Transcript seed coat

Vegetative Plant Development
Chapter 37
Embryo Development
Begins once the egg cell is fertilized
-The growing pollen tube enters angiosperm
embryo sac and releases two sperm cells
-One sperm fertilizes central cell and
initiates endosperm development
-Other sperm fertilizes the egg to
produce a zygote
-Cell division soon follows, creating
the embryo
2
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Pollen tube
Polar nuclei
Egg cell
just before
fertilization
Integuments
(ovule wall)
Micropyle
Sperm cell
just before
fertilizing
central cell
Sperm cell
just before
fertilizing
egg cell
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Embryo Development
The first zygote division is asymmetrical,
resulting in two unequal daughter cells
-Small cell divides repeatedly forming a ball
of cells, which will form the embryo
-Large cell divides repeatedly forming an
elongated structure called a suspensor
-Transports nutrients to embryo
The root-shoot axis also forms at this time
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Embryo Development
Polar nuclei
3n endosperm
2n zygote
Egg
Sperm
Micropyle Pollen tube
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Embryo Development
Globular
Suspensor Endosperm proembryo
First cell
division
Basal cell
Shoot apical meristem
Shoot
Procambium
Hypocotyl apical
Ground
meristem
Cotyledon meristem
Cotyledons
Protoderm
Root apex
(radicle)
Endosperm
Root apical Cotyledons
meristem
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Embryo Development
Asymmetrical cell division is also observed in
the zygote of the brown alga Fucus
-Unequal material distribution forms a bulge
-Cell division occurs there, resulting in:
-A smaller cell that develops into a
rhizoid that anchors the alga
-A larger cell that develops into the
thallus, or main algal body
Fate of two cells is held “in memory” by cell
wall components
7
Embryo Development
Gravity
Thallus cell Thallus
Light
Zygote
Bulge
Rhizoid cell Rhizoid
First cell
division
(asymmetrical)
Young alga
Adult alga
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Embryo Development
Arabidopsis mutants have revealed the
normal developmental mechanisms
-Suspensor mutants undergo aberrant
development in the embryo followed by
embryo-like development of the suspensor
-Thus, the embryo normally prevents
embryo development in suspensor
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10
Development of Body Plan
In plants, three-dimensional shape and form
arise by regulating cell divisions
-The vertical axis (root-shoot axis) becomes
established at a very early stage
-Cells soon begin dividing in different
directions producing a solid ball of cells
-Apical meristems establish the root-shoot
axis in the globular stage
11
Development of Body Plan
The radial axis (inner-outer axis) is created
when cells alternate between synchronous
cell divisions
-Produce cells walls parallel to and
perpendicular to the embryo’s surface
The 3 basic tissue systems arise at this stage
-Dermal, ground and vascular
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Development of Body Plan
Root–shoot axis
Radial axis
Cell wall forming parallel
to embryo surface
Embryo
Suspensor
13
Development of Body Plan
Cell wall
forming
perpendicular
to embryo
surface
Vascular tissue system
(procambium)
Ground tissue system
(ground meristem)
Shoot apical meristem
Root–shoot
axis
Dermal tissue system
(protoderm)
Multiple parallel
and perpendicular
divisions, accompanied
by apical growth divisions
lengthening the root–
shoot axis
Root apical meristem
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Development of Body Plan
Both shoot and root meristems are apical
meristems, but are independently controlled
-Shootmeristemless
stm mutant
(STM) is necessary for
shoot formation, but
not root development
-STM encodes a
transcription factor
with homeobox region
STM wild type
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Development of Body Plan
The HOBBIT gene is required for root
meristem, but not shoot meristem formation
16
Development of Body Plan
One way that auxin induces gene expression
is by activating the MONOPTEROS (MP)
protein
-Auxin releases the repressor from MP
-MP then activates the transcription of a
root development gene
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18
Development of Body Plan
19
Formation of Tissue Systems
Primary meristems differentiate while the
plant embryo is still at the globular stage
-No cell movements are involved
The outer protoderm develops into dermal
tissue that protects the plant
The ground meristem develops into ground
tissue that stores food and water
The inner procambium develops into vascular
tissue that transports water & nutrients
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21
Morphogenesis
The heart-shaped globular stage gives rise to
bulges called cotyledons
-Two in eudicots and one in monocots
These bulges are produced by embryonic
cells, and not by the shoot apical meristem
-This process is called morphogenesis
-Results from changes in planes and
rates of cell division
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Morphogenesis
The form of a plant body is largely determined
by the plane in which its cells divide
-Based on the position of the cell plate
-Determined by microtubule orientation
Microtubules also guide cellulose deposition
as the cell wall forms around the new cell
-Cells expand in the directions of the two
sides with the least cellulose reinforcement
23
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Nucleus Microtubules
Cell division
Cell division
Forming cell
plate
a.
