Flowers:
Flowers are modified shoots,
with a condensed axis known as thalamus and bearing appendages called floral
organs. They are meant essentially for sexual reproduction.
A typical flower is
hermaphrodite, i.e. bearing fertile organs of both male and female. The stalk
that bears the flower is condensed, so that the internodes become shorter and
the nodes come to lie close to each other. The tip of the stalk or receptacle
is swollen; and bears four different organs; from inside out: Sepals (calyx),
Petals (corolla), Stamens (Androecium) and Carpels (gynoecium). These floral
whorls are modified leaves.
The stamens
(Microsporophyll) and carpels (megasporophylls) are essential parts of flower.
They are directly involved in the process of reproduction. The remaining two
floral whorls sepals and petals are non essential and aid in the process of
reproduction.
Figure : Parts of a flower
The table describes the main parts of a flower and
their functions:
Structure
|
Function
|
Sepals
|
Protect the unopened
flower
|
Petals
|
May be brightly coloured
to attract insects
|
Stamens
|
The male parts of the
flower (each consists of an anther held up on a filament)
|
Anthers
|
Produce male sex cells
(pollen grains)
|
Stigma
|
The top of the female part
of the flower which collects pollen grains
|
Ovary
|
Produces the female sex
cells (contained in the ovules)
|
Nectary
|
Produce a sugary solution
called nectar, which attracts insects
|
TERMS RELATED TO FLOWER
·
Bracts: Bract is modified, usually reduced leaf like structure present
beneath flower or inflorescence. Flower with bracts is called bracteate
flower and without bracts are known as ebracteate. Bracts protect the flower in bud condition.
·
Based on attachment:
Pedicel: Stalk of
an individual flower
Peduncle: stalk of an inflorescence
Sessile: If pedicel absent
·
Complete/Incomplete Flower:
Complete: A flower with 4 whorls of floral parts; pistil,
stamens, sepals and petals
Incomplete: A flower lacking one or more of the four
kinds of floral whorls sepals, petals, stamens or pistils.
·
Floral Symmetry:
Actinomorphic/ Regular: flowers in which each whorl s
similar in shape, and the flower can be divided in to two halves along more
than one median longitudinal plane
Zygomorphic/ Irregular: flower in which members of some
or all of the floral whorls are unequal. The can be divided longitudinally in
to two equal halves in only one vertical plane.
Figure : On the basis of symmetry;
a. actinomorphic; b. zygomorphic
·
On the basis of reproductive
organs:
Hermaphrodite or Bisexual: Both stamens (male
reproductive organ) and pistil (female reproductive organ) present
Unisexual: flower with reproductive organ of only one
sex. They can be of two types based on types of reproductive organs present:
·
Staminate
·
Pistillate
·
Based on the number of
floral parts
Dimerous/ Trimerous/ Tetramerous/ Pentamerous
·
Based on Position of Floral
organs on Thalamus:
·
Hypogynous: A flower in
which ovary is superior and all floral organs are below the level of ovary
·
Perigynous: Ovary at same
level as remaining floral organs.
·
Epigynous: Ovary inferior to
remaining floral organs.
Smallest Flower: Wolffia
microscopic
Largest Flower: Rafflesia
National Flower of India:
Lotus (Nelumbium)
Pre
Fertilization Changes:
The decision to flower
occurs much before the actual flowers are seen.
Flowers originate from shoot
meristem, which normally generate leaves and shoots. Several hormonal and structural changes are
started that lead to differentiation and further development of floral
primordium.
The meristem stops
vegetative growth when flowering begins and either produces a single flower or
a group of flowers. Inflorescences are formed first which then bear floral buds
that from flowers. The flowering process involves two steps:
·
Induction or the change in
form and function of the vegetative meristem to develop a flower
·
Evocation: Development of
floral meristem
The floral meristem, like
shoot meristem is divided in to two layers; Tunica and corpus.
In the flower, male
(androecium) and female (gynoecium) reproductive structures develop.
STAMEN,
MICROSPORANGIUM & POLLEN GRAIN
Stamen in a typical flower
comprises of two parts:
·
Filament: long and slender stalk
·
Anther: upper broad, bilobed structure
The lower end of filament is
attached to the thalamus or the petal of the flower.
