Eukaryotic Cell Cycle & Cell Division (Notes)

Summary

These notes cover the eukaryotic cell cycle, mitosis, meiosis, and sexual reproduction. They detail the stages involved, highlight important terms, and describe the processes of chromosome replication and segregation. Information on the differences between mitosis and meiosis is also provided.

Full Transcript

Chapter 14 – How Eukaryotic Cells Sort and Transmit
Chromosomes: Mitosis and Meiosis
Chapter Outline
1. The eukaryotic cell cycle
2. Mitotic cell division
3. Meiosis
4. Sexual reproduction
5. Variations in chromosome
structure and number

Remember blue font color
marks important ideas and bold
marks terms to master
14.1 The Eukaryotic Cell Cycle

Section 14.1 Learning
Outcomes
1. Describe how sets of
chromosomes are examined
microscopically
2. Define the following
terms and sketch examples
of each: sister chromatids,
diploid cell, haploid cell,
homologous chromosomes
3. Describe the phases of the
eukaryotic cell cycle
4. Explain how cyclins, cdks,
and checkpoints regulate
progression through the
eukaryotic cell cycle
14.1 The Eukaryotic Cell Cycle

Cell division, the reproduction of cells, is a highly regulated process
The cell cycle is a series of
events that results in cell
division; it is highly regulated
so cell division occurs at the
appropriate time
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14.1 The Eukaryotic Cell Cycle
Chromosomes Are Inherited in Sets and Occur in
Homologous Pairs
When cells prepare to divide, the chromosomes become compact
enough to be seen with a light microscope

A karyotype reveals
the number, size, and
form of chromosomes
in an actively dividing
cell
 14.1 The Eukaryotic Cell Cycle
Chromosomes Are Inherited in Sets and Occur in
Homologous Pairs

Human genome:
23 pairs
46 total
22 autosomal pairs
1 sex pair

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Diploid
Haploid
14.1 The Eukaryotic Cell Cycle
Chromosomes Are Inherited in Sets and Occur in
Homologous Pairs
Homologs / Homologous
chromosomes
Same DNA sequences in the same
order
Packages of genes
Gene locus
Two Alleles at each Gene Locus
Sets up a “back up” system in case
you inherit a “nonfunctional”
copy from one parent

This Photo by Unknown Author is licensed under CC
BY-SA
 14.1 The Eukaryotic Cell Cycle
Dividing cells progress through a series of phases

Cells may also
exit the cycle
and remain in
G0, a non-
dividing phase
14.1 The Eukaryotic Cell Cycle
The Cell Cycle Is a Series of Phases That Lead to
Cell Division
G1 (first gap) phase is a period when cells typically grow;
environmental conditions and signaling molecules can direct a cell
to progress through the cell cycle
S (synthesis) phase is the period of DNA replication; after
replication the 2 duplicate copies of each chromosome stay joined to
each other and are called sister chromatids
G2 (second gap) phase is a period
when a cell synthesizes the
proteins necessary for
chromosome sorting and cell
division; some growth may occur
M phase is a period of division;
mitosis divides one cell nucleus
into two nuclei and cytokinesis
divides the cytoplasm
14.1 The Eukaryotic Cell Cycle
Cyclins and Cyclin-Dependent Kinases Advance
a Cell through the Cell Cycle
14.1 The Eukaryotic Cell Cycle
Cyclins and Cyclin-Dependent Kinases Advance
a Cell through the Cell Cycle
Checkpoints regulate the advancement of a cell through the cell
cycle
14.2 Mitotic Cell Division

Section 14.2 Learning
Outcomes
1. Explain how the replication
of eukaryotic chromosomes
produces sister chromatids
2. Describe the structure and
Loading… function of the spindle
apparatus
3. Name the phases of mitosis
and describe the key events
that occur during each phase
4. Sketch the phases of
mitosis for a diploid cell
with a total of 8
chromosomes (4
homologous pairs)
14.2 Mitotic Cell Division

During mitotic cell division, a cell divides to produce two new cells
that are genetically identical to the original cell (and genetically
identical to each other)
Original cell is the mother cell; new cells are daughter cells
Process involves mitosis and cytokinesis

Mitotic divisions are used for
asexual reproduction and
for growth and development
of multicellular organisms
14.2 Mitotic Cell Division
Eukaryotic Chromosomes Are Replicated and Compacted

