pollen Pistil Interaction and how fertilisation takes place
yogeshhedjk
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Sep 10, 2024
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About This Presentation
pollen Pistil Interaction and how fertilisation takes place
Slide Content
Pollen – pistill interaction and
fertilization
fertilization
Content:
About pollen grains
Stucture of stigma
Pollen pistill interaction
Self incompatibility
Fertilization
About pollen grains
Stucture of stigma
Pollen pistill interaction
Self incompatibility
Fertilization
•The wall of a pollen grain is quite complex structurally.
•It has an inner layer called the intine, composed of
cellulose, and an outer layer called the exine that
consists of the polymer sporopollenin.
•It has one or several weak spots, germination pores,
where the pollen opens after it has been carried to the
stigma of another flower.
Pollen grains
•It has an inner layer called the intine, composed of
cellulose, and an outer layer called the exine that
consists of the polymer sporopollenin.
•It has one or several weak spots, germination pores,
where the pollen opens after it has been carried to the
stigma of another flower.
Pollen grains
•Sporopollenin is remarkably
waterproof and resistant to almost
all chemicals.
•It protects the pollen grain and
keeps it from drying out as it is
being carried by wind or Animals.
•The exine can have ridges, bumps, spines, and numerous other
features so characteristic that each species has its own particular
pattern .
•In many cases, it is possible to examine single pollen grain
and know exactly which species of plant production it.
waterproof and resistant to almost
all chemicals.
•It protects the pollen grain and
keeps it from drying out as it is
being carried by wind or Animals.
•The exine can have ridges, bumps, spines, and numerous other
features so characteristic that each species has its own particular
pattern .
•In many cases, it is possible to examine single pollen grain
and know exactly which species of plant production it.
•Because sporopollenin is so resistant, pollen grains and their
characteristic patterns fossilize well.
•By examining samples of old soil, botanists can determine
exactly which plants grew in an area at a particular time in
the ancient past.
characteristic patterns fossilize well.
•By examining samples of old soil, botanists can determine
exactly which plants grew in an area at a particular time in
the ancient past.
•For the study of pollen-pistil interactions
and incompatibility responses, it is
necessary to have a detailed
understanding of the stigmatic surface
which receives pollen grains.
•The surface cells of the area which
receives pollen are more or less
glandular and frequently elongated
unicellular or multicellular papillae.
The stigma structure
and incompatibility responses, it is
necessary to have a detailed
understanding of the stigmatic surface
which receives pollen grains.
•The surface cells of the area which
receives pollen are more or less
glandular and frequently elongated
unicellular or multicellular papillae.
The stigma structure
There are usually two basic types of stigma :
(i)the dry type – where papillae are free from any apparent
exudates .
(ii) the wet type – where the receptive surface is covered
With exudates .
(i)the dry type – where papillae are free from any apparent
exudates .
(ii) the wet type – where the receptive surface is covered
With exudates .
•The dry stigmas are dry only in relative sense, since the papillae
bear a hydrated proteinaceous covering over the cuticle,called
pellicle.
•The families with dry stigmas,such as brassicaceae, and
Asteraceae,pellicle does not show enzymatic properties.
•The cuticle,underlying the pellicle,is made of short radially
directed rodlets with intervening discontinuities.
bear a hydrated proteinaceous covering over the cuticle,called
pellicle.
•The families with dry stigmas,such as brassicaceae, and
Asteraceae,pellicle does not show enzymatic properties.
•The cuticle,underlying the pellicle,is made of short radially
directed rodlets with intervening discontinuities.
•In wet stigmas, secretions continue to accumulate throughout
the life of the stigma and these secretions from a medium in
which the captured pollens germinate.
•In some genera there is an overlying lipid layer, forming " liquid
cuticle" The stigmatic exudates contain sugars, phenolic
compounds, many free amino acids and proteins.
•The viscosity of the exudates is due to the presence of
mucopolysaccharides.
•The aqueous phase of the stigmatic exudate shows non specific
esterase activity.
•Wet stigmas occur in many families, such as Solanaceae,
Liliaceae etc.
the life of the stigma and these secretions from a medium in
which the captured pollens germinate.
