Meiosis 2023 - PDF

Summary

This document is a lecture on meiosis, covering basic concepts, stages, and genetic consequences. It also touches on gametogenesis, spermatogenesis, and oogenesis. The lecture was given by Eman Ramadan Abdel-Hamid at FOMSCU in 2023.

Full Transcript

MEIOSIS
DR/ Eman Ramadan Abdel-Hamid
Lecturer of Medical Genetics
FOMSCU
BASIC CONCEPTS:

HOMOLOGOUS CHROMOSOMES
 PLOIDY
Diploid (2n) Cell Haploid (n) Cell
46 chromosomes 23 chromosomes
23 pairs of chromosomes

Somatic cells gametes
Objectives (ILOs):

Meiosis:

❑ Definition
❑ Stages( meiosis I & meiosis II)
❑ Genetic consequences of meiosis
❑ Comparison between Meiosis& Mitosis
❑ Oogenesis & Spermatogenesis
DEFINITION
Meiosis is the cell div ision process unique to germline
cells that produces haploid gametes from diploid
precursor cells.

Meiosis involves one round of DNA replication followed
by tw o rounds of cell division: meiosis I & meiosis II.
STAGES
1- Meiosis I:(Reduction division)
During which homologous chromosomes
separate.
Haploid cells with duplicated
chromosomes are formed from a diploid
cell.

2- Meiosis II:
During which sister chromatids separate.
4 Haploid cells with unduplicated
chromosomes are formed.
 Stages of Meiosis

Meiosis I Meiosis II
Prophase I Prophase II
Leptotene stage
Zygotene stage
Pachytene stage Metaphase II
Diplotene stage
Diakinesis
Anaphase II
Metaphase I
Telophase II
Anaphase I
Cytokinesis
Telophase I
Cytokinesis
 MEIOSIS I

Interphase I

Before meiosis I starts, the cell enters an interphase stage, during
which DNA synthesis occur.
 MEIOSIS I

Prophase I

Leptotene
Zygotene
Pachytene
Diplotene
Diakinesis
 MEIOSIS I

Prophase I: Leptotene

lepto-: narrow, fine
Tene: band, ribbon
Chromatin begins to condense &
chromosomes become visible.
 MEIOSIS I

Prophase I: Zygotene
Synapsis (the process of pairing of
homologous chromosomes) Zygo-: union, fusing
begins.

A synaptonemal complex begins
to form, holding each pair of
homologous chromosomes
together.

Bivalents= Tetrads= paired
homologues.
 MEIOSIS I
Prophase I: Pachytene Pachy-: thick

Synapsis is complete.
Crossing over (recombination)
occurs: The breakage and exchange
of homologous segments of non-
sister chromatids from paternal and
maternal members of a pair of
homologous chromosomes.
 MEIOSIS I

Prophase I: Diplotene
Diplo-: double
The synaptonemal complex
starts to disappear.

The homologous chromosomes
start to separate, except at the
chiasmata.
 MEIOSIS I

Prophase I: Diakinesis Dia-: through, across
Kinesis: motion

Chromosomes reach maximum
condensation.

Nuclear membrane starts to
break down.
MEIOSIS I
 MEIOSIS I

Metaphase I
The nuclear membrane disappears.

A spindle has formed.

Paired chromosomes are aligned along the
equatorial plane.
 MEIOSIS I

Anaphase I
Homologous chromosomes are drawn to
opposite poles of the cell (disjunction).

The 23 pairs of homologous chromosome are
assorted independently of one another →
original paternal and maternal chromosome sets
are distributed into random combinations.
 MEIOSIS I

Telophase I & Cytokinesis I
Telophase I: Each haploid set of
chromosomes groups at one pole of the
cell.

Cytokinesis I: A cleavage furrow forms,
dividing the cell into two daughter cells,
which enter interphase.
MEIOSIS I
 MEIOSIS II

Interphase II

- Before meiosis II starts, the cell enters a brief interphase, with
NO S phase.
 MEIOSIS II

Prophase II

- Each chromosome consists of one pair
of sister chromatids held together at the
centromere.
 MEIOSIS II

Metaphase II

- Chromosomes are aligned at the equatorial
plane.
 MEIOSIS II

Anaphase II

- Sister chromatids separate and are pulled to
opposite poles.
 MEIOSIS II

Telophase II & Cytokinesis

Telophase II: One member of each pair
of homologous chromosomes is present
at each pole.

Cytokinesis: A cleavage furrow forms,
dividing each cell into two daughter cells.
MEIOSIS II
Genetic Consequences of Meiosis

1. Reduction of the chromosome number from diploid to haploid.

2. Segregation of alleles so that only one member of the original
gene pair is included in each gamete.

3. Generation of genetic diversity by two mechanisms:
a. Recombination as a result of crossing over.
b. Independent assortment of homologous chromosomes.
Comparison of Mitosis and Meiosis
GAMETOGENESIS

The process of formation of haploid gametes from diploid
precursor cells.

Gametogenesis:

Spermatogenesis

Oogenesis
SPERMATOGENESIS
SPERMATOGENESIS

Starts at puberty &
continues throughout life.

Process takes ~ 64 days.

200 million sperm/per
ejaculate.
OOGENESIS
Ova develop from oogonia in the ovarian cortex during
prenatal life. Each oogonium is the center of a developing
follicle.

By 3rd month of prenatal development, oogonia have begun to
develop into primary oocytes.

Primary oocytes start meiosis I, and are arrested in
prophase I.
OOGENESIS
Primary oocytes are arrested in prophase I from before birth
till puberty.

Starting from puberty, once a month, individual follicles
begin to grow & mature, and one is ovulated.
Primary
oocytes
OOGENESIS

The primary oocyte completes meiosis I, giving the
secondary oocyte, and the first polar body.

Meiosis II begins during ovulation but is arrested in
metaphase II.

Meiosis II is completed only if fertilization occurs. The
second polar body is formed.
There is a period
of arrest between
start of meiosis I
and start of
meiosis II

Prolonged arrest of
primary oocyte in
prophase I

higher risk of
nondisjunction with
advanced maternal
age

Higher risk of fetal
chromosomal
abnormalities with
advanced maternal
age