to Produce
DNA is replicated in Pairs Called
S phase beforeSister Chromatids
Mitosis.
The copy is “stapled” to the original.
This will be helpful when moving chromosomes around in mitosis.
The identical copies are called sister chromatids.
One replicated chromosome contains two sister chromatids.
14.2 Mitotic Cell Division
The Spindle Apparatus Organizes and Sorts
Chromosomes During Cell Division
The spindle apparatus organizes and sorts the chromosomes during
cell division; it is composed of microtubules
In animal cells, microtubule growth and organization start at two
centrosomes (aka microtubule organizing centers)
A single centrosome duplicates
during interphase
Centrosomes separate from
each other during mitosis and
each defines a pole of the
spindle apparatus
Centrosomes in animal cells
have centrioles; however
centrioles are not found in
many other eukaryotic species
14.2 Mitotic Cell Division
The Transmission of Chromosomes in Eukaryotes
Requires a Sorting Process Known as Mitosis
Big goal of Mitosis:
Line up those replicated chromosomes…
Snap them apart, sending one chromatid to one daughter cell and
the other chromatid to the other daughter.
14.2 Mitotic Cell Division
The Transmission of Chromosomes in Eukaryotes
Requires a Sorting Process Known as Mitosis
14.2 Mitotic Cell Division
The Transmission of Chromosomes in Eukaryotes
Requires a Sorting Process Known as Mitosis
14.2 Mitotic Cell Division
The Transmission of Chromosomes in Eukaryotes
Requires a Sorting Process Known as Mitosis
The process of cytokinesis, which divides the cytoplasm to produce
2 distinct daughter cells, occurs differently in plant and animal cells
In animal cells, a cleavage furrow forms which constricts (like a
drawstring) to separate the cells
In plant cells, vesicles from the Golgi move along microtubules to
the center of the cell and coalesce to form a cell plate
New cell wall will form from the cell plate
14.3 Meiosis

Section 14.3 Learning
Outcomes
1. Describe the processes of
synapsis and crossing over
2. Name the phases of meiosis
and describe the key events
that occur during each phase
3. Sketch the phases of
meiosis for a diploid cell with
a total of 8 chromosomes (4
homologous pairs)
4. Compare and contrast
mitosis and meiosis, focusing
on key steps that account for
the different outcomes of
these two processes
14.3 Meiosis and Sexual Reproduction

In humans, specialized cells within the
reproductive organs (ovaries and testes)
undergo Meiosis to produce gametes
(sperm and egg cells)
14.3 Meiosis and Sexual Reproduction
Meiosis I Separates Homologous Chromosomes
Like mitosis, meiosis begins after a cell
has progressed through the G1, S, and G2
phases of the cell cycle
Like mitosis, the sorting of chromosomes
during meiosis occurs as a series of
stages called prophase, prometaphase,
metaphase, anaphase, and telophase

Meiosis I separates homologous
chromosomes from each other
The pairing of homologous
chromosomes is a distinguishing
feature of meiosis
Meiosis II separates sister chromatids
from each other
14.3 Meiosis and Sexual Reproduction
Meiosis I Separates Homologous Chromosomes
14.3 Meiosis and Sexual Reproduction
Meiosis I Separates Homologous Chromosomes
Cytokinesis follows meiosis I

Meiosis I has produced 2 haploid cells;
these cells do not have pairs of
homologous chromosomes anymore

There is no S phase between meiosis I
and meiosis II

Meiosis II separates sister chromatids
during anaphase whereas meiosis I
separates bivalents during anaphase
14.3 Meiosis and Sexual Reproduction
Meiosis II Separates Sister Chromatids
The sorting events of meiosis II include prophase II, prometaphase II,
metaphase II, anaphase II, telophase II
14.3 Meiosis and Sexual Reproduction
Mitosis and Meiosis Differ in a Few Key Steps
Mitosis produces 2 diploid daughter cells that are genetically identical
Meiosis produces 4 haploid daughter cells that are genetically diverse
14.4 Sexual Reproduction

Section 14.4 Learning
Outcomes
1. Explain how meiosis
enhances genetic diversity
among gametes
2. Compare and contrast the
advantages and disadvantages
of sexual reproduction
3. Distinguish between diploid-
dominant, haploid-dominant,
and alternation of generations
life cycles
14.4 Sexual Reproduction
Sexual Reproduction Provides a Mechanism for
Greater Genetic Diversity in Offspring
Sexual reproduction involves two haploid gametes (generated by
meiosis) fusing together to form a diploid cell called a zygote
A potential advantage of sexual reproduction is that is allows for
greater genetic variation in offspring (which can be acted upon by
natural selection, allowing faster adaptation to the environment)
Meiosis enhances genetic diversity through random alignment of
homologous chromosomes and though crossing over
For humans there are over 8 million (223) possibilities for the
alignment of the chromosomes
For any diploid species, the number of random alignments
equals 2n where n equals the number of chromosomes per set
Compared with asexual reproduction, disadvantages of sexual
reproduction include need for two types of gametes, specialized
body parts, and ability to find mates (all of which require energy)
14.4 Sexual Reproduction
Sexually Reproducing Species Produce Haploid and
Diploid Cells at Different Times in Their Life Cycles
A life cycle is a sequence of events that produces another generation
of organisms
For sexually reproducing organisms, the life cycle involves an
alternation between haploid and diploid states
Different organisms vary in regards to the amount of time they
spend in haploid versus diploid states

Most animal species are classified as
diploid-dominant species, meaning
most of the life cycle is spent in the
diploid state
14.4 Sexual Reproduction
Sexually Reproducing Species Produce Haploid and
Diploid Cells at Different Times in Their Life Cycles
Many fungi and some protists are haploid-dominant species,
meaning most of the life cycle is spent in a haploid state
The “mature” multicellular organism is composed of haploid
cells

