Bioc270-02 Lecture Chapter 2 Cell Cycle Mitosis Meiosis PDF

Summary

This document is lecture notes for a general genetics course (BIOL 270) on the cell cycle, mitosis, and meiosis, covering concepts like chromosome theory, different cell types, and the genetic processes in these cell divisions. Fall 2024.

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General Genetics
BIOL 270
Lecture Chapter 2
Dr Haslina Razali
Fall 2024
PART I Basic Principles: How Traits Are Transmitted CHAPTER
CHAPTER
3
The Chromosome

Theory of Inheritance

CHAPTER OUTLINE

▪ 4.1 Chromosomes: The Carriers of Genes
▪ 4.2 Mitosis: Cell Division That Preserves Chromosome Number
▪ 4.3 Meiosis: Cell Divisions That Halve Chromosome Number
▪ 4.4 Gametogenesis
▪ 4.5 Validation of the Chromosome Theory

2
Chromosomes are cellular structures that transmit genetic
information

❑ Breeding experiments and microscopy
provided evidence for the
chromosome theory of inheritance

❑ Proper development relies on
accurately passing on genes and
accurate maintenance of chromosome
number

❑ The abstract idea of a gene was
changed to a physical reality by the
chromosome theory

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Hartwell et al., 4th ed., Chapter 4
 Evidence that genes reside in chromosomes
Mitosis – process that generates _______________containing
2 daughter cells the same number and
type of chromosomes/genes as parent cell. In other words, the 2 daughter cells are
identical to each other to the parent cell.

❑ For instance, in humans:
46 chromosomes 46 chromosomes
(parent cell) (each daughter cell)

4
 Evidence that genes reside in chromosomes
❑ Meiosis – process that generates gametes (= egg and sperm cell ) that have ____the
half
number of chromosomes compared to the parent cell.

❑ For instance, in humans:

46 chromosomes 23 chromosomes
(parent cell) (gamete: sperm or egg cell)

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Hartwell et al., 4th ed., Chapter 4
 Diploid versus haploid: 2n versus n
❑ Most body cells are diploid (chromosomes are in pairs: one copy from mother
and one copy from father)
❑ Meiosis: diploid (2n) → haploid (n) gametes (= egg and sperm cells)
In humans , 2n = 46 and n = 23, In Drosophila, 2n = 8, n = 4

Diploid = double set of chromosomes

Haploid = 1 set of chromosomes

Fig. 4.2

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Fertilization is the union of haploid gametes to produce diploid
zygotes

7
 Homologous chromosomes are matched in size, shape and
banding patterns
❑ Homologs (= homologous pairs of chromosomes) contain the same set of genes,
but can have different alleles for some genes

❑ Non-homologs carry completely unrelated sets of genes

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Hartwell et al., 4th ed., Chapter 4
Metaphase chromosomes can be classified by centromere position

Fig. 4.3

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 Homologous chromosomes are matched in size,
shape and banding patterns
❑ Karyotype – micrograph (photo) of stained
chromosomes arranged in homologous
pairs (see Figure)
Sex chromosomes – unpaired X and Y
chromosome
Autosomes – all chromosomes except X
and Y

❑ Cells of each species have a characteristic
diploid number of chromosomes
▪e.g. D. melanogaster, 2n = 8; D.
obscura, 2n = 10; D. virilis, 2n = 12;
sweet peas, 2n = 14; goldfish, 2n = 94;
dogs, 2n = 78 10
 Karyotype of a human male
❑ The chromosomes most visible only at the metaphase stage of mitosis (more
condensed).
❑ 22 homologous pairs of autosomes and two sex chromosomes.
❑ Each chromosome has a characteristic size and shape in the “normal” cell

Photos of metaphase
human chromosomes
(2n = 46, n = 23)

Fig. 4.4

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Hartwell et al., 4th ed., Chapter 4
 The X and Y chromosomes determine sex in humans

Children receive an X chromosome from their mother, but either an X or
Y chromosome from their father
Results in 1:1 ratio of females-to-males

Fig. 4.6
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Hartwell et al., 4th ed., Chapter 4
Mechanisms of sex determination differ between species

Homogametic
vs
Heterogametic

13
Table 4.2
 The cell cycle is a repeating pattern of cell growth and division

❑ During mitosis chromosomes are equally distributed to two genetically
identical daughter cells

