Transcript Chapter 32
Chapter 32
Plant Growth and Development
AP Biology
Spring 2011
Chapter 32.1
Overview of Plant Development
Seed Germination
Germination: the resumption of growth after a time of
arrested development
Environmental Factors Influence Seed
Germination
Seasonal Rains: provide water amounts necessary to
swell and rupture the seed coat
Water activates enzymes necessary to hydrolyze the stored
starch
Starches are converted to sugars
Provides the energy for the meristems to initiate cell division
Oxygen is required, reaches embryo and aerobic respiration
provides ATP needed for growth
Environmental Factors Influence Seed
Germination
Repeated cell divisions produce a seedling with a primary
root
When the primary root breaks through the seed coat
germination is complete
Seed dormancy and germination is climate specific
Occurs only when conditions are favorable for the seedling to
survive
Patterns of Early Growth
Growth: an increase in the number, size, and volume of
cells
Development: the emergence of specialized,
morphologically different body parts
Patterns of germination, growth, and development have a
heritable basis dictated by a plant’s genes
Patterns of Early Growth
Early cell divisions may result in unequal distribution of
cytoplasm
Cytoplasmic differences trigger variable gene expression, which
may result in variations in hormone synthesis
Even though all cells have the same genes, it is the selective
expression of those genes that results in cell differentiation
Patterns of Early Growth
Plant growth and development starts with the selective
transcription and translation of genes
Ex. Page 543 Fig. 32.3 and 32.4
Pattern of growth and development of corn (monocot) and
bean plant (dicot)
Chapter 32.2
Plant Hormones and Other Signaling Molecules
Major Types of Plant Hormones
Plant hormones have central roles in the coordination of
plant growth and development
Giberellins
Acidic compounds synthesized in seeds and young shoot
tissues
Promote stem elongation, germination and starch
hydrolysis
Help induce flowering in some plants
Auxins
Produced at apical meristems of roots and shoots, coleoptiles in monocots
Influence cell division and elongation either positively or negatively
depending on the tissue
Cause leaves to grown in patterns, stems to bend toward light, roots to
grow down
Auxins at shoot tips prevent lateral bud growth- apical dominance
Help prevent abscission where leaves,
flowers, or fruits drop from plant
Abscission: dropping of leaves,
flowers, fruits
Cytokinins
Stimulate cell division in root and shoot meristems,
where they are most abundant
Can release lateral buds from apical dominance and can
stop leaves from aging prematurely
Used commercially to prolong the life of stored
vegetables and cut flowers
Ethylene (a gas)
Can promote or inhibit cell growth so that tissues expand
in the most suitable directions
Induces fruit ripening
Concentrations high when plant is stressed
Ex. Autumn or end of life cycle
Induces abscission of leaves and fruits, and sometimes death of
whole plant
Abscisic Acid (ABA)
Inhibits cell growth
Helps prevent water loss (by promoting stomata closure)
When growing season ends, ABA overrides gibberellins, auxins,
and cytokinins; causes photosynthetic products to be diverted
from leaves to seeds
When plant is water stressed, root cells produce more ABA
which xylem move to leaves
Promotes seed and bud dormancy
Other Signaling Molecules
Brassinosteroids: help promote cell division and
elongation
Stems stay short in their absence
Jasmonates: help other hormones control seed
germination, root growth, and tissue defense responses to
pathogens
FT protein: part of a signaling pathway that induces
flower formation
Other Signaling Molecules
Salicylic Acid: interacts with nitric oxide in respose to
attacks from pathogens
Nitric Oxide: functions in plant defense response
Systemin: peptide that forms when insects attack plant
tissues; travels throughout the plant turning on genes for
substances that interfere with the insect’s digestion
Commercial Uses
Many synthetic and natural plant hormones are used
commercially
Ethylene: makes fruits ripen quickly
Gibberellin: promotes larger fruits
Synthetic Auxins: spayed on unpollinated flowers to
produce seedles fruits
Synthetic Auxin 2,4-D: used as herbicides
Accelerates the growth of eudicot weeds to a point that the
plant cannot sustain it and the weeds die
Chapter 32.3
Mechanisms of Plant Hormone Action
Signal Transduction
Plants have pathways of cell communication
Hormone Action in Germination
Imbibed water stimulates cells of embryo to release gibberellin
In aleurone layer, hormone triggers transcription and
translation of amylase genes to hydrolyze starch molecules
Digests starch into transportable sugar
Amylase moves into endosperm’s starch rich cells
Water moves giberellin to cells of aleurone (protein storing layer)
Water also activates protein digesting enzymes
Sugar monomers released from starch fuel aerobic respiration
ATP from aerobic respiration provides the energy for growth
of the primary root and shoot
Polar Transport of Auxin
Auxin concentration gradients start forming during early
cell divisions of embryo sporophyte
Cells exposed to higher concentrations transcribe
different genes than those exposed to lower
concentrations
Help form plant parts (leaves) in expected patterns
Helps young cells elongate
Polar Transport of Auxin
Auxin concentration highest at source: apical meristem in
a shoot (or coleoptile)
Auxin transported down, toward shoot’s base
Polar transport takes place in parenchyma cells
Polar Transport of Auxin
Auxin gives up hydrogen in each cell, which alters
cytoplasmic pH
Membrane pumps activly transport H+ outside, which
lowers pH of moist cell wall
Enzymes in cell wall become active at lower pH
Polar Transport of Auxin
Enzymes cleave crosslink's between microfibrils, which
support the wall
Water is diffusing into the cell, turgor pressure builds
against wall
Microfibrils now free to move apart, wall is free to
expand
Ta-dah….cell lengthens!
