mutants can be distinguished by their
different responses to experimental treatments.
·
The
affected gene in ctr mutants codes
for a protein kinase.
°
Because
this mutation activates the ethylene
response, this suggests that the normal kinase product of the wild-type allele
is a negative regulator of ethylene
signal transduction.
°
One
hypothesis proposes that binding of the hormone ethylene to a receptor leads to
inactivation of the kinase and inactivation of this negative regulator allows
synthesis of the proteins required for the triple response.
·
The
cells, organs, and plants that are genetically programmed to die on a
particular schedule do not simply shut down their cellular machinery and await
death.
°
Rather,
during programmed cell death, called apoptosis,
there is active expression of new genes, which produce enzymes that break down
many chemical components, including chlorophyll, DNA, RNA, proteins, and
membrane lipids.
°
A
burst of ethylene productions is associated with apoptosis whether it occurs
during the shedding of leaves in autumn, the death of an annual plant after
flowering, or as the final step in the differentiation of a xylem vessel
element.
·
The
loss of leaves each autumn is an adaptation that keeps deciduous trees from
desiccating during winter when roots cannot absorb water from the frozen
ground.
°
Before
leaves abscise, many essential elements are salvaged from the dying leaves and
stored in stem parenchyma cells.
°
These
nutrients are recycled back to developing leaves the following spring.
·
When
an autumn leaf falls, the breaking point is an abscission layer near the base
of the petiole.
°
The
parenchyma cells here have very thin walls, and there are no fiber cells around
the vascular tissue.
°
The
abscission layer is further weakened when enzymes hydrolyze polysaccharides in
the cell walls.
°
The
weight of the leaf, with the help of the wind, causes a separation within the
abscission layer.
·
A
change in the balance of ethylene and auxin controls abscission.
°
An
aged leaf produces less and less auxin, and this makes the cells of the
abscission layer more sensitive to ethylene.
°
As
the influence of ethylene prevails, the cells in the abscission layer produce
enzymes that digest the cellulose and other components of cell walls.
·
The
consumption of ripe fruits by animals helps disperse the seeds of flowering
plants.
°
Immature
fruits are tart, hard, and green but become edible at the time of seed
maturation, triggered by a burst of ethylene production.
°
Enzymatic
breakdown of cell wall components softens the fruit, and conversion of starches
and acids to sugars makes the fruit sweet.
°
The
production of new scents and colors helps advertise fruits’ ripeness to
animals, which eat the fruits and disperse the seeds.
·
A
chain reaction occurs during ripening: ethylene triggers ripening and ripening,
in turn, triggers even more ethylene production—a rare example of positive
feedback on physiology.
°
Because
ethylene is a gas, the signal to ripen even spreads from fruit to fruit.
°
Fruits
can be ripened quickly by storing the fruit in a plastic bag, accumulating
ethylene gas, or by enhancing ethylene levels in commercial production.
°
Alternatively,
to prevent premature ripening, apples are stored in bins flushed with carbon
dioxide, which prevents ethylene from accumulating and inhibits the synthesis
of new ethylene.
·
Genetic
engineering of ethylene signal transduction pathways has potentially important
commercial applications after harvest.
°
For
example, molecular biologists have blocked the transcription of one of the genes
required for ethylene synthesis in tomato plants.
°
These
tomato fruits are picked while green and are induced to ripen on demand when
ethylene gas is added.
·
Plant
responses often involve interactions of many hormones and their signal
transduction pathways.
°
The
study of hormone interactions can be a complex problem.
°
For
example, flooding of deepwater rice leads to a 50-fold increase in internal
ethylene and a rapid increase in stem elongation.
§
Flooding
also leads to an increase in sensitivity to GA that is mediated by a decrease
in
§
Thus,
stem elongation is the result of interaction among three hormones and their
signal transduction chains.
°
Imagine
that you are a molecular biologist assigned the task of genetically engineering
a rice plant that will grow faster when submerged.
§
What
is the best molecular target for genetic manipulation? Is it an enzyme that
inactivates
°
Many
plant biologists are promoting a systems-based approach.
