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Sensory Systems in Plants

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Title: Sensory Systems in Plants


1
Sensory Systems in Plants
  • Chapter 41

2
Responses to Light
  • Pigments other than those used in photosynthesis
    can detect light and mediate the plants response
    to it
  • Photoperiodism response to changes in the length
    of day and night, it is nondirectional
    Phototropisms are directional growth responses to
    light
  • Both compensate for plants inability to move

3
Responses to Light
  • Phytochrome (P) consists of two parts
  • -Chromophore which is light-receptive
  • -Apoprotein which initiates a signal-transduction
    pathway

4
Responses to Light
  • The phytochrome molecule exists in two
    interconvertible forms
  • -Pr is the inactive form
  • -Absorbs red light at 660 nm
  • -Pfr is the active form
  • -Absorbs far-red light at 730 nm
  • -Tagged by ubiquitin for degradation in the
    proteasome

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Responses to Light
  • In Arabidopsis, five forms of phytochromes have
    been characterized PHYA to PHYE
  • -Involved in several plant growth responses
  • 1. Seed germination
  • -Inhibited by far-red light and stimulated by
    red light in many plants

7
Responses to Light
  • 2. Shoot elongation
  • -Etiolation occurs when shoot internodes
    elongate because red light and active Pfr are
    not available
  • 3. Detection of plant spacing
  • -Crowded plants receive far-red light bounced
    from neighboring plants
  • -This increases plant height in
    competition for sunlight

8
Responses to Light
  • Phytochromes are involved in many signaling
    pathways that lead to gene expression
  • -Pr is found in the cytoplasm
  • -When it is converted to Pfr it enters the
    nucleus
  • -Pfr binds to transcription factors, leading
    to expression of light-regulated genes

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Responses to Light
  • Phytochrome also works through protein-kinase
    signaling pathways
  • -When Pr is converted to Pfr, its protein kinase
    domain causes autophosphorylation or
    phosphorylation of another protein
  • -This initiates a signaling cascade that
    activates transcription factors leading to
    expression of light-regulated genes

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12
Phototropisms
  • Phototropic responses including the bending of
    growing stems to sources of light with blue
    wavelengths (460-nm range)

13
Phototropisms
  • A blue-light receptor phototropin 1 (PHOT1) has
    been characterized
  • -Has two regions
  • -Blue-light activates the light-sensing region
    of PHOT1
  • -Stimulates the kinase region of
    PHOT1 to autophosphorylate
  • -Triggers a signal transduction

14
Phototropisms
15
Circadian Clocks
  • Circadian rhythms (around the day) are
    particularly common among eukaryotes
  • Have four characteristics
  • 1. Continue in absence of external inputs
  • 2. Must be about 24 hours in duration
  • 3. Cycle can be reset or entrained
  • 4. Clock can compensate for differences in
    temperature

16
Responses to Gravity
  • Gravitropism is the response of a plant to the
    gravitational field of the Earth
  • -Shoots exhibit negative gravitotropism roots
    have a positive gravitropic response

17
Responses to Gravity
  • Four general steps lead to a gravitropic
    response
  • 1. Gravity is perceived by the cell
  • 2. A mechanical signal is transduced into a
    gravity-perceiving physiological signal
  • 3. Physiological signal is transduced to other
    cells
  • 4. Differential cell elongation occurs in the
    up and down sides of root and shoot

18
Responses to Gravity
  • In shoots, gravity is sensed along the length of
    the stem in endodermal cells surrounding the
    vascular tissue
  • -Signaling is in the outer epidermal cells
  • In roots, the cap is the site of gravity
    perception
  • -Signaling triggers differential cell elongation
    and division in the elongation zone

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Stem Response to Gravity
  • Auxin accumulates on lower side of the stem
  • -Results in asymmetrical cell elongation and
    curvature of the stem upward
  • Two Arabidopsis mutants, scarecrow (scr) and
    short root (shr) do not show a normal gravitropic
    response
  • -Due to lack of a functional endodermis and
    its gravity-sensing amyloplasts

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Root Response to Gravity
  • Lower cells in horizontally oriented root cap are
    less elongated than those on upper side
  • -Upper side cells grow more rapidly causing the
    root to ultimately grow downward
  • Auxin may not be the long-distance signal between
    the root cap and elongation zone
  • -However, it has an essential role in root
    gravitotropism

