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Published byNigel Hudson Modified over 9 years ago
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1 SURVEY OF BIOCHEMISTRY Electron Transport and Oxidative Phosphorylation
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2 Redox Centers
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3 The Mitochondrion Zoom in on the cristae: ~2000 per cell
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4 How does electron transfer work? NADH binds to Complex I on the matrix side of the membrane
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5 Electron Transfer with NADH NADH transfers its e - to redox centers in Complex I 2e - go to FMN… FMN resembles FAD without the adenine dinucleotide group
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6 Electron Transfer with FMNH 2 NADH transfers 2e - to FMN - a redox center in Complex I FMNH 2 can then pass each e - to series of Fe-S clusters in a stepwise manner:
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7 Fe-S Clusters in Complex I Complex I contains Fe-S clusters as cofactors
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8 Coenzyme Q (Ubiquinone) Electrons pass from Fe-S clusters to a “mobile” electron carrier cofactor called Coenzyme Q
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9 Electron Transfer with CoQ Coenzyme Q initially binds to Complex I to pick up 2 e - from the Fe-S clusters in Complex I
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10 Complex II Succinate-Coenzyme Q Oxidoreductase FADH 2 Complex II is not shown Electrons pass from FADH 2 to CoQ via Complex II 4H + ions get pumped out of the matrix by Complex I and CoQ but not Complex II
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11 Electron Transfer with CoQ Coenzyme Q binds to Complex III on the Intermembrane space side One e - goes to Cytochrome c One e - goes into the Q cycle
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12 Electron Transfer with Cyt c Once CoQ loses its 2e -, it can dissociate from the upper region of Complex III and rebind near the matrix side and pick up the e - it just donated! Meanwhile, Cytochrome c carries its e - to Complex IV
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13 Electron Transfer with Cyt c Another CoQ carrying 2e - can bind to Complex III, passing one of its e - to Cytochrome c and one into the Q cycle and ultimately to the original CoQ molecule.
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14 Proton Pumping from Matrix NADHFMNFe-SCoQ 4 H + ions get pumped from matrix into the intermembrane space as 2 electrons are passed through Complex I (mechanism unknown)
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15 Complex III and Complex IV Cytochrome bc 1 O 2 + 4 H + 2H 2 O Cytochrome c oxidase How does ATP get made?
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16 Chemiosmotic Theory Idea that the free energy needed to transport e - is conserved by the formation of a transmembrane proton gradient. Proton gradient drives ATP synthesis.
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17 Complex V: ATP Synthase F 1 F 0 ATPase F 0 - water insoluble w/ 8 types of subunits F 1 - water soluble peripheral membrane protein w/ 5 types of subunits
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18 Binding Mechanism in ATP Synthase O = openL = looseT = tight 1.ATP binds into the T protomer first 2.ADP and P i bind to the L protomer 3.Supply of energy induces a conformational change 4.ATP goes to the O protomer and is released 5.ATP is synthesized at the T protomer
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19 Overview of Electron Transport Notice these inhibitors of electron transport!
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20 Coordinated Control of Glycolysis and the TCA Cycle
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21 Pros and Cons of Aerobic Metabolism Anaerobic Metabolism of Glucose: C 6 H 12 O 6 + 2 ADP + 2 P i 2 Lactate + 2 H + + 2 H 2 O + 2 ATP Aerobic Metabolism of Glucose: C 6 H 12 O 6 + 32 ADP + 32 P i + 6O 2 6 CO 2 + 38H 2 O + 32 ATP PRO: Aerobic metabolism is up to 16x more productive than anerobic metabolism!
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22 Pros and Cons of Aerobic Metabolism O 2 + e - O 2 - CON: Aerobic metabolism, with its high efficiency, tends to produce free radicals of oxygen! Superoxide radical Other harmful possibilities: H 2 O 2 + Fe 2+ OH + OH - + Fe 3+ O 2 - + H 2 O 2 O 2 + H 2 O + OH
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23 Superoxide Dismutase (SOD) An inherent antioxidant enzyme 2O 2 - + 2H + O 2 + H 2 O 2 Catalase SOD 2H 2 O 2 2 H 2 O + O 2 Other potential antioxidants
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