§
Using
genomic techniques, biologists can identify all the genes in a plant.
§
Two
plants are already sequenced: Arabidopsis
and the rice plant Oryza sativa.
§
Using
microassay and proteomic techniques, scientists can determine which genes are
inactivated or activated in response to an environmental change.
°
New
hypotheses and approaches will emerge from analysis of these comprehensive data
sets.
Concept 39.3 Responses to light are critical for plant success
·
Light
is an especially important factor in the lives of plants.
°
In
addition to being required for photosynthesis, light also cues many key events
in plant growth and development.
°
These
effects of light on plant morphology are what plant biologists call photomorphogenesis.
°
Light
reception is also important in allowing plants to measure the passage of days
and seasons.
·
Plants
detect the presence, direction, intensity, and wavelength of light.
°
For
example, the measure of the action
spectrum of photosynthesis has two peaks, one in the red and one in the
blue.
§
These
match the absorption peaks of chlorophyll.
·
Action
spectra can be useful in the study of any
process that depends on light.
°
A
close correspondence between an action spectrum of a plant response and the
absorption spectrum of a purified pigment suggests that the pigment may be the
photoreceptor involved in mediating the response.
·
Action
spectra reveal that red and blue light are the most important colors regulating
a plant’s photomorphogenesis.
°
These
observations led researchers to two major classes of light receptors: a
heterogeneous group of blue-light
photoreceptors and a family of photoreceptors called phytochromes that absorb mostly red light.
Blue-light photoreceptors are a heterogeneous
group of pigments.
·
The
action spectra of many plant processes demonstrate that blue light is effective
in initiating diverse responses.
·
The
biochemical identity of the blue-light photoreceptor was so elusive that they
were called cryptochromes.
°
In
the 1990s, molecular biologists analyzing Arabidopsis
mutants found three completely different types of pigments that detect blue
light.
§
These
are cryptochromes (for the inhibition
of hypocotyl elongation), phototropin
(for phototropism), and a carotenoid-based photoreceptor called zeaxanthin (for stomatal opening).
Phytochromes function as photoreceptors in
many plant responses to light.
·
Phytochromes
were discovered from studies of seed germination.
°
Because
of their limited food resources, successful sprouting of many types of small
seeds, such as lettuce, requires that they germinate only when conditions,
especially light conditions, are near optimal.
°
Such
seeds often remain dormant for many years until light conditions change.
§
For
example, the death of a shading tree or the plowing of a field may create a
favorable light environment.
·
In
the 1930s, scientists at the U.S. Department of Agriculture determined the
action spectrum for light-induced germination of lettuce seeds.
°
They
exposed water-swollen seeds to a few minutes of monochromatic light of various
wavelengths and stored them in the dark for two days and recorded the number of
seeds that had germinated under each light regimen.
°
While
red light (660 nm) increased germination, far-red light (730 nm) inhibited it and the response depended
on the last flash of light.
·
The
photoreceptor responsible for these opposing effects of red and far-red light
is a phytochrome.
°
It
consists of a protein covalently bonded to a nonprotein part that functions as
a chromophore, the light-absorbing part of the molecule.
°
The
chromophore is photoreversible and reverts back and forth between two isomeric
forms with one (Pr) absorbing red light and becoming (Pfr),
and the other (Pfr) absorbing far-red light and becoming (Pr).
·
This
interconversion between isomers acts as a switching mechanism that controls
various light-induced events in the life of the plant.
°
The
Pfr form triggers many of the plant’s developmental responses to
light.
°
Exposure
to far-red light inhibits the germination response.
·
Plants
synthesize phytochrome as Pr, and if seeds are kept in the dark, the
pigment remains almost entirely in the Pr form.
°
If
the seeds are illuminated with sunlight, the phytochrome is exposed to red
light (along with other wavelengths), and much of the Pr is
converted to Pfr, triggering germination.
·
The
phytochrome system also provides plants with information about the quality of light.
°
During
the day, with the mix of both red and far-red radiation, the Pr <=>Pfr
photoreversion reaches a dynamic equilibrium.