❑ Interphase: 3 parts:
o gap 1 (G1) phase,
o synthesis (S) phase,
o gap 2 (G2) phase
▪ Period of cell growth and chromosome duplication between divisions

▪ Formation of microtubules in cytoplasm
o Centrosome – microtubule organizing center near the nuclear envelope (pair of
centrioles in animal cells)
o Centrioles – core of centrosome, not found in plant cells
14
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Checkpoints help regulate the
cell cycle

❑ At each checkpoint, prior
events must be completed
before the next step of the
cycle can begin

❑ Details of cell-cycle regulation
and checkpoint controls are
described in Chapter 17

Fig. 4.11

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 The cell cycle: An alternation between interphase and mitosis

❑ G1 and G2 phases: Most of cell growth
occurs during these phases
❑ Some terminally differentiated cells stop
dividing and arrest (stop) in G0 stage

❑ S Phase: DNA duplication occurs. This
result in two identical sister chromatids in
later stages.

G1 S G2
Fig. 4.7a
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Hartwell et al., 4th ed., Chapter 4
 What happens during interphase and checkpoints?

❑ Start of Interphase → G1 phase → the cell
grows and protein necessary for cell division
are synthesized.
❑ Enzymes necessary for DNA duplication
❑ G1/S checkpoint → cell is committed to divide
❑ S phase (DNA synthesis) → chromosome
duplication (double) → production of identical
sister chromatids joined at the centromere
❑ If this phase is blocked (by drugs or mutation) →
Is there DNA duplication or mitosis? NO
❑ G2 phase → additional biochemical events necessary for cell division take place
❑ After G2/M checkpoint has passed, the cell is ready to divide
❑ Interphase → chromosomes are in relaxed (uncoiled and cannot be seen with a
microscope) 17
 What happens during interphase and checkpoints?

❑ Formation of microtubules in cytoplasm
o Centrosome – microtubule
organizing center near the nuclear
envelope (pair of centrioles in animal
cells)
o Centrioles – core of centrosome, not
found in plant cells
❑S and G2 stages → centrosomes replicate
→ 2 centrosomes at close proximity

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 Two general types of cells in plants and animals

❑Somatic cells make up vast
majority of cells in the organism

In G0 or are actively going
through mitosis

❑ Germ cells are precursors to gametes
Set aside from somatic cells during embryogenesis
Become incorporated into reproductive organs
Only cells that undergo meiosis produce haploid gametes
Cell cycle: Interphase & Mitotic phase (Mitosis & Cytokinesis)

Prometaphase

https://www.thoughtco.com/stages-of-mitosis-373534 20
 Mitosis

Sister Two daughter
chromatids cells
separate

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 Stages of mitosis: Prophase

❑ Chromosomes form (condense) and become visible
❑ Centrosomes (pairs of centrioles) start to move toward opposite poles
❑ Nucleolus comes apart

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Hartwell et al., 4th ed., Chapter 4
 Stages of Mitosis: Prometaphase
❑ Nuclear envelope breaks down, nucleus comes apart
❑ Spindle fibers (microtubules) extend from centrosomes and connect to kinetochores at
centromere region of each chromatid.
❑ Mitotic spindle starts to forms (Kinetochore microtubules, polar microtubules & astral
microtubules)
❑ Centrosomes are at or near opposite poles

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Hartwell et al., 4th ed., Chapter 4
 Stages of mitosis: Metaphase

❑ Chromosomes line up one by one at the metaphase plate with sister chromatids facing
opposite poles
❑ Spindle is fully formed: Centrosomes are at opposite poles and spindle fibers are
attached to kinetochores of chromosomes.
❑ Some spindle fibers attach to each other at the metaphase plate

24
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Hartwell et al., 4th ed., Chapter 4
 Stages of mitosis: Anaphase

❑ Sister chromatids are pulled apart by spindle fibers (microtubules).
❑ Spindle fibers (kinetochore microtubles) pull separated sister chromatids (= new
‘daughter chromosomes’) toward opposite poles (characteristic V shape)

Figure 4.8d
Is the genetic information from one sister chromatids the same of it’s
counterpart moving in the
Copyright © The opposite direction?
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Hartwell et al., 4th ed., Chapter 4
YES 25
 Stages of mitosis: Telophase