The number and length of
stamens is different in different species.
Figure 2.2
Anther Structure:
·
Tetragonal
·
Bilobed or made of two
anther lobes that are connected by a strip of sterile part called connective.
·
Dithecous or each lobe is
made of two theca.
Each theca contains 1
microsporangia. Thus, each anther lobe is dithecous with 2 microsporangia in
each. The total number of microsporangia in each anther is 4.
The microsporangia develop
in to pollen sacs. They extend longitudinally all through the length of an
anther and are packed with pollen grains.
Structure of
Microsporangium:
A transverse section of a
microsporangium appears almost circular. It is surrounded by 4 wall layers:
·
Epidermis
·
Endothecium
·
Middle layers
·
Tapetum
The outer three layers are protective and help in
dehiscence of anther to release pollen grain.
The fourth layer, tapetum provided nourishment to the
developing pollen grain. The cells of tapetum are generally multinucleate or
may have large polyploidy nucleus.
Development of
Microsporangium (Microsporogenesis)
The process of formation of
microspore from microspore mother cell through meiosis
It involves the following
steps:
·
A young anther has groups of homogenous cell.
They are compactly arranged in the centre of each microsporangium and are known
as sporogenous tissues.
·
Each of the cells of
sporogenous tissue is capable of forming microspores, and hence is also known
as potential pollen or micropsore mother cell (PMC)
·
As anther develops, cells of
sporogenous tissue develop in to loosely arranged microspore mother cells or
Pollen mother cells (PMC).
·
The PMCs undergo meiotic
division to form microspore tetrads.
·
The microspore, as they are
formed are arranged in a cluster of four cells – microspore tetrad.
·
As the anthers mature and
dehydtrate,the microspores dissociate from each other and develop into pollen
grains.
Thus inside each microsporangium several thousand
microspores or pollen grains are formed.
Pollen Grain
The study of
pollen grains is known as Palynology
A pollen grain is a microscopic body that contains the
male reproductive cell of a plant. It is crucial in a plant's fertilization
process.
·
Pollen grains develop from
microspore and represent the male gametophyte
·
Typically haploid,
unicellular with single nucleus
·
Usually spherical, measuring
25-50 micrometers in diameter
Shape Colour and Size: Pollen grains of various species can vary quite a lot
in size (from about 10 to nearly 100 micrometer; exceptions are the
thread-shaped pollen grains of some eelgrass). They also vary in shape: round,
oval, disc or bean-shaped and sometimes filamentous. The natural color is
mostly white, cream, yellow or orange. The texture of the cell wall shows also great
variations, from smooth to spiky.
Structure:
Prominent two layered wall
·
Exine: Outer, hard layer. Made of sporopollenin which is one
of the most resistant organic materials known. It is resistant to strong acids,
alkali and high temperatures. No enzyme that degrades sporopollenin is so far
known. Pollen grains are well preserved as fossils due to sporopollenin.
Exine has prominent apertures where sporopollenin is
absent and the exine is thin. These are known as germ pore when they are
circular and germ furrows when they are elongated.
·
Intine: Inner wall of pollen grain.
It is a thin and continuous layer made of cellulose and pectin.
Cytoplasm
·
Rich in starch and
unsaturated oils
·
Surrounded by a thin plasma membrane
Pollen
Germination / Development of Male Gametophyte
Male gametophyte begins to develop while the
pollen grain is still in the microsporangium or pollen sac. This type of
germination is known as precocious germination.
Microspore undergoes only 2 mitotic divisions:
·
1st : forms a larger vegetative cell and a smaller generative
cell
·
2nd: The generative cell
divides to form two male gametes. Thus a three cell stage is formed.
The 2nd division may occur after
pollination i.e. during the growth of pollen tube into stigma. In such plants
the pollen is shed at 2 cell stage. This occurs in 60% of the plants. In some
other plants the male gametes are formed prior to pollination and the pollen is
shed at 3 cell stage.
The vegetative cell is
bigger, has abundant food reserve and has large irregularly shaped nucleus.
The genitive cell is
smaller, floats in cytoplasm of vegetative cell. It is spindle shaped with
dense cytoplasm and a nucleus.
