The Link Reaction & The Krebs Cycle (DP IB Biology)
Revision Note
The Link Reaction
Entering the link reaction
The end product of glycolysis is pyruvate (3C)
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
Once in the matrix pyruvate takes part in the link reaction
The link reaction
The link reaction takes place in the matrix of the mitochondria
It is referred to as the link reaction because it links glycolysis to the Krebs cycle
The steps are:
Oxidative decarboxylation reaction in which:
Carbon dioxide is removed to produce a 2C molecule
This 2C molecule is then oxidised (loss of hydrogen and 2 high energy electrons) to produce an acetyl compound and thereby reducing NAD to NADH
Combination of the acetyl compound 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
Acetyl coenzyme A is supplied to the Krebs cycle where aerobic respiration continues
Link Reaction Diagram
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.
Examiner Tips and Tricks
Remember that there are two pyruvate molecules produced per glucose molecule so you need to multiply everything by 2 when thinking about what happens to a single glucose molecule in aerobic respiration.
The Krebs Cycle
The Krebs cycle (sometimes called the citric acid cycle) consists of a series of enzyme-controlled reactions
The Krebs cycle takes place in the matrix of the mitochondria
Two carbon (2C) Acetyl CoA enters the circular pathway from the link reaction
A four carbon compound (4C) called oxaloacetate accepts the 2C acetyl fragment from acetyl CoA to form a six carbon compound (6C) called citrate
Coenzyme A is released in this reaction to be reused in the link reaction
Citrate (6C) is then converted back to oxaloacetate (4C) through a series of oxidation-reduction (redox) reactions
The Krebs Cycle Diagram
The Krebs Cycle uses acetyl CoA from the link reaction to produce reduced carbon dioxide, reduced NAD, reduced FAD and ATP
The reactions involved in the Krebs cycle
Oxaloacetate (4C) is regenerated in the Krebs cycle through a series of redox reactions
Decarboxylation of citrate (6C)
Releasing two CO2 as waste gas
Oxidation (dehydrogenation) of citrate (6C) releases hydrogen atoms
Reduction of coenzymes NAD and FAD (by the released H atoms)
3 NAD+ and 1 FAD → 3NADH + H+ and 1 FADH2
Substrate-level phosphorylation
A phosphate is transferred from one of the intermediates to ADP, forming one ATP
As the link reaction produces two molecules of acetyl CoA (one per each pyruvate), the Krebs cycle occurs twice
Per glucose molecule, the Krebs cycle produces:
4 CO2
2 ATP
6 NADH + H+ (reduced NAD)
2 FADH2 (reduced FAD)
Examiner Tips and Tricks
The Krebs cycle is often referred to as cyclical or circular. This is because the 4C oxaloacetate is regenerated throughout the reaction so that it can start all over again by adding another acetyl CoA.
You are required to name only the intermediates citrate (6C) and oxaloacetate (4C) in the Krebs cycle.
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