Cell and Nuclear Division PDF

Summary

This document provides a conceptual overview of cell division, specifically focusing on the processes of mitosis and meiosis in eukaryotic cells. It includes descriptions of the various phases, key events, and the role of checkpoints in regulating the cell cycle. The content covers comparison between prokaryotic and eukaryotic cell division as well.

Full Transcript

D 2. 1 C E L L A N D
N U C L EA R
D IV I S I O N
 GUIDING QUESTIONS
HOW CAN LARGE NUMBERS OF GENETICALLY
IDENTICAL CELLS BE PRODUCED?

HOW DO EUKARYOTES PRODUCE GENETICALLY
VARIED CELLS THAT CAN DEVELOP INTO
GAMETES?
 Compare
prokaryotic

CELL DIVISION cells and
eukaryotic
cells.

PROKARYOTIC CELLS EUKARYOTIC CELLS
BINARY FISSION
o Mitosis – somatic
body cells (46
chromosomes)

o Meiosis – gametes
(23 chromosomes)

Compare: Give an account of similarities and differences between two
(or more) items, referring to both (all) of them throughout.
 CELL DIVISION IN EUKARYOTES
INCLUDES INTERPHASE
Interphase is
the longest
portion of a cell’s
life and has
three
subdivisions:
First Gap (G1)
Synthesis (S)
Second Gap
(G2)
This Photo by Unknown Author is licensed under
CC BY-SA-NC
This P
hoto
by
Unknow
n
Autho
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licens
 First Gap

G
G
Kina
se 0
 CYCLINS
CYCLINS ARE A GROUP OF PROTEINS THAT CONTROL CELL CYCLE PROGRESSION
CYCLINS WERE DISCOVERED BY TIMOTHY HUNT, LELAND H. HARTWELL AND PAUL M
NURSE, WHO FOUND THAT THE CONCENTRATION OF EACH CYCLIN WAS DIFFERENT AT
EACH STAGE AND CHANGED IN A CYCLICAL FASHION. THEY WON A NOBEL PRIZE IN 2001
FOR THEIR CONTRIBUTION TO PHYSIOLOGY AND MEDICINE.
CYCLINS BIND TO CYCLIN-DEPENDENT KINASES (CDKS) WHICH ARE ENZYMES
CYCLINS MOVE CELLS THROUGH THE PHASES OF THE CELL CYCLE AND STOP
PROGRESS AT CHECKPOINTS
SOME CELLS PAUSE DURING G1 AND ENTER G0
This Photo by Unknown Author is licensed under CC BY
A cell can stay in G1
indefinitely. Two
factors determine
the length of this
pause, the type of
tissue that the
cell is in and the
Temperature
function of the Light
cell. pH levels
Nutrient
This pause is often availability
referred to as G0, or
resting phase.
Nerve and heart
muscle cells, once
CHECKPOINTS
Synthesis

S
Kina
se Checkp Second Gap
Casc oint
ade

G
G
0
 The name ‘interphase’ implies a period of time between
stages and that nothing much is going on. This is not the case!

Interphase is when the cell is going about it’s day-to-day
‘business’ i.e. carrying out it’s programmed functions and
growing (metabolic reactions, protein synthesis, DNA
replication, increase in the number of mitochondria and
chloroplasts)
QUESTION: Imagine if cells did not have a
growth phase. What would happen to the
size of daughter cells with progressive
rounds of mitosis?
Interphase
is when all of
the cell’s
genetic
instructions
are
processed.
Any time new cells are required,
mitosis is required:

Growth: An 18 year old has many more cells than an 18 month old! This P
hoto
by
Embryonic development: You start as a zygote, one cell! Unknow
n

Tissue repair: Burnt, bashed, cut or eaten; dead or lost cells need
Autho
r is
licen

to be replaced. sed
under
CC BY-
Asexual reproduction: In organisms
Sea stars: These eukaryotes only
reproduce by fission. SA-NC

Asexual Hydra: They reproduce by budding.
rep. in Yeast: These organisms reproduce by budding.
animal Paramecium: They produce offspring by binary fission.
s Stick insects: They use the mode of parthenogenesis sometimes to reproduce.
 “MITOSIS, HOW CELLS R
ENEW!”

s old
s is i DN)
o 2
Mit (SNC
s
new
Mitosis: The cell divides its chromosomes into 2
identical sets
4 Main stages
^
C
CHECKPOINT
Cytoki
nesis
(pinch
ing)
Proph
ase