❑ Cytokinesis (= the splitting of the cell) starts
❑ Nuclear envelope forms around each group of chromatids
o Nucleoli form again
o Spindle fibers come apart
o Chromosomes decondense to become chromatin again

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 Cytokinesis is the final stage of cell division

❑ Cytokinesis: Parent cells split into two daughter cells with identical nuclei
❑ Result: Each new daughter cell has a full set of daughter chromosomes (2n = diploid) that
are identical to the parent cell
❑ Large number of important organelles and cellular components (e.g. ribosomes,
mitochondria, Golgi bodies, chloroplast) parceled out to emerging daughter cells (unequal
distribution)

Figure 4.8f

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Cytokinesis: The cytoplasm divides and produces two daughter
cells

▪ Animals have contractile
ring that contracts to form
cleavage furrow

▪ Plants cells have cell plate
that forms near equator of cell

▪ Organelles (e.g. ribosomes,
mitochondria, Golgi bodies)
are distributed to each
daughter cell

Fig. 4.9
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Hartwell et al., 4th ed., Chapter 4
 After cell division

❑ Enters the Interphase
❑ G1 – Protein synthesis & cell
growth

❑ S – Chromosome & centrosome
duplication

❑ G2 – More protein synthesis & cell
growth

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Counting Chromosomes and DNA Molecules

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 Mitosis: Once more

Youtube video clips:
https://www.youtube.com/watch?v=AhgRhXl7w_g
https://www.youtube.com/watch?v=C6hn3sA0ip0

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Checkpoints help regulate the
cell cycle
❑ At each checkpoint, prior events
must be completed before the
next step of the cycle can begin

❑ Chromosomes completely
copied

❑ All kinetochore attached to
spindle fibers before separating
at centromeres

❑ Cell size sufficient Fig. 4.11

32
 Mitosis has five stages that have distinct cytological
characteristics

Interphase: DNA replication (and transcription)

The five stages of mitosis and their major events:

Prophase – chromatin condenses to form chromosomes
MITOSIS

Prometaphase – spindle forms and sister chromatids attach to
microtubules from opposite centrosomes

Metaphase – chromosome line up at the metaphase plate

Anaphase – sister chromatids separate and move to opposite poles

Telophase – chromosomes decondense (form chromatin) and nuclei
form again
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Hartwell et al., 4th ed., Chapter 4
 Genetic consequences of the cell cycle

❑ From one single cell to two daughter cells containing the same genetic
materials.
❑ Each of the cells = full complement of chromosomes.
❑ BUT cytoplasmic content (organelles) are not identical or are evenly divided.

Dr. Haslina Razali 34
Mitosis: Once more

35
Mitosis: Once more

36
 Recap

A. C.
The three cells shown in figures a–c
are all from the same individual.
o For each cell, indicate what
stage of cell division is
represented?
B.
o State the number of
chromosome and number of
chromatids in each cell.

37
 Overview of Meiosis

❑ Two rounds of meiosis
❑ Replication occurs once
❑ Cells divide twice

Fig. 4.12

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Hartwell et al., 4th ed., Chapter 4
Two types of division in Meiosis

Reductional division

Equational division

39
 Prophase I:

❑ Homologous chromosomes pair up and are held together by synaptonemal
complex
❑ Crossing-over (recombination) occurs during Prophase I Synapsed chromosome pair =
bivalent (2 chromosomes)/tetrad
(4 chromatids)

What is
crossing
over?

Crossing over is where genetic information is
exchanged between nonsister chromatids of a
homolog pair
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Feature Fig. 4.13
Hartwell et al., 4th ed., Chapter 4
40
 Prophase I (continued):

❑ Synaptonemal
complex comes
apart and
chromatids in
each tetrad
become visible

Feature Fig. 4.13

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Hartwell et al., 4th ed., Chapter 4
 In Metaphase I and Anaphase I,
homologs move to opposite poles

❑ Note that the
centromeres do
not divide
❑ and sister
chromatids are not
separated

Feature Fig. 4.13
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Hartwell et al., 4th ed., Chapter 4
Meiosis I: from diploid (2n) to haploid (n)

