CHAPTER 2 –
SEXUAL REPRODUCTION INFLOWERING PLANT 
FLOWERS : modified shoot, Site of sexual Reproduction. Male and female reproductive organs are borne on flowers
PARTS OF A FLOWER: Four whorls-
· Calyx (sepals): green in colour, protects the bud.
· Corolla (petals): colourful, attracts insects for pollination.
· Androecium (Male reproductive organ),
· Gynoecium (Female reproductive organs) Calyx & corolla: accessory whorl.
Androecium & gynoecium: Essential whorl.
Male Reproductive Organ
· Androecium consists of Stamens.
· Stamen consists of anther, filament & connective (when anther is bilobed)
· Anther: bilobed
(two theca) has 4 microsporangia.
MICROSPOROGENESIS: The process of formation of micro spores from pollen mother cell (2n) through meiosis.
Microsporangium is 4 layered:
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Epidermis:
single
outer layer Endothecium: dehiscence of
anther Middle
layer: 2-4 layered, crushes when sporogenous tissue mature. Tapetum:
dense
cytoplasm & multinucleate, Nourishes
the developing pollen grain & formation of pollen wall, |
Microspore
mother cell (2n) Meiosis Microspore (n) Mitosis Pollen grains
(n) |
 |
Pollen grains: Male gametophyte, size-25-50 µm. Two layered: -
· Exine: Exine is made of sporopollenin. (Hardest natural substance).
· Intine: Intine is made of cellulose and pectin.
Pollen Maturation: Mature pollen grains have two cells large vegetative cell & small generative cell.
Generative cell forms two male gametes by mitotic division.
Pollen grains shed in 2-celled / 3celled stage
(See Fig 2.5 a
and b page 23 NCERT)
Gynoecium / carpel (the
female reproductive organ)
(Structure of anatropous ovule) / Megasporangium
· Apocarpus : free carpel
· Syncarpus : fused carpel
· Monocarpellary: single carpel
· Multicarpellary : Many carpel.
· Each Carpel consists of ovary, style & stigma.
· Ovules are attached to ovary by placenta.
· Funicle – stalk of ovule
· Hilum, a region where funicle is attached
· Integuments –cover embryo sac.
· Micropyle – a pore for entry of pollen tube.
· Embryo Sac: Female gametophyte
· Nucellus: it covers embryo sac, seed up to maturation.
Megasporogenesis-
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· The formation
of megaspore from the megaspore mother cell –MMC (2n) is called
megasporogenesis. · In megaspore
tetrad, 3 degenerate & one functional megaspore develops into female
gametophyte (embryo sac). · Embryo sac
(Polygonum type) - 8 nucleate & 7 celled. · Synergid cell have special cellular thickening at the micropylar tip called filiform apparatus, which play an imp. role in guiding the pollen tube into the synergid.  |
MEGASPOROGENESIS  |
POLLINATION– transfer of pollen from anther to stigma. Agents of pollination –air, water, insect, bat, bird, man.
Type of pollination-
a. Self-pollination (Autogamy)- Auto gamy (Same flower), Geitenogamy Different flowers same plant
b. Cross pollination (Hetrogamy) -Xenogamy (different flowers on different plants of the same species)
Autogamy: Chasmogamous flower-exposed anther and stigma. E.g.-
Viola, Commelina, Oxalis. Cleistogamous flower: anther
and stigma-closed. It assured seed set in the absence of pollinator.
e.g.,- Viola,
Oxalis.
Adaptation
for pollination
|
Wind
pollination |
Water pollination |
Insect pollination |
|
Pollen grains – light,
non-sticky, colourless, well exposed stamens, feathery stigma & numerous flower. |
Pollen grains protected by
mucilaginous covering, long stalk & long coiled style. |
Colorful & showy
flower, high fragrance, produce nectar, sticky pollen grains & stigma. |
Special
type of Pollination:
A. Amorphophallus (flower
height-6 feet), provides safe place for lay eggs of insects.
B. A moth deposits eggs in the locule of ovary of Yucca plant & inturn pollinates Yucca.
Out Breeding Devices: to promote cross pollination because self-pollination results in inbreeding depression.
· Heterostyly: Different size of style & stamens eg. Primula (Pin & Thrum flowers)
· Herkogamy: Anatomical barrier eg. Calotropis procera.