Metap
hase
This Photo by Unknown Author is licensed under CC BY

Anapha
Pe
a

MA
T
Peo
ple

Mee
t

And This Photo by Unknown Author is licensed under CC BY
Don’t forget
about
Cytokinesis!
 Inward pinching
of plasma
Recall : The fluid membrane
nature of the double
membrane facilitates
the process of
cytokinesis

Midway between
two poles and
relatively rigid 🡪
move outward
from central
region
The cell plate is formed
from the fusion of vesicles
containing cell wall
materials
 Stage Events
Gap 1 (G1) Protein Synthesis
Organelles produced
Cytoplasm increases in size
Checkpoint 🡪 cascade 🡪 G0
Synthesis (S) DNA is duplicated
Gap 2 (G2) Organelles produced
Cytoplasm increases in size
Checkpoint
r y

m
m
a Mitosis The cell divides it’s chromosomes into two
s
u identical sets
I
n 4 Stages
Prophase (early/late)
Metaphase (pre-metaphase) 🡪 checkpoint
Anaphase
Telophase

Cytokinesis The parent cell divides into two daughter cells
 A NOTE ON CANCER

A DISEASE THAT OCCURS WHEN A CELL’S CYCLE IS OUT OF CONTROL
CHECKPOINTS ARE MECHANISMS THAT REGULATE PROGRESSION THROUGH THE CELL
CYCLE INSURING THAT EACH STEP TAKES PLACE ONLY ONCE AND IN THE RIGHT
SEQUENCE. MUTATIONS OF CHECKPOINT PROTEINS ARE FREQUENT IN ALL TYPES OF
CANCER AS DEFECTS IN CELL CYCLE CONTROL CAN LEAD TO GENETIC INSTABILITY.
THE G1/S TRANSITION IS WHERE MOST CANCER‐RELATED DEFECTS OCCUR.
MASS OF ABNORMAL CELLS ARE REFERRED TO AS A TUMOR
PRIMARY TUMOR IS ONE THAT OCCURS AT THE ORIGINAL SITE OF THE CANCER
SECONDARY TUMOR IS A METASTASIS THAT HAS SPREAD FROM THE ORIGINAL
LOCATION TO ANOTHER PART OF THE ORGANISM
FIRST YEAR 2 SKETCHBOOK
ENTRY

DRAW THE PHASES OF
MITOSIS AND ANNOTATE
THE MAJOR EVENTS.

This Photo by Unknown Author is licensed
under CC BY-SA
 Now for Meiosis
Meiosis is a reduction division...
⚫ Cell division process in which the number of
chromosomes is cut in half.
⚫ Results in the formation of gametes (such as
eggs and sperm)
⚫ Gametes have ½ the chromosomes of regular
cells (HAPLOID = n)
⚫ Fusion of an egg and sperm results in a zygote
(Somatic)
⚫ Proper chromosome number has been restored
(DIPLOID = 2n)
⚫ The halving of the chromosome number allows a
sexual life cycle with fusion of gametes
⚫ In a diploid human cell
⚫ 46 chromosomes grouped into 23
pairs of chromosomes
(homologous chromosomes)
⚫ We use the letter n to denote the
number of unique chromosomes in an
organism.
⚫ In eukaryotes, there are n pairs of
chromosomes. With two of each, that
makes a total of 2n per cell.

⚫ Haploid = n = egg/sperm = gamete
= 23 chromosomes
⚫ Diploid = 2n = zygote = somatic =
46 chromosomes
 Homologous Chromosomes
Homologous chromosomes are chromosome pairs of the same length, centromere
position, and staining pattern with genes for the same characteristics. One
homologous chromosome is inherited from the organism's mother, the other from the
organism's father (23 pairs in humans = 46)
 Process of Meiosis
Meiosis includes two rounds of division: Meiosis I & Meiosis II.

Meiosis I Prophase I, Metaphase I, Anaphase I and Telophase I
Homologous chromosomes are paired
While paired, they cross over and exchange genetic information (DNA)
Homologous pairs are then separated, and two daughter cells are produced

Meiosis II Prophase II, Metaphase II, Anaphase II and Telophase II
The same as mitosis
Sister chromatids of each chromosome separate
Result is four haploid daughter cells
 Homologous chromosomes Sister chromatids
separate... separate...

One diploid
nucleus

Four haploid
nuclei
One diploid
nucleus

First Division
halves the
chromosome
number!

