Cell Division Chapter 4 PDF

Summary

This document provides an overview of cell division. It covers the different phases and processes involved in mitosis and meiosis, including the significance and importance of cell division for maintaining and supporting life processes throughout the human body and in other living things.

Full Transcript

CHAPTER 4:
CELL DIVISION
 mitosis and meiosis Introduction
Cell division – new cells arise from pre-existing cells.
Parent cells divide equally into two cells daughter
cells
Responsible for:
importance of cell division
i) growth of organism
ii) replacement of old cells
iii) repair of damaged cells and tissues
iv) reproduction ex binary fission
 Haploid & Diploid cells
girl XX
boy XY
Haploid
all 23 chromosomes are not the same

 One set of chromosomes
 Half the number of chromosomes (n)
 In humans, number (n) = 23
must be haploid to avoid uncontrollable
 Gametes (sex cells- sperm & ova) cell division
carry out mitosis and divide producing identical daughter cell is not identical cuz different genes
and penetrate into womb characteristics are same ex; hair colour
Diploid zygote after sperm n ovum fertilising
same size and same shape= homologous chromosome

 Two sets of chromosomes
 Chromosomes present in pairs (2n)
 In humans, 2n = 46
 All body cells (somatic cell)

meiosis reduces the cell division meaning to maintain chromosome number
 Karyokinesis (nuclear division)
- division of the genetic material / chromosomes
- each daughter cell receive exactly one complete
In eukaryotes involves set, ideally accurate and identical copies

Cytokinesis (cytoplasm division)
- division of cytoplasm of the parent cell.
- each daughter cell receives about half the
cytoplasmic content

 Karyokinesis Mitosis (equation division)
Meiosis (reductional division)
 Cell Cycle
The recurring sequence of events that includes the
duplication of a cell's contents and its subsequent
division. DNA MULTIPLICATION
In single-cell organisms, each round of the cell cycle
produce an entirely new organism.
In humans and other higher-order animals, cell death
and growth are constant processes replace damage n dead cells
cell cycle is necessary for maintaining appropriate
cellular conditions.
 The cell cycle has a
number of universal
trends:
1. DNA packaged into
chromosomes must
be replicated.
2. The copied contents
2 cells formed
of the cell must migrate
to opposite ends of
the cell.
3. The cell must
physically split into
two separate cells.
interphase

Two major phases of cell cycle
Division phase:
Interphase: resting age true or false
its false cuz its M phase
G1 (Growth 1 / Gap 1)
Cytoplasmic phase
S (Synthesis) metabolically active
G2 (Growth 2 / Gap 2)
past year question
 Interphase
A period of intense synthesis and growth in the
cell
Cell produces many materials required for its own
growth and activities
Genetic material DNA replicates during interphase.

Division phase
Process of nuclear division, which involves
separation of chromatids and their redistribution as
chromosomes into daughter cells.
Cytokinesis occurs after completion of nuclear
division.
sister chromatids

need to preapare materials n things for
S phase

Gap 1 phase
Cell grows in preparation for
DNA replication, and certain
intracellular components, such
as the centrosomes undergo
replication.
Protein and RNA are
synthesized
Normal metabolic activities take
place
Longest phase.

46 chromosomes = 92 chromatids
they are identical so its sister chromatids

Synthesis phase
DNA packaged into
chromosomes is replicated/
DNA duplicated/ synthesized
To allows each cell created by
cell division to have the same
genetic make-up.
Synthesis of a number of
proteins and enzymes that are
involved in DNA synthesis.
Chromosomes remain
extended/ Each chromosome
2 chromatids joined at the
centromere
Gap 2 phase
Mitochondria and chloroplast
replicate, tubulin is synthesized.
Chromosomes prepare to
condense.
Centrioles already replicated.
Asters are formed
Increase energy
because its preparing for important phase which is
mitosis
M phase
Nuclear division
Cytoplasmic division
M phase starts at the end of G2 and ends at the start of the
next G1 phase. It includes the four stages of nuclear division
(mitosis), as well as cytoplasmic division (cytokinesis).
 Mitosis
Process where a successive nuclear division 2n
2n
in a diploid cell occurs. 2n
2 diploid cells form.
2n 2n
Occurs in all body cells except gamete.
Ensures that the next generation will have
2n 2n
the same number of chromosomes (DNA) 2n
and genetically identical to the parent cell.
Mitosis Pak MAT

- Prophase
- Metaphase
- Anaphase
Two daughter
cells are formed.
- Telophase Genetically
Identical.

http://www.johnkyrk.com/mitosis.html
Interphase
Preparing phase
Nucleoli visible
Nuclear envelope intact
Chromosomes still long
and thin, not visible inside
the nucleus
Centrosome replicate
two pairs of centrioles
Prophase
thin thread like
Chromatin condense and become
visible in the light microscope.
Nucleolus and nuclear membrane
disappears.
Centrioles moving to opposite
ends of the cell.
Spindle fibers attach to
kinetochore of centromere.
Kinetochore
The vertebrate kinetochore is a complex structure that
specifies the attachments between the chromosomes
and microtubules of the spindle and is thus essential for
accurate chromosome segregation.