Cellulose
fiber
Water uptake
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b.
Expansion
Morphogenesis
Early in embryonic development, most cells
can give rise to a wide range of cell and
organ types, including leaves
-As development proceeds, the cells with
multiple potentials are restricted to the
meristem regions
-Many meristems have been established
by the time embryogenesis ends and the
seed becomes dormant
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Morphogenesis
During embryogenesis, angiosperms undergo
three other critical events:
-Storage of food in the cotyledons or
endosperm
-Differentiation of ovule tissue to form a
seed coat
-Development of carpel wall into a fruit
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Morphogenesis
Endosperm varies between plants
-In coconuts it is liquid
-In corn it is solid
-In peas and beans it is used up during
embryogenesis
-Nutrients are stored in thick, fleshy
cotyledons
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Seeds
In many angiosperms, development of the
embryo is arrested soon after meristems
and cotyledons differentiate
-The integuments develop into a relatively
impermeable seed coat
-Encloses the seed with its dormant
embryo and stored food
29
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Shoot apical meristem
Seed coat
(integuments)
Procambium
Root apical
meristem
Root cap
Endosperm
Cotyledons
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Seeds
Seeds are an important adaptation because:
1. They maintain dormancy under
unfavorable conditions
2. They protect the young plant when it is
most vulnerable
3. They provide food for the embryo until it
can produce its own food
4. They facilitate dispersal of the embryo
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Seeds
Once a seed coat forms, most of the
embryo’s metabolic activities cease
Germination cannot take place until water
and oxygen reach the embryo
-Seeds of some plants have been known
to remain viable for thousands of years
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Seeds
Specific adaptations ensure that seeds will
germinate only under appropriate conditions
-Some seeds lie within tough cones that do
not open until exposed to fire
33
Seeds
-Some seeds only germinate when
sufficient water is available to leach
inhibitory chemicals from the seed coat
-Still other seeds germinate only after they
pass through the intestines of birds or
mammals
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Fruits
Fruits are most simply defined as mature
ovaries (carpels)
-During seed formation, the flower ovary
begins to develop into fruit
-It is possible, however, for fruits to develop
without seed development
-Bananas are propagated asexually
35
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Stigma
Style
Pericarp
(ovary wall)
Exocarp
Mesocarp
Endocarp
Ovary
Part of
ovary
developing
into seed
Developing
seed coat
Embryo
Endosperm (3n)
Carpel
prior sporophyte generation
degenerating gametophyte generation (developing
fruit)
next sporophyte generation
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Fruits
The ovary wall is termed the pericarp
-Has three layers: exocarp, mesocarp and
endocarp
-Their fate determines the fruit type
Fruits can be:
-Dry or fleshy
-Simple (single carpel), aggregate (multiple
carpels), or multiple (multiple flowers)
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True Berries
The entire pericarp
is fleshy, although
there may be a thin
skin. Berries have
multiple seeds in
either one or more
ovaries. The
tomato flower had
four carpels that
fused. Each carpel
contains multiple
ovules that develop
into seeds.
