Transcript Lecture 32a
The Proton Motive Force • The transfer of H+ through a proton pump generates an electrochemical gradient of protons, called a proton motive force. - It drives the conversion of ADP to ATP through ATP synthase. - This process is known as the chemiosmotic theory. Figure 14.5 The Proton Motive Force • When protons are pumped across the membrane, energy is stored in two different forms: • - The electrical potential (Dy) arises from the separation of charge between the cytoplasm and solution outside the cell membrane. • - The pH difference (DpH) is the log ratio of external to internal chemical concentration of H+. • The relationship between the two components of the proton potential Dp is given by: • Dp = Dy – 60DpH Figure 14.6 Dp Drives Many Cell Functions • Besides ATP synthesis, Dp drives many cell processes including: rotation of flagella, uptake of nutrients, and efflux of toxic drugs. Figure 14.9 The Respiratory ETS • ETS proteins such as cytochromes associate electron transfer with small energy transitions, which are mediated by cofactors. • Energy transitions typically involve these kinds of molecular structures: • - Metal ions, such as iron or copper, held in place with amino acid residues • - Conjugated double bonds and heteroaromatic rings, such as the nicotinamide ring of NAD+/NADH Figure 14.11 Figure 14.13 A Bacterial ETS for Aerobic NADH Oxidation Figure 14.14 ETS • Animation: A bacterial electron transfer system Click box to launch animation The F1Fo ATP Synthase • The F1Fo ATP synthase is a highly conserved protein complex, made of two parts: - Fo: Embedded in the membrane - Pumps protons - F1: Protrudes in the cytoplasm - Generates ATP Figure 14.17 H+ Flux Drives ATP Synthesis Figure 14.18AB The F1Fo ATP Synthase • Animation: ATP Synthase Mechanism Click box to launch animation • Oxidized forms of nitrogen • - Nitrate is successively reduced as follows: • NO3– → NO2– → NO → 1/2 N2O → 1/2 N2 nitrate nitrite nitric oxide nitrous oxide nitrogen gas - In general, any given species can carry out only one or two transformations in the series. Oxidized forms of sulfur - Sulfate is successively reduced by many bacteria as follows: SO42– → SO32– → 1/2 S2O32– → S0 → H2S sulfate sulfite thiosulfate sulfur hydrogen sulfide • Anaerobic environments, such as the bottom of a lake, offer a series of different electron acceptors. • - As each successive TEA is used up, its reduced form appears; the next best electron acceptor is then used, generally by a different microbe species. Figure 14.20 Lithotrophy • Lithotrophy is the acquisition of energy by oxidation of inorganic electron donors. • A kind of lithotrophy of great importance in the environment is nitrogen oxidation. 1/2 O2 O2 1/2 O2 NH4+ → NH2OH → HNO2 → HNO3 ammonium hydroxylamine nitrous acid (nitrite) nitric acid (nitrate) Surprisingly, ammonium can also yield energy under anaerobic conditions through oxidation by nitrite produced from nitrate respiration. Hydrogenotrophy • Hydrogenotrophy is the use of molecular hydrogen (H2) as an electron donor. - H2 has sufficient reducing potential to donate e– to nearly all biological electron acceptors. - Including chlorinated organic molecules, via dehalorespiration - Which has potential for bioremediation Figure 14.24