Sexual Reproduction in Flowering Plants | CBSE Biology Class XII Notes

 ➢   FLOWER

✔       Reproductive unit of the flowering plants.

✔       Atypical bisexual flower consists of 4 different whorls – calyx, corolla, androecium and gynoecium.

✔       Calyx – outermost whorl consists of sepals.

✔       Corolla – composed of petals that are usually brightly colored.

✔       Androecium – represents the male reproductive organ.

o   Composed of stamens.

o   Each stamen is made up of Anther and a stalk / filament.

✔       Gynoecium – represents the female reproductive organ

o   Composed of carpels.

o   Carpels have 3 parts- stigma, style and ovary.

o   Ovary is the basal enlarged portion.

o   Style is the tubular structure that connects the stigma to the ovary.

o   Stigma is the tip of the style that typically acts as the receptive surface for the pollen grains.

o   Monocarpellary: gynoecium consisting of a single pistil.

o   Multicarpellary: gynoecium consisting of more than one pistil.

o   Syncarpous: When carpels are fused.

o   Apocarpous: When carpels are free

➢   PRE-FERTILIZATION: STRUCTURE AND EVENTS

➢   Stamens, Microsporangium and Pollen Grains

✔       Structure of stamen – Consists of 2 parts:

o   Filament- Long, slender stalk

o   Anther- Terminal, bilobed structure

✔       Proximal end of filament is attached to the base of the flower (thalamus).

✔       Structure of Anther – Bilobed (2 parts of anther) and dithecous (Each lobe has 2 theca)

o   A longitudinal groove separates the two theca.

o   Due to the bilobed & dithecous nature the anther is tetragonal (four sided) structure.

o   Each of the corners consists of one microsporangia, i.e. 2 microsporangia are present in each of the theca.

o   Microsporangia develops into pollen sacs that contain the pollen grains.

➢  Structure of Microsporangia:

✔       In young anthers, each of the microsporangium is composed of sporogenous tissue surrounded by a total of 4 layers.

✔       The outer 3 layers (epidermis, endothecium & middle layer) perform the function of protection.

✔       The innermost layer (Tapetum) helps in nourishing the developing pollen grains.

✔       Nature of the cells of Tapetum

o   Dense cytoplasm

o   Possess more than one nucleus.

➢   Microsporogenesis

✔       Each of the cells of the sporogenous tissue acts as the pollen mother cell (PMC) or microspore mother cell.

✔       The process of formation of microspore from PMC is called microsporogenesis.

✔       The PMC undergoes meiotic cell division to form microspore tetrads (haploid cells arranged in a cluster of 4 cells).

✔       The microspores dissociate from each other and give rise to the pollen grain as the anther matures and dehydrates.

➢   Male Gametophyte (Pollen Grains)

✔       It represents the male gametophyte.

✔       They have 2 layered walls.

o   Exine – outer layer, made up of sporopollenin.

▪    Sporopollenin is resistant to high temperatures and strong acids and alkali.

▪    They are also resistant to degradation by enzymes.

▪    Due to this the pollen grains are well preserved as fossils.

▪    Germ pore: Prominent aperture in the exine where the sporopollenin is absent.

▪    Germ pore is essential for the pollen germination.

o   Intine – inner thin layer, made up of cellulose and pectin.

✔       Cytoplasm of the pollen grain is surrounded by plasma membrane.

✔       Matured pollen grains have 2 cells

o   Vegetative cell –

▪    Bigger cell

▪    Abundant food reserve

▪    Large irregular shaped nucleus

o   Generative cell

▪    Smaller cell

▪    Floats in the cytoplasm of the vegetative cell

▪    Dense cytoplasm

✔       In 60% angiosperms the pollen grains are released in 2 celled stage, while in the remaining 40% it is released in a 3 celled condition (generative cell divides mitotically to give rise to the two male gametes).

