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Cell Cycle and Mitosis

6.2 Cell Cycle and Mitosis
 
Introduction
  • The cell cycle refers to the sequence of events that involves DNA multiplication and cell division to produce two daughter cells.
  • The cell cycle consists of interphase and M phase.
  • Interphase is the longest phase in the cell cycle.
  • This phase is made up of the G1, S and G2 phase.
 
This image is a diagram illustrating the cell cycle. It is divided into four segments: G1 phase, S phase, G2 phase, and M phase. The G1 phase, S phase, and G2 phase are collectively referred to as interphase. The M phase includes prophase, metaphase, anaphase, telophase, and cytokinesis. The diagram is circular, with each phase labeled and colored distinctly. The center of the circle contains the label Cell Cycle with a logo above it. There are two text boxes providing additional information about the phases.
 
Interphase
G1 phase
  • Cells grow.
  • Cell components such as mitochondrion and endoplasmic reticulum are produced at this stage.
  • Proteins used in the cell cycle are also synthesised during this time.
  • At this stage, the nucleus looks big and the chromosome is in the form of chromatin.
S phase
  • DNA synthesis occurs in the S  phase.
  • The DNA in the nucleus is replicated.
  • Each chromosome multiplies into two identical chromosomes known as sister chromatids.
  • Both chromatids contain the same copy of the DNA molecule.
  • Both chromatids are joined at the centromeres.
G2 phase
  • The cells will continue to grow and remain active metabolically during the G2 phase.
  • Cells gather energy and make final arrangements to enter the next stage of cell division.
  • After the interphase stage, the cell will enter the M phase.
 
M phase
  • M phase is made up of mitosis and cytokinesis.
  • Mitosis involves prophase, metaphase, anaphase and telophase.
 

 
Mitosis
 Prophase
  • In the nucleus, chromatin starts to shorten and thicken to form a chromosome structure that can be seen through a light microscope.
  • The chromosome is seen to be made up of two identical threads called sister chromatids.
  • Both sister chromatids are joined at the centromere.
  • The nucleus membrane disintegrates, the nucleolus disappears, the centriole moves to the opposite poles and the spindle fibres start to form.
Metaphase
  • Centrioles are at the opposite poles of the cell.
  • The spindle fibres maintain the chromosomes at the equatorial plane.
  • The chromosomes become aligned in a single row on the equatorial plane.
  • Metaphase ends when the centromere begins to divide.
 Anaphase
  • The centromere divides into two and the sister chromatids separate.
  • Spindle fibres shorten, contract and the sister chromatids are attracted to the opposite pole cells.
  • Anaphase ends when the chromatid arrives at the pole of the cell.
Telophase
  • When the chromatids are at the opposite poles, they are now called the daughter chromosome.
  • Each pole contains one set of complete and identical chromosomes.
  • Chromosomes are shaped again as fine chromatin threads.
  • Nucleoli are formed again.
  • Spindle fibres disappear.
  • A new nucleus membrane is formed.
  • The telophase stage is followed by cytokinesis.
 
 

 
Cytokinesis
  • Cytokinesis is the division of cytoplasm that happens immediately after the nucleus is formed, that is, at the end of telophase.
 
Cytokinesis in Animal Cell
  • Cytokinesis occurs in animal cells when the plasma membrane constricts in the middle of the cell between the two nuclei.
  • Microfilaments at the point of constriction will contract, causing the cell to constrict until it splits to form two daughter cells.
 
 
Cytokinesis in Plant Cell
  • Cytokinesis in plant cells also begins when the formed vesicles combine to form cell plates at the centre of the cell.
  • The cell plates are surrounded by a new plasma membrane and a new cell wall substance is formed among the spaces of the cell plates.
  • The cell plates expand outwards until they combine with the plasma membranes.
  • At the end of cytokinesis, cellulose fibres are produced by the cells to strengthen the new cell walls.
  • Two daughter cells are formed.
  • Each cell has a diploid condition.
 
​​​​
 

 
The Necessity of Mitosis
  • Mitosis is important for the following life processes.
  • For embryo development and organism growth, mitosis ensures that rapid cell growth occurs.
  • Through the mitosis process, the lizard is able to grow a new tail (regeneration) if the tail breaks.
  • When the body is injured, mitosis will produce new cells to replace cells that are dead or damaged.
  • Mitosis aids organisms such as hydra to produce new individuals through the formation of new buds.
  • In agriculture, the technique of culturing plant tissues is used to produce young plants through the culturing of parent cells without going through the fertilisation process.
  • Stem cell therapy uses stem cells from bone marrows to treat damaged cartilage.
  • The culturing technique uses stem cells from animals which are then cultured in laboratories to produce meat.
The views expressed in the notes here are those of the contributor and don’t necessarily represent the views of Pandai.