❑Interkinesis = No
chromosome
duplicate

Feature Fig. 4.13

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Hartwell et al., 4th ed., Chapter 4
 During Meiosis II, sister chromatids separate and move to
opposite poles

Are the
sister
chromatids
identical to
each other?
NO
Feature Fig. 4.13

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Hartwell et al., 4th ed., Chapter 4
Meiosis II: from haploid (n) to haploid (n)

Feature Fig. 4.13
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Hartwell et al., 4th ed., Chapter 4
 Overview of Meiosis I

▪ Homologs pair up, exchange parts, and then segregate

▪ Maternal and paternal homologous pairs of chromosomes recombine and
create new combinations of alleles (‘crossing- over’)

▪ After recombination (crossing over), homologous pairs of chromosomes
segregate to different daughter cells (Propose I – Pachytene)

▪ Sister chromatids remain together throughout meiosis I

▪ Depending on the species, length of time in prophase I can be short or very
long

▪ Number of chromosome is reduced to half (haploid)

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 Overview of Meiosis II

▪ Enters interkinesis, a period between Meiosis I and Meiosis II – No DNA
duplication

▪ Separation of sister chromatids

▪ Number of chromosome is still half (Haploid)

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Hartwell et al., 4th ed., Chapter 4 47
Meiosis: Once more

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Meiosis: Once more

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 Meiosis clips

https://www.youtube.com/watch?v=vyf2xwqzfFs
https://www.youtube.com/watch?v=BVO-Ram1L2M
https://www.youtube.com/watch?v=D1_-mQS_FZ0

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Mitosis Meiosis
Somatic cells undergo mitosis. Germ cells undergo meiosis.
Purpose: Produce somatic cells for Purpose: Produce gametes (egg &
growth or replacing other cells. sperm cells);

51
52
 Mitosis versus Meiosis

Table 4.3
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Hartwell et al., 4th ed., Chapter 4
Mitosis versus Meiosis (continued)

Table 4.3
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Hartwell et al., 4th ed., Chapter 4
 Meiosis contributes to genetic
diversity in two ways

❑Crossing-over between
homologs creates different
combinations of alleles within
each chromosome

❑Independent assortment of
non-homologs creates different
combinations of alleles
Fig. 4.16
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Hartwell et al., 4th ed., Chapter 4
 Crossing over

❑Crossing-over between
homologs creates different
combinations of alleles within
each chromosome

56
 Independent assortment

A a A a
❑ Independent
B b b B assortment of
non-homologs
creates different
A a A a
combinations of
alleles
B b b B
A A a a A A a a

B B b b b b B B
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 Gametogenesis in sexually
reproducing animals

❑ Germ line – specialized diploid cells set aside during embryogenesis

❑ Gametogenesis – the formation of gametes
Involves meiosis as well as specialized events before and after meiosis
Different types of animals have variations on general aspects of this
process
In humans, oogenesis produces one ovum from each primary oocyte
In humans, spermatogenesis produces four sperm from each primary
spermatocyte

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 Mistakes in meiosis produce defective gametes

❑ Nondisjunction – mistakes in chromosome segregation during Meiosis I or II
(usually during Anaphase I, e.g. trisomy 21)

May result in gametes or embryos that don’t survive

Can also result in abnormal chromosome numbers in surviving individuals (e.g.
trisomy 21, Down syndrome; or XXY, Klinefelter syndrome)

❑ Many hybrids between species (i.e. donkey x horse → mule) are sterile because
chromosomes cannot pair properly (hybrid sterility)

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 Down-Syndrome: Mistake during Meiosis

Trisomy 21:
The cause for
down-syndrome

Probability with
mother’s age:
25: 1/1200
35: 1/350
40: 1/100
49: 1/10
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Klinefelter Syndrome: Mistake during meiosis

❑ extra X chromosome in a male

❑ Two X chromosomes ->
female development fail

❑ Tall, thin and sterile, mental
retardation

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 Sterile hybrids

Many hybrids between species
(i.e. donkey (62) x horse (64) → mule (63))
are sterile because chromosomes cannot pair
properly (hybrid sterility)

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 https://www.denverpost.co
m/2013/08/16/colorado-
miracle-mule-foal-lived-
short-life-but-was-well-
loved/
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