2.5.1 Cell Surface Membrane

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Created by
Imogen Stevens

Cards (37)

  • What are membranes considered in all cells?
    Vital structures
  • What does the cell surface membrane create?
    An enclosed space separating the internal cell environment from the external environment
  • What do intracellular membranes form within the cell?
    Compartments such as organelles and vacuoles
  • What is the permeability characteristic of membranes?
    They are partially permeable
  • What roles do membranes play in material exchange?
    They control the exchange of materials passing through them
  • What types of transport can substances use to cross membranes?
    Diffusion, facilitated diffusion, osmosis, and active transport
  • How do membranes contribute to cell signaling?
    By acting as an interface for communication between cells
  • What is an example of a membrane-bound organelle?
    Lysosome
  • What do lysosomes contain that is crucial for their function?
    Hydrolytic enzymes
  • Why is compartmentalization important for lysosomes?
    To prevent hydrolytic enzymes from breaking down cellular components
  • When was the fluid mosaic model of membranes first outlined?
    1972
  • What does the fluid mosaic model explain?
    How biological molecules are arranged to form cell membranes
  • Why are cell membranes described as 'fluid'?
    Because phospholipids and proteins can move around via diffusion
  • How do phospholipids mainly move within the membrane?
    Sideways, within their own layers
  • What analogy is used to describe the movement of proteins in the fluid mosaic model?
    Like icebergs in the sea
  • What does the term 'mosaic' refer to in the fluid mosaic model?
    The scattered pattern produced by proteins within the phospholipid bilayer
  • What are the four main components of the fluid mosaic model?
    Phospholipids, cholesterol, glycoproteins, and glycolipids
  • What forms the basic structure of the membrane?
    Phospholipids
  • What do the tails of phospholipids form in the membrane?
    A hydrophobic core
  • How do phospholipid bilayers act as barriers?
    They prevent most water-soluble substances from passing
  • What happens to water-soluble molecules due to phospholipid bilayers?
    They cannot leak out of the cell and unwanted molecules cannot enter
  • How can phospholipids act as signaling molecules?
    By moving within the bilayer to activate other molecules
  • What is the effect of cholesterol on membrane fluidity at low temperatures?
    It increases fluidity, preventing rigidity
  • How does cholesterol stabilize the cell membrane at higher temperatures?
    By stopping the membrane from becoming too fluid
  • What is the role of cholesterol in relation to phospholipid tails?
    It binds to the hydrophobic tails, stabilizing them
  • What is the effect of cholesterol on the impermeability of the membrane to ions?
    It affects the impermeability
  • What do glycolipids and glycoproteins contain that allows them to act as receptors?
    Carbohydrate chains on their surface
  • What are the three main receptor types associated with glycolipids and glycoproteins?
    Signaling receptors, endocytosis receptors, and adhesion receptors
  • What role do some glycolipids and glycoproteins play in cell recognition?
    They act as cell markers or antigens
  • What do transport proteins create to facilitate movement across the membrane?
    Hydrophilic channels
  • What are the two types of transport proteins?
    Channel proteins and carrier proteins
  • How do carrier proteins function in transporting substances?
    They change shape to transport a substance across the membrane
  • What is the specificity of transport proteins?
    Each transport protein is specific to a particular ion or molecule
  • How do transport proteins contribute to cellular control?
    They allow the cell to control which substances enter or leave
  • What are the main components of cell membranes and their functions?
    • Phospholipids: Form the bilayer and act as a barrier
    • Cholesterol: Increases fluidity and stability
    • Glycoproteins: Act as receptors and cell markers
    • Glycolipids: Involved in cell recognition and signaling
    • Transport proteins: Facilitate movement of substances
  • What is the fluid mosaic model and its significance?
    • Describes the arrangement of molecules in cell membranes
    • Explains fluidity and mosaic appearance due to proteins
    • Important for understanding membrane functions like transport and signaling
  • How do the components of the fluid mosaic model interact to maintain membrane integrity?
    • Phospholipids create a barrier
    • Cholesterol modulates fluidity and stability
    • Proteins facilitate transport and signaling
    • Glycolipids and glycoproteins assist in recognition and communication