Post-pollination changes occur in the pollen once it lands on the stigma:
·
Pollen grain absorbs water and nutrients from the stigma secretions through
its germ pores.
·
Intine protrudes out through
one of the germ pores or through a germ furrow.
·
Generative nucleus divides
to form two male nuclei which appear as distinct male gametes.
·
Protruded intine forms
pollen tube.
Pollen grain must remain
viable when they fall on stigma. The period of viability of pollen grains is
variable. It depends on temperature, and humidity. In certain plants it loses
viability within 30 minutes e.g. cereals such as rice and wheat. In some others
such as members of leguminoceae, Solanaceae, Rosaceae; they maintain viability
for months. Like semen, it is possible to store pollen grains of large number
of species for years in liquid nitrogen at -196degC. Such stored
pollen can be used as pollen banks similar to sperm banks for plant breeding
programmes.
Harms due to Pollen
Pollens of many species
cause allergies and bronchial problemsin some people leading to respiratory
disorders such as asthma, bronchitis etc. e.g. Parthenium or carrot
grass that came to India as contaminant with wheat, has spread everywhere and
is responsible for pollen allergy.
Uses of Pollen
Rich in nutrients hence used
as food supplements in form of pollen tablets and syrups. Available in these
forms in markets, in western countries. Consumption of pollen has been shown to
increase performance of athletes and race horses.
Pistil,
Megasporangium (Ovule) and Embryo Sac
Pistil
Gynoecium or pistil
represents the female reproductive part of the flower. It is composed of 1 or
more carpels/pistil.
If single pistil: monocarpellary
If more than 1 pistil: multicarpellary
Multicapellary with all
pistils fused: syncarpous e.g. Petunia, Papaver
Multicarpellary with all
pistils free: apocarpous e.g. Ranunculus, Aconitum
Parts of Pistil: 3 distinct parts:
·
Stigma
·
Style
·
Ovary
Pistil is a highly modified
leaf folded along the midrib. A cushion like ridge develops on the ventral side
of modified leaf that forms the placenta on which ovules are borne.
Stigma: Upper generally knobbed. Stigma serves as landing
platform for pollen garins
Style: elongated slender part. Raises the stigma to expose it,
and thus increases the chances of pollination.
Ovary: Basal bulged part of pistil. Inside the ovary is the ovarian
cavity or locule. Depending on the number of locules or chambers,
the ovary is known as unilocular, Bilocular, trilocular etc.
Placenta located on the
inside of ovary cavity produces different types of placentation, depending
on the attachment of megasporangium (ovule) inside the ovarian cavity.
Number of ovules in the
ovarian cavity may be 1 (e.g. wheat, paddy, mango); or many (papaya, water
melon, orchids)
Megasporangium (Ovule):
Ovule is small structure
attached to the placenta by means of a stalk called as funicle.
The point on the ovule where
funicle is attached is known as Hilum. Hilum represents the junction
between ovule and funicle.
Each ovule is enclosed in 1
or 2 protective envelops known as integuments.
The integuments leave a
small opening called micropyle at the tip of the ovule.
Opposite the micropyle end,
is the chalaza, which represents the base of the ovule. The integuments
arise from chalaza.
Inside the integuments is a
layer of parenchymatous tissue known as nucellus, which is nutritive in
function. The parenchyma cells of nucellus are rich in reserve food materials.
Depending on the nature of
nucellus and integuments, ovule is classified in the following groups:
On the basis of type of Nucellus: Tenuinucellate (nucellus thin), & crassinucellate
(Nucellus thick)
On the basis of integument number: Unitegmic ( Ovule with 1 integument); and Bitegmic (ovule
with two integuments)
On the basis of relationship
of funicle with ovule and the orientation of the ovule; ovule is classified as
follows:
Orthotropous or upright
ovule
Anatropous or inverted
ovule.
Besides these, there are
variously inclined ovules such as campylotropous, amphitropous etc.
Inside the nucellus is the embryo sac or femnale gametophyte. An ovule ususally has only one embryo sac
formed from 1 megaspore through reduction division.
Megasporogensis:
Porcess of formation of
megaspore from megaspore mother cell (MMC)
In the nucellus, towards the
micropylar end, [1]a
distinct microspore mother cell is differentiated. It is a large cell contaning
dense cytoplasm and distinct nucleus.
