Cell Cycle Control & Mitosis PDF

Summary

This document explains cell cycle control and mitosis. It details the different phases of the cell cycle, the functions of cyclins and CDKs, and the process of mitosis. The document also includes information on factors stimulating cell entry into the cycle and clinical correlations with cancer.

Full Transcript

14 Cell Cycle control & Mitosis
ILOs
By the end of this lecture, students will be able to
1. Interpret the significance of different phases of the cell cycle.
2. Correlate the phases of mitosis to normal and abnormal division outcomes.

Cell cycle control

The capability of the cell to begin and advance through the cell cycle is governed by the
presence and interactions of a group of related proteins known as cyclins, with specific
cyclin-dependent kinases (CDKs). Thus:

Cyclin D, synthesized during early G1 phase, binds to CDK4 as well as to CDK6.
Additionally, in the late G1 phase cyclin E is synthesized and binds to CDK2. These three
complexes, through other intermediaries, permit the cell to enter and progress through
the S phase.
Cyclin A binds to CDK2 and CDK1 and these complexes permit the cell to leave the S phase
and enter the G2 phase and induce the formation of cyclin B.
Cyclin B binds to CDK1, and this complex allows the cell to leave the G2 phase and enter
the M phase.(Figure 23-2)

Fig 23-2. Control of the cell cycle

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Fate of cyclins
Once the cyclins have performed their specific functions, they enter the ubiquitin-
proteasome pathway, where they are degraded into their component molecules.

Cell cycle check points
The cell also employs quality control mechanisms, known as checkpoints, to safeguard
against early transition between the phases. These checkpoints ensure the meticulous
completion of essential events, such as adequate cell growth, correct DNA synthesis, and
proper chromosome segregation, before permitting the cell to leave its current phase of
the cell cycle. The cell accomplishes such delays in the progression through the cell cycle
by activating inhibitory pathways and/or by suppressing activating pathways. (check the
details in Figure 23-3)

Factors stimulating the cell to enter the cycle:
The triggers inducing the cell to enter the cell cycle may be:
(1) A mechanical force (e.g., stretching of smooth muscle),
(2) Injury to the tissue (e.g., ischemia), and
(3) Cell death.
All of these incidents cause the release of ligands by signaling cells in the involved tissue.
Frequently, these ligands are growth factors that indirectly induce the expression of
proto-oncogenes, genes that are responsible for controlling the proliferative pathways of
the cell.
Clinical Hint
Oncogenes and cancer: Normal cell proliferation and differentiation are controlled by a
group of genes called protooncogenes; altering the structure or expression of these
genes promotes the production of tumours. The expression of proto-oncogenes must
be very strictly regulated to prevent unwanted and uncontrolled cell proliferation.
Mutations in proto-oncogenes that enable the cell to escape control and divide in an
uncontrolled way are responsible for many cancers. Such mutated proto-oncogenes are
known as oncogenes. Altered oncogene activity can be induced by a change in the DNA
sequence (mutation), an increase in the number of genes (gene amplification), or gene
rearrangement.

The Chromosomes
Chromosomes are chromatin fibers that become so condensed and tightly coiled
during mitosis and meiosis so that they are visible with the light microscope.

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 Each chromosome is formed of two sister chromatids attached at a point called
the centromere.
As the cell leaves the interphase stage and prepares to undergo mitotic or meiotic
activity, the chromatin fibers are extensively condensed to form chromosomes, carrying
the duplicated DNA (In which phase of the cell cycle?)

Fig. 23-3. Structure of the chromosome

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Types of cells in the human body
1. Somatic cells
They are the body cells that are produced by mitosis and contain 46 chromosomes
(diploid number), representing 23 homologous pairs of chromosomes. One member
of each of the chromosome pairs is derived from the maternal parent; the other
comes from the paternal parent. Of the 23 pairs, 22 are called autosomes; the
remaining pair, which determines gender, are the sex chromosomes.

The sex chromosomes of the female are two X chromosomes (XX); those of the male
are the X and Y chromosomes (XY). Only one of the two X chromosomes in female
somatic cells is transcriptionally active. The inactive X chromosome, randomly
determined early in development, remains inactive throughout the life of that
individual.
The number of chromosomes in somatic cells is specific for the species and is called
the genome, the total genetic makeup.

