1.1 - Introduction to cells

avatar
Created by
joshuachatterjee

Cards (39)

  • Cell theory states that:
    • All living things are composed of cells (or cell products)
    • The cell is the smallest unit of life
    • Cells only arise from pre-existing cells
  • Cells only arise from pre-existing cells:
    • Cells multiply through division
    • All life evolved from simpler ancestors
    • Mitosis results in genetically identical diploid daughter cells
    • Meiosis generates haploid gametes (sex cells)
  • Striated muscle
    • Challenges the idea that a cell has one nucleus.
    • Muscle cells have more than one nucleus per cell.
    • Muscle Cells called fibres can be very long (300mm).
    • They are surrounded by a single plasma membrane but they are multi-nucleated (many nuclei).
    • This does not conform to the standard view of a small single nuclei within a cell.
  • Aseptate fungal hyphae
    • Challenges the idea that a cell is a single unit.
    • Fungal hyphae are again very large with many nuclei and a continuous cytoplasm.
    • The tubular system of hyphae form dense networks called mycelium.
    • Like muscle cells they are multi-nucleated.
    • They have cell walls composed of chitin.
    • The cytoplasm is continuous along the hyphae with no end cell wall or membrane.
  • Giant algae (Acetabularia)
    • Acetabularia is a single-celled organism that challenges both the idea that cells must be simple in structure and small in size.
    • Gigantic in size (5 – 100mm).
    • Complex in form, it consists of three anatomical parts:
    1. Bottom rhizoid (that resembles a set of short roots)
    2. Long stalk
    3. Top umbrella of branches that may fuse into a cap.
    • The single nucleus is located in the rhizoid.
  • Metabolism - the web of all the enzyme-catalysed reactions in a cell or organism, e.g. respiration
    Response - Living things can respond to and interact with the environment
    Homeostasis - The maintenance and regulation of internal cell conditions, e.g. water and pH
    Growth - Living things can grow or change size / shape
    Excretion – the removal of metabolic waste
    Reproduction - Living things produce offspring, either sexually or asexually
    Nutrition – feeding by either the synthesis of organic molecules (e.g. photosynthesis) or the absorption of organic matter
  • Metabolism in Paramecium occurs mostly in the cytoplasm.
  • The response of Paramecium involves the wave action of the cilia moving the paramecium in response to changes in the environment.
  • Homeostasis in Paramecium involves the contractile vacuole filling up with water and expelling it through the plasma membrane to manage the water content.
  • Growth in Paramecium occurs after consuming and assimilating biomass from food, until the paramecium divides.
  • The nucleus in Paramecium can divide to support cell division by mitosis.
  • Excretion in Paramecium is controlled by the plasma membrane, controlling the entry and exit of substances.
  • Nutrition in Paramecium involves food vacuoles containing organisms the paramecium has consumed.
  • Nutrition in Chlorella involves photosynthesis happening inside the chloroplasts to provide the algae with food
  • Magnification=Image size/Actual size
  • Benefits of Large SA:Vol ratio:
    • Shorter Diffusion pathways
    • Concentration gradients are easier to generate
  • Disadvantages of large SA:Vol ratio:
    • Small, warm blooded animals lose heat very quickly and need to eat constantly
  • Desert plants would lose water quickly with flat leaves
    • They minimise SA:Vol ratio to conserve water
    • CAM plants change their metabolism to save water
  • Cells and tissues specialised for gas or material exchange will increase their surface area to optimise the transfer of materials, e.g. microvilli in the small intestine
  • The cell must consequently divide in order to restore a viable SA:Vol ratio and survive.
  • Cells divide as two small cells are more efficient than one large cell, allowing for cell differentiation, specialised functions and more complex multicellular life.
  • Cells compartmentalise, using membranes to carry out metabolic processes, such as in organelles like mitochondrion, maximising the surface area for reactions.
  • Some organs, like the intestines, fold up, making absorption of food molecules more efficient.
  • Alveoli in the lungs are thin membranes that maximise the surface for gas exchange.
  • Roots are long and branched, with root hairs on the cells, to maximise the surface area for water uptake.
    • All (diploid) cells of an individual organisms share an identical genome
    • Each cell contains the entire set of genetic instructions for that organism
    • BUT not all genes are expressed (activated) in all cells
    • In (totipotent) embryonic stem cells the entire genome is active
    • Newly formed cells receive signals which deactivate (or more rarely activate) genes, e.g. a skin cell does not need to be able to produce haemoglobin (the pigment in red blood cells that carries oxygen)
    • In humans 220 distinct highly specialised cell types have been recognised
    • All specialised cells and the organs constructed from them have developed as a result of differentiation
  • Totipotent:
    Can differentiate into any type of cell.
  • Pluripotent:
    Can differentiate into many
    types of cell.
  • Multipotent:
    Can differentiate into a few closely-related types of cell.
  • Unipotent:
    Can regenerate but can only differentiate into their associated cell type
    (e.g. liver stem cells can only make liver cells).  
  • Stargardt's macular dystrophy:
    • Affects 1 in 10000 children
    • Recessive genetic condition
    • Mutation causes an active transport protein on photoreceptor cells to malfunction
    • The photoreceptor cells degenerate
    • Results in production of a dysfunctional protein that cannot perform energy transport
    • Causes progressive, and loss of central vision
  • Stargardt's macular dystrophy treatment:
    • Embryonic stem cells are treated to divide and differentiate to become retinal cells
    • Retinal cells are injected into retina
    • Retinal cells attach to retina and become functional
    • Central vision improves as a result of more functional retinal cells
  • Leukemia:
    • Cancer of the blood or bone marrow
    • Results in abnormally high levels of poorly functioning white blood cells
  • Leukemia treatment:
    • Hematopoetic stem cells are harvested from bone marrow, peripheral blood or umbilical cord blood
    • Chemotherapy and radiotherapy used to destroy diseased white blood cells
    • New white blood cells need to be replaced with healthy cells
    • HSCs are transplanted back into the bone marrow
    • HSCs differentiate to form new healthy white blood cells
  • Use of a patient's own HSCs mean there is far less risk of immune rejection than with a traditional bone marrow transplant
  • Embryo stem cells:
    • Can be obtained from excess embryos generated from IVF programs
    • Only obtained by destruction of embryo
    • Almost unlimited growth potential
    • Higher risk of tumour development
    • Can differentiate into any cell type
    • Less chance of genetic damage than adult cells
    • Compatibility - not genetically identical to patient
  • Cord blood stem cells:
    • Limited quantities but easily obtained and stored
    • Umbilical cord discarded anways
    • Reduced growth potential
    • Lower risk of tumour development
    • Limited capacity to differentiate
    • Less chance of genetic damage than adult cells
    • Fully compatible with patient as stem cells are genetically identical
  • Adult stem cells:
    • Difficult to obtain - very few and buried deep in tissues
    • Adult patient permission to extract cells
    • Reduced growth potential
    • Lower risk of tumour development
    • Limited capacity to differentiate
    • Genetic damage can occur through mutations through life of adult
    • Fully compatible