it will be holding so
tightly until spindle fibre
shorten
ex u pull someone until their
hands becomes two
Metaphase
Spindle fibers align the chromosomes
along the middle of the cell Spindle fiber

(metaphase plate) equatorial plane

To ensure that when the
chromosomes are separated, each
new nucleus will receive one copy
of each chromosome
fishing fish mouth is kinotechore
we pull the fish towards u
the rod wire becomes short-
Anaphase
Chromosomes separate.
Chromatids move to opposite
sides of the cell.
not shortening
Pulled by depolymerization of
the microtubules. spindle fibre
Leads by centromeres
 prophase and telophase are oppsites only
Cleavage furrow
Telophase decondense

Chromosomes arrive
at opposite poles of cell.
Nuclear membranes and
nucleoli appear.
Chromosomes disperse, no cytokinesis
longer visible under the light
microscope.
Spindle fibers disperse
Cytokinesis begin.
 1]actin formed at the center of the cell
2]actin contract
3]pinches off cytoplasm
4]form two daugher cells
5]forms cleavage furrow Cleavage of
an animal
cell (SEM)
Cytokinesis (animal)

In animal cells,
cytokinesis results
when a fiber ring
composed of a
protein called actin
around the center of
the cell contracts
pinching the cell into
two daughter cells.

cleavage furrow
1]vesicles accumulates at equator
2] vesicles pulls together to form larger vesicles
3] cellulose in the cell forms cell wall
4] cell plate is formed

Cytokinesis
(plant)
In plant cells, a
cell plate of
cellulose forms in
the vicinity of the
equators and
divides the cell
into two daughters.

golgi apparatus form new cell plate
 Differences between mitosis in plant and animal cells
Characteristic Animal cells Plant cells
Formation of spindle Formation of spindle Formation of spindle
fibres fibres between 2 pairs fibres in the absence of
of centrioles centrioles

Aster formation Present Absent
Cytokinesis Involves furrowing & Involves formation of
cleavage of cytoplasm cell plate
Where it occurs In tissue throughout the Mainly in meristem
body tissues
 importance

Significance of Mitosis
Growth
Cell replacement
Allows genetic stability within the populations of
cells (daughter cells formed are genetically
identical to their parent cell, no variation)
binary fission
Basis of asexual reproduction
Repair and regeneration
 mitosis meiosis

meiosis II
2n=4

Process where two successive nuclear division in a diploid
cell occurs.
4 haploid cells form. meiosis reduces the number of chromosomes

2n n
occurs in reproductive cells (gametes).
Meiosis ensures that the next generation will have:
- diploid number of chromosomes
- combination of traits that differs from the parent
(variation).
 daughter cells which are haploid
Meiosis I Meiosis II
4 daughter cells which are haploid
cells

Prophase I Prophase II
mid sem Metaphase II
Leptotene
Anaphase II
Zygotene
Telophase II
Pachytene
Diplotene
Diakinesis
Metaphase I
Anaphase I
Telophase I Two daughter cells
are formed 2nn
- Chromosome undergoes
replication, making an
identical copy of itself.
- Chromosomes are still long
and thin, not visible inside the
nucleus.
- Cells spend most of their life in
this non-reproductive phase.
 chromatin condenses
chromosomes.
- pairing of homologous a pair of chromosomes that
have the same shape,size
chromosomes. and centromeres are
at middle
- crossing over occur
(*chiasmata).
- nuclear membrane and
nucleolus disappear.
nuclear spindle develops.
chromosomes arrange
equator of the spindle

Meiosis I
Five different substages in prophase 1
 homologous chromosomes are alligned at the equatorial plate

tetrads line-up along the equator
of the spindle (equatorial plate).
- spindle fibers attach to the
centromere region of each
homologous chromosome pair.

Meiosis I
tetrads separate, pulled by
microtubules
- move to opposite poles of the
cell.
 chromosomes form a compact
group at each pole.
- two daughter nuclei haploid (n)
chromosomes.
- nuclear membrane reforms
- nucleolus reappears.

Meiosis I
Meiosis II: Chromosomes condense again,
following a brief interphase (no DNA replication)

centrioles replicate.
nucleolus and nuclear envelopes (if
formed during Telophase I) dissolve.
- spindle fibers reform

Meiosis II
- spindles moving chromosomes
into equatorial area

Meiosis II

centromeres split.
chromatids of the chromosomes
separate pulled to the opposite
poles.
 S PHASE - DNA REPLICATION

- chromosomes gather into nuclei.
- cytokinesis separate the cells
- nuclear membrane and nucleolus
reappear.
- daughter cell n

NO DNA REPLICATION

Meiosis II
 Meiosis I

Prophase I Metaphase I Anaphase I Telophase I

Prophase II Metaphase II Anaphase II Telophase II

Meiosis II
 Produce gametes for sexual reproduction
Maintain diploid chromosome number across
generations.
Increase genetic variation when male and female
gametes fuse together