The MMC undergoes meiosis to
form four haploid megaspore. Of the four megaspores, only one (the megaspore at
the chalazal end) remains as the functional megaspore. The remaining three
degenerate.
With the formation of haploid megaspore, the sporophyte phase of
plant’s life cycle ends and the gametophyte phase begins.
Development oif female
gametophyte:
The functional megaspore
develops in to the female gametophyte (embryo
sac). This method of development of embryo sac from a single megaspore is known
as monosporic development.
The nucleus of megaspore
divides mitotically in to 2 daughter nuclei. These 2 move at opposite poles of
embryo sac. The next mitotic division leads to formation of 4 nucleate embryo
sac and later 8 nucleate stage. These mitotic divisions are free nuclear, i.e.
the karyokinesis is not followed by cytokinesis.
One nucleus from each pole
migrates to the centre of cell to form two polar nuclei. At this stage, cell
walls are formed leading to formation of typical female gametophyte or embryo sac.
A typical female gametophyte
contains 8 nuclei:
- 3 at the chalazal end: antipodals. They provide polarity to embryo sac.
- 3 at the micropylar end: egg apparatus comprising of 2 synergids and 1 egg cell. The synergids have special cellular thickenings at the micropylar tip called filiform appartus, which play an important role in guiding the pollen tubes inside the synergids.
- 2 at the centre: Polar nuclei
The nuclei at the two poles
form their own cell walls; while the two at the centre or polar nuclei lie in
the large central cell.
Thus a mature female
gametophyte (embryo sac) is 8 nucleate and 7 cell structure.
POLLINATION
Transfer of pollen grain
from anther to stigma.
Both male and female gametes
in angiosperms are non motile in angiosperms, thus plants have developed a
number of adaptations to enable pollination. They use a number of external
agents for this purpose.
Types of Pollination
On the basis of source of
pollen, pollination can be of many types:
I.
Plants are said to be self
pollinated when the pollen is transferred from anther to stigma of same flower
or of another flower on the same plant.
Self pollination can be of
following types:
- Autogamy: Pollination is achieved within the same flower. Thus the flower in this case is bisexual.
For a successful pollination through autogamy, ecrtain
conditions must be met:
- Homogamy or the anther and stigma in bisexual flower should attain maturity at the same time. Pollen maturity and stigma receptivity should occur at the same time.
- The anther and stigma should lie close to each other.
Even if these conditions are
met, autogamy is not an exclusive (only) method of pollination in bisexual
flower. There is always the possibility of stigma receiving pollen from another
flower of same plant or of another plant; since the flowers are open and stigma
is exposed.
Certain plants such as Viola (common pansy), Oxalis, Commelina; ensure autogamy as
the only method of pollination by producing two types of flowers:
ü Chasmogamous Flowers or the flowers that are normal
bisexual, with stigma exposed and anther avaiable for dispersal by external
agencies.
ü Cleistogamous Flower or the flowers that do not open at
all, so that the anthers and stigma remain enclosed within the flowers and are
not at all exposed.
In such flowers anthers and
stigma lie close to each other so that when the anther dehisces, mature pollen
grain is released within the flower and directly comes in contact with its own
stigma. Thus pollinbation is achieved.
In absence of exposure,
cleistogamous flowers are essentially autogamous. They are also able to produce
seed essentially, even in absence of an external pollinator.
- Geitonogamy: Transfer of pollen grain from stigma to anther of another flower on the same plant.
Gitonogamy exhibits characters similar to both autogamy
and xenogamy.
It is similar to xenogamy since it requires agents of
pollination
It is similar to autiogamy genetically; since pollen
grains and stigma belong to same plant; resulting in similar gene combination
in seed.
II.
Cross Pollination refers to
transfer of pollen from anther of a flower to stigma of a flower of another
plant. It is also known as Xenogamy.
In this type of pollination, pollen and oule of geentically different types are
brought together.
