Transcript Document

Plant Reproduction
Chapter 42
Reproductive Development
Angiosperms represent an evolutionary
innovation with their production of flowers
and fruits
Plants go through developmental changes
leading to reproductive maturity by
adding structures to existing ones with
meristems
-A germinating seed becomes a vegetative
plant through morphogenesis
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Gamete
production and
pollination
n
2n
n
2n
2n
Maturation
and flowering
Fertilization
CHAPTER 42
2n
CHAPTER 36
Development
of plant body
Zygote
2n
Embryo
CHAPTER 37
development
2n
2n
2n
Dispersal
and
germination
Fruit
and seed
maturation
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Reproductive Development
Flowering is the default state
In Arabidopsis, the gene embryonic flower
(EMF) prevents early flowering
-emf mutants
lacking a functional
EMF protein flower
immediately
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Reproductive Development
The juvenile-to-adult transition can be induced
by overexpressing a flowering gene
-LEAFY (LFY) was cloned in Arabidopsis
-Overexpression
of LFY in aspen,
causes
flowering to
occur in weeks
instead of years
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Flower Production
Four genetically regulated pathways to
flowering have been identified
1. The light-dependent pathway
2. The temperature-dependent pathway
3. The gibberellin-dependent pathway
4. The autonomous pathway
Plants can rely primarily on one
pathway, but all four pathways can be
present
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Let’s Take a Look at the
Autonomous Pathway in Some
Detail First
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Autonomous Pathway
The autonomous pathway does not depend
on external cues except for basic nutrition
It allows day-neutral plants to “count” nodes
and “remember” node location
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Autonomous Pathway--Plants
Can Count
Upper Axillary Bud Released from Apical Dominance Lower Axillary Bud Released from Apical Dominance
5 nodes*
removed
13 nodes*
removed
5 nodes*
replaced
13 nodes*
replaced
Shoot
removed
here
Shoot
removed
here
Intact plant
Shoot removed Replacement shoot
*nodes = leaf bearing node
Intact plant
Shoot removed Replacement shoot
-Tobacco plants produce a uniform number of nodes
before flowering
-Upper axillary buds of flowering tobacco remember their
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position if rooted or grafted
Autonomous Pathway--Plants
Can Remember
Shoot Florally Determined
Shoot
removed
here
Shoot Not Florally Determined
Shoot
removed
here
Shoot
removed
Shoot
removed
Intact plant
a.
Rooted shoot
Flowering
rooted shoot
Intact plant
Rooted shoot
Flowering
rooted shoot
b.
Not-Florally Determined Plants are said not to
remember...Florally Determined plants are said to
remember
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Roots Inhibit Flowering
Control plant:
no treatment
Experimental plant:
pot-on-pot treatment
Experimental plant:
Lower leaves were
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continually removed
A Model of All the
Flowering Pathways
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Repression of Floral Inhibitors
Cold
Temperaturedependent
Vernalization
pathway
Flowerrepressing
genes
Autonomous Autonomous
pathway
gene expression
Gibberellindependent Gibberellin
pathway
Flowerpromoting
genes
LFY
Lightdependent
pathway
CO
AP1
ABCDE
Floral organ
floral organ
development
identity genes
Light
Adult meristem
Activation of Floral Meristem Identity Genes
inhibition
activation
Floral meristem
Gibberellin binds to the promoter of LFY
CO is a transcription factor that turns on other genes,
resulting in the expression of LFY
-Phytochromes regulate CO transcription
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Flower Structure
Floral organs are thought to have evolved
from leaves
A complete flower has four whorls
-Calyx, corolla, androecium, and
gynoecium
An incomplete flower lacks one or more of
these whorls
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Stamen
Male
structure Anther
Filament
Petal
Carpel
Stigma Female
structure
Style
Ovary
Ovule
Sepal
Receptacle
all stamens = androecium
all carpels = gynoecium
all petals = corolla
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all sepals = calyx
Gamete Production
Plant sexual life cycles are characterized by
an alternation of generations
-Diploid sporophyte  haploid
gametophyte
In angiosperms, the gametophyte generation
is very small and is completely enclosed
within the tissues of the parent sporophyte
-Male gametophyte = Pollen grains
-Female gametophyte = Embryo sac
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Gamete Production
Gametes are produced in separate,
specialized structures of the flower
Reproductive organs of angiosperms
differ from those of animals in two ways:
1. Both male and female structures
usually occur together in the same
individual
2. Reproductive structures are not
permanent parts of the adult individual
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Anther
Pollen sac
Microspore
mother cell
Microspores
Ovule
Generative Cells
