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NAD is commonly called by other names, including NAD+ or NADH. These are both forms of NAD — NAD+ is the positively charged form, which has lost an electron, and NADH is the neutral form which ...
The proton is released into solution, while the reductant RH 2 is oxidized and NAD + reduced to NADH by transfer of the hydride to the nicotinamide ring. RH 2 + NAD + → NADH + H + + R; From the hydride electron pair, one electron is attracted to the slightly more electronegative atom of the nicotinamide ring of NAD +, becoming part of the ...
[10] While under standard conditions malate cannot reduce the more electronegative NAD +:NADH couple, in the cell the concentration of oxaloacetate is kept low enough that Malate dehydrogenase can reduce NAD + to NADH during the citric acid cycle. Fumarate + 2 H + + 2 e − → Succinate +0.03 [9] O 2 + 2H + + 2e − → H 2 O 2 +0.30
1/2 O 2 + NADH + H + → H 2 O + NAD + The potential difference between these two redox pairs is 1.14 volt, which is equivalent to -52 kcal/mol or -2600 kJ per 6 mol of O 2. When one NADH is oxidized through the electron transfer chain, three ATPs are produced, which is equivalent to 7.3 kcal/mol x 3 = 21.9 kcal/mol.
The energy from the acetyl group, in the form of electrons, is used to reduce NAD+ and FAD to NADH and FADH 2, respectively. NADH and FADH 2 contain the stored energy harnessed from the initial glucose molecule and is used in the electron transport chain where the bulk of the ATP is produced. [1]
The glycerol-3-phosphate shuttle is a mechanism used in skeletal muscle and the brain [1] that regenerates NAD + from NADH, a by-product of glycolysis. NADH is a reducing equivalent that stores electrons generated in the cytoplasm during glycolysis. NADH must be transported into the mitochondria to enter the oxidative phosphorylation pathway.
NADH + NADP + + H + outside => NAD + + NADPH + H + inside. This redox reaction is a transfer of hydride equivalents from NADH to NADP + coupled to a translocation of protons across a membrane. NADP + is reduced to NADPH by NADH, which is oxidized into NAD +. This reduction is tied to the inward translocation of protons across a membrane. [2]
The name "dehydrogenase" is based on the idea that it facilitates the removal (de-) of hydrogen (-hydrogen-) and is an enzyme (-ase). Dehydrogenase reactions come most commonly in two forms: the transfer of a hydride and release of a proton (often with water as a second reactant), and the transfer of two hydrogens.