°
Plants
can use the ratio of these two forms to monitor and adapt to changes in light
conditions.
·
For
example, changes in this equilibrium might be used by a tree that requires high
light intensity as a way to assess appropriate growth strategies.
°
If
other trees shade this tree, its phytochrome ratio will shift in favor of Pr
because the canopy screens out more red light than far-red light.
°
The
tree could use this information to indicate that it should allocate resources
to growing taller.
°
If
the target tree is in direct sunlight, then the proportion of Pfr
will increase, which stimulates branching and inhibits vertical growth.
Biological clocks control circadian rhythms in
plants and other eukaryotes.
·
Many
plant processes, such as transpiration and synthesis of certain enzymes,
oscillate during the day.
°
This
is often in response to changes in light levels, temperature, and relative
humidity that accompany the 24-hour cycle of day and night.
°
Even
under constant conditions in a growth chamber, many physiological processes in
plants, such as opening and closing of stomata and the production of
photosynthetic enzymes, continue to oscillate with a frequency of about 24
hours.
·
For
example, many legumes lower their leaves in the evening and raise them in the
morning.
°
These
movements continue even if plants are kept in constant light or constant
darkness.
°
Such
physiological cycles with a frequency of about 24 hours that are not directly
paced by any known environmental variable are called circadian rhythms.
°
These
rhythms are ubiquitous features of eukaryotic life.
·
Because
organisms continue their rhythms even when placed in the deepest mine shafts or
when orbited in satellites, they do not appear to be triggered by some subtle
but pervasive environmental signal.
°
All
research thus far indicates that the oscillator for circadian rhythms is
endogenous (internal).
°
This
internal clock, however, is entrained (set) to a period of precisely 24 hours
by daily signals from the environment.
·
If
an organism is kept in a constant environment, its circadian rhythms deviate
from a 24-hour period to free-running periods ranging from 21 to 27 hours.
°
Deviations
of the free-running period from 24 hours does not mean that the biological
clocks drift erratically, but that they are not synchronized with the outside
world.
·
In
considering biological clocks, we need to distinguish between the oscillator
(clock) and the rhythmic processes it controls.
°
For
example, if we were to restrain the leaves of a bean plant so they cannot move,
they will rush to the appropriate position for that time of day when we release
them.
°
We
can interfere with a biological rhythm, but the clockwork goes right on ticking
off the time.
·
A
leading hypothesis for the molecular mechanisms underlying biological
timekeeping is that it depends on synthesis of a protein that regulates its own
production through feedback control.
°
This
protein may be a transcription factor that inhibits transcription of the gene
that encodes for the transcription factor itself.
°
The
concentration of this transcription factor may accumulate during the first half
of the circadian cycle and decline during the second half due to
self-inhibition of its own production.
·
Researchers
have recently used a novel technique to identify clock mutants in Arabidopsis.
°
Molecular
biologists spliced the gene for luciferase to the promoter of certain
photosynthesis-related genes that show circadian rhythms in transcription.
§
Luciferase
is the enzyme responsible for bioluminescence in fireflies.
°
When
the biological clock turned on the promoter of the photosynthesis genes in Arabidopsis, it also stimulated
production of luciferase, and the plant glowed.
§
This
enabled researchers to screen plants for clock mutations, several of which are
defects in proteins that normally bind photoreceptors.
°
The
altered genes in some of these mutants affect proteins that normally bind
photoreceptors.
Light entrains the biological clock.
·
Because
the free running period of many circadian rhythms is greater than or less than
the 24-hour daily cycle, they eventually become desynchronized with the natural
environment when denied environmental cues.
°
Humans
experience this type of desynchronization when we cross several times zones in
an airplane, leading to the phenomenon we call jet lag.
°
Eventually,
our circadian rhythms become resynchronized with the external environment.
°
Plants
are also capable of reestablishing (entraining) their circadian
synchronization.
·
Both
phytochrome and blue-light photoreceptors can entrain circadian rhythms of
plants.
°
The
phytochrome system involves turning cellular responses off and on by means of
the Pr <=> Pfr switch.