✔       Pollen grains can cause allergies and bronchial afflictions (infections), leading to asthma, bronchitis, etc. E.g. Parthenium or carrot grass

✔       Pollen products: pollen grains are rich in nutrients

o   Available in the form of tablets & syrups.

o   It can increase the performance of athletes & race horses

✔       Pollen Viability:

o   30 Minutes: Cereals like Rice & Wheat.

o   Months: Members of Solanaceae, Rosaceae, Leguminoseae.

o   Years: Artificial means- Liquid Nitrogen (-196⁰C)

➢   The Pistil, Megasporangium (ovule) and Embryo sac

✔       Each pistil consists of the stigma, style and ovary.

✔       The ovary contains the ovarian cavity (locule).

✔       The megasporangia (ovules) are located inside the ovarian cavity connected by placenta.

✔       The number of ovules depends on the plant species:

o   One: wheat, paddy, mango

o   Many: Papaya, water-melon, orchids

➢   Structure of Megasporangium (Ovule)

✔       Ovule connects with the placenta via a stalk called funicle.

✔       Hilum is the junction funicle and ovule.

✔       The protective layers of the ovule are called the Integuments (1 or 2 layers).

✔       Inner to the integuments are the nucellus.

✔       Integuments are present all around the nucellus except at a small opening called the micropyle.

✔       Chalaza end represents the basal part of the ovule, and is opposite to the micropylar end.

✔       The female gametophyte (embryo sac) is located inside the nucellus.

✔       Generally, the ovules have a single embryo sac.

✔       The embryo sac develops into the megaspore.

✔       Nucellar cells are rich in reserve food materials.

✔       The nucellus provides nutrition to the developing embryo sac.

➢   Megasporogenesis

✔       The process of formation of the megaspore from the megaspore mother cell is called megasporogenesis.

✔       A single megaspore mother cell (MMC) is formed in the micropylar region of the nucellus of the megasporangium (ovule).

✔       The MMC undergoes meiotic cell division resulting in 4 megaspores.

➢   Female Gametophyte (Embryo sac)

✔       The development of the embryo sac in the majority of the flowering plants follows the monosporic development process.

✔       Out of the 4 megaspores only one remains functional while the remaining three degenerates.

✔       Only the functional megaspore develops into female gametophyte.

✔       The functional megaspore undergoes free nuclear cell division.

✔       Three mitotic nuclear divisions of the functional megaspore nucleus give rise to a 8 nucleate stage of embryo sac.

✔       After this stage the six of the eight nuclei are surrounded by cell walls and are organized into six different cells.

o   3 of these cells move towards the chalazal end are called the antipodals.

o   The remaining 3 cells move to the micropylar end and form the egg apparatus.

▪    Egg apparatus consists of the egg cell and two synergids.

▪    The synergids have special cellular thickenings called the filiform apparatus.

✔       The remaining two nuclei (polar nuclei) are placed in the large central cell.

✔       As a result of this organization, a typical angiospermic embryo sac, at maturity is 7-celled but 8-nucleate.

➢   Pollination

✔       In the case of plants both gametes are non-motile.

✔       The transfer of pollen grains to the stigma of the pistil of the same flower or another flower is called pollination.

✔       This process occurs with the help of external agents – pollinating agents.

Pollination Types: Based on the source of pollination.

✔       Autogamy : (Self-pollination)

o   Involvement of a single flower.

o   Pollen grains are transferred from the anther to the stigma of the same flower.

o   Complete autogamy is rare in a flower remains open with exposed anther and stigma.

o   Criteria for autogamy.

▪    Synchrony in pollen release and stigma receptivity.

▪    Close proximity of the anther and stigma.

o   Plants with 2 types of flower – Viola (common pansy), Oxalis, and Commelina

▪    Chasmogamous Flower: (Regular flower with exposed anther & stigma)

▪    Cleistogamous Flower: (Flowers do not open at all)

●    Anther and stigma lie close to each other.

●    Pollen falls directly on the stigma upon pollen dispersal.

●    No need of the pollinating agents

●    No chance of cross pollination.

●    Advantage of Cleistogamous flower:

o   Production of assured seed-set even in the absence of pollinators.

●    Disadvantage of Cleistogamous flower:

o   Due to self-pollination variation may not be created.

o   Prevent the evolution of genetically superior variety.

