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2 NADH+H + from the oxidative decarboxylation of pyruvate and 6 from Krebs cycle: 8 × 2.5 ATP; 2 FADH 2 from the Krebs cycle: 2 × 1.5 ATP; Altogether this gives 4 + 3 (or 5) + 20 + 3 = 30 (or 32) ATP per molecule of glucose These figures may still require further tweaking as new structural details become available.
The movement of protons creates an electrochemical gradient across the membrane, is called the proton-motive force. It has two components: a difference in proton concentration (a H + gradient, ΔpH) and a difference in electric potential, with the N-side having a negative charge. [4]
Within aerobic respiration, the P/O ratio continues to be debated; however, current figures place it at 2.5 ATP per 1/2(O 2) reduced to water, though some claim the ratio is 3. [5] This figure arises from accepting that 10 H + are transported out of the matrix per 2 e −, and 4 H + are required to move inward to synthesize a molecule of ATP. [6]
[5] [6] Simplified model of F O F 1-ATPase alias ATP synthase of E. coli. Subunits of the enzyme are labeled accordingly. Rotation engine of ATP synthase. Located within the thylakoid membrane and the inner mitochondrial membrane, ATP synthase consists of two regions F O and F 1. F O causes rotation of F 1 and is made of c-ring and subunits a ...
The number of c subunits determines how many protons are required to make the F O turn one full revolution. For example, in humans, there are 8 c subunits, thus 8 protons are required. [ 12 ] After c subunits, protons finally enter the matrix through an a subunit channel that opens into the mitochondrial matrix. [ 11 ]
The presence of large amounts of dissolved and free oxygen in the oceans and atmosphere may have driven most of the extant anaerobic organisms to extinction during the Great Oxygenation Event (oxygen catastrophe) about 2.4 billion years ago. Cellular respiration using O 2 enables aerobic organisms to produce much more ATP than anaerobic ...
In biochemistry and in biological fluids, at pH = 7, it is thus important to note that the reduction potential of the protons ( H +) into hydrogen gas H 2 is no longer zero as with the standard hydrogen electrode (SHE) at 1 M H + (pH = 0) in classical electrochemistry, but that E red = − 0.414 V {\displaystyle E_{\text{red}}=-0.414\mathrm {V ...
It is a metallo-oxo cluster comprising four manganese ions (in oxidation states ranging from +3 to +4) [6] and one divalent calcium ion. When it oxidizes water, producing oxygen gas and protons, it sequentially delivers the four electrons from water to a tyrosine (D1-Y161) sidechain and then to P680 itself.