chapter 32
DESCRIPTION
Plant Growth and Development. Chapter 32. Fig. 32-1a, p.540. Hormones – signaling molecules that stimulate or inhibit gene activity Gibberellins are a class of plant hormones that stimulate stem lengthening. Impacts, Issues: Foolish Seedlings, Gorgeous Grapes. - PowerPoint PPT PresentationTRANSCRIPT
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CHAPTER 32
Plant Growth and Development
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Fig. 32-1a, p.540
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IMPACTS, ISSUES: FOOLISH SEEDLINGS, GORGEOUS GRAPES
Hormones – signaling molecules that stimulate or inhibit gene activity
Gibberellins are a class of plant hormones that stimulate stem lengthening
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IMPACTS, ISSUES: FOOLISH SEEDLINGS, GORGEOUS GRAPES
Synthetic gibberellins have applications in production of grocery fruits and vegetables such as celery, grapes, and oranges
Understanding how plants grow and develop is essential for farmers to maximize the quality of their produce
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SEED GERMINATION Process by which the plant embryo
resumes growth after seed dispersal Depends upon environmental
factors Temperature Soil moisture Oxygen levels
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SPLITTING THE SEED COAT
Imbibition Water molecules move
into a seed As water moves in, the
seed swells and the coat ruptures
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GENES GOVERN DEVELOPMENT All cells in a plant inherit the same
genes Positional differences and unequal
cytoplasmic divisions lead to differences in metabolic output
Activities of daughter cells begin to vary as a result of selective gene expression
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PLANT HORMONES Gibberellins Auxins Cytokinins Abscisic Acid Ethylene
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PLANT HORMONES
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GIBBERELLIN More than 80 forms have been isolated from
plants, as well as from fungi In nature, gibberellin:
Helps seeds and buds break dormancy Makes stems lengthen Influences flowering
Applied by growers to enhance stem length, control ripening
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GIBBERELLIN
Fig. 32-5, p.544
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AUXINS Promote stem lengthening Play a role in responses to gravity and light Indoleacetic acid (IAA) is the most common
auxin in nature Certain synthetic auxins are used as
herbicides
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Fig. 32-6, p.545
control plant auxin treated
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CYTOKININS Promote cell division Most abundant in root and shoot meristems
and in maturing fruits In mature plants, produced in roots and
transported to shoots Used to artificially extend the shelf life of cut
flowers; delays leaf death
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ETHYLENE
Induces aging responses Unlike other plant
hormones, ethylene is a gas Used to ripen fruits for
market
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ABSCISIC ACID (ABA)
Causes the suspension of growth; promotes dormancy of buds and seeds
Used to induce dormancy in plants to be shipped
Also plays a role in drought response
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PLANT HORMONE APPLICATIONS
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SIGNAL TRANSDUCTION Pathway of cell communication in
plants
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Fig. 32-7, p.546
signalreception
signaltransduction
cellular response
Hormone binds to and activates cell receptor
Activated receptor activates enzymes and other molecules, ahich enter reactions that induce or inhibit some cellular activity
cell wall membrane receptor
cytoplasm of target
cell
SIGNAL TRANSDUCTION
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GERMINATION Gibberellin acts in the endosperm’s
aleurone, a protein-storing layer
Transcription of the gene for amylase, which hydrolyzes starch molecules
Sugar monomers released are transported to fuel plant growth
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PLANT TROPISMS Adjustment of plant growth toward
or away from an environmental stimulus
Phototropism - stimulus is light Gravitropism - stimulus is gravity Thigmotropism - stimulus is contact
with an object
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GRAVITROPISM
Roots tend to grow toward pull of gravity; shoots grow against it
Gravitational field is sensed via position of statoliths (a type of amyloplast)
Auxin is involved in response; causes asymmetric cell elongation
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Fig. 32-12a,b, p.548
Gravitropism
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PHOTOTROPISM
Change in growth in response to light
Controlled by the flow of auxin produced in the plant tip
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Fig. 32-14c, p.549
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THIGMOTROPISM Growth in response to contact with a
solid object Allows vines and tendrils to wrap
around supports Cells on contact side elongate, causing
stem to curl Auxin and ethylene may be involved
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Fig. 32-15, p.549
Thigmotropism
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BIOLOGICAL CLOCKS Internal timing mechanisms
Trigger shifts in daily activity Help induce seasonal adjustments
Phytochrome is part of the switching mechanism Blue-green plant pigment
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FLOWERING TIME
Environmental cue is night length
Unidentified hormone(s) are thought to be central to flowering
Fig. 32-17, p.550
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PHYTOCHROME AND FLOWERING Long-day plants flower when night is shorter
than a critical length Short-day plants flower when the night is
longer than critical value When an intense red flash interrupts a long
night, both respond as if it were a short night
A short pulse of far-red light after the red flash cancels effect of the red flash
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Fig. 32-19, p.551
Long-Day Plant:
flowered
did not flower
critical night length
did not flower
floweredTime being measured (hours)
0 4 8 12 16 20 24
Short-Day Plant:
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VERNALIZATION Low temperature stimulation of
flowering Seasonal responses
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CONTROL OF ABSCISSION Abscission
Dropping of flowers, fruits, or leaves What brings it about?
Auxin production declines Cells in abscission zone produce ethylene Enzymes digest cell walls that attach leaf
or fruit to plant
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Fig. 32-22a, p.552
Abscission
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SENESCENCE Sum total of processes that lead to
death of a plant or some of its parts Factors that influence senescence:
Decrease in daylight is recurring factor Wounds, drought, or nutritional
deficiencies can also bring it about
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DORMANCY A predictable period of metabolic
inactivity Short days; long, cool nights trigger
dormancy Experiments have shown that
exposure to light blocks dormancy Demonstrates involvement of
phytochrome
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BREAKING DORMANCY
Seeds and buds respond to environmental cues by resuming growth
May require exposure to low temperatures for some interval
Probably involves gibberellins and abscisic acid
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SOLAR TRACKING Differs from phototrophic growth in that it
doesn’t involve asymmetric growth
Turgor pressure in cells causes the petiole (stalk that attaches leaf to stem) to straighten
Plants reposition flat leaves to minimize heat absorption or maximize exposure to sunlight
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Fig. 32-25, p.553
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PROTECTING CROPS
Herbicides Insecticides Fungicides Can kill or sicken nontarget organisms Pests can develop resistance
DDT