24
Responses to Mechanical Stimuli
  • Thigmomorphogenesis is a permanent form change in
    response to mechanical stresses
  • Thigmotropism is directional growth of a plant or
    plant part in response to contact
  • -Thigmonastic responses occur in same direction
    independent of the stimulus
  • Examples of touch responses
  • -Snapping of Venus flytrap leaves
  • -Curling of tendrils around objects

25
Responses to Mechanical Stimuli
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Responses to Mechanical Stimuli
  • Some turgor movements are triggered by light
  • -This movement maximizes photosynthesis

28
Responses to Mechanical Stimuli
  • Bean leaves are horizontal during the day when
    their pulvini are rigid

-But become more or less vertical at night as
the pulvini lose turgor
29
Water and Temperature Responses
  • When water and temperature affect plants,
    responses can be short-term or long-term
  • Dormancy results in the cessation of growth
    during unfavorable conditions
  • -Often begins with dropping of leaves
  • Abscission is the process by which leaves or
    petals are shed
  • -One advantage is that nutrient sinks can be
    discarded, conserving resources

30
Water and Temperature Responses
  • Abscission involves changes that occur in an
    abscission zone at the petioles base
  • -Hormonal changes lead to differentiation of
    -Protective layer Consists of several layers
    of suberin-impregnated cells
  • -Separation layer Consists of 1-2 layers of
    swollen, gelatinous cells
  • -As pectins break down, wind and rain
    separate the leaf from the stem

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Seed Dormancy
  • Seeds allow plant offspring to wait until
    conditions for germination are optimal
  • -Legume seeds often last decades and even longer
    without special care
  • -Seeds that are thousands of years old have been
    successfully germinated
  • Essential steps leading to dormancy include
  • -Accumulating food reserves, forming a
    protective seed coat and dehydration

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Responses to Chilling
  • Plants respond to cold temperatures by
  • 1. Increasing number of unsaturated lipids in
    their plasma membranes
  • 2. Limiting ice crystal formation to
    extracellular spaces
  • 3. Producing antifreeze proteins
  • Some plants can undergo deep supercooling
  • -Survive temperatures as low as 40OC

35
Responses to High Temperatures
  • Plants produce heat shock proteins (HSPs) if
    exposed to rapid temperature increases
  • -HSPs stabilize other proteins
  • Plants can survive otherwise lethal temperatures
    if they are gradually exposed to increasing
    temperature
  • -Acquired thermotolerance

36
Hormones and Sensory Systems
  • Hormones are chemicals produced in one part of an
    organism and transported to another part where
    they exert a response
  • In plants, hormones are not produced by
    specialized tissues
  • -Seven major kinds of plant hormones
  • -Auxin, cytokinins, gibberellins,
    brassinosteroids, oligosaccharins, ethylene,
    and abscisic acid

37
Auxin
  • Discovered in 1881 by Charles and Francis Darwin
  • -They reported experiments on the response of
    growing plants to light
  • -Grass seedlings do not bend if the tip is
    covered with a lightproof cap
  • -They do bend when a collar is placed below
    the tip

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Auxin
  • The Darwins hypothesized that shoots bend towards
    light in response to an influence transmitted
    downward from the tip
  • Thirty years later, Peter Boysen-Jensen and Arpad
    Paal demonstrated that the influence was
    actually a chemical

40
Auxin
  • In 1926, Frits Went performed an experiment that
    explained all of the previous results
  • -He named the chemical messenger auxin
  • -It accumulated on the side of an oat seedling
    away from light
  • -Promoted these cells to grow faster
    than those on the lighted side
  • -Cell elongation causes the plant to
    bend towards light

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43
Auxin
  • Winslow Briggs later demonstrated that auxin
    molecules migrate away from the light into the
    shaded portion of the shoot
  • -Barriers inserted in a shoot tip revealed equal
    amounts of auxin in both the light and dark sides
    of the barrier
  • -However, different auxin concentrations
    produced different degrees of curvature

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How Auxin Works
  • Indoleacetic acid (IAA) is the most common
    natural auxin
  • -Probably synthesized from tryptophan

46
How Auxin Works
  • The auxin receptor is the transport inhibitor
    response protein 1 (TIR1)
  • Two families of proteins mediate auxin-induced
    changes in gene expression
  • -Auxin responses factors (ARFs)
  • -Aux/IAA proteins

