Medical_biology_lecture_5_meiosis_066173670171c10639544e8e1f9fd289.pdf

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University of Al-Ameed
College of Medicine

Medical Biology
Lecture 5

MEIOSIS
ASSIST. PROF. DR. AHMED ZUHAIR
ALWAELI
2023-2024

Introduction
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Welcome to today's lecture on meiosis, a
fundamental process in cell biology essential for
sexual reproduction and genetic diversity.

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Meiosis is a highly orchestrated mechanism, crucial
for the formation of gametes and ensuring genetic
variability in offspring.

Objectives of the Lecture
• Upon completing this lecture, students will be able to:
• Understand the Phases of Meiosis:
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Describe the key events in each phase of meiosis, from prophase I to
cytokinesis.
Recognize the dynamic changes in cellular components during meiosis.
• Explore Meiosis in Health:
Understand the physiological roles of meiosis in sexual reproduction and
genetic diversity.
Appreciate how meiosis contributes to the maintenance of genetic variability.
• Examine Diseases Related to Meiosis:
Investigate how dysregulation of meiosis contributes to genetic disorders.
Explore conditions resulting from errors in meiosis, such as aneuploidyrelated disorders.
• Consider Meiotic Abnormalities and Therapeutic Opportunities:
Examine current therapeutic strategies targeting meiosis-related conditions.
Discuss potential future developments in drug development aimed at
modulating meiotic processes.

Overview of Mitosis
•

Definition:
Meiosis is the
process of cell
division that results
in four nonidentical daughter
cells, each with half
the number of
chromosomes of
the parent cell.

Phases of Meiosis
Phases of Meiosis:
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Meiosis I

Prophase I, Metaphase I,
Anaphase I, Telophase I,
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Meiosis II

Prophase II, Metaphase II,
Anaphase II, Telophase II (PMAT
x2).
Cytokinesis: The division of the
cytoplasm following meiosis,
resulting in four separate
daughter cells.
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Phases of Meiosis- Prophase I
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Prophase I is divided into a series of substages
which are named according to the appearance of
chromosomes.
• Leptotene
• Zygotene
• Pachytene
• Diplotene
• Diakinesis

Phases of Meiosis- Prophase I
Homologous
Chromosome
Pairing: Chromosomes
align
with
their
homologous
partners
during prophase I.
• Crossing
Over:
Exchange of genetic
material
between
homologous
chromosomes,
enhancing
genetic
diversity.
• Synapsis:
The close
association
of
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Phases of Mitosis – Metaphase I
Homologous
Chromosomes Align at the
Metaphase Plate:
Chromosomes align at the
metaphase plate in pairs.
• Independent Assortment:
Random distribution of
homologous chromosome pairs
to daughter cells, contributing
to genetic diversity..
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Phases of Mitosis – Anaphase I
Homologous
Chromosomes Separate:
Homologous chromosome pairs
separate and move to opposite
poles.
• Reduction Division: The
number of chromosomes in
each daughter cell is reduced by
half.
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Phases of Mitosis – Telophase I
Chromosomes Reach
Opposite Poles:
Chromosomes reach the
poles, and nuclear envelopes
may reform.
• Cytokinesis: The division of
the cytoplasm occurs,
resulting in two haploid
daughter cells.
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Phases of Meiosis - Prophase II
• Chromosome

Condensation:
Chromosomes
condense again in
preparation for the
second meiotic
division.
• Nuclear Envelope
Breakdown: Nuclear
envelope dissolves,
allowing spindle fibers

Phases of Meiosis - Metaphase II
Chromosomes Align at
the Metaphase Plate:
Chromosomes align
individually at the
metaphase plate.
• Spindle Fibers Attach:
Spindle fibers attach to the
centromeres of individual
chromosomes.
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Phases of Meiosis - Anaphase II
Sister Chromatids
Separate: Sister
chromatids separate and
move towards opposite
poles.
• Chromosome
Movement: Spindle
fibers shorten, pulling
chromatids toward the
centrosomes.
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Phases of Meiosis - Telophase II
Nuclear Envelope
Reformation:
Chromatids reach opposite
poles, and nuclear
envelopes begin to reform.
• Cytokinesis: Division of
the cytoplasm occurs,
resulting in four haploid
daughter cells.
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Comparison with Mitosis:
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While both are forms of cell division, mitosis results
in two identical daughter cells diploid (2n), while
meiosis yields four non-identical cells with half
the chromosome number haploid (1n).

Mitosis in Health
Genetic Diversity in
Offspring: Meiosis ensures
the production of genetically
diverse gametes,
contributing to the variability
of the offspring.
• Evolutionary
Significance: The genetic
diversity generated by
meiosis contributes to the
adaptation and evolution of
species over time.
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Diseases Related to Meiosis
Genetic Disorders:
• Errors in meiosis can lead to aneuploidy, where cells
have an abnormal number of chromosomes.
• Examples include Down Syndrome and Turner
Syndrome.
• Aneuploidy: Abnormal chromosome numbers due
to errors in meiosis.
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Diseases Related to Meiosis
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Genetic Disorders: Nondisjunction
Down syndrome – trisomy of chromosome 21
Patau syndrome – trisomy of chromosome 13
Edwards syndrome – trisomy of chromosome 18
Klinefelter syndrome – extra X chromosomes in
males – i.e. XXY, XXXY, XXXXY, etc.
Turner syndrome – lacking of one X chromosome
in females – i.e. X0
Triple X syndrome – an extra X chromosome in
females
Jacobs syndrome – an extra Y chromosome in
males.

Clinical Diagnosis and Genetic
Counseling
Diagnostic Methods for Meiotic Errors:
• Techniques such as karyotyping and genetic testing
enable the identification of meiotic abnormalities.
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Meiotic Abnormalities and Therapeutic
Opportunities
Targeting Meiotic Pathways: Understanding meiotic
processes is essential for developing therapeutic strategies
against meiosis-related conditions.
• Meiosis as a Therapeutic Target: Opportunities for
developing drugs that selectively modulate meiosis in genetic
disorders.
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Conclusion
Meiosis is a fundamental process crucial for sexual
reproduction, ensuring genetic diversity in offspring.
• Dysregulation of meiosis can lead to genetic
disorders, emphasizing the importance of
understanding meiotic processes in clinical contexts.
• Ongoing research into meiotic pathways offers
potential therapeutic avenues for mitigating diseases
related to meiotic abnormalities.
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Questions and Homework
What are the key phases of meiosis, and how does
each phase contribute to the formation of genetically
diverse gametes?
• Can you explain the significance of crossing over and
synapsis during meiosis?
• How do errors in meiosis contribute to genetic
disorders, and can you provide examples?
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• Thank you for your attention. It's

time for questions and discussion.