Mitosis and Meiosis Lecture Notes PDF

Summary

This document contains detailed lecture notes on cell cycle, mitosis, and meiosis. It explains the stages and processes involved, helping understand cell division mechanisms. The notes include diagrams and descriptions of key stages like prophase, metaphase, anaphase, and telophase.

Full Transcript

Lecture No.: 11

CELL CYCLE
Cell cycle can be defined as the entire sequence of events happening from the
end of one nuclear division to the beginning of the next. A cell cycle consists of
two phases, viz., 1) interphase and 2) the cell division proper. The time required
for the completion of cell cycle differs from species to species.
Interphase
Interphase is generally known as DNA systhesis phase. Interphase consists of
G1, S and G2 sub phases. G1 is the resting phase, S is the period of DNA
replication and G2 again is a resting stage after DNA replication.

G1 Phase: It is a pre-DNA replication phase. Thus, this is a phase between
telophase and S phase. This is the longest phase which takes 12 hours in Vicia
faba. It is the most variable period of cell cycle. Synthesis of proteins and RNA
take place during this phase.
S (Synthetic) Phase: This phase comes after G1and takes lesser time than
G1phase. In Vicia faba, it takes six hours. The chromosome and DNA replications
take place during this phase.
G2 Phase: This is the post-DNA replication phase and last sub stage of
interphase. This phase also takes 12 hours in Vicia faba. Synthesis of protein and
RNA occur during this stage.
CELL DIVISION
All the cells are produced by division of pre-existing cells. Continuity of life
depends on cell division. In the cell division, the division of nucleus is called
karyokinesis and division of cytoplasm is called cytokinesis. The cell division is of
two types. 1) Mitosis and 2) Meiosis
MITOSIS
The term mitosis was coined by Flemming in 1882. Mitosis occurs in somatic
organs like root tip, stem tip and leaf base etc. Hence it is also known as somatic
cell division. The daughter cells are similar to the mother cell in shape, size and
chromosome complement. Since the chromosome number is same in the
daughter cells as compared to that of mother cell, this is also known as homotypic
or equational division.
Mitotic cell cycle includes the following stages:
Interphase : This is the period between two successive divisions. Cells in
interphase are characterized by deeply stained nucleus that shows a definite
number of nucleoli. The chromosomes are not individually distinguishable but
appear as extremely thin coiled threads forming a faintly staining network. The cell
is quite active metabolically during interphase.
Mitosis consist of four stage, viz., (a) Prophase, (b) Metaphase, (c)
Anaphase and (d) Telophase
a) Prophase: The nucleus takes a dark colour with nuclear specific stains
and also with acetocarmine / orcein. The size of the nucleus is
comparatively big and the chromosomes that are thin in the initial
stages slowly thicken and shorten by a specific process of coiling.
The two chromatids of a chromosome are distinct with matrix coating
and relational coiling. The disinte gration of nuclear membrane
denotes the end of prophase.
b) Metaphase: After the disintegration of nuclear membrane, the shorter
and thicker chromosomes will spread all over the cytoplasm. Later,
the size of the chromosomes is further reduced and thickened. T he
distinct centromere of each chromosome is connected to the poles
through spindle fibres. The chromosomes move towards equator and
the centromere of each chromosome is arranged on the equator. This
type of orientation of centromeres on the equator is known as auto -
orientation. The chromosomes at this stage are shortest and thickest.
The chromatids of a chromosome are held together at the point of
centromeres and the relational coils are at its minimum.
 c) Anaphase: The centromere of each chromosome separates first and
moves to towards the poles. Depending on the position of the
centromeres (metacentric, acrocentric and telocentric), the
chromosomes show ` V `, ` L ` and ` I ` shapes respectively as the
anaphase progresses. The sister chromatids move to the poles. The
chromosome number is constant but the quantity of each
chromosome is reduced to half.
d) Telophase: Chromosomes loose their identity and become a mass of
chromatin. The nucleus will be re-organized from the chromatin. At
late telophase stage, the cell plate will divide the cell into two
daughter cells.
Cytokinesis : The division of cytoplasm usually occurs between late anaphase
and end of telophase. In plants, cytokinesis takes place through the
formation of cell plate, which begins in the centre of the cell and moves
towards the periphery in both sides dividing the cytoplasm into two
daughter cells. In animal cells, cytokinesis occurs by a process known as
cleavage, forming a cleavage furrow.
Significance of Mitosis
Mitosis plays an important role in the life of living organisms in various
ways as given below:
1. Mitosis is responsible for development of a zygote into adult organism after
the fusion of male and female gametes.
2. Mitosis is essential for normal growth and development of living organisms.
It gives a definite shape to a specific organism.
3. In plants, mitosis leads to formation of new organs like roots, leaves, stems
and branches. It also helps in repairing of damaged parts.
4. It acts as a repair mechanism by replacing the old, decayed and dead cells
and thus it helps to overcome ageing of the cells.
5. It helps in asexual propagation of vegetatively propagated crops like
sugarcane, banana, sweet potato, potato, etc. mitosis leads to production
of identical progeny in such crops.
6. Mitosis is useful in maintaining the purity of types because it leads to
production of identical daughter cells and does not allow segregation and
recombination to occur.
7. In animals, it helps in continuous replacement of old tissue with new ones,
such as gut epithelium and blood cells.

