Biology Module 11: Phases of Cell Cycle - Meiosis PDF

Summary

This document provides a detailed description of the different phases of the cell cycle, focusing on meiosis. The text breaks down the processes of meiosis I and meiosis II, including key stages like prophase, metaphase, anaphase, and telophase in each stage. It also clarifies the purpose of meiosis, the differences between meiosis and mitosis, and the implications of errors in meiosis.

Full Transcript

OWNED BY: Necy Luz Español Villamor Dinolan Ayag Lubo

DATE: August 22, 2024
LESSON TITLE: THE DIFFERENT PHASES OF CELL CYCLE: MEIOSIS
MODULE NUMBER: MODULE 11
LESSON OBJECTIVES:
Identify the different phases of the meiotic cell division.
Describe the events happening in the different phases of the meiotic cell division.

MEIOSIS
- type of cell division that reduces the chromosome number by half
- from Diploid (2n = 46 chromosomes) to Haploid (n = 23 chromosomes).
- Only in reproductive cells in sexually reproducing organisms.
- Ensures genetic variability and maintains the chromosome number across generations.

PHASES OF MEIOSIS (MEIOSIS I & MEIOSIS II)

1. MEIOSIS I (REDUCTIONAL DIVISION):
- Reduces chromosome number from diploid (46) to haploid (23).

~ PHASES OF MEIOSIS I:
A.) PROPHASE I:
Leptonema: Chromosomes become visible after coiling.
Zygonema: Homologous chromosomes pair in a process called synapsis,
forming a bivalent (two homologous chromosomes consisting of four chromatids).
Pachynema: Chromosomes thicken, and crossing-over occurs (exchange of
chromosome segments between homologous chromosomes), ensuring genetic
variability.
Diplonema: Homologous chromosomes begin to separate, and chiasmata
(points of crossing-over) are visible.
Diakinesis: Chromosomes fully condense; chiasmata move to the ends, and
the nuclear envelope breaks down, allowing spindle fibers to form.

B.) METAPHASE I
- Homologous chromosomes align on the metaphase plate. Spindle fibers
attach to chromosomes from opposite poles.

C.) ANAPHASE I
- Homologous chromosomes separate and move to opposite poles. Unlike in
mitosis, sister chromatids remain attached at the centromere.

D.) TELOPHASE I:
- Homologous chromosomes complete their migration to the poles. The
nuclear envelope reforms, and cytokinesis occurs, producing two haploid daughter
cells.
OWNED BY: Necy Luz Español Villamor Dinolan Ayag Lubo

2. MEIOSIS II (EQUATIONAL DIVISION):
- Similar to mitosis, meiosis II separates sister chromatids, maintaining the haploid
number (23 chromosomes).

~ PHASES OF MEIOSIS II:
A.) PROPHASE II
- Spindle apparatus forms again; chromosomes condense and prepare for
division.

B.) METAPHASE II
- Chromosomes align on the metaphase plate. The kinetochores of sister
chromatids face opposite poles.

C.) ANAPHASE II
- Centromeres separate, and chromatids (now individual chromosomes)
move to opposite poles.

D.) TELOPHASE II:
- Nuclear envelopes reform around the separated chromosomes. Cytokinesis
occurs, producing four non-identical haploid daughter cells.

KEY TERMS & DEFINITIONS:
MEIOSIS: A type of cell division that reduces the chromosome number by half,
creating four genetically diverse haploid cells from a diploid parent cell.

DIPLOID (2n): A cell containing two complete sets of chromosomes (46 in
humans).

HAPLOID (n): A cell containing one complete set of chromosomes (23 in humans).

HOMOLOGOUS CHROMOSOMES: Pairs of chromosomes (one from each parent)
that are similar in shape, size, and genetic content.

SYNAPSIS: The pairing of homologous chromosomes during meiosis.

BIVALENT/TETRAD: A pair of homologous chromosomes (4 chromatids).

CROSSING-OVER: The exchange of genetic material between homologous
chromosomes, contributing to genetic diversity.

CHIASMA: The point where two homologous non-sister chromatids exchange
genetic material.
OWNED BY: Necy Luz Español Villamor Dinolan Ayag Lubo

NONDISJUNCTION: Failure of chromosomes or chromatids to separate properly
during meiosis, leading to genetic disorders (Down Syndrome).

CYTOKINESIS:
- Division of the cytoplasm, completing cell division and resulting in four
genetically distinct haploid cells.

KEY POINTS TO REMEMBER:
1. Purpose of Meiosis: To reduce chromosome numbers and create genetic diversity
through recombination (crossing-over).
2. Meiosis I Vs Meiosis II:
- Meiosis I reduces the chromosome number from diploid to haploid.
- Meiosis II separates sister chromatids, like mitosis, but in haploid cells.
3. Errors in Meiosis: Nondisjunction and other errors (translocation, deletion) can cause
genetic disorders, impacting human health significantly.
4. Crossing-over & Genetic Variability:
- Crossing-over during Prophase I is key to introducing genetic variation in offspring,
which is a fundamental advantage of sexual reproduction.

DIFFERENCES BETWEEN MITOSIS AND MEIOSIS:
1. NUMBER OF CELL DIVISIONS:
- Mitosis: 1
- Meiosis: 2
2. NUMBER OF DAUGHTER CELLS:
- Mitosis: 2
- Meiosis: 4
3. GENETIC IDENTITY:
- Mitosis: Daughter cells are genetically identical to the parent cell.
- Meiosis: Daughter cells are genetically different from the parent cell due
to crossing-over and independent assortment.
4. CHROMOSOME NUMBER:
- Mitosis: Same as parent cell (diploid, 46 chromosomes).
- Meiosis: Half of parent cell (haploid, 23 chromosomes).
5. WHERE:
- Mitosis: Somatic cells.
- Meiosis: Gametes (sex cells).
6. WHEN:
- Mitosis: Throughout life for growth and repair.
- Meiosis: During sexual maturity for reproduction.
7. ROLE:
- Mitosis: Growth, repair, and asexual reproduction.
- Meiosis: Sexual reproduction and genetic diversity.
OWNED BY: Necy Luz Español Villamor Dinolan Ayag Lubo

COMMON ERRORS IN MEIOSIS:
NON-DISJUNCTION: Failure of homologous chromosomes or sister chromatids
to separate, leading to genetic disorders like:
- DOWN SYNDROME: Extra copy of chromosome 21.
- KLINEFELTER SYNDROME: Additional X chromosome (XXY).
- TURNER SYNDROME: Missing X chromosome in females (XO).

OTHER ERRORS:
- TRANSLOCATION: A chromosome fragment attaches to a non-
homologous chromosome.
- DELETION: Loss of a chromosome segment, affecting the genetic
material.