5-7-5-the-link-reaction

Aerobic Respiration: Link Reaction

• The end product of glycolysis is pyruvate

• Pyruvate contains a substantial amount of chemical energy that can be further utilised in respiration to produce more ATP

• When oxygen is available pyruvate will enter the mitochondrial matrix and aerobic respiration will continue

• Pyruvate moves across the double membrane of the mitochondria via active transport

  • It requires a transport protein and a small amount of ATP

Pyruvate enters the mitochondrial matrix from the cytosol (cytoplasm) by active transport

• It is referred to as the link reaction because it links glycolysis to the Krebs cycle

• The steps are:

  • Pyruvate is oxidised by enzymes to produce acetate, CH₃CO(O)- and carbon dioxide, requiring the reduction of NAD to NADH

  • Combination with coenzyme A to form acetyl coenzyme A (acetyl CoA)

• It produces:

  • Acetyl coA

  • Carbon dioxide (CO₂)

  • Reduced NAD (NADH)

pyruvate + NAD + CoA → acetyl CoA + carbon dioxide + reduced NAD

The link reaction occurs in the mitochondrial matrix. It dehydrogenates and decarboxylates the three-carbon pyruvate to produce the two-carbon acetyl CoA that can enter the Krebs Cycle.

Role of coenzyme A

• A coenzyme is a molecule that helps an enzyme carry out its function but is not used in the reaction itself

• Coenzyme A consists of a nucleoside (ribose and adenine) and a vitamin

• In the link reaction, CoA binds to the remainder of the pyruvate molecule (acetyl group 2C) to form acetyl CoA

• It then supplies the acetyl group to the Krebs cycle where it is used to continue aerobic respiration

• This is the stage that brings part of the carbohydrate (or lipid/amino acid) into the further stages of respiration and links the initial stage of respiration in the cytoplasm to the later stages in the mitochondria