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 14.4 Sexual Reproduction
Sexually Reproducing Species Produce Haploid and
Diploid Cells at Different Times in Their Life Cycles
Plants and some algae exhibit an alternation of generations,
spending similar amounts of time in diploid and haploid states
The sporophyte is a multicellular diploid organism and the
gametophyte is a multicellular haploid organism
 Let’s practice

Question 8
A type of organism that exhibits alternation of generations is
) an animal
) a mammal
) a fungus
) a plant
) both a and b are correct
14.5 Variation in Chromosome Structure and Number

Section 14.5 Learning
Outcomes
1. Describe how chromosomes
vary in size, centromere
location, and number
2. Identify the 4 ways that the
structure of chromosomes can
be changed
3. Compare and contrast
changes in the number of sets
of chromosomes and changes
in the number of individual
chromosomes
4. Sketch examples of the
following phenomena: triploid,
tetraploid, monosomy, trisomy
14.5 Variation in Chromosome Structure and Number

Variations in chromosome structure and number can have major
effects on organisms
Several human diseases are caused by chromosomal changes
Changes in chromosome number and structure have been
important in the evolution of new species
Some types of chromosome variation are normal and some are
abnormal
14.5 Variation in Chromosome Structure and Number
Natural Variation Exists in Chromosome Structure
and Number
Chromosome composition within a given species tends to remain
relatively constant, although composition differs across species
Humans 2 sets of 23 chromosomes (total of 46)
Dog 2 sets of 39 chromosomes (total of 78)
Fruit fly 2 sets of 4 chromosomes (total of 8)
Tomato 2 sets of 12 chromosomes (total of 24)

Features used to classify and describe chromosomes include size,
location of the centromere, and banding patterns
14.5 Variation in Chromosome Structure and Number
Mutations Can Alter Chromosome Structure
Banding patterns of eukaryotic chromosomes are used to detect
changes in chromosome structure that occur as a result of mutation
Chromosomal mutations involve breaking and rejoining the
chromosomes; mutations are classified as deletions, duplications,
inversions, and translocations

Deletions and duplications change
the total amount of genetic
material in a chromosome
A deletion removes part of a
chromosome

A duplication causes part of
the chromosome to be repeated
14.5 Variation in Chromosome Structure and Number
Mutations Can Alter Chromosome Structure
Inversions and translocations are
chromosomal rearrangements
An inversion changes the direction
of the genetic material along a single
chromosome

A translocation attaches a segment
of one chromosome to a different
chromosome
Translocations can be simple or
reciprocal
14.5 Variation in Chromosome Structure and Number
Variation Occurs in the Number of Chromosome Sets
and the Number of Individual Chromosomes
Variations in chromosome number can be categorized based on:
The number of sets of chromosomes
The number of particular chromosomes within a set
Organisms that are euploid have chromosomes that occur in one or
more complete sets
Diploid (2n) 2 complete sets

Polyploid 3 or more
complete sets
Triploid (3n) 3
complete sets
Tetraploid (4n) 4
complete sets
14.5 Variation in Chromosome Structure and Number
Variation Occurs in the Number of Chromosome Sets
and the Number of Individual Chromosomes
Aneuploidy is different than euploidy
refers to an alteration in the number of just one chromosome
An extra copy of a particular chromosome causes trisomy (2n +1)
Lacking a copy of a chromosome causes monosomy (2n -1)
14.5 Variation in Chromosome Structure and Number
Variation Occurs in the Number of Chromosome Sets
and the Number of Individual Chromosomes
A change in chromosome number can
occur because of nondisjunction, the
abnormal sorting of chromosomes
during cell division

Nondisjunction during meiosis can
generate aneuploid gametes that have
too many or too few chromosomes
14.5 Variation in Chromosome Structure and Number
Changes in Chromosome Number Have
Important Consequences
In animals, deviations from diploidy
are usually lethal
A few exceptions: male bees are
haploid whereas female bees are
diploid, and there are some
polyploid species of amphibians
and reptiles

There are some cases of survivable
aneuploidies
Typically trisomies for smaller
chromosomes with fewer genes
14.5 Variation in Chromosome Structure and Number
Changes in Chromosome Number Have
Important Consequences
In animals, deviations from diploidy are usually lethal
Why?
for many genes the level of gene expression correlates with the
number of gene copies
3 copy (instead of 2) 150% of the normal amount of
product, which typically interferes with normal cell function

There are some cases of survivable aneuploidies
Typically trisomies for smaller chromosomes with fewer
genes
14.5 Variation in Chromosome Structure and Number
Changes in Chromosome Number Have
Important Consequences
In contrast to animals, plants commonly exhibit polyploidy which is
important in agriculture
Polyploid plants often have characteristics that are helpful to
humans large, robust, adaptable
Ex: the wheat we use to make bread is hexaploid (6n)
 Let’s practice

Question 10
A person who is born with Patau Syndrome carries 3 copies of
chromosome 13 in his or her cells. Which of the following terms is an
inaccurate description of this genetic condition?
) euploid
) trisomy 13
) triploid
) Aneuploid
) A, B, C
) A, D
) B and C