MITOSIS
Lecture No: 12

MEIOSIS
The term meiosis was coined by J.B. Farmer in 1905. This type of division
is found in organisms in which there is sexual reproduction. The term has been
derived from Greek word; Meioum = diminish or reduce. The cells that undergo
meiosis are called meiocytes. Three important processes that occur during
meiosis are:
1. Pairing of homologous chromosomes (synapsis)
2. Formation of chiasmata and crossing over
3. Segregation of homologous chromosomes
The first division of meiosis results in reduction of chromosome number to half
and is called reduction division. The first meiotic division is also called heterotypic
division. Two haploid cells are produced at the end of first meiotic division and in
the second meiotic division, the haploid cells divide mitotically and results in the
production of four daughter cells (tetrad), each with haploid number of
chromosomes. In a tetrad, two daughter cells will be of parental types and the
remaining two will be recombinant types. The second meiotic division is also
known as homotypic division. Both the meiotic divisions occur continuously and
each includes the usual stages viz., prophase, metaphase, anaphase and
telophase.
Meiotic cell cycle involves the following stages:
Interphase : Meiosis starts after an interphase which is not very different from that
of an intermitotic interphase. During the premeiotic interphase DNA duplication
occurs during the S phase
I. Meiosis-I:
(1) Prophase -I: It is of a very long duration and is also very complex. It has been
divided into the following sub-stages:
a) Leptotene or Leptonema: Chromosomes at this stage appear as long
thread like structures that are loosely interwoven. In some species, on
these chromosomes, bead-like structures called chromomeres are found all
along the length of the chromosomes.
b) Zygotene or Zygonema: It is characterized by pairing of homologous
chromosomes (synapsis ), which form bivalents. The paired homologous
 chromosomes are joined by a protein containing frame work known as
synaptonemal complex. The bivalents have four strands
c) Pachytene or Pachynema: The chromosomes appear as thickened
thread-like structures. At this stage, exchange of segments between non-
sister chromatids of homologous chromosomes known as crossing over
occurs. During crossing over, only one chromatid from each of the two
homologous chromosomes takes part. The nucleolus still persists.
d) Diplotene or Diplonema: At this stage further thickening and shortening
of chromosomes takes place. Homologous chromosomes start
separating from one another. Separation starts at the centromere and
travels towards the ends (terminalization). Homologous
chromosomes are held together only at certain points along the
length. Such points of contact are known as chiasmata and represent
the places of crossing over. The process of terminalization is
completed at this stage.
e ) Diakinesis: Chromosomes continue to undergo further contraction.
The bivalents appear as round darkly stained bodies and they are
evenly distributed throughout the cell. The nuclear membrane and
nucleolus disappear.
2) Metaphase-I: The chromosomes are most condensed and have smooth
outlines. The centromeres of a bivalent are connected to the poles
through the spindle fibres. The bivalents will migrate to the equator
before they disperse to the poles. The centromeres of the bivalents are
arranged on either side of the equator and this type of orientation is
called co-orientation.
3) Anaphase-I: The chromosomes in a bivalent move to opposite poles
(disjunction). Each chromosome possess two chromatids. The
centromere is the first to move to the pole. Each pole has a haploid
number of chromosomes
4) Telophase-I: Nuclear membranes are formed around the groups of
chromosomes at the two poles. The nucleus and nucleolus are re -
organized.
II. Meiosis-II: The second meiotic division is similar to the mitotic division and it
includes the following four stages:
 1) Prophase-II: The chromosomes condense again. The nucleolus and
nuclear membrane disappear. The chromosomes with two chromatids each
become short and thick
2) Metaphase -II: Spindle fibres appear and the chromosomes get arranged
on the equatorial plane(auto-orientation). This plane is at right angle to the
equatorial plane of the first meiotic division.
3) Anaphase-II: Each centromere divides and separates the two chromtids,
which move towards the opposite poles.
4) Telophase-II: The chromatids move to the opposite poles The nuclear
envelope and the nucleolus reappears. Thus at each pole, there is re -
organization of haploid nucleus.
Cytokinesis: The division of cytoplasm takes place by cell plate method in plants
and by furrow method in animals. The cytokinesis may take place after meiosis I
and meiosis II separately or sometimes may take place at the end of meiosis II
only.