Cell Cycle and Mitosis

6.2 Cell Cycle and Mitosis
 
Introduction
  • The cell cycle refers to the sequence of events that involves DNA multiplication and cell division to produce two daughter cells.
  • The cell cycle consists of interphase and M phase.
  • Interphase is the longest phase in the cell cycle.
  • This phase is made up of the G1, S and G2 phase.
 
This image is a diagram illustrating the cell cycle. It is divided into four segments: G1 phase, S phase, G2 phase, and M phase. The G1 phase, S phase, and G2 phase are collectively referred to as interphase. The M phase includes prophase, metaphase, anaphase, telophase, and cytokinesis. The diagram is circular, with each phase labeled and colored distinctly. The center of the circle contains the label Cell Cycle with a logo above it. There are two text boxes providing additional information about the phases.
 
Interphase
G1 phase
  • Cells grow.
  • Cell components such as mitochondrion and endoplasmic reticulum are produced at this stage.
  • Proteins used in the cell cycle are also synthesised during this time.
  • At this stage, the nucleus looks big and the chromosome is in the form of chromatin.
S phase
  • DNA synthesis occurs in the S  phase.
  • The DNA in the nucleus is replicated.
  • Each chromosome multiplies into two identical chromosomes known as sister chromatids.
  • Both chromatids contain the same copy of the DNA molecule.
  • Both chromatids are joined at the centromeres.
G2 phase
  • The cells will continue to grow and remain active metabolically during the G2 phase.
  • Cells gather energy and make final arrangements to enter the next stage of cell division.
  • After the interphase stage, the cell will enter the M phase.
 
M phase
  • M phase is made up of mitosis and cytokinesis.
  • Mitosis involves prophase, metaphase, anaphase and telophase.
 

 
Mitosis
 Prophase
  • In the nucleus, chromatin starts to shorten and thicken to form a chromosome structure that can be seen through a light microscope.
  • The chromosome is seen to be made up of two identical threads called sister chromatids.
  • Both sister chromatids are joined at the centromere.
  • The nucleus membrane disintegrates, the nucleolus disappears, the centriole moves to the opposite poles and the spindle fibres start to form.
Metaphase
  • Centrioles are at the opposite poles of the cell.
  • The spindle fibres maintain the chromosomes at the equatorial plane.
  • The chromosomes become aligned in a single row on the equatorial plane.
  • Metaphase ends when the centromere begins to divide.
 Anaphase
  • The centromere divides into two and the sister chromatids separate.
  • Spindle fibres shorten, contract and the sister chromatids are attracted to the opposite pole cells.
  • Anaphase ends when the chromatid arrives at the pole of the cell.
Telophase
  • When the chromatids are at the opposite poles, they are now called the daughter chromosome.
  • Each pole contains one set of complete and identical chromosomes.
  • Chromosomes are shaped again as fine chromatin threads.
  • Nucleoli are formed again.
  • Spindle fibres disappear.
  • A new nucleus membrane is formed.
  • The telophase stage is followed by cytokinesis.
 
 

 
Cytokinesis
  • Cytokinesis is the division of cytoplasm that happens immediately after the nucleus is formed, that is, at the end of telophase.
 
Cytokinesis in Animal Cell
  • Cytokinesis occurs in animal cells when the plasma membrane constricts in the middle of the cell between the two nuclei.
  • Microfilaments at the point of constriction will contract, causing the cell to constrict until it splits to form two daughter cells.
 
 
Cytokinesis in Plant Cell
  • Cytokinesis in plant cells also begins when the formed vesicles combine to form cell plates at the centre of the cell.
  • The cell plates are surrounded by a new plasma membrane and a new cell wall substance is formed among the spaces of the cell plates.
  • The cell plates expand outwards until they combine with the plasma membranes.
  • At the end of cytokinesis, cellulose fibres are produced by the cells to strengthen the new cell walls.
  • Two daughter cells are formed.
  • Each cell has a diploid condition.
 
​​​​
 

 
The Necessity of Mitosis
  • Mitosis is important for the following life processes.
  • For embryo development and organism growth, mitosis ensures that rapid cell growth occurs.
  • Through the mitosis process, the lizard is able to grow a new tail (regeneration) if the tail breaks.
  • When the body is injured, mitosis will produce new cells to replace cells that are dead or damaged.
  • Mitosis aids organisms such as hydra to produce new individuals through the formation of new buds.
  • In agriculture, the technique of culturing plant tissues is used to produce young plants through the culturing of parent cells without going through the fertilisation process.
  • Stem cell therapy uses stem cells from bone marrows to treat damaged cartilage.
  • The culturing technique uses stem cells from animals which are then cultured in laboratories to produce meat.
The views expressed in the notes here are those of the contributor and don’t necessarily represent the views of Pandai.
Chapter : Cell Division
Topic : Discuss the necessity of mitosis in: (i) development of embryo. (ii) growth of organisms. (iii) healing of wounds on the skin. (iv) regeneration. (v) asexual reproduction
Form 4 Biology
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