°
In
darkness, the phytochrome ratio shifts gradually in favor of the Pr
form, in part from synthesis of new Pr molecules and, in some
species, by slow biochemical conversion of Pfr to Pr.
°
When
the sun rises, the Pfr level suddenly increases by rapid
photoconversion of Pr.
°
This
sudden increase in Pfr each day at dawn resets the biological clock.
Photoperiodism synchronizes many plant
responses to changes of season.
·
The
appropriate appearance of seasonal events is of critical importance in the life
cycles of most plants.
°
These
seasonal events include seed germination, flowering, and the onset and breaking
of bud dormancy.
°
The
environmental stimulus that plants use most often to detect the time of year is
the photoperiod, the relative lengths of night and day.
°
A
physiological response to photoperiod, such as flowering, is called photoperiodism.
·
One
of the earliest clues to how plants detect the progress of the seasons came
from a mutant variety of tobacco studied by W. W. Garner and H. A. Allard in
1920.
°
This
variety, Maryland Mammoth, does not flower in summer as normal tobacco plants
do, but in winter.
°
In
light-regulated chambers, they discovered that this variety would flower only
if the day length was 14 hours or shorter, which explained why it would not
flower during the longer days of the summer.
·
Garner
and Allard termed the Maryland Mammoth a short-day
plant, because it required a light period shorter than a critical length to flower.
°
Other
examples include chrysanthemums, poinsettias, and some soybean varieties.
·
Long-day plants will only flower when the
light period is longer than a
critical number of hours.
°
Examples
include spinach, iris, and many cereals.
·
Day-neutral plants will flower when they
reach a certain stage of maturity, regardless of day length.
°
Examples
include tomatoes, rice, and dandelions.
·
In
the 1940s, researchers discovered that it is actually night length, not day
length, that controls flowering and other responses to photoperiod.
°
Research
demonstrated that the cocklebur, a short-day plant, would flower if the daytime
period was broken by brief exposures to darkness, but not if the nighttime
period was broken by a few minutes of dim light.
·
Short-day
plants are actually long-night plants, requiring a minimum length of
uninterrupted darkness.
°
Cocklebur
is actually unresponsive to day
length, but it requires at least 8 hours of continuous
darkness to flower.
·
Similarly,
long-day plans are actually short-night plants.
°
A
long-day plant grown on photoperiods of long nights that would not normally
induce flowering will flower if the period of continuous darkness is
interrupted by a few minutes of light.
·
Long-day
and short-day plants are distinguished not
by an absolute night length but by whether the critical night lengths sets a
maximum (long-day plants) or minimum (short-day plants) number of hours of
darkness required for flowering.
°
In
both cases, the actual number of hours in the critical night length is specific
to each species of plant.
°
While
the critical factor is night length, the terms “long-day” and “short-day” are
embedded firmly in the jargon of plant physiology.
·
Red
light is the most effective color in interrupting the nighttime portion of the
photoperiod.
·
Action
spectra and photoreversibility experiments show that phytochrome is the active
pigment.
·
If
a flash of red light during the dark period is followed immediately by a flash
of far-red light, then the plant detects no interruption of night length,
demonstrating red/far-red photoreversibility.
·
Plants
measure night length very accurately.
°
Some
short-day plants will not flower if night is even one minute shorter than the
critical length.
°
Some
plants species always flower on the same day each year.
·
Humans
can exploit the photoperiodic control of flowering to produce flowers “out of
season.”
°
By
punctuating each long night with a flash of light, the floriculture industry
can induce chrysanthemums, normally a short-day plant that blooms in fall, to
delay their blooming until Mother’s Day in May.
§
The
plants interpret this as not one long night, but two short nights.
·
While
some plants require only a single exposure to the appropriate photoperiod to
begin flowering, others require several successive days of the appropriate
photoperiod.
·
Other
plants respond to photoperiod only if pretreated by another environmental
stimulus.
°
For
example, winter wheat will not flower unless it has been exposed to several
weeks of temperatures below 10oC (called vernalization) before exposure to the appropriate photoperiod.
