Cell divison

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  • Chromosomes carry genetic information in a molecule called DNA.
    A type of cell division called mitosis ensures that when a cell divides each new cell produced has the same genetic information.
  • DNA exists in a cell's nucleus within structures called chromosomes. Each section of a chromosome that contains the code for the production of a particular protein is called a gene.
  • Each chromosome is made from a single molecule of DNA, but when a cell is ready to divide, the DNA copies itself, then coils and condenses to form the chromosomes that we see in micrographs
  • Each human body cell contains 46 chromosomes. These can be arranged into 23 pairs.
    Each chromosome in a pair carries the same types of genes. The 23rd pair are the sex chromosomes:
    • In females, the two chromosomes are identical in shape. There are two X chromosomes. Females are referred to as XX.
    • In males, one of the chromosomes is different in shape. There is an X and also a Y chromosome. Males are referred to as XY
  • Cells divide when:
    • an organism grows
    • an organism becomes damaged and needs to produce new cells
    It is essential that any new cells produced contain genetic information that is identical to the parent cell.
  • A growing and dividing cell goes through a series of stages called the cell cycle.
    The first stages of the cell cycle involve cell growth, then the synthesis of DNA. The single strand of DNA that makes up each chromosome produces an exact copy of itself.
    The cell undergoes a type of cell division called 
  • In mitosis, two cells called daughter cells are produced, each identical to the parent cell.
  • Stem cells are cells that have not undergone differentiation. A cell which has not yet become specialised is called undifferentiated.
    An embryo develops from a fertilised egg. Cells at the early stages in the development of the embryo are stem cells.
  • If cells are removed from the embryo – called embryonic stem cells - they will differentiate into any cell type.
    Some stem cells remain in the bodies of adults – adult stem cells. Adult stem cells are found in limited numbers at certain locations in the body.
  • Adult stem cells can be found in several regions of the body, including the:
    • brain
    • eyes
    • blood
    • heart
    • liver
    • bone marrow
    • skin
    • muscle
  • Adult stem cells can differentiate into related cell types only, for example, bone marrow cells can differentiate into blood cells and cells of the immune system but not other cell types.
  • Stem cells in plants
    Cell division in plants occurs in regions called meristems.
    Cells of the meristem can differentiate to produce all types of plant cells at any time during the life of the plant.
    The main meristems are close to the tip of the shoot, and the tip of the root.
  • In a growing shoot, new cells are being produced continuously near the tip. As the cells become older, further away from the tip, they become differentiated – they enlarge and develop vacuoles.
  • Cells of the Circulatory system specialised to transport substances, defend the body, regulate temperature
  • Cells of the Excretory system Specialised to remove waste products and unwanted substances regulate the water content of the body
  • Cells of the Muscular system specialised to Bring about movement
  • Cells of the nervous system specialised to Respond to internal and external stimuli and conditions, carry messages for the body to work as a coordinated whole
  • Cells of the Respiratory system Specialise to Deliver oxygen for respiration and removing waste
  • Cells of the Skeletal system specialised to bring about movement, support and protect internal structures, produce blood cells, store and release calcium
  • Cells from meristems can be cloned. Meristematic cells are removed from a plant and grown in tissue culture. The cells are grown in a culture medium that contains agar – to provide support and water for the growing cells – along with nutrients and plant hormones to stimulate growth and cell division.
  • Plants are cloned to produce identical plants quickly and economically
  • Producing new plants by cloning is quicker than allowing plants to reproduce and collecting and sowing seeds. It’s therefore an effective way of producing new individuals from rare and endangered plants, helping to preserve the species.
  • Clones will be genetically identical to the original plant providing the meristem cells. This is useful to provide crop plants for large-scale cultivation that have desirable characteristics such as disease resistance.
  • Tissue culture and cloning are important in growing identical plants produced by genetic engineering
  • Cloning in plants also occurs naturally, for instance, in runners in strawberry plants. An older, simpler method of cloning plants that gardeners use to produce new, identical plants is by taking cuttings.
  • Stem cells can divide to produce new cells, which can then divide into different cell types. They therefore have the potential to be transplanted into patients to treat medical conditions and disease. They could be used to replace cells that have been damaged or destroyed, eg:
    • in type 1 diabetes
    • in cases of multiple sclerosis, which can lead to paralysis
    • in cases of spinal cord or brain injury, that have led to paralysis
  • The stem cells used could be:
    • embryonic stem cells
    • adult stem cells
  • Embryonic stem cells can differentiate into a wider range of cell types, but are difficult to obtain and their use raises ethical challenges. The best source is the five-day-old embryo.
  • Adult stem cells will differentiate into a narrower range of cell types. Bone marrow transplants are an example of adult stem cell transplant. Bone marrow cells will differentiate into different types of blood cell. Bone marrow transplants are carried out:
    • In cases of blood cell cancer such as leukaemia and lymphoma
    • when blood cells have been destroyed by cancer treatment
  • Adult stem cell transplants could use a patient's own stem cells or be from a donor. Those that use the patient’s own stem cells would be genetically identical and would not be rejected by the patient's immune system.
  • Those from a donor would not be genetically identical. Fewer complications would arise if the stem cells came from a close member of the family. Alternatively, donor cells could come from a person with closely-matched tissue types.
  • Therapeutic cloning:
    Therapeutic cloning could produce stem cells with the same genetic makeup as the patient.
    The technique involves the transfer of the nucleus from a cell of the patient to an egg cell whose nucleus has been removed.
  • Stem cells produced in this way could be transferred to the patient. Although human stem cells have been produced in this way, and used in research, there is no evidence that, as yet, they have been used to treat anyone.