Mixed

How many ATP can be produced from NADH and FADH2?

How many ATP can be produced from NADH and FADH2?

2.5 ATP/NADH and 1.5 ATP/FADH2 are produced in the electron transport chain.

How much ATP NADH and FADH2 are produced per molecule of glucose during glycolysis?

One glucose molecule produces four ATP, two NADH, and two pyruvate molecules during glycolysis.

How many ATP is released respectively when NADH and FADH2 molecules get oxidised?

Oxidation of one molecule of NADH gives rise to 3 molecules of ATP, while that of one molecule of FADH2 produces 2 molecules of ATP.

How many molecules of ATP NADH and FADH2 are produced per glucose?

Thus, the total yield from 1 glucose molecule (2 pyruvate molecules) is 6 NADH, 2 FADH2, and 2 ATP.

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Why does NADH give 3 ATP and FADH2 produce 2?

NADH produces 3 ATP during the ETC (Electron Transport Chain) with oxidative phosphorylation because NADH gives up its electron to Complex I, which is at a higher energy level than the other Complexes. FADH2 produces 2 ATP during the ETC because it gives up its electron to Complex II, bypassing Complex I.

Is NADH 2.5 or 3 ATP?

When electrons from NADH move through the transport chain, about 10 H +start superscript, plus, end superscript ions are pumped from the matrix to the intermembrane space, so each NADH yields about 2.5 ATP.

How many NADH 2 FADH2 and ATP molecules are produced in a single TCA cycle?

three NADH molecules
Products of the Citric Acid Cycle Each turn of the cycle forms three NADH molecules and one FADH2 molecule. These carriers will connect with the last portion of aerobic respiration to produce ATP molecules. One GTP or ATP is also made in each cycle.

How many ATP are produced from NADH?

2.5 ATP
When electrons from NADH move through the transport chain, about 10 H +start superscript, plus, end superscript ions are pumped from the matrix to the intermembrane space, so each NADH yields about 2.5 ATP.

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How does 1 NADH produce 3 ATP?

NADH produces 3 ATP during the ETC (Electron Transport Chain) with oxidative phosphorylation because NADH gives up its electron to Complex I, which is at a higher energy level than the other Complexes.

How NADH produce three ATP while fadh produces two molecules of ATP?

The oxidation of one molecule of NADH thus leads to the synthesis of three molecules of ATP, whereas the oxidation of FADH2, which enters the electron transport chain at complex II, yields only two ATP molecules.

Why does NADH generate more ATP than fadh?

The reason why more ATP are produced from NADH than from FADH2 is that FAD takes less energy to reduce than does NAD+; so when the opposite (oxidation) occurs, more energy is released from NADH than from FADH2.

How many ATP does NADH produce during oxidative phosphorylation?

Under ideal conditions each NADH molecule will result in three ATP molecules, and each FADH2 molecule will result in two ATP molecules during oxidative phosphorylation. Calculate the total number of ATP molecules that might be produced in this phase of cellular respiration from one glucose molecule.

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How many ATP molecules might be produced from one glucose molecule?

34 ATP molecules might be produced in this phase of cellular respiration from one glucose molecule. Considering all the stages of cellular respiration (glycolysis, link, Krebs cycle, and oxidative phosphorylation) how many ATP molecules that might be produced from one glucose molecule, assuming ideal circumstances?

Is any ATP produced in the electron transport chain?

No ATP is produced in the electron transport chain. Is any ATP used in the electron transport chain? No, the electrons provide energy. Describe the movement of hydrogen ions through the membrane. Hydrogen ions diffuse through ATP synthase. Would free energy be required for the hydrogen ions to move with the concentration gradient?

What happens to the energy released when ATP is hydrolyzed?

Notice, however, that the energy released when ATP is hydrolyzed is approximately midway between those of the high-energy and the low-energy phosphate compounds. This means that the hydrolysis of ATP can provide energy for the phosphorylation of the compounds below it in the table.