Agents Of Pollination
2 abiotic agents: wind and water
1 biotic agent: animal
Adaptations in
flowers for Pollination
I. Wind Pollination
I. Wind Pollination
pollen grains :– light, non- sticky, winged
anther :- well exposed
stigma :- large and feathery
flower :- one ovule, arranged as inflorescence
e.g. corn
cob, cotton, date palm
II. Water Pollination
- Bryophytes, Pteridophytes, Algae
II. Water Pollination
- Bryophytes, Pteridophytes, Algae
pollen grains : protected by mucilaginous covering
e,g,
: Fresh water plants- Vallisneria,
Hydrilla
Sea grass- Zostera
Main features of wind and water pollinated plants
- produce pollen grains in large no.
- do not produce nectar
III. Insect Pollination
- Flowers : large, colourful, fragrant, rich in nectar
- Pollen grains : sticky
- Stigma : sticky
Certain rewards to pollinators:
Sea grass- Zostera
Main features of wind and water pollinated plants
- produce pollen grains in large no.
- do not produce nectar
III. Insect Pollination
- Flowers : large, colourful, fragrant, rich in nectar
- Pollen grains : sticky
- Stigma : sticky
Certain rewards to pollinators:
nectar and (edible) pollen grains as foods
provide safe place for laying eggs
Ex : Amorphophallus,
Yucca
Outbreeding Devices
Continued self - Pollination leads to inbreeding depression. Plants develop various mechanisms to avoid self pollination and ensure cross pollination.
Ways to avoid Self-pollination :
(i) Pollen release & stigma receptivity – not synchronized
Outbreeding Devices
Continued self - Pollination leads to inbreeding depression. Plants develop various mechanisms to avoid self pollination and ensure cross pollination.
Ways to avoid Self-pollination :
(i) Pollen release & stigma receptivity – not synchronized
Protandry: Pollen matures first
Protogyny: Ovule matures first
(ii) Stigma and anther – placed at different positions
(iii) Self-incompatibility: genetic mechanism that prevents self pollen from fertilizing the ovules by inhibiting pollen germination or growth of pollen tube in pistil.
(iv) Production of unisexual flowers
Eg: castor, maize (prevents autogamy)
papaya (prevents autogamy & geitonogamy)
Pollen – Pistil Interaction
All events – from deposition of pollen on stigma till the pollen tube enters the ovule are called Pollen-pistil interaction.
• Recognition of compatible pollen
• Germination of pollen grains
• Development of Male Gametophyte
Artificial Hybridization
(ii) Stigma and anther – placed at different positions
(iii) Self-incompatibility: genetic mechanism that prevents self pollen from fertilizing the ovules by inhibiting pollen germination or growth of pollen tube in pistil.
(iv) Production of unisexual flowers
Eg: castor, maize (prevents autogamy)
papaya (prevents autogamy & geitonogamy)
Pollen – Pistil Interaction
All events – from deposition of pollen on stigma till the pollen tube enters the ovule are called Pollen-pistil interaction.
• Recognition of compatible pollen
• Germination of pollen grains
• Development of Male Gametophyte
Artificial Hybridization
Crossing different varieties of species. Hybrid individual
with desirable characters of the parent plants are produced. This involves:
- Collection of desired pollen grains for pollination
- Stigma protected from contamination
Emasculation : removal of anther
Bagging : flower covered- bag made up of butter-prevent
contamination of stigma from unwanted pollen
Bagged flower- attains receptivity - mature pollen grains- dusted on the stigma – rebagged - fruits allowed to develop
Fertilization
The process of
fertilization was discovered by Strasburger in 1884. After pollination the
intine of pollen grain forms pollen tube through weak areas on exine (germ
pore). The growth of pollen tube is stimulated by the sugary substances
produced in stigma.
The pollen tube
with two male gametes and tube nucleus runs through the style and finally turns
towards the micropylar end of the ovule in the cavity of ovary. The length of
pollen tube depends on the length of styles.
On piercing the nucellus, the pollen tube penetrates the
embryo sac. Its tip penetrates in the embryo sac and reaches the egg apparatus
passing either between the egg and synergids or between one synergid and wall
of the embryo sac. Ultimately, the tip of the pollen tube bursts and two male
gametes are discharged.
The tube
nucleus disorganises before bursting of pollen tube. One of these male gametes
fuses with the egg cell or oosphere (syngamy) causing fertilization, as a
result of which diploid oospore or zygote is formed. The other gamete fuses
with the secondary nucleus (triple fusion) forming the triploid endosperm
nucleus which later on gives rise to endosperm.