·
While
buds produce flowers, it is leaves that detect photoperiod and trigger
flowering.
°
If
even a single leaf receives the appropriate photoperiod, all buds on a plant
can be induced to flower, even if they have not experienced this signal.
°
Plants
lacking leaves will not flower, even if exposed to the appropriate photoperiod.
°
The
flowering signal, not yet chemically identified, is called florigen, and it may be a hormone or some change in the relative
concentrations of two or more hormones.
·
Whatever
combination of environmental cues (such as photoperiod or vernalization) and
internal signals (such as hormones) is necessary for flowering to occur, the
outcome is the transition of a bud’s meristem from a vegetative state to a
flowering state.
°
This
requires that meristem-identity genes that induce the bud to form a flower must
be switched on.
°
Then
organ-identity genes that specify the spatial organization of floral
organs—sepals, petals, stamens, and carpels—are activated in the appropriate
regions of the meristem.
°
Identification
of the signal transduction pathways that link external cues to the gene changes
required for flowering are active areas of research.
Concept 39.4 Plants respond to a wide variety of stimuli other than
light
·
Because
of their immobility, plants must adjust to a wide range of environmental
circumstances through developmental and physiological mechanisms.
°
While
light is one important environmental cue, other environmental stimuli also
influence plant development and physiology.
Plants respond to environmental stimuli
through a combination of developmental and physiological mechanisms.
·
Both
the roots and shoots of plants respond to gravity, or gravitropism, although in diametrically different ways.
°
Roots
demonstrate positive gravitropism, and shoots exhibit negative gravitropism.
°
Gravitropism
ensures that the root grows in the soil and that the shoot reaches sunlight
regardless of how a seed happens to be oriented when it lands.
°
Auxin
plays a major role in gravitropic responses.
·
Plants
may tell up from down by the settling of statoliths,
specialized plastids containing dense starch grains, to the lower portions of
cells.
°
In
one hypothesis, the aggregation of statoliths at low points in cells of the
root cap triggers the redistribution of calcium, which in turn causes lateral
transport of auxin within the root.
°
The
high concentrations of auxin on the lower side of the zone of elongation
inhibits cell elongation, slowing growth on that side and curving the root
downward.
·
Experiments
with Arabidopsis and tobacco mutants
have demonstrated the importance of “falling statoliths” in root gravitropism,
but these have also indicated that other factors or organelles may be involved.
°
Mutants
lacking statoliths have a slower response than wild-type plants.
°
One
possibility is that the entire cell helps the root sense gravity by
mechanically pulling on proteins that tether the protoplast to the cell wall,
stretching proteins on the “up” side and compressing proteins on the “down
side.”
°
Other
dense organelles may also contribute to gravitropism by distorting the
cytoskeleton.
·
Plants
can change form in response to mechanical perturbations.
°
Such
thigmomorphogenesis may be seen when
comparing a short, stocky tree growing on a windy mountain ridge with a taller,
more slender member of the same species growing in a more sheltered location.
°
Because
plants are very sensitive to mechanical stress, researchers have found that
even measuring the length of a leaf with a ruler alters its subsequent growth.
·
Rubbing
the stems of young plants a few times results in plants that are shorter than
controls.
°
Mechanical
stimulation activates a signal transduction pathway that increases cytoplasmic
calcium, which mediates the activity of specific genes, including some that
encode for proteins that affect cell wall properties.
·
Some
plant species have become, over the course of their evolution, “touch
specialists.”
°
For
example, most vines and other climbing plants have tendrils that grow straight
until they touch something.
°
Contact
stimulates a coiling response, thigmotropism,
caused by differential growth of cells on opposite sides of the tendril.
°
This
allows a vine to take advantage of whatever mechanical support it comes across
as it climbs upward toward a forest canopy.
·
Some
touch specialists undergo rapid leaf movements in response to mechanical
stimulation.
°
For
example, when the compound leaf of a Mimosa
plant is touched, it collapses and leaflets fold together.
