5.2 Respiration

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Plane Vevo

Cards (9)

  • Why is respiration important?
    ● Respiration produces ATP (to release energy)
    ● For active transport, protein synthesis
  • Summarise the stages of aerobic respiration
    Aerobic respiration
    1. Glycolysis - cytoplasm (anaerobic)
    2. Link reaction - mitochondrial matrix
    3. Krebs cycle - mitochondrial matrix
    4. Oxidative phosphorylation - inner mitochondrial membrane
  • Summarise the stages of anaerobic respiration
    Anaerobic respiration
    1. Glycolysis - cytoplasm
    2. NAD regeneration - cytoplasm
  • Describe the process of glycolysis
    1. Glucose phosphorylated to glucose phosphate ○ Using inorganic phosphates from 2 ATP
    2. Hydrolysed to 2 x triose phosphate
    3. Oxidised to 2 pyruvate
    2 NAD reduced
    4 ATP regenerated (net gain of 2)
  • Explain what happens after glycolysis if respiration is anaerobic
    1. Pyruvate converted to lactate (animals & some bacteria) or ethanol (plants & yeast)
    2. Oxidising reduced NADNAD regenerated
    3. So glycolysis can continue (which needs NAD) allowing continued production of ATP
  • Suggest why anaerobic respiration produces less ATP per molecule of glucose than aerobic respiration
    ● Only glycolysis involved which produces little ATP (2 molecules)
    ● No oxidative phosphorylation which forms majority of ATP (around 34 molecules
  • What happens after glycolysis if respiration is aerobic?
    Pyruvate is actively transported into the mitochondrial matrix
  • Describe the link reaction
    1. Pyruvate oxidised (and decarboxylated) to acetate
    ○ CO2 produced
    Reduced NAD produced (picks up H)
    2. Acetate combines with coenzyme A, forming Acetyl
    Coenzyme A Products per glucose molecule: 2 x Acetyl Coenzyme A, 2 X CO2 and 2 X reduced NAD
  • Describe the Krebs cycle
    1. Acetyl coenzyme A (2C) reacts with a 4C molecule
    ○ Releasing coenzyme A
    ○ Producing a 6C molecule that enters the Krebs cycle
    2. In a series of oxidation-reduction reactions, the 4C molecule is regenerated and:
    ○ 2x CO2 lost
    ○ Coenzymes NAD & FAD reduced
    ○ Substrate level phosphorylation (direct transfer of Pi from intermediate compound to ADP) → ATP produced Products per glucose molecule: 6 x reduced NAD, 2 x reduced FAD, 2 x ATP and 4 x CO2