Thus the process of fertilization which
occurs twice in the same embryo sac at a time by the two male gametes (syngamy
and triple fusion) is called double fertilization. The process of double
fertilization was discovered by S.G. Nawaschin (1897) in Lilium and Fritillaria species
Double Fertilisation / Syngamy
Double fertilization is a complex fertilization mechanism of flowering plants (angiosperms). This process
involves the joining of a female gametophyte (megagametophyte, also called the
embryo sac) with two male gametes (sperm).
- pollen tube releases male gametes into synergids
- fusion of 1 of male gametes and egg cell
- fusion of 2nd male gamete and polar nuclei =Triploid endosperm nucleus- PEN (Triple Fusion)
- PEN – now called Primary Endosperm Nucleus – Endosperm
Significance of double fertilization:
- pollen tube releases male gametes into synergids
- fusion of 1 of male gametes and egg cell
- fusion of 2nd male gamete and polar nuclei =Triploid endosperm nucleus- PEN (Triple Fusion)
- PEN – now called Primary Endosperm Nucleus – Endosperm
Significance of double fertilization:
Double fertilization is found in angiosperms only. In
angiosperms, female gametophyte abruptly stops its growth at 8 nucleate
stages. Further growth of embryo sac occurs only when the zygote has been
formed and primary endosperm nucleus has been created by triple fusion.
The triple fusion
initiates the formation of endosperm. The endosperm is formed only when it is
needed. The need arises after fertilization because the endosperm provides
nutrition for the simultaneously developing embryo.
If fertilization fails no endosperm will be formed. Thus,
there will be wastage of energy in the development of endosperm. There is no
such provision in gymnosperms. There is, therefore, no wastage of energy on
this account in angiosperms.
Post- fertilization Events
All events that occur in a flower, after double fertilization is called Post- fertilization events
Major events are :
(i) Development of endosperm
(ii) Development of embryo
(iii) Maturation of ovule into seed
(iv) Maturation of ovary into fruit
Endosperm
Endosperm development precedes embryo development since endosperm accumulates food and acts as source of nutrition to the developing embryo.
† Two types of endosperm development :
(i) Free nuclear type (common method) during which few initial nuclear development is not followed by development of cell wall.
The nuclei so formed either remain free in the cytoplasm of
embryo sac or form walls later.
In coconut the cell wall formation of endosperm never
occurs. The tender coconut water is thus thousands of nuclei present in the
surrounding kernel, which is cellular endosperm.
(ii) Cellular type: Cytokinesis follows each nucleus division.
(ii) Cellular type: Cytokinesis follows each nucleus division.
† Cells of endosperm– store food materials- used for developing embryo
† Non - Albuminous / Non-Endospermic seeds- endosperm completely utilized - before maturation of seeds. Ex: pea
† Albuminous / Endospermic seeds- a portion of endosperm remain in mature seeds. Ex: castor
Embryo
† Embryogeny – early stages of embryo development
† Zygote → Proembryo → Mature embryo (globular/heart-shaped)
Embryo develops at the micropylar end of the embryo sac.
Early stages of embryo development is similar in both
monocots and dicots.
Embryo consists of:
- embryonal axis
- cotyledons
- plumule
- radicle
The portion of embryonal axis above the cotyledons is known as epicotyle. This forms plumule or stem tip.
The portion of embryonal axis below the cotyledons is known
as hypocotyle. This forms radicle or root tip. The root tip is covered by root
cap.
Monocotyledonous Seed: Has only one cotyledon or scutellum.
- Scutellem = Cotyledon. Present on lateral side of embryonal axis.
- Coleorrhiza: undifferentiated sheath covering radical & root cap
- Coleoptile: sheath covering plumule
Seed
- Fertilized and mature ovule develops into seed.
Seed consists of:
- cotyledon(s)
- embryonal axis
- Integuments of ovary harden as tough protective seed coat which is double layered and formed by integuments. The integuments are:
Monocotyledonous Seed: Has only one cotyledon or scutellum.
- Scutellem = Cotyledon. Present on lateral side of embryonal axis.
