OCR A Level Biology 2.6 Cell Division Notes PDF

Summary

This document provides notes on cell division, including mitosis and meiosis, and cellular organization. Topics covered include the role of mitosis, the cell cycle, and the stages of mitosis (prophase, metaphase, anaphase, and telophase), cytokinesis, interphase, and cell organization. The document also explains the process of meiosis.

Full Transcript

OCR (A) Biology A-level

Topic 2.6: Cell division, cell diversity and
cellular organisation
Notes

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The role of mitosis and the cell cycle is to produce identical daughter cells for growth and
asexual reproduction of cells. All the cells produced by mitosis are genetically identical
therefore mitosis does not give rise to genetic variation.
During the cell cycle, a cell it forms, it grows and then divides to form daughter cells. There
are three stages of the cell cycle and it is controlled by checkpoints.
Mitosis – mitosis is a form of cell division that produces identical cells, there are four
stages of mitosis: prophase, metaphase, anaphase and telophase.

Cytokinesis – during cytokinesis the parent and replicated organelles move to
opposite sides of the cell and the cytoplasm divides thus producing two daughter
cells
Interphase – during this stage the cell grows and then prepares to divide –
chromosomes and some organelles are replicated, chromosomes also begin to
condense
During prophase, the nuclear envelope breaks down and subsequently disappears. The
chromosomes condense and the centrioles move to opposite poles of the cell for the purpose
of spindle formation.
During metaphase, the chromosomes move to the equator and attach to the spindle fibres
via centromeres.
In the anaphase stage, the sister chromatids are separated.
During telophase, the nuclear envelope reforms, creating two daughter cells. The spindle is
broken down and subsequently disappears. The chromosomes uncoil.

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 Meiosis
Meiosis is a form of cell division that gives rise to genetic variation. The main role of
meiosis is production of haploid gametes as cells produced by meiosis have half the number
of chromosomes. Meiosis produces genetically different cells, genetic variation is achieved
through:
Crossing over of chromatids where pairs of chromosomes line up and exchange
some of their genetic material

Independent assortment of chromosomes – there are various combinations of
chromosome arrangement
This form of cell division is a two phase process in which four haploid gametes are
generated from a diploid cell. During meiosis I, homologous chromosomes separate therefore
there is only one chromosome of every pair per gamete, whereas in meiosis II the sister
chromatids separate.
The stages of meiosis I are prophase I, metaphase I, anaphase I and telophase I.
Prophase I closely resembles the prophase stage of mitosis, with the exception of synapsis
and crossing over of homologous chromosomes (at chiasmata) which allow the genetic
exchange to occur.
Metaphase I is when each pair of bivalents align at the equator. The position of each
bivalent is random (Random assortment) and this contributes to genetic variation.
During anaphase I, the homologous chromosomes separate whereas during telophase I the
nuclear envelope reforms around haploid nuclei containing half the number of
chromosomes.
During meiosis II composed of prophase II, metaphase II, anaphase II and telophase II,
another round of cell division occurs, leading to formation of four haploid daughter cells,
containing single chromosomes. It is during Anaphase II that the centromeres split separating
chromatids.

Cellular organisation
Cells group together to form tissues with the purpose of performing a common function.
Examples of tissues include xylem and phloem tissues in plans. Organs are groups of
tissues which work together to perform a wider function whereas an organ system is
composed of many organs which work together to perform an essential life function.
Tissue types and their functions:
Xylem- transport water and minerals as well as provide structural support. They are
long cylinders made of dead tissue with open ends. Xylem vessels are thickened
with a tough substance called lignin. They consist of parenchyma, fibres and vessels
and are produced by meristem cells which produce smaller cells that elongate.

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 Phloem - tubes made of living cells which are involved in translocation which is the
movement of food substances and nutrients from leaves to storage organs and
growing plants of the plant. The meristem tissue produces cells that elongate and line
up end-to-end to form a long tube. Their ends do not break down completely but
produce perforated structures known as sieve plates. Metabolically active companion
cells are located next to sieve plates and are involved in mediating the movement of
photosynthesis products upwards and downwards in the tubes.

Epithelial – sheet of cells that serves as a lining/cover a surface. There are two
types, squamous which are smooth, flat and very thin, fitting closely together to create
a smooth surface, such as the lining of blood vessels and cheeks. Whereas ciliated
epithelium is composed of column shaped cells containing cilia which form the lining
of structures such as trachea and bronchi. The cilia move together to move the mucus
produced by goblet cells along. Ciliated epithelium is also found in the oviducts.

Connective – involved in providing support and holding various structures together,
examples include cartilage and bone
Muscle – specialised for movement through contraction
Nervous – specialised for impulse conduction

Stem cells
Stem cells are undifferentiated cells which are genetically identical and have the ability to
develop into any of the various kinds of cells. Stem cells have various uses in research and
medicine, for instance repair of damaged tissues, treatment of neurological disorders such
as Parkinson’s and Alzheimer’s as well as studying development.
The process by which a cell specialised to carry out a particular function is known as
differentiation. Stem cells can be found in the bone marrow where they differentiate into
erythrocytes (red blood cells) and neutrophils (white blood cells). The role of
erythrocytes is transporting oxygen in the blood. They are relatively short lived as they are
constantly destroyed and created. Whereas the neutrophils are involved in attacking and
destroying foreign microorganisms in the process of phagocytosis.
Plants retain their ability to differentiate into different types of cells throughout their life.
Division of plant cells occurs at a high rate in meristems. Dividing meristem cells are known
as the cambium and give rise to xylem and phloem tissue.
Other specialised cells:
Sperm cells – male gametes, made in the testes throughout a man’s life, they are
adapted to reach, penetrate and fertilise the ovum i.e. the female gamete

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 Palisade cells – most basic plant cell type, contain many chloroplasts and are
specialised for photosynthesis

Root hair cells – specialised epidermal cells found in close proximity to root tips.
They have thin and long extensions which serve for the purpose of increasing
surface area and maximising the contact with water which contains essential
mineral ions which are absorbed through the roots. They are short-lived and are
constantly produced in the root tip.

Guard cells – found in pairs in the epidermis of leaves and are involved in
controlling the opening and closing of stomata. Guard cells contain chloroplasts
whereas epidermal cells do not. They respond to water influx which causes them to
alter their shape, causing stoma to open.

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