°
This
occurs when pulvini, motor organs at the joints of leaves, become flaccid from
a loss of potassium and subsequent loss of water by osmosis.
°
It
takes about ten minutes for the cells to regain their turgor and restore the
“unstimulated” form of the leaf.
°
The
folding of Mimosa leaves may reduce
surface area in response to strong winds, thus reducing water loss. Collapse of
the leaves exposes thorns on the stem, which may serve to deter herbivory.
·
One
remarkable feature of rapid leaf movement is that signals are transmitted from
leaflet to leaflet via action
potentials.
°
Traveling
at about a centimeter per second through the leaf, these electrical impulses
resemble nervous-system messages in animals, although the action potentials of
plants are thousands of times slower.
°
Action
potentials, which have been discovered in many species of algae and plants, may
be widely used as a form of internal communication.
°
In
the carnivorous Venus flytrap, stimulation of sensory hairs in the trap results
in an action potential that travels to the cells that close the trap.
·
Occasionally,
factors in the environment change severely enough to have an adverse effect on
a plant’s survival, growth, and reproduction.
°
These
environmental stresses can devastate crop yields.
°
In
natural ecosystems, plants that cannot tolerate environmental stress will
either succumb or be outcompeted by other plants, and they will become locally
extinct.
·
Thus,
environmental stresses, both biotic
and abiotic, are important in
determining the geographic range of plants.
·
On
a bright, warm, dry day, a plant may be stressed by a water deficit because it
is losing water by transpiration faster than water can be restored by uptake
from the soil.
°
Prolonged
drought can stress or even kill crops and plants in natural ecosystems.
°
Plants
have control systems that enable them to cope with less extreme water deficits.
·
Much
of the plant’s response to a water deficit helps the plant conserve water by
reducing transpiration.
·
As
the water deficit in a leaf rises, guard cells lose turgor and the stomata
close.
°
A
water deficit also stimulates increased synthesis and release of abscisic acid
in a leaf, which also signals guard cells to close stomata.
°
Because
cell expansion is a turgor-dependent process, a water deficit will inhibit the
growth of young leaves.
°
As
plants wilt, their leaves may roll into a shape that reduces transpiration by
exposing less leaf surface to dry air and wind.
°
These
responses also reduce photosynthesis.
·
Root
growth also responds to water deficit.
°
During
a drought, the soil usually dries from the surface down.
°
This
inhibits the growth of shallow roots, partly because cells cannot maintain the
turgor required for elongation.
°
Deeper
roots surrounded by soil that is still moist continue to grow, and the root
system proliferates in a way that maximizes exposure to soil water.
·
Plants
in flooded soils (or overwatered houseplants) can suffocate because the soil
lacks the air spaces that provide oxygen for cellular respiration in the roots.
·
Some
plants are adapted to very wet habitats.
°
Mangroves,
inhabitants of coastal marshes, produce aerial roots that provide access to
oxygen.
°
Less
specialized plants in waterlogged soils may produce ethylene in the roots,
causing some cortical cells to undergo apoptosis, which creates air tubes that
function as “snorkels.”
·
An
excess of sodium chloride or other salts in the soil threaten plants for two
reasons.
°
First,
by lowering the water potential of the soil, plants can lose water to the
environment rather than absorb it.
°
Second,
sodium and certain other ions are toxic to plants when their concentrations are
relatively high.
°
The
selectively permeable membranes of root cells impede the uptake of most harmful
ions, but this aggravates the problem of acquiring water.
·
Some
plants produce compatible solutes, organic compounds that keep the water
potential of the cell more negative than that of the soil, without the toxic
quantities of salt.
·
Still,
most plants cannot survive salt stress for long.
°
The
exceptions are halophytes, salt-tolerant plants with adaptations such as salt
glands that pump salts out across the leaf epidermis.
·
Excessive
heat can harm and eventually kill a plant by denaturing its enzymes and
damaging its metabolism.
°
Transpiration
helps dissipate excess heat through evaporative cooling, but at the cost of
possibly causing a water deficit in many plants.
°
Closing
stomata to preserve water sacrifices evaporative cooling.
