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Glycolysis & Fermentation

Glycolysis & Fermentation. 3.7.1 Define cell respiration. Cell respiration is the controlled release of energy from organic compounds in cells to form ATP . ATP – adenosine triphosphate Molecule that directly fuels most biological reactions ATP cycle: ADP + P i ATP.

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Glycolysis & Fermentation

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  1. Glycolysis & Fermentation

  2. 3.7.1 Definecell respiration. • Cell respiration is the controlled release of energy from organic compounds in cells to form ATP. • ATP – adenosine triphosphate • Molecule that directly fuels most biological reactions • ATP cycle: ADP + Pi ATP

  3. Oxidation – Reduction (Redox) Reactions • Electrons are “traded”. • Loss of electrons = oxidation • Gain of electrons = reduction • LEO-GER • Lose Electrons Oxidized – Gain Electrons Reduced • OIL RIG • Oxidation Is Loss – Reduction Is Gain

  4. 3.7.2 Statethat, in cell respiration, glucose in the cytoplasm is broken down by glycolysis into pyruvate,with a small yield of ATP. • Glycolysis is the first step in cell respiration. • It is common to ALL life on earth, both aerobic and anaerobic. • The enzymes involved in this process have not changed. This indicates that mutations in the DNA that affect these enzymes did not survive the evolutionary process.

  5. 3.7.2 Statethat, in cell respiration, glucose in the cytoplasm is broken down by glycolysis into pyruvate,with a small yield of ATP. • Glycolysis occurs in the cytosol of the cell. • It does not require the presence of oxygen.

  6. 3.7.2 Statethat, in cell respiration, glucose in the cytoplasm is broken down by glycolysis into pyruvate,with a small yield of ATP. • It requires: • 2 ATP molecules • 1 glucose molecule (6-C) • It yields: • 4 ATP molecules (net gain to the cell of 2 ATP molecules) • 2 pyruvate molecules (3-C)

  7. Objective #1: Summarize lactic acid fermentation as an example of anaerobic respiration in cells, including input, output, and location in the cytosol.

  8. Learning Goals: • State that glucose is broken down in the cytosol with a small yield of ATP. • State that the electron carrier molecule NAD+ is reduced when it gains electrons during glycolysis. • State that pyruvate, the end product of glycolysis, serves as an electron acceptor for oxidizing NADH back to NAD+, which can then be reused in glycolysis.

  9. Learning Goals: • State that pyruvate is converted to lactic acid in one step, with no additional yield of ATP. • Summarize the process of lactic acid fermentation, including inputs, intermediary molecules, and final products.

  10. Objective #2: Summarize alcohol fermentation as an example of anaerobic respiration in cells, including input, output, and location in the cytosol.

  11. Alcohol Fermentation: • glucose is broken down in the cytosol • yield of 2 ATPmolecules • the electron carrier molecule NAD+ is reduced when it gains electrons during glycolysis • pyruvate is converted to alcohol in two steps, with no additional yield of ATP

  12. Alcohol Fermentation: • CO2is released in the first step, the conversion of pyruvate to acetaldehyde • in the second step, acetaldehyde is reduced by NADH to alcohol, which regenerates NAD+ necessary for the continuation of glycolysis

  13. Lactic Acid Fermentation: • glucose is broken down in the cytosol • yield of 2 ATPmolecules • the electron carrier molecule NAD+ is reduced when it gains electrons during glycolysis • pyruvate, the end product of glycolysis, serves as an electron acceptor for oxidizing NADH back to NAD+, which can then be reused in glycolysis • ethanol is the end product of the reaction

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