✔       Geitonogamy : (Cross  pollination involving one plant)

o   Pollen grains are transferred from the anther of one flower to the stigma of another flower but from the same plant.

o   It is functionally cross pollination.

o   Genetically it is similar to autogamy as pollen grain is from one plant.

✔       Xenogamy : (Cross  pollination involving different plant)

o   Pollen grain is transferred from anther of one flower to the stigma of another flower of a different flower.

o   Unites genetically different types of pollen grains.

Agents of Pollination

✔       Biotic pollinating agents – living organisms: [used by majority of plants]

✔       Abiotic pollinating agents – Wind and Water

✔       Why do plants produce a large amount of pollen grains compared to the numbers of ovules available for pollination??

o   Ans- As the event of pollen grain coming in contact with the stigma is a chance factor, to compensate this uncertainty and the probable loss of pollen large amounts of pollen grain is released.

Pollination by wind – Anemophily

✔     Common in grasses.

✔     Nature of Flower:

o   Pollen grains are lightweight.

o   The pollen is non-sticky.

o   Well exposed stamen.

o   Large feathery stigma.

o   Inflorescence consists of numerous flowers.

▪    Example- corn cob

Pollination by Water – Hydrophily

✔       Rare – limited only to 30 plant genera (mostly monocotyledons)

✔       Example- Vallisneria and Hydrilla (Fresh water), Zostera (marine sea-grass)

✔       Pollination in Vallisneria :

o   Female flower reaches the top of the water surface

o   Male flower/pollen grains released on the water surface

o   The pollen grains reach the stigma via passive water current.

✔       Pollination in Seagrasses :

o   The female flower remains submerged in the water.

o   Pollen grains (long & ribbon shaped) are released inside the water.

o   Pollen grains reach the stigma via passive water current and achieve pollination.

✔       Property of pollen grain in water pollinated plant species

o   Presence of protective mucilaginous covering that prevents them from wetting.

✔       Aquatic plants like water hyacinth and water lily – follow pollination by insects or wind, as the flower reaches the water surface.

Pollination by Biotic organisms

✔       Pollinating agents include- Bees, butterflies, flies, beetles, wasps, ants, moths, birds (sunbirds and hummingbirds) and bats.

✔       Among the animals, insects, particularly bees are the dominant biotic pollinating agents.

✔       Other organisms – primates (lemurs), arboreal (tree-dwelling) rodents, or even reptiles (gecko lizard and garden lizard).

✔       Nature of flower :

o   Large flowers

o   Colorful

o   Fragrant and rich in nectar

o   Pollen grains are sticky

o   In the case of small flowers- many are clustered into an inflorescence.

✔       Animals are attracted towards flowers due to the foul odours.

✔       Floral rewards are provided to sustain the animal visit.

o   Pollen and nectar are floral rewards

✔       When the pollinator visits the flower to harvest the floral reward the body of the pollinator gets a coating of the pollen.

✔       When these animals come in contact with stigma it brings about the pollination.

✔       Floral rewards as a safe place to lay egg

o   E.g.-Amorphophallus – tallest flower

o   E.g.- Yucca plant and a moth species.

▪    They can’t complete their life cycle without each other

▪    Moth deposits the egg in the locule of ovary

▪    The flower in turn gets pollinated by the moth

▪    The moth larva comes out of the eggs as the seeds start developing.

➢   Outbreeding Devices:

✔       Continued self-pollination result in inbreeding depression.

✔       As majority of the flowers are bisexual, there is a need for the plants to develop methods by which it can prevents self-pollination and promote cross pollination.

✔       The outbreeding devices enables them to achieve it.

o   Pollen release and stigma receptivity are not synchronized,

o   Different position of the stigma and the anther so that the pollen grains do not come in contact with the stigma

o   Self-incompatibility: genetic mechanism that prevents the self-pollen from pollen germination or pollen tube growth.

o   Production of unisexual flowers.

✔       In case of monecious plants (maize, castor) where both the male and female flowers are present on the same plant – it prevents autogamy but not geitonogamy.