pH change also activates transcription factors, after auxin
exposure, proteins that help cell assume its new shape
are synthesized
Chapter 32.4
Adjusting the Direction and Rates of Growth
Response to Gravity
Gravitroprism: growth response to gravity
Shoots grow up, roots grow down
Auxin, with growth-inhibiting hormone: may play a
role in promoting or inhibiting growth in various regions
of the plant
Statoliths: are unbound starch grains in plastids, respond
to gravity and may trigger redistribution of auxin
Response to Light
Phototropism: growth response to light
Bending toward light is caused by elongation of cells
(auxin stimulation) on the side of the plant NOT exposed
to light
Phototropins: pigments that absorb blue wavelengths of
light and signal the redistribution of auxin that initiates
the elongation of cells
Response to Contact
Thigmotropism: shift in growth triggered by physical
contact with surrounding objects
This response to auxin and ethylene is prevalent in
climbing vines and in the tendrils that support some
plants
Tendrils: new, modified leaves or stems
When cells at shoot tip touch stable object, cells on
contact side stop elongating and cells on other side keep
growing
Unequal rates of growth make vine or tendril curl around
object
Response to Mechanical Stress
Responses to the mechanical stress of strong winds
explain why plants grown at higher elevations are stubbier
than those at lower elevations
Grazing animals, growing outside vs. greenhouse can also
inhibit plant growth
Human intervention such as shaking can inhibit plant
growth
Chapter 32.5
Seasonal Shifts in Growth
Seasonal Shifts
Circadian Cycle: completed in 24 hour period
Photoperiodism: refers to biological response to
alternations in the length of darkness relative to daylight
during a circadian cycle
Ex. The number of hours plant spends in darkness and daylight
shifts with seasons
Seasonal Shifts
Biological Clocks: internal mechanisms that preset the
time for recurring shifts in daily tasks or seasonal patterns
of growth, development, and reproduction
Seasonal Shifts
Phytochrome: blue-green pigment functions as a
receptor for red and far-red light
Red light at sunrise causes phytochrome to shift from its
inactive form (Pr) to its active form (Pfr)
Far-red light at sunset shifts to inactive form (Pr)
Longer the nights, longer the interval when phytochrome is
inactive
Pfr can induce gene transcription
Can bring about seed germination, shoot elongation, branching, leaf
expansion, and flower, fruit and seed formation, then dormancy
Chapter 32.6
When to Flower?
Response to Hours of Darkness
Flowering process is keyed to changes in day length
throughout the year
Cue is length of darkness
Response to Hours of Darkness
Short-day plants: flower
in early spring or fall
Long-day plants: flower
in summer
Nights are longer than some
critical value
Nights are shorter than
some critical value
Day-neutral plants:
flower whenever they are
mature enough to do so
Response to Hours of Darkness
Phytochrome is trigger for flowering
Detection of photoperiod (alternations in length of
darkness relative to daylight) occurs in leaves, where
hormones inhibit a shift from leaf growth to flower
formation
Revisiting the Master Genes
3 groups of master genes A, B, C control formation of
floral structures from whorls of a floral shoot
In response to photoperiods of other environmental cues,
leaf cells transcribe a flowering gene
mRNA transcript travels in phloem to as-yet
undifferentiated floral buds, where they are translated
into FT protein
This signaling molecule with a transcription factor turn on
master genes that cause undetermined bud of
meristematic tissue to develop into a flower
Vernalization
Vernalization: low temperature stimulation of flowering
Unless certain biennials and perennials are exposed to
low temperatures, flowers will not form on their stems in
spring
Chapter 32.7
Entering and Breaking Dormancy
Abscission and Senescence
Abscission: the dropping of leaves, flowers, fruits, other
parts
Senescence: sum total of the processes leading to the
death of plant parts or the whole plant
Abscission and Senescence
Recurring cue is decrease in day length that triggers a
decrease in auxin production
Cells in abscission zones produce ethylene, which causes
cells to deposit suberin in their walls
Simultaneously, enzymes digest cellulose and pectin in the
middle lamella to weaken the abscission zone
Lamella: cementing layer between plant cell walls
Bud Dormancy
Dormancy occurs in autumn when days shorten, and
growth stops in many trees and non-woody perennials
It will not resume until spring
Bud Dormancy
Strong cues for dormancy include short days, cold nights,
and dry, nitrogen deficient soil
Requirement for multiple cues for dormancy has great
adaptive value in preventing plant growth on occasional
warm autumn days only to be killed later by frost
Dormancy broken by milder temperatures, rains, and
nutrients