- Coleorrhiza: undifferentiated sheath covering radical & root cap
- Coleoptile: sheath covering plumule
Seed
- Fertilized and mature ovule develops into seed.
Seed consists of:
- cotyledon(s)
- embryonal axis
- Integuments of ovary harden as tough protective seed coat which is double layered and formed by integuments. The integuments are:
- Testa (outer coat)
- Tegmen (inner coat)
- Micropyle: - small opening
on seed coat, it facilitates entry of H2O & O2 into seeds (for germination)
- Hilum:- scar on seed coat
- Seed - Albuminous / Non-Albuminous
- Hilum:- scar on seed coat
- Seed - Albuminous / Non-Albuminous
Non albuminous seeds do not have residual endosperm. The
endosperm is completely consumed during embryo development. E.g. pea and
groundnut
Albuminous seeds retain part of endosperm as some of it is
only used during embryo development e.g. wheat, maize barley etc.
- Perisperm : remnants of nucellus that is persistent. Ex: Black pepper
- Dormancy: state of inactivity
Advantages of Seeds
- Perisperm : remnants of nucellus that is persistent. Ex: Black pepper
- Dormancy: state of inactivity
Advantages of Seeds
To plants
(i) Seeds - reserve food materials-
nourish seedling
(ii) Seed coat- protection to young embryo
(iii) Seeds of large no of species –live for several years
(iv) Seeds - better adaptive strategies- dispersal to new habitats- better survival
(ii) Seed coat- protection to young embryo
(iii) Seeds of large no of species –live for several years
(iv) Seeds - better adaptive strategies- dispersal to new habitats- better survival
To mankind
(i) used as food - throughout
the year
(ii) seed - basis of agriculture
Fruit
(ii) seed - basis of agriculture
Fruit
As ovule matures in to seeds, ovary develops in to fruit.
The wall of ovary develops in to fruit wall or pericarp.
- True fruit : - Fruit formed from the ovary
- Parthenogenesis: If ovary transform to fruit without fertilization. Ex : Banana
- Parthenocarpy – induced with gibberellins & auxins without fertilization.
- False fruit: any part other than ovary- forms the fruit. Ex: Apple
Apomixis & Polyembryony
Other modes of reproduction
Apomixis
- Form of asexual reproduction- mimics sexual reproduction- seed formed without fertilisation
- Formation of apomictic seeds :
· diploid cell (formed without meiosis) - develop into embryo without fertilization
· cells of nucellus (2n) surrounding embryo sac- protrude into embryo sac - develop into embryos. Ex. Citrus and Mango.
Polyembryony
- Occurrence of more than one embryo in a seed
- Often associated with apomixes. Ex: Citrus, groundnut
- True fruit : - Fruit formed from the ovary
- Parthenogenesis: If ovary transform to fruit without fertilization. Ex : Banana
- Parthenocarpy – induced with gibberellins & auxins without fertilization.
- False fruit: any part other than ovary- forms the fruit. Ex: Apple
Apomixis & Polyembryony
Other modes of reproduction
Apomixis
- Form of asexual reproduction- mimics sexual reproduction- seed formed without fertilisation
- Formation of apomictic seeds :
· diploid cell (formed without meiosis) - develop into embryo without fertilization
· cells of nucellus (2n) surrounding embryo sac- protrude into embryo sac - develop into embryos. Ex. Citrus and Mango.
Polyembryony
- Occurrence of more than one embryo in a seed
- Often associated with apomixes. Ex: Citrus, groundnut
Hybrid seeds: cultivation of hybrid seeds is preferred for
increased productivity, rich nutrition, better quality and disease resistance.
But one of the major problems of cultivation of hybrid seeds is that if seeds
obtained from hybrid plants are sown, plants in progeny will segregate and do
not maintain the hybrid characters. Thus cost of cultivation from hybrid seeds
is very high.
But if apomictic plants are grown from hybrid seeds, the
hybrid characters are preserved and the farmer can grow hybrid plants
repeatedly year after year.
[1] In the
nucellus, towards the micropylar end, a distinct hypodermal, archesporial cell
is formed. It undergoes periclinal division to form outer primary parietal cell
and inner primary sporogenous cell. Primary parietal cell divides to form
parietal tissue of nucellus and primary sporogenous cell forms megaspore mother
cell.
