7.3: Electron Transport in Respiration

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Here we focus on the details of respiration as it occurs in the mitochondria of eukaryotic cells. The end products of electron transport are \(\rm NAD^{+}\), FAD, water, and protons. The protons end up outside the mitochondrial matrix because they are pumped across the cristal membrane using the free energy of electron transport. Electron transport and oxidative phosphorylation are summarized in Figure 7.1.

Screen Shot 2022-05-16 at 11.01.46 PM.png — Figure 7.1: Electron transport and oxidative phosphorylation on the cristal membrane: NADH and \(\rm FADH_2\) oxidation feeds electrons into electron transport, releasing free energy to powers proton pumps that force \(\rm H^{+}\) ions (i.e., protons) out of the mitochondrion. The resulting pH (i.e., \(\rm H^{+}\) ) gradient fuels ATP synthesis when protons flow into the mitochondrial matrix through a regulated cristal membrane ATP synthase (red).

Roman-numbered protein complexes, along with coenzyme Q (“Q”) and cytochrome C (“Cyt C”) constitute the ETC. The role of the respiratory ETC is to oxidize NADH or \(\rm FADH_2\) to \(\rm NAD^{+}\) and FAD, respectively. Electrons from these reduced electron carriers are transferred from one ETC complex to the next. At the end of the chain, electrons, protons, and oxygen unite in complex IV to make water. Under standard conditions in a closed system, electron transport is downhill, with an overall release of free energy (a negative \(\Delta Go\)) at equilibrium.

161 Electron Transport Oxidizes Reduced Electron Carriers

162-2 Finding the Free Energy of Electron Transport

163-2 Separating Electron Transport from Oxidative Phosphorylation

In the illustration above, we can see three sites in the respiratory ETC that function as \(\rm H^{+}\) pumps. At these sites, the negative change in free energy of electron transfer is large and coupled to the action of a proton pump, which forces protons out of the mitochondrial matrix and across the cristal membrane. Because the outer mitochondrial membrane is freely permeable to protons, the gradient created is, in effect, between the cytoplasm and the mitochondrial matrix. Protons flow back into the mitochondrial matrix through lollipop-shaped ATP synthase complexes on the cristal membrane, and this flow releases the gradient free (potential) energy that will be harnessed to make ATP by oxidative phosphorylation.

164-2 Proton Pumps Store Free Energy of the ETC in Proton Gradients

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