✔       In case of dioecious plants (papaya) where both the male and female flowers are on different plants – it prevents both autogamy and geitonogamy.

➢   Pollen-pistil interaction

✔       All the events–from pollen deposition on the stigma until pollen tubes enter the ovule–are together referred to as pollen-pistil interaction.

✔       Pollination might lead to the deposition of pollen grains of various plant species.

✔       The process of pollination does not guarantee fertilization.

✔       Only if the right type of pollen (compatible pollen grain of the same species) is landing on the stigma, it might lead to fertilization.

✔       If the pollen grain is the right type (compatible) then the post-pollination events continue leading to fertilization.

✔       If the pollen grain is the wrong type (incompatible) the pistil rejects it.

✔       An incompatible pollen is rejected by:

o   Prevention of pollen germination

o   Prevention of pollen tube growth

✔       The decision of compatible and non-compatible pollen is due to the continuous chemical talk between the pollen grain and the pistil.

✔       Pollen germination:

o   Compatible pollen grain germinates to form pollen tubes through germ pore.

o   The content of the pollen grain moves into the pollen tube.

✔       Pollen tube travels through the style and reaches the ovary.

✔       It enters the ovule through the micropyle and then enters one of the synergids through the filiform apparatus.

✔       The filiform apparatus guides the entry of the pollen tube.

➢   Artificial Hybridization:

✔       These refer to the crossing experiments in plants where only the desired pollen grains are used for pollination and the stigma is protected from contamination of unwanted pollen grains.

✔       It is one of the major approaches in the crop improvement program.

✔       Steps:

o   Emasculation: Removal of anthers (in case of bisexual flower) before the dehiscence of anther.

▪    In case of unisexual flower this step is not necessary.

o   Bagging: Covering of the emasculated flower with a bag (butter paper) of suitable size to prevent contamination of stigma by unwanted pollens.

o   Controlled pollination: When the stigma matures, the matured pollen from a desired male parent is dusted on it and the flower is rebagged and further development is allowed.

➢   DOUBLE FERTILIZATION

✔       The pollen tube releases two male gametes to the cytoplasm of the synergids.

✔       One male gamete fuses with the nucleus of the egg forming a diploid cell called zygote.

o   This fertilization event is called syngamy.

✔       The remaining male gamete fuses with the two polar nuclei of the central cell and produces primary endosperm nucleus (PEN) that is triploid in nature.

o   This fertilization event is called triple fusion as it involves the fusion of 3 haploid nuclei.

✔       As there are two fertilization events taking place at the same time in the embryo sac, this phenomenon is called double fertilization.

o   This event is unique to the angiospermic plants.

✔       Fate of double fertilization:

o   The central cell after triple fusion becomes the Primary endosperm cell and develops into Endosperm.

o   The zygote divides and develops into the embryo.

➢   POST FERTILIZATION: STRUCTURE AND EVENTS

✔       This phase involves the following:

o   Endosperm development

o   Embryo development

o   Maturation of ovules into seeds

o   Maturation of ovary into fruits

➢  Endosperm

✔       Development of the endosperm starts prior to the embryo development.

o   The PEN divides and forms the endosperm tissue.

o   The cells are filled with reserve food materials.

o   They provide nutrition to the developing embryo.

✔       Endosperm development:

o   PEN undergoes repeated division to give rise to the free nuclei (free nuclear endosperm)

o   The free nuclear endosperm forms the cellular endosperm when they undergo cellularization.

✔       Example – Coconut

o   Free nuclear endosperm: tender coconut water

o   Cellular endosperm: white kernel (edible part)

➢   Embryo

✔       The embryo develops from the zygote in the micropylar region of the embryo sac.

✔       Stages of embryogeny (embryo development):

o   Proembryo

o   Globular stage

o   Heart-shaped stage

o   Mature embryo

✔       Component of dicot embryo:

o   an embryonal axis and two cotyledons

o   Epicotyl: portion of embryonal axis above the level of cotyledons.

▪    Terminates with Plumule (future shoot)

o   Hypocotyl: Cylindrical portion below the level of cotyledons.