Significance of Meiosis
Meiosis plays a very important role in the biological populations in various
ways as given below:
1. It helps in maintaining a definite and constant number of chromosomes in a
species.
2. Meiosis results in production of gametes with haploid (half) chromosome
number. Union of male and female gametes leads to formation of zygote
which receives half chromosome number from male gamete and half from
the female gamete and thus the original somatic chromosome number is
restored.
3. Meiosis facilitates segregation and independent assortment of
chromosomes and genes.
4. It provides an opportunity for the exchange of genes through the process of
crossing over. Recombination of genes results in generation of variability in
a biological population which is important from evolution points of view.
5. In sexually reproducing species, meiosis is essential for the continuity of
generation. Because meiosis results in the formation of male and female
gametes and union of such gametes leads to the development of zygotes
and thereby new individual.

MEIOSIS
 Differences between mitosis and meiosis

Mitosis Meiosis
1. Consists of one nuclear division 1. Consists of two nuclear divisions
2. One cell cycle results in production of 2. One cell cycle results in production of
two daughter cells four daughter cells
3. The chromosome number of daughter 3. Daughter cells contain half the
cells is the same as that of mother chromosome number of mother cell (n)
cell (2n)
4. Daughter cells are identical with 4. Daughter cells are different from
mother cell in structure and mother cell in chromosome number
chromosome composition and composition
5. It occurs in somatic cells 5. It occurs in reproductive cells
6. Total DNA of nucleus replicates 6. About 0.3% of the DNA is not
during S phase replicated during S phase and it occurs
during the zygotene stage.
7. The prophase is not divided into sub 7. The prophase I is divided into five sub
stages stages
8. There is no pairing between 8. Homologous chromosomes pair during
homologous chromosomes pachytene
9. Segregation and recombination do 9. Crossing over takes place during
not occur pachytene
10. Chromosomes are in the form of dyad 10. Chromosomes are in the form of tetrad
at metaphase at metaphase
11. The centromeres of all the 11. The centromeres of all the
chromosomes lie on the equatorial chromosomes lie on either side of the
plate (auto orientation) during equatorial plate (co-orientation) during
metaphase metaphase I
12. At metaphase, centromere of each 12. The centromere does not divide at
bivalent divides longitudinally metaphase I
13. One member of sister chromatids 13. One member of homologous
moves to opposite pole during chromosomes moves to opposite poles
anaphase during the anaphase I
14. Maintains purity due to lack of 14. Generates variability due to
segregation and recombination segregation and recombination