· Self-Sterility: Pollens do not germinate on stigma of self-flower eg. Malva
· Protandry: anther mature before pistel eg. Hibiscus rosa sinensis
.· Protogyny: Pistil matures before anther eg. Aristolochia
Self-Incompatibility: Pollen &
stigma of same flower & same plant rejects to each other .
Pollen Pistel Interaction: Stigma have the ability to recognize the right type of pollen it
rejects the pollen grains of other species & also the incompatible pollens
of the species.
Artificial Hybridization: it is a major
approach to crop improvement programme. It is achieved by -
i) Emasculation: Removal
of anthers from the flower bud of a bisexual flower before the anther dehisces using a pair of forceps.
ii) Bagging -
covering the emasculated flowers with a bag of
suitable size to protect them from contamination with unwanted pollen.
iii). Rebagging : Mature
pollen grains collected from anther of the male plant & dusted on stigma,
and the flowers are rebagged and the fruits allowed to develop.
Double fertilization
Fertilization is the process of fusion of male & female gametes
(n+n) to form a diploid (2n) zygote.
First
fertilization: Fusion of male gamete with egg is called SYNGAMY & develops embryo
(2N) Second fertilization: Fusion of
polar nuclei with 2nd male gamete is called TRIPLE FUSION &
develops PEN (3N).
Since two types of fusions, syngamy & triple fusion takes place in an embryo sac the phenomenon is termed as double fertilization.
C.
Post fertilization changes:
1. Endosperm: 3 type of endosperm development
i).
Nuclear: PEN successive nuclear divisions to give rise free
nuclei
eg. Coccus
, Areca catechu (betal nut).
ii). Cellular:
Wall formation occurs after every division of PEN eg. Annona squamosa, Adoxa.
iii) . Helobial : both type of development is present (nuclear & cellular) eg. Monocots.
Embryo development:
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1. Zygote divides
by mitosis into suspensor & embryo cells 2. Suspensor cell forms a globular basal cell which remains embedded in
the endosperm & a multicellular suspensor bearing the embryo 3.Globular embryo
becomes heart-shaped & then mature embryo with radicle, plumule & Cotyledons. Scutellum : Monocot
embryo |
|
|
DICOT
EMBRYO |
MONOCOT EMBRYO
GRASS |
|
Difference
between:
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EPICOTYL |
HYPOCOTYL |
|
·
Area of embryo axis between the plumule & cotyledonary node. · In hypogeal germination epicotyls elongates & seeds
remain underground. |
·
Area of embryo axis between the radicle & cotyledonary node. · In epigeal germination, hypocotyls elongate &
push the seed out of soil. |
|
COLEOPTILE |
COLEORHIZA |
|
· Covering of plumule in monocots. ·
Coleoptile breaks grain covering and
elongates. · It turns in green. · It protects plumule during emergence from soi. |
· Covering of radicle in monocots. ·
It breaks grain covering but stop further growth · It remains inside
soil. · No such function. |
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PERISPERM |
PERICARP |
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· It is a part of seed. · It is Remnant of nucellus. · Dry ·
No significant importance ·
Eg. Black pepper, beet |
· It is a part of
fruit. ·
It is ovary wall (epicarp, mesocarp & endocarp). · Dry / fleshy · Protection, dispersal and nutrition of seed. · Eg. Mango |
|
TRUE FRUITS |
FALSE FRUITS |
|
True Fruit develops only from the ovary, e.g.
mango, tomato |
False
Fruit develops from parts of the flower other than the ovary e.g. apple, peach etc |
|
Albuminous Seed |
Non albuminous seed |
|
·
Seed retains endosperm as it is
not completely used up during embryo development. ·
Eg. Wheat, maize, barley, sunflower,
castor. |
·
Seeds do not retain endosperm as
it is completely utilized during embryo development. ·
Eg. Pea, groundnut. |
|
Apomixis |
Parthenogenesis |
|
· It is a asexual reproduction
which mimics sexual reproduction where seeds are formed without fertilization
from diploid egg cell and other cells of nucellus. |
·
Development of haploid female
gamete (egg cell) into an adult
without fertilization. |
Significance of fruit formation:
·
The fruits protect the seeds from unfavorable
climatic conditions.
·
Both fleshy and dry fruits help in the dispersal of
seeds to distant places.
·
source of many chemicals like sugars, protein, oil,
organic acids, vitamins and minerals.
·
provide nutrition to the developing seedlings.
Importance of Apomixis:
Since apomictic seed are produced asexually so they
maintain their agronomic characters. So they are used in hybrid seed industry,
floriculture, horticulture.
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