▪    Terminates with radicle (future root)

▪    The root tip (radicle) is covered with root cap.

✔       Monocot Embryo:

o   Consists of only one cotyledon

o   Scutellum: Cotyledons of grass family

o   Coleorrhiza:  Sheath of the radical and root cap

o   Coleoptile: Hollow foliar structure that encloses the shoot apex and few leaf primordia.

➢   Seed

✔       Developed from the fertilised ovule.

✔       Components of seed:

o   seed coat(s)

o   cotyledon(s)

o   an embryo axis.

✔       Non-albuminous seeds:

o   Matured seeds with no residual endosperm

o   E.g.- Pea, Groundnut

✔       Albuminous seeds:

o   Matured seeds with residual endosperm

o   E.g.- wheat, maize, barley, castor

✔       Perisperm: The residual, persistent nucellus in seeds.

o   E.g.- black pepper, beet

✔       Seed Development:

o   Seed coat develops as the integuments hardens.

o   Micropyle remains as a small pore in the seed coat.

▪    Essential to facilitate the entry of oxygen and water for seed germination.

o   When the seed matures, it becomes dry & the metabolic rate of the embryo slows down.

o   At this stage the embryo enters the dormancy stage.

➢   Fruit

✔       It is developed from the ovary.

✔       The ovarian walls develop into the fruit wall.

✔       Types of fruit

o   Fleshy fruit : guava, orange, mango, etc.,

o   Dry fruit : groundnut, and mustard, etc.

o   True fruit: when fruit is developed from ovary

▪    E.g.- Mango, Pea, etc.,

o   False fruit: fruit developed from parts other than ovary like thalamus

▪    E.g.- apple, strawberry, cashew, etc.,

➢  PARTHENOCARPY

✔       Development of fruit without fertilization.

✔       The fruit developed by this process is called parthenocarpic fruit.

✔       They are generally seedless.

✔       E.g.- pineapple, banana, cucumber, grape, orange, etc.

✔       Can be induced with the help of hormones.

➢  Advantage of seeds:

✔       Pollination and fertilization are independent of water, seed formation is more dependable.

✔       seeds have better adaptive strategies for dispersal to new habitats.

✔       They can nourish the young seedlings as they are rich in reserve food materials.

✔       The Hard seed coat provides protection to the embryo.

✔       Produce new genetic combinations leading to variations, as they are the product of sexual mode of reproduction.

➢   Seed Viability:

✔       Ability of seed to remain alive after their dispersal.

✔       It can be a few months to several years.

✔       Oldest recorded Viable Seed: Lupine(Lupinus arcticus) excavated from Arctic Tundra.

o   10000 years of dormancy.

✔       Date Palm (Phoenix dactylifer) : 2000 years old viable seed

➢  APOMIXIS & POLYEMBRYONY

➢   Apomixis

✔       It is a form of asexual reproduction that mimics sexual reproduction.

✔       Process of production of seeds without fertilization.

✔       Example- Some species of Asteraceae and grasses.

✔       Method-1:

o   Diploid egg cell is produced without reduction division and it develops onto embryo without fertilization.

✔       Method-2:

o   Nucellar cells surrounding the embryo sac starts dividing, protrudes into the embryo sac and develop into embryo. (Citrus, Mango)

o   Such cases each ovule have more than one embryo – POLYEMBRYONY

➢  Hybrid Seeds and Apomixis

✔       Cultivation of hybrids has tremendously increased productivity

✔       Problems with Hybrid Seeds:

o   Hybrids seeds has to be produced every year.

o   Seeds obtained from hybrid plants when grown, tend to segregate and loose the hybrid traits.

o   Cost factor

✔       Solution to this problem

o   Apomictic Hybrid Seeds

o   As there is no fertilization, there will be no segregation in the hybrid progeny.

o   The farmer can use the apomictic hybrid seeds for many years to raise the crop and need not buy the seed every year.

✔       Because of its importance there is active research going on to understand the genetics of apomixis and to transfer apomictic genes into hybrid varieties.

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