Glycolysis
Glycolysis is a series of chemical reactions that convert sugars (primarily glucose) to pyruvate (also known as pyruvic acid). Glycolysis uses and generates chemical energy. It also produces electron carrier molecules. This chemical pathway is found in nearly all living cells.
Oxidative
Phosphorylation
In the inner mitochondrial membrane, the energy released through the electron transport chain is used to generate chemical energy in the form of ATP.
Acetyl CoA
Production
Acetyl CoA is the major input into the citric acid cycle. The breakdown of sugars is a major source of acetyl CoA formation. The metabolic breakdown of both proteins and fats can also produce this important molecule.
Citric Acid
Cycle
The citric acid cycle is also known as the Krebs cycle and the tricarboxylic acid (or TCA) cycle. This cycle occurs in aerobic organisms. It generates electron carrier molecules that are used in the electron transport chain.
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2
3
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Electron carriers:
Energy carrier:
ATP
Sugar
Sugar
NAD+
sugar
O2
lactate
O2
CoA
pyruvate
NAD+
O2
Acetyl CoA
FADH2
H2O
O2
NADH
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Net Gain Glycolysis

2 ATP to perform work
2 NADH that travel to the electron transport chain in the mitochondria
2 pyruvate that can move onto the mitochondria or be used in fermentation

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Net Gain
Acetyl CoA Formation

Per pyruvate molecule:
1 NADH molecule that travels to the electron transport chain

Per glucose molecule:
2 NADH
2 CO2

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Net Gain
Citric Acid Cycle

Per acetyl CoA molecule:
1 ATP to perform work, 3 NADH and 1 FADH2 that travels to the electron transport chain

Per glucose molecule:
2 ATP, 6 NADH, 2 FADH2

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Net Gain Oxidative Phosphorylation

Energy released through the passing of electrons is used to transport protons across the membrane. Protons (H+) pass through ATP synthase, generating an additional 25 ATP molecules for each glucose molecule that entered glycolysis.

Limited oxygen
Arsenic
DNP (diet pill)
When oxygen is low, the electron carriers necessary for glycolysis can be replenished through fermentation. Each pyruvate is converted to a lactate molecule. During this process, an NAD+ molecule is produced which can return to glycolysis.
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Lack of oxygen disables electron transport chain

Oxygen is no longer the final electron acceptor molecule in the electron transport chain, stalling the flow of electrons through the complexes of the electron transport chain. This disables oxidative phosphorylation and ATP synthesis in the mitochondrion.

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Arsenic stops acetyl CoA formation

The pyruvate coming from glycolysis can no longer be converted to acetyl CoA, so there is no acetyl CoA to enter the citric acid cycle. The few ATP molecules produced in the cell are generated through glycolysis.

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DNP stops ATP production

Protons bind to DNP and are carried by DNP across the membrane, instead of returning to the mitochondrial matrix through ATP synthase.

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