•In some genera there is an overlying lipid layer, forming " liquid
cuticle" The stigmatic exudates contain sugars, phenolic
compounds, many free amino acids and proteins.
•The viscosity of the exudates is due to the presence of
mucopolysaccharides.
•The aqueous phase of the stigmatic exudate shows non specific
esterase activity.
•Wet stigmas occur in many families, such as Solanaceae,
Liliaceae etc.
Pollen–pistil interactions
•As soon as a pollen grain lands on the stigma, it is hydrated.
•As a result of hydration, the exine and intine proteins are
released on the stigmatic surface.
•The pollen wall proteins bind to the pellicle within few minutes
of the contact and thereafter cannot be released readily by
leaching.
•The stigma surface pellicle thus forms a receptor site for the
pollen wall proteins.
•When pollen is compatible, erosion of the cuticle of the
stigma papilla begins beneath the emerging pollen tube.
•As soon as a pollen grain lands on the stigma, it is hydrated.
•As a result of hydration, the exine and intine proteins are
released on the stigmatic surface.
•The pollen wall proteins bind to the pellicle within few minutes
of the contact and thereafter cannot be released readily by
leaching.
•The stigma surface pellicle thus forms a receptor site for the
pollen wall proteins.
•When pollen is compatible, erosion of the cuticle of the
stigma papilla begins beneath the emerging pollen tube.
•This is the essential preliminary requirement to the penetration
of the pollen tube.
•In wet stigma, the cuticle generally ruptures during the
deposition of exudates and the pollen tube enters through the
pectocellulose layer.
•In hollow styles, the pollen tube grows through the stylar canal,
whereas in solid style, it traverses the intercellular spaces.
•During its course through the style, the pollen tube utilizes
nutrients from the pistil.
of the pollen tube.
•In wet stigma, the cuticle generally ruptures during the
deposition of exudates and the pollen tube enters through the
pectocellulose layer.
•In hollow styles, the pollen tube grows through the stylar canal,
whereas in solid style, it traverses the intercellular spaces.
•During its course through the style, the pollen tube utilizes
nutrients from the pistil.
•Pollination initiates many physiological and biochemical
changes in the pistil.
•This included increase in respiration, changes in RNA and
protein synthesis pattern and increase in the activity of
enzymes.
•Signals of compatible or incompatible Pollination are
transferred to the ovule even before the pollen tube is reached
there.
•For instance, in incompatible pollination, degeneration of one
of the synergids begins much before the entry of the pollen
tube in the ovules.
•Following pollination, signals are evidently passed to the style
and overy to initiate response in accordance with the
compatible or incompatible pollination.
changes in the pistil.
•This included increase in respiration, changes in RNA and
protein synthesis pattern and increase in the activity of
enzymes.
•Signals of compatible or incompatible Pollination are
transferred to the ovule even before the pollen tube is reached
there.
•For instance, in incompatible pollination, degeneration of one
of the synergids begins much before the entry of the pollen
tube in the ovules.
•Following pollination, signals are evidently passed to the style
and overy to initiate response in accordance with the
compatible or incompatible pollination.
when viable pollens of the same or other individuals of same
species prevent fertilization,it is known as intraspecific
incompatibility or self incompatibility.
Self – incompatibility is thus a device to promote cross
pollination. It ensures a certain degree of heterozygosity in a
population, which is a major factor in the evolution of the
species. It is extremely widespread among the flowering
plants.
Self incompatibility
On the basis of morphological features of the flower,self
incompatibility is of the following two types:
(a) Heteromorphic
(b) Homomorphic
species prevent fertilization,it is known as intraspecific
incompatibility or self incompatibility.
Self – incompatibility is thus a device to promote cross
pollination. It ensures a certain degree of heterozygosity in a
population, which is a major factor in the evolution of the
species. It is extremely widespread among the flowering
plants.
Self incompatibility
On the basis of morphological features of the flower,self
incompatibility is of the following two types:
(a) Heteromorphic
(b) Homomorphic
Heteromorphic
(a) Distyly : there are two types of style and stamens
●
Pin type: long style and short stamens (ss).