go on to make 2 sperm
Cells
Megaspore
mother cell
Megaspores
Antipodals
Megaspore enlarges and
undergoes
repeated mitotic divisions
to produce eight haploid
nuclei...Egg cell is enclosed
within a seven-celled
embryo sac
Egg
cell
Synergids
Surviving
megaspore
Polar
nuclei
MITOSIS
Degenerated
megaspores
MITOSIS
Generative cell
Tube cell
nucleus
Pollen grains
(microgametophytes)
Eight-nucleate embryo sac
(megagametophyte)
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Pollination
Pollination is the process by which pollen is
placed on the stigma
-Self-pollination = Pollen from a flower’s
anther pollinates stigma of the same flower
-Cross-pollination = Pollen from anther of
one flower pollinates another flower’s stigma
-Also termed outcrossing
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Pollination
Successful pollination in many angiosperms
depends on regular attraction of pollinators
Flowers & animal pollinators have coevolved
resulting in specialized relationships
-Bees are the most
common insect
pollinators
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Pollination
Flowers that are visited regularly by birds
often have a red color
-Usually inconspicuous to insects
Hummingbirds
obtain nectar from
flowers that match
the length and
shape of their
beaks
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Pollination
Self-pollinating plants usually have small,
relatively inconspicuous flowers that
shed pollen directly into the stigma
Self-pollination is favored in stable
environments
1. Plants do not need to be visited by
animals to produce seed
2. Offspring are more uniform and probably
better adapted to their environment
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Pollination
Several evolutionary strategies promote
outcrossing
1. Separation of male and female
structures in space
-Dioecious plants produce only ovule
or only pollen
-Monoecious plants produce male and
female flowers on the same plant
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Pollination
2. Separation of male and female
structures in time
-Even if functional stamens and pistils
are both found in the same flower, they
may reach maturity at different times
-Plants in which this occurs are called
dichogamous
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Pollination
3. Self-incompatibility
-Pollen and stigma recognize each other
as self and so the pollen tube is blocked
-Controlled by alleles at the S locus
-Gametophytic self-incompatibility
-Block is after pollen tube germination
-Sporophytic self-incompatibility
-The pollen tube fails to germinate
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Pollination
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Gametophytic Self-Incompatibility
Sporophytic Self-Incompatibility
S2
S1
S2
S2
S2
S1
S1
S2
X
X
X
S1S2
pollen parent
a.
S2S3
stigma of
pollen recipient
S1S2
pollen parent
S2S3
stigma of
pollen recipient
b.
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Fertilization
Angiosperms undergo a unique process called
double fertilization
-A pollen grain that lands on a stigma
forms a pollen tube that pierces the style
-While the pollen tube is growing, the
generative cell divides to form 2 sperm cells
-When pollen tube reaches the ovule, it
enters one of the synergids and releases
the two sperm cells
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Fertilization
-Then double-fertilization occurs
-One sperm cell nucleus fuses with the
egg cell to form the diploid (2n) zygote
-Other sperm cell nucleus fuses with the
two polar nuclei to form the triploid (3n)
endosperm nucleus
-Eventually develops into the
endosperm that nourishes embryo
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Pollen grain
Stigma
Generative cell
Tube cell
Tube cell
Sperm cells
Style
Carpel Tube cell
nucleus
Ovary
Embryo
sac
Ovule
Pollination
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Endosperm nucleus (3n)
Zygote (2n)
Pollen tube
Antipodals
Egg cell
Polar nuclei
Synergids
Release of sperm cells
Double fertilization
Growth of pollen tube
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Plant Life Spans
Once established, plants live for variable
periods of time, depending on the species
Woody plants, which have extensive
secondary growth, typically live longer
than herbaceous plants, which don’t
-Bristlecone pine, for example, can live
upward of 4,000 years
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Plant Life Spans
Perennial plants are able to flower and
produce seeds and fruit for an indefinite
number of growing seasons
-May be herbaceous or woody
-In deciduous plants all the leaves fall, and
the tree is bare, at a particular time of year
-In evergreen plants, the leaves drop
throughout the year, and so the plant is
never completely bare
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Plant Life Spans
Annual plants grow, flower, and form fruits
and seeds, and typically die within one
growing season
-Are usually herbaceous
-The process that leads to the death of the
plant is called senescence
Biennial plants have two-year life cycles
-They store energy the first year and flower
the second year
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