Outer pericarp
Fused
carpels
Seed
Legumes
Split along two carpel edges (sutures) with seeds attached
to edges; peas, beans. Unlike fleshy fruits, the three tissue
layers of the ovary do not thicken extensively. The entire
pericarp is dry at maturity.
Stigma
Pericarp
Seed
Style
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Drupes
Single
Pericarp
seed
Exocarp (skin)
enclosed
Mesocarp
in a hard
Endocarp (pit)
pit; peaches,
plums, cherries.
Each layer of the
pericarp has a
different structure
and function, with
the endocarp forming
Seed
the pit.
Samaras
Not split and
with a wing
formed from the
outer tissues;
maples, elms,
ashes.
Seed
Pericarp
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Aggregate Fruits
Derived from
many ovaries of
a single flower;
strawberries,
blackberries.
Unlike tomato,
these ovaries
are not fused
and covered by
a continuous
pericarp.
Sepals of a
single flower
Seed
Ovary
Multiple Fruits
Individual flowers
form fruits around
a single stem. The
fruits fuse as seen
with pineapple.
Pericarp of
individual flower
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Main stem
Fruits
Developmentally, fruits are fascinating organs
that contain 3 genotypes in one package:
-The fruit and seed coat are from the prior
sporophyte generation
-The developing seed contains remnants of
the gametophyte generation
-The embryo represents the next
sporophyte generation
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Fruit Dispersal
Occurs through a wide array of methods
-Ingestion and transportation by birds or
other vertebrates
-Hitching a ride with hooked spines on
birds and mammals
-Burial in caches by herbivores
-Blowing in the wind
-Floating and drifting on water
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Germination
Germination is defined as the emergence of
the radicle (first root) from the seed coat
Germination begins when a seed absorbs
water & oxygen is available for metabolism
-Often requires an additional environmental
signal such as specific wavelength of light
-Or appropriate temperature
-Or stratification (period of low
temperature exposure
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Germination
Germination can occur over a wide
temperature range (5o-30oC)
Some seeds will not germinate even under he
best conditions
-The presence of ungerminated seeds in
the soil of an area is termed the seed bank
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Germination
Germination requires energy sources such as:
-Starch stored in amyloplasts, proteins, or
fats and oils
In cereal grain kernels, the single cotyledon is
modified into a massive scutellum
-Its abundant food is used first during
germination
-Later it serves as a conduit from the
endosperm to the rest of the embryo 46
Germination
Embryo produces gibberellic acid
-This hormone signals the aleurone (outer
endosperm layer) to produce a-amylase
-Breaks down the endosperm’s starch
into sugars that are passed to embryo
Abscisic acid, another hormone, can inhibit
starch breakdown
-Establishes dormancy
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1. Gibberellic acid (GA) binds
Pericarp
to cell membrane receptors
on the cells of the aleurone
layer. This triggers a signal
transduction pathway.
Aleurone
Signaling pathway
GA receptor
DNA
GA
Endosperm
Aleurone cell
Starch
a-amylase
Sugars
Gibberellic
acid
2. The signaling pathway
leads to the transcription of
a Myb gene in the nucleus
and translation of the Myb
RNA into Myb protein in
the cytoplasm.
Myb protein
Transcription
and translation
Transcription and translation
3. The Myb protein then
Embryo
Scutellum
(cotyledon)
enters the nucleus and
activates the promoter for
the a-amylase gene,
resulting in the production
and release of a-amylase.
a-amylase
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Germination
As the sporophyte pushes through the seed
coat, it orients with the environment such
that the root grows down & shoot grows up
-Usually, the root emerges before the shoot
-The shoot becomes photosynthetic, and
the postembryonic phase is under way
Cotyledons may be held above or below the
ground
-May become photosynthetic or shrivel 49
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First leaves
Plumule
Epicotyl
Cotyledon
Hypocotyl
Hypocotyl
First leaf
AdventiColeoptile Scutellum tious root
Withered
cotyledons
Seed coat
Primary roots Secondary roots
a.
Coleorhiza
Radicle
Primary root
b.
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