2. Germ cells
They are either the sperm in male or ovum in the female and produced by meiosis.
They contain 23 chromosomes (haploid number) and one sex chromosome either X
or Y.

Mitosis (M) occurs at the conclusion of the G2 phase and thus completes the cell cycle.
Mitosis is the process whereby the cytoplasm and the nucleus of the cell are divided
equally into two identical daughter cells. First, the nuclear material is divided in a
process called karyokinesis, followed by division of the cytoplasm, called cytokinesis.
The process of mitosis is divided into four distinct stages: prophase, metaphase,
anaphase, and telophase

Mitosis
Mitosis is the process of cell division that results in the formation of two identical
daughter cells.

I- Prophase
During prophase, the chromosomes condense, and the nucleolus disappears.
Each chromosome consists of two parallel sister chromatids.
As chromosomes condense, the nucleolus disappears.
The centrosome also divides into two regions, each half containing a pair of
centrioles and a microtubule-organizing center (MTOC), which migrate away
from each other to opposite poles of the cell.

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 Fig. 23-4 Centrosome structure & prophase

From each MTOC, astral rays and spindle fibers develop, giving rise to the
mitotic spindle apparatus. It is thought that the astral rays (microtubules that
radiate out from the pole of the spindle) may assist in orienting the MTOC at the
pole of the cell.
Those microtubules that attach to the centromere region of the chromosome
are the spindle fibers, which assist in directing the chromosome alignment on
cell equator and later migration of chromatids to the cell pole. In the absence of
centrioles, the microtubule-nucleating material is dispersed within the cytoplasm
with the result that astral rays and spindle fibers do not form properly, and
mitosis does not proceed in the appropriate manner. (How is related to the cell
cycle?)
Spindle fibers bind to the kinetochore in preparation for chromatid migration to
effect karyokinesis.
II- Metaphase
The nuclear envelope disappears early at this phase.
The newly duplicated chromosomes align themselves on the equator of the
mitotic spindle, being directed by the spindle fibers, and become maximally
condensed.
Each chromatid is oriented parallel to the equator, and spindle microtubules are
attached to its kinetochore (a protein on the centromere that helps in
movement of chromatids), radiating to the spindle pole (fig. 22-5).

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 Fig. 23-5. Metaphase & kinetochore

III- Anaphase
During anaphase, the sister chromatids separate and begin to migrate to
opposite poles of the cell, and a cleavage furrow begins to develop (fig. 22-6).
The spindle/kinetochore attachment site leads the way, with the arms of the
chromatids simply moving along, contributing nothing to the migration or its
pathway.
In late anaphase, a cleavage furrow begins to form at the plasmalemma,
indicating the region where the cell will be divided during cytokinesis.

Figure 23-6 Anaphase & telophase

IV- Telophase

Telophase, the terminal phase of mitosis, is characterized by cytokinesis,
reconstitution of the nucleus and nuclear envelope, disappearance of the mitotic
spindle, and unwinding of the chromosomes into chromatin.

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The chromosomes uncoil and become organized into heterochromatin and
euchromatin of the interphase cell.
Nucleolus reappears.
Cytokinesis is the division of the cytoplasm into two equal parts during mitosis.
The cleavage furrow continues to deepen (fig. 22-6). The remaining microtubules
are surrounded by a contractile ring, composed of actin and myosin filaments
attached to the plasma membrane. Constriction of the ring helps in separation of
the two new cells.
Each daughter cell resulting from mitosis is identical in every respect, including
the entire genome, and each daughter cell possesses a diploid (2n) number of
chromosomes.
Clinical correlations

Understanding of mitosis and the cell cycle has greatly aided cancer
chemotherapy, making it possible to use drugs at the time when the cells are in a
particular stage of the cell cycle. For example, vincristine and similar drugs
disrupt the mitotic spindle, arresting the cell in mitosis.
Colchicine , another plant alkaloid that produces the same effect, has been used
extensively in studies of individual chromosomes and karyotyping.

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