·
Most
plants have a backup response that enables them to survive heat stress.
°
Above
a certain temperature—about 40°C for most plants in temperate regions—plant
cells begin to synthesize relatively large quantities of heat-shock proteins.
°
Some
heat-shock proteins are identical to chaperone proteins, which function in
unstressed cells as temporary scaffolds that help other proteins fold into
their functional shapes.
°
Similarly,
heat-shock proteins may embrace enzymes and other proteins and help prevent
denaturation.
·
One
problem that plants face when the temperature of the environment falls is a
change in the fluidity of cell membranes.
°
When
the temperature becomes too cool, lipids are locked into crystalline structures
and membranes lose their fluidity, which adversely affects solute transport and
the functions of other membrane proteins.
°
One
solution is to alter lipid composition in the membranes, increasing the
proportion of unsaturated fatty acids, which have shapes that keep membranes
fluid at lower temperatures.
§
This
response requires several hours to days, which is one reason rapid chilling is
generally more stressful than gradual seasonal cooling.
·
Freezing
is a more severe version of cold stress.
°
At
subfreezing temperatures, ice forms in the cell walls and intercellular spaces
of most plants.
§
Solutes
in the cytosol depress its freezing point.
°
This
lowers the extracellular water potential, causing water to leave the cytoplasm
and, therefore, causing dehydration.
°
The
resulting increase in the concentration of salt ions in the cytoplasm is also
harmful and can lead to cell death.
·
Plants
native to regions where winters are cold have special adaptations that enable
them to cope with freezing stress.
°
This
may involve an overall resistance to dehydration.
°
In
other cases, the cells of many frost-tolerant species increase their
cytoplasmic levels of specific solutes, such as sugars, which are better
tolerated at high concentrations and which help reduce water loss from the cell
during extracellular freezing.
Concept
39.5 Plants defend themselves against herbivores and pathogens
·
Plants
do not exist in isolation, but interact with many other species in their
communities.
°
Some
of these interspecific interactions—for example, associations with fungi in
mycorrhizae or with insect pollinators—are mutually beneficial.
°
Most
interactions that plants have with other organisms are not beneficial to the
plant.
§
As
primary producers, plants are at the base of most food webs and are subject to
attack by a wide variety of plant-eating (herbivorous) animals.
§
Plants
are also subject to attacks by pathogenic viruses, bacteria, and fungi.
Plants deter herbivores with both physical and
chemical defenses.
·
Herbivory
is a stress that plants face in any ecosystem.
·
Plants
counter excess herbivory with both physical defenses, such as thorns, and
chemical defenses, such as the production of distasteful or toxic compounds.
·
For
example, some plants produce an unusual amino acid, canavanine, which resembles arginine.
°
If
an insect eats a plant containing canavanine, canavanine is incorporated into
the insect’s proteins in place of arginine.
°
Because
canavanine is different enough from arginine to adversely affect the conformation
and, hence, the function of the proteins, the insect dies.
·
Some
plants even recruit predatory animals that help defend the plant against
specific herbivores.
·
For
example, a leaf damaged by caterpillars releases volatile compounds that
attract parasitoid wasps, hastening the destruction of the caterpillars.
°
Parasitoid
wasps inject their eggs into their prey, including herbivorous caterpillars.
°
The
eggs hatch within the caterpillars, and the larvae eat through their organic
containers from the inside out.
·
These
volatile molecules can also function as an “early warning system” for nearby
plants of the same species.
°
Lima
bean plants infested with spider mites release volatile chemicals that signal
“news” of the attack to neighboring, noninfested lima bean plants.
°
The
leaves of the noninfested plant activate defense genes whose expression
patterns are similar to that produced by exposure to jasmonic acid, an important plant defense molecule.
§
As
a result, noninfested neighbors become less susceptible to spider mites and
more attractive to mites that prey on spider mites.
Plants use multiple lines of defense against
pathogens.
·
A
plant’s first line of defense against infection is the physical barrier of the
plant’s “skin,” the epidermis of the primary plant body and the periderm of the
secondary plant body.