●
Thrum type : short style and long stamens
(Ss).
●
Pin × pin = ss × ss = incompatibility
●
Thrum × thrum = Ss × Ss = incompatibility
●
Thrum × pin = Ss × ss = compatibility
●
Pin× thrum = ss × Ss = compatibility
self-incompatibility is associated with the different
lengths of stamens and style on flowers on the same
plant, this is known as heteromorphic incompatibility.
(a) Distyly : there are two types of style and stamens
●
Pin type: long style and short stamens (ss).
●
Thrum type : short style and long stamens
(Ss).
●
Pin × pin = ss × ss = incompatibility
●
Thrum × thrum = Ss × Ss = incompatibility
●
Thrum × pin = Ss × ss = compatibility
●
Pin× thrum = ss × Ss = compatibility
self-incompatibility is associated with the different
lengths of stamens and style on flowers on the same
plant, this is known as heteromorphic incompatibility.
(b) Tristyly : when style has three different positions
Ex - Lythrum salicaria.
Ex - Lythrum salicaria.
Homomorphic
•Homomorphic incompatibility is characterised by the
occurrence of only one type of flowers in all the
individuals of a species. It is governed by multiple
alleles,called S alleles.
•Mating is not possible if the pollen carriers the same
S allele which is present in the female gamete.
A. Gamatopytic Self incompatibility
B. Sporophytic Self incompatibility
•Homomorphic incompatibility is characterised by the
occurrence of only one type of flowers in all the
individuals of a species. It is governed by multiple
alleles,called S alleles.
•Mating is not possible if the pollen carriers the same
S allele which is present in the female gamete.
A. Gamatopytic Self incompatibility
B. Sporophytic Self incompatibility
•Gametophytic self incompatibility - associated with pollen
with one generative nucleus in pollen tube Ex - Solanaceae
.
•Incompatible reaction is determined by its own genotype
and not by genotype of plant on which pollen produced .
•Three types of mating -
•Fully incompatible. Ex - S1S2 × S1S2
•Partially incompatible . Ex - S1S2 × S1S3
•Fully compatible . Ex - S1S2 × S3S4
with one generative nucleus in pollen tube Ex - Solanaceae
.
•Incompatible reaction is determined by its own genotype
and not by genotype of plant on which pollen produced .
•Three types of mating -
•Fully incompatible. Ex - S1S2 × S1S2
•Partially incompatible . Ex - S1S2 × S1S3
•Fully compatible . Ex - S1S2 × S3S4
•Sporophytic self incompatibility : Pollen grains of two
generative nuclei .
•The incompatible reaction of pollen is governed by the
genotype of plant on which pollen is produced and not by
genotype of the pollen. Ex - Brassicaceae ( cabbage famil) .
•Sporophytic incompatibility is governed by single gene ‘ S’.
•Homozygotes are normal part of systems.
•S1 Dominates S2 , S2 dominates S3 and so on…
•Three types of mating -
•Complete incompatibility. Ex - S1S2 × S1S2
•Complete incompatibility. Ex - S1S2 × S1S4
•Complete compatible. Ex - S1S2 × S2S3
generative nuclei .
•The incompatible reaction of pollen is governed by the
genotype of plant on which pollen is produced and not by
genotype of the pollen. Ex - Brassicaceae ( cabbage famil) .
•Sporophytic incompatibility is governed by single gene ‘ S’.
•Homozygotes are normal part of systems.
•S1 Dominates S2 , S2 dominates S3 and so on…
•Three types of mating -
•Complete incompatibility. Ex - S1S2 × S1S2
•Complete incompatibility. Ex - S1S2 × S1S4
•Complete compatible. Ex - S1S2 × S2S3
Fertilization
•The growing pollen tube penetrates
the stigmatic tissue and pushes its
way through the style and then
down the wall of the ovary.
•The style may be hollow or solid. If
it is hollow, then the pollen tube
grows along the epidermal surface
but in case of solid style, the pollen
tube travels through intercellular
spaces between the cells which lie
in its path.
