cell_division_2022s (1).ppt

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Royal College of Surgeons in Ireland
Medical University of Bahrain
Cell Division
Salim Fredericks

Objectives
1. Define the phases of the cell cycle
2. List the stages and explain the mechanism
and outcomes of mitosis
3. List the stages and explain the mechanism
and outcomes of meiosis
4. Explain the mechanisms producing genetic
variation
5. Define basic terms in Mendelian genetics
including: allele, genotype, phenotype,
homozygote, heterozygote, dominant and
recessive

Cell Division
Cell division required during
• development
• to generate new cells in the adult
In somatic cells, division occurs by mitosis
Mitosis occurs as part of the cell cycle
diploid cells  diploid cells
Meiosis is a specialized form of cell division giving rise
to sperm and egg cells
diploid cells haploid cells

Cell cycle

Phases of the cell cycle
G2 (3-4 h)
A short
resting
phase
before cell
division
occurs

S (5-6 h)
The ‘synthesis’
phase - DNA
replication occurs

Mitosis (approx. 2 h )
Cell division

G0 (variable
length)
G0 is an optional
non-replicative
phase; many
differentiated
cells remain in G0,
eg: hepatocytes
G1 (approx 10 h)
A period of cell growth and
preparation for cell division
(incl. replication of key components,
eg: centrosomes)

Humans (2n) = 23 chromosome pairs,
22 autosomes + sex chromosomes
Sex-determining chromosomes
XX = female
XY = male

Mitosis

Cell cycle: mitosis
• Mitosis is one
sector of the cell
cycle which
describes how
the genome goes
from being
– duplicated to
– segregated

Cell cycle: mitosis
Genomic DNA must be copied accurately and
divided
between the daughter cells
Mitosis:
DNA is copied once; 46  92 chromosomes
Cell divides once
92 chromosomes / 2 cells  46 chromosomes
= 2 X 23 (diploid)

Cell cycle : mitosis

Concepts of Genetics 10th ed. W. Klug,
et al., (2012)

Cell cycle : mitosis

Concepts of Genetics 10th ed. W. Klug,
et al., (2012)

Mitotic Spindle

•Centromere is essential for segregation during cell division.
•Chromosome fragments lacking centromere (acentric) do not
become attached to spindle and are not passed to daughter cells

Mitosis and DNA replication
• End result of DNA replication: two DNA
molecules, each with one old strand and
one new strand
• Both have the same sequence on each
strand
• The two DNA molecules form the sister
chromatids seen during mitosis
• they are separated during anaphase and
each daughter cell gets one of them
• After separation, each chromatid is
referred to as a chromosome
  each daughter cell gets a full copy of
the genetic information in the parent cell

Meiosis

Meiosis
reduces diploid to haploid

Overview of meiosis
Fate of two chromosome pairs rather than the true 23 pairs.
The result of the two meiotic divisions (in this illustration and
in reality) is four haploid cells.

Meiosis: preceded by one round of DNA synthesis

5 stages of
Prophase
of
Meiosis 1

Recombination:
Exchange
between
maternal and
paternal
chromosome
(homologs)
Bivalent / Tetrad
4 stranded structure
chromatids x 2 homologous chromosomes)

Bivalent align at Metaphase plate

Spindle fibers pull one complete
chromosome (2 Chromatids) to either
pole
Random segregation of paternal and maternal chromosomes

= Independent assortment

Division without replication

Genetics From Genes to Genomes, 4th Edition Leland Hartwell, Leroy
Hood, Michael Goldberg, Ann Reynolds, Lee Silver 2010

Egg formation begins in the
fetal ovaries and arrests
during the prophase of
meiosis I. Fetal ovaries
contain about 500,000
primary oocytes arrested in
the diplotene of meiosis I.
Only one of the three
(rarely, four) cells produced
by meiosis serves as the
functional gamete, or ovum.

Genetics From Genes to Genomes, 4th Edition Leland
Hartwell, Leroy Hood, Michael Goldberg, Ann Reynolds,
Lee Silver 2010

Human sperm form continuously in the testes after puberty.
Once they divide to produce the primary spermatocytes, the subsequent
stages of spermatogenesis—meiotic divisions in the spermatocytes and
maturation of spermatids into sperm

Mitosis compared
with meiosis

Comparison of Mitosis and meiosis

Genetics From Genes to Genomes, 4th Ed (2010)
Hartwell, Hood, Goldberg, Reynolds, Silver

Mechanism of
variation

Genetic diversity is generated in Meiosis I by 2 processes:
a) Independent assortment

For three pairs of homologs, eight (2 3 ) different alignments can
occur. Our 23 chromosome pairs can line up in 8 million (2 23 )
different ways.

b) Recombination by crossing over

(1) Independent assortment
Each bivalent is a 4-stranded structure (4
chromatids)
The mitotic spindle pulls 2 chromatids
towards each pole
Which one?
The choice maternal vs. Paternal homolog is
random

 223 = 8.4 x 106 possible combinations

(2) Recombination

Occurs during Pachytene in Meiosis I
Physical breakage of the DNA duplex
in one maternal and one paternal
chromatid, and joining of the maternal
& paternal ends
DNA sequences are exchanged
between the chromatids; but, DNA
sequences are neither gained nor lost
Unless a mistake :
Non-disjunction Cytogenetics
MM16

Recombination does not normally
occur in mitosis; if/when it does, DNA
sequences are gained or
lost with bad consequences

Meiotic tetrad with two chiasmata

Haploid (n)

Diploid (2n)

Haploid gametes arise by meiosis from diploid precursors
Fertilisation:
Sperm and egg chromosomes combine during the first mitosis
forming diploid zygote.
Further rounds of mitosis and differentiation to form the
whole organism

Basic terminology

Fundamentals of Anatomy & Physiology 4/e © Prentice Hall

Different alleles combine to produce different
genotypes:
AA

or

aa

Homozygote

Aa

Heterozygote

Genotype =
Phenotype =

genetic constitution
physical appearance
(healthy or disease)

Phenotype is (largely) determined by genotype
If A determines phenotype, it is said to be dominant
a is therefore said to be recessive

Simple Mendelian Inheritance
Recessive trait
in pea plants
Cross:

[Single-genes]

R = round vs. r = wrinkled
(R is dominant over r)
Progeny:

Rr x Rr

R

Gametes: R & r
R

Genotype ratio: 1 : 2 : 1
Phenotype:

3:1

r

r
RR

Rr

Rr
rr

Human inherited diseases
Some diseases are caused by genetic (ie: DNA) defects
disease genotype --- > disease phenotype
Two broad categories:
1. Single-gene (monogenic) defects
Single disease allele, dominant or recessive
Simple Mendelian inheritance pattern
2. Multi-gene (polygenic) defects
Interactions of several genes
Complex (ie: non-Mendelian) inheritance

Disease
Expression?
04_06.jpg

Mendelian inheritance patterns:
Autosomal dominant
Autosomal recessive
(Y - linked)

MM11
MM12
MM 13

X - linked dominant
X - linked recessive
Identified in families by ‘Pedigree Analysis’

Further Resources:
• Chapter 2: Chromosome structure and function.
Human Molecular Genetics, Strachan and Read.
• Mitosis
http://www.biosolutions.info/2007/04/mitosis.html
• Meiosis
http://www.biosolutions.info/2007/04/meiosis.html