°
However,
viruses, bacteria, and the spores and hyphae of fungi can enter the plant
through injuries or through natural openings in the epidermis, such as stomata.
°
Once
a pathogen invades, the plant mounts a chemical attack as a second line of
defense that kills the pathogens and prevents their spread from the site of
infection.
·
Plants
are generally resistant to most pathogens.
°
Plants
have an innate ability to recognize invading pathogens and to mount successful
defenses.
°
In
a converse manner, successful pathogens cause disease because they are able to
evade recognition or suppress host defense mechanisms.
°
Those
few pathogens against which a plant has little specific defense are said to be
virulent.
°
Avirulent pathogens gain enough
access to their host to perpetuate themselves without severely damaging or
killing the plant.
°
Specific
resistance to a plant disease is based on what is called gene-for-gene recognition.
§
This
involves recognition of pathogen-derived molecules by the protein products of
specific plant disease resistance (R)
genes.
°
There
are many pathogens, and plants have many R
genes.
°
An
R protein usually recognizes only a single corresponding pathogen molecule that
is encoded by an avirulence (Avr)
gene.
°
Many
Avr proteins play an active role in pathogenesis and are thought to redirect
host metabolism to the advantage of the pathogen.
·
The
simplest biochemical model for gene-for-gene recognition is the receptor-ligand
model.
°
The
R protein functions as a specific receptor protein that triggers resistance on
binding to the correct corresponding Avr protein.
°
If
the host lacks the R gene that
counteracts the pathogen’s Avr gene,
the pathogen can invade and kill the plant.
·
The
“guard” hypothesis for gene-for-gene recognition proposes that R proteins
function as a surveillance system to detect changes in protein activity or
conformation induced by Avr proteins.
·
Regardless
of the mechanism, recognition of pathogen-derived molecules by R proteins
triggers a signal transduction pathway leading to a defense response in the
infected plant tissue.
°
This
defense includes an enhancement of the localized response at the site of
infection and a systemic response of the whole plant.
·
Even
if a plant is infected by a virulent strain of a pathogen—one for which that
particular plant has no genetic resistance—the plant is able to mount a
localized chemical attack in response to molecular signals released from cells
damaged by infection.
°
Molecules
called elicitors, often cellulose
fragments called oligosaccharins
released by cell wall damage, induce the production of antimicrobial compounds
called phytoalexins.
·
Infection
also activates genes that produce PR
proteins (for pathogenesis-related).
°
Some
of these are antimicrobial and attack bacterial cell walls.
°
Others
spread “news” of the infection to nearby cells.
·
Infection
also stimulates cross-linking of molecules in the cell wall and deposition of
lignins.
°
This
sets up a local barricade that slows spread of the pathogen to other parts of
the plant.
·
If
the pathogen is avirulent based on an R-Avr
match, the localized defense response is more vigorous and is called a hypersensitive response (HR).
°
There
is an enhanced production of phytoalexins and PR proteins, and the “sealing”
response that contains the infection is more effective.
°
After
cells at the site of infection mount their chemical defense and seal off the
area, they destroy themselves.
§
These
areas are visible as lesions on a leaf or other infected organ, but the leaf or
organ will survive, and its defense response will help protect the rest of the
plant.
·
Part
of the hypersensitive response includes production of chemical signals that
spread throughout the plant, stimulating production of phytoalexins and PR
proteins.
°
This
response, called systemic acquired
resistance (SAR), is nonspecific, providing protection against a diversity
of pathogens for days.
·
A
good candidate for one of the hormones responsible for activating SAR is salicylic acid.
°
A
modified form of this compound, acetylsalicylic acid, is the active ingredient
in aspirin.
§
Centuries
before aspirin was sold as a pain reliever, some cultures had learned that
chewing the bark of a willow tree (Salix)
would lessen the pain of a toothache or headache.
°
In
plants, salicylic acid also appears to have medicinal value, but only through
the stimulation of the systemic acquired resistance system.
°
Plant
biologists investigating disease resistance and other evolutionary adaptations
of plants are getting to the heart of how a plant responds to internal and
external signals.