Four haploid
Meiosis I:
Prophase I:
Nuclear envelope dissolves
Spindle of microtubules starts to form
Homologues become closely associated in synapsis
Pairing of homologous
chromosomes
Crossing over may occur between non-sister
chromatids (of homologous pairs)
Chiasmata: evidence of
exchange between
chromatids

This micrograph shows a pair of
homologous chromosomes,
each with two chromatids,
during prophase I of meiosis in a
salamander

Two chiasmata are visible
(bivalent)
 Crossing over can occur on any part of a
chromosome
The size of the section swapped between
chromosomes can be almost any size
The number of chiasmata on each chromatid can
vary

These three points alone lead to innumerable
possibilities

Condensation will then follow
Chiasmata and Crossing over

This image shows that
multiple chiasmata can
form within one tetrad.
Genetic Variation
Meiosis I
Metaphase I: Spindle fibres
▪ Microtubules from opposite poles attach to each
homologue, not each sister chromatid
▪ Spindle microtubules move homologous pairs to
equator of the cell
▪ The orientation of each pair of homologues
(maternal and paternal) on either side of equator
is random and independent of other
homologous pairs
Genetic Variation
Genetic Variation

Haploid
cells

(between non-sister
homologous
chromatids...)
 Mendel’s Law of
Independent Assortment
Mendel's law of independent assortment, states that allele
pairs separate independently during the formation of gametes.
This means that traits are transmitted to offspring
independently of one another.
Mendel’s Law of Independent Assortment and Meiosis
Thomas Hunt
Thomas Hunt Morgan and
Meiosis
Meiosis I
Anaphase I:
▪ Microtubules of the spindle shorten
▪ Homologues are separated from each other
▪ Sister chromatids remain attached to each
other at their centromeres
Meiosis
Telophase I
⚫ Nuclear envelopes form around each set of
chromosomes
⚫ Each new nucleus is now haploid
⚫ Sister chromatids are no longer identical
because of crossing over
⚫ Cytokinesis occurs
 Homologous chromosomes Sister chromatids
separate... separate...

One diploid
nucleus

Four haploid
nuclei
One diploid
nucleus

First Division
halves the
chromosome
number!

Four haploid
Meiosis II
Prophase II
⚫ Chromosomes, which still
consist of two chromatids,
condense and become visible
⚫ The new spindle microtubules
develop at right angles to the
old spindle
⚫ Nuclear envelope breaks down
Meiosis II
Metaphase II
⚫ Chromosomes line up along
equator
⚫ Each chromosome attaches to a
spindle fibre by means of its
centromere
 Microtub
ule fibres

Meiosis
Anaphase II
⚫ Centromeres separate and
chromatids are moved to the
opposite poles
Meiosis II
Telophase II
⚫ Chromatids reach opposite
poles
⚫ Nuclear envelops forms
⚫ Cytokinesis occurs
 Homologous chromosomes Sister chromatids
separate... separate...

One diploid
nucleus

Four haploid
nuclei
LET’S PAUSE FOR
GLENN….
HTTPS://GIZMOS.EXPLORELEARNING.COM/
 One diploid
nucleus

m e!
k Ti
b oo First Division
tch
S k e halves the
chromosome
number!

Four haploid
 Non-Disjunction
Non-disjunction occurs when chromosomes don’t separate properly during meiosis
(egg/sperm cell chromosomes vary)
Incorrect number of chromosomes
Problems with meiotic spindle cause errors in daughter cells
Homologous chromosomes do not separate properly during Meiosis I (eg. stick
together)
Sister chromatids fail to separate during Meiosis II
Too many or too few chromosomes
Non-Disjunction
 TRISOMY 21: 3 COPIES OF CHROMOSOME 21 (1 IN 800 BIRTHS)
Trisomy 21
MALFORMATION OF THE DIGESTIVE SYSTEM
DIFFERING DEGREES OF LEARNING DIFFICULTIES
PHYSICAL ABNORMALITIES
CHROMOSOME 21 IS THE SMALLEST HUMAN CHROMOSOME
FREQUENCY OF DOWN SYNDROME CORRELATES WITH THE AGE OF THE MOTHER
Down Syndrome Karyotype
WWW.EXPLORELEA
RNING.COM
 Errors in Chromosome Division

FERTILIZATION RESULTING IN 1
OR MORE EXTRA
CHROMOSOMES IS CALLED
POLYSOMY
Errors during
chromosome division
Trisomy 13 – Patau syndrome
Trisomy 18 – Edwards syndrome
Trisomy 21 – Down syndrome
RECALL: Non-Disjunction
Comparison of Mitosis and Meiosis