•The growing pollen tube penetrates
the stigmatic tissue and pushes its
way through the style and then
down the wall of the ovary.
•The style may be hollow or solid. If
it is hollow, then the pollen tube
grows along the epidermal surface
but in case of solid style, the pollen
tube travels through intercellular
spaces between the cells which lie
in its path.
•After arriving in the ovary, the pollen tube finds its way into the
ovule. The pollen tube may enter into the ovule via three routes.
1.through the micropyle (Porogamy)
2.through the chalazal end (Chalazogamy
3.through the integument and funiculus (Mesogamy )
ovule. The pollen tube may enter into the ovule via three routes.
1.through the micropyle (Porogamy)
2.through the chalazal end (Chalazogamy
3.through the integument and funiculus (Mesogamy )
•the two synergids are identical before pollination and do not
show any signs of change. However, one of the synergids shows
structural malformations suggestive of disintegration prior to
the arrival of the pollen tube in the embryo sac.
•In fact, disintegration of the synergid is a consequence of
pollination, and the diversity of changes associated with
disintegration is most often initiated when the pollen tube is in
the style.
•When the pollen tube reaches the embryo sac, the tip of the tube
grows through the filiform apparatus into the degenerating
synergid.
show any signs of change. However, one of the synergids shows
structural malformations suggestive of disintegration prior to
the arrival of the pollen tube in the embryo sac.
•In fact, disintegration of the synergid is a consequence of
pollination, and the diversity of changes associated with
disintegration is most often initiated when the pollen tube is in
the style.
•When the pollen tube reaches the embryo sac, the tip of the tube
grows through the filiform apparatus into the degenerating
synergid.
•Immediately after releasing, the
male gametes show amoeboid
movement and one male gamete
moves toward the egg and other
one move to the polar nuclei.
•After passage through the
cytoplasm of the degenerating
synergid, pollen tube growth ceases
and then the tube discharges its
contents of sperm and cytoplasm
into this synergid
male gametes show amoeboid
movement and one male gamete
moves toward the egg and other
one move to the polar nuclei.
•After passage through the
cytoplasm of the degenerating
synergid, pollen tube growth ceases
and then the tube discharges its
contents of sperm and cytoplasm
into this synergid
•As the one of the male gametes reached the egg, it fuses with
it. As a result of this fusion diploid zygote (2n) forms (because
you know the egg and the male gamete, both are haploid). The
fusion of male and female gametes is known as fertilization.
This is also known as syngamy.
•The other male gamete fuses with the two polar nuclei (or
secondary nucleus, if the two have already fused) and so forms
triple fusion nucleus (3n), called primary endosperm nucleus.
•Thus in an embryo sac two sexual fusions occur; one is syngamy
(i.e. fusion of one male gamete with the egg) and another is triple
fusion (i.e. fusion of other male gamete with the polar nuclei or
secondary nucleus), and therefore, the phenomenon is known as
double fertilization.
it. As a result of this fusion diploid zygote (2n) forms (because
you know the egg and the male gamete, both are haploid). The
fusion of male and female gametes is known as fertilization.
This is also known as syngamy.
•The other male gamete fuses with the two polar nuclei (or
secondary nucleus, if the two have already fused) and so forms
triple fusion nucleus (3n), called primary endosperm nucleus.
•Thus in an embryo sac two sexual fusions occur; one is syngamy
(i.e. fusion of one male gamete with the egg) and another is triple
fusion (i.e. fusion of other male gamete with the polar nuclei or
secondary nucleus), and therefore, the phenomenon is known as
double fertilization.
Text book of botany structure, development and
reproduction in angiosperms. Authors: V. Singh, P. C.
Pande, D. K. Jain.
Botany : an introduction to plant biology / James D. Mauseth.
https://uou.ac.in/sites/default/files/slm/BSCBO-202.pdf
Reference:
reproduction in angiosperms. Authors: V. Singh, P. C.
Pande, D. K. Jain.
Botany : an introduction to plant biology / James D. Mauseth.
https://uou.ac.in/sites/default/files/slm/BSCBO-202.pdf
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