47
How Auxin Works
  • 1. Auxin binds TIR1 in the SCF complex if
    Aux/IAA is present
  • 2. SCF complex tags Aux/IAA proteins with
    ubiquitin
  • 3. These are degraded in the proteasome
  • 4. Transcriptional activators of ARF genes are
    released from repression by Aux/IAA
  • 5. Auxin-induced gene expression

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How Auxin Works
  • One of the downstream effects of auxin is an
    increase in plasticity of the plant cell wall
  • -The acid growth hypothesis provides a model
    linking auxin to cell wall expansion

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51
Synthetic Auxins
  • Naphthalene acetic acid (NAA) and indolebutyric
    acid (IBA) have many uses in agriculture and
    horticulture
  • -Prevent abscission in apples and berries
  • -Promote flowering fruiting in pineapples
  • 2,4-dichlorophenoxyacetic acid (2,4-D) is a
    herbicide commonly used to kill weeds

52
Cytokinins
  • Are purines that appear to be derivatives of
    adenine

Synthetic cytokinins
53
Cytokinins
  • Cytokinins are produced in the root apical
    meristems and developing fruits
  • -Stimulate cell division and differentiation, in
    combination with auxin
  • Cytokinins promote the growth of lateral buds
    into branches
  • -They inhibit the formation of lateral roots,
    while auxin promotes their formation

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Cytokinins
  • Cytokinins promote the synthesis or activation of
    cytokinesis proteins
  • -They also function as anti-aging hormones
  • Plant tissue can form shoots, roots, or an
    undifferentiated mass depending on the relative
    amounts of auxin and cytokinin

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Cytokinins
  • The plant pathogen Agrobacterium introduces genes
    into the plant genome that increase the
    production of cytokinin and auxin

-Cause massive cell division and formation of a
crown gall tumor
58
Gibberellins
  • Named after the fungus Gibberella fujikuroi which
    causes rice plants to grow very tall
  • Gibberellins belong to a large class of over 100
    naturally occurring plant hormones
  • -All are acidic and abbreviated GA
  • -Have important effects on stem elongation

59
Gibberellins
  • Adding gibberellins to certain dwarf mutants
    restores normal growth and development

60
Gibberellins
  • GA is used as a signal from the embryo that turns
    on transcription of genes encoding hydrolytic
    enzymes in the aleurone layer
  • -When GA binds to its receptor, it frees
    GA-dependent transcription factors from a
    repressor
  • -These transcription factors can now directly
    affect gene expression

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Gibberellins
  • GAs hasten seed germination
  • -They also function as pheromones in ferns

GAs are used commercially to extend internode
length in grapes -The result is larger grapes
63
Brassinosteroids
  • First discovered in the pollen of Brassica spp.
  • -Are structurally similar to steroid hormones

64
Brassinosteroids
  • Have a broad spectrum of physiological effects
  • -Elongation, cell division, stem bending,
    vascular tissue development, delayed senescence
    and reproductive development
  • Additive effects with auxins and gibberellins
    have been reported

65
Oligosaccharins
  • Are complex plant cell wall carbohydrates that
    have a hormone-like function
  • -Can be released from the cell wall by enzymes
    secreted by pathogens
  • -Signal the hypersensitive response (HR)
  • In peas, oligosaccharins inhibit auxin-stimulated
    elongation of stems
  • -While in regenerated tobacco tissue, they
    inhibit roots and stimulate flowers

66
Ethylene
  • A gaseous hydrocarbon (H2CCH2)
  • Auxin stimulates ethylene production in the
    tissues around the lateral bud and thus retards
    their growth
  • Ethylene also suppresses stem and root elongation

67
Ethylene
  • Ethylene controls leaf, flower and fruit
    abscission
  • It hastens fruit ripening
  • -Indeed, an antisense copy of the gene has been
    used to create transgenic tomato
  • -These stay fresh longer

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Abscisic Acid
  • Abscisic acid is synthesized mainly in mature
    green leaves, fruits and root caps
  • There is little evidence that this hormone plays
    a role in abscission
  • Abscisic acid induces formation of dormant winter
    buds
  • It counteracts gibberellins, by suppressing bud
    growth and elongation, and auxin, by promoting
    senescence

70
Abscisic Acid
  • Abscisic acid is also necessary for dormancy in
    seeds
  • -Prevents precocious germination called vivipary
  • Abscisic acid is important in the opening and
    closing of stomata
  • -Triggers movement of K out of guard cells

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