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Chapter 10 Chem 341 Suroviec Fall 2016.

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Presentation on theme: "Chapter 10 Chem 341 Suroviec Fall 2016."— Presentation transcript:

1 Chapter 10 Chem 341 Suroviec Fall 2016

2 I. Introduction Redox reaction that releases electrons into mitochondrial electron transport chain Mitochondrial electron-transport chain Electrons transferred to other substances to participate in additional oxidation rxns Transferred electrons participate in sequential redox reactions of multiple redox centers in 4 enzyme complexes During electron transfer protons are expelled making a proton gradient

3 A. Mitochondrial Anatomy
Contains Pyruvate dehydrogenase CAC enzymes Enzymes and redox proteins for electron transport and oxidative phosphorylation B. Mitochondrial Transport Outer membrane contains proteins allows diffusion of proteins Intermembrane space equivalent to cytosol

4 1. Cytosolic Reducing Equivalents
NADH produced in cytocol must gain access into mitochodrial electron transport chain Inner membrane does not have NADH transport protein Only the electrons from cytosolic NADH are transported

5 II. Electron Transport In a redox reaction there are electrons transferred Reduction Potentials Indicates a substance’s ability to accept electrons

6 Example Calculate the reduction potential of substance A when E = 0.5V, [Ared] = 5 x 10-6M, [Aox] = 2 x 10-4M and n = 2

7 B. Free Energy Change DG can be calculated from Eo’ electrons flow spontaneously from substance with lower Eo’ to higher Eo’ Example In yeast, alcohol dehydrogenase reduces acetaldehyde to ethanol. Find DGo’

8 B. Sequence of Electron Transport
Oxidation of NADH and FADH2 is carried out by electron transport chain Set of protein complexes containing redox centers with progressively greater affinities for electrons

9

10 1. Complex I Passes electrons from NADH to CoQ Contain FMN Contain iron – sulfur clusters

11 2. Complex II Contains succinate dehydrogenase Passes electrons from succinate to CoQ

12 3. Complex III Passes electrons from reduced CoQ to cytochrome c

13 Q - Cycle In complex III need to transport 1 electron at a time from CoQ through cytochromes

14 4. Complex IV Catalyzes one electron oxidation of 4 consecutive reduced cytochrome c molecules Reduces oxygen

15 Inhibitors of electron transport

16 III. Oxidative Phosphorylation
Chemiosmosis Free energy of electron transport is conserved by pumping H+ from matrix to intermembrane space Gradient makes ATP synthesis possible

17 Binding change mechanism
B. ATP synthase Multisubunit: F1 and F0 Binding change mechanism

18 IV. Control of Oxidative Phosphorylation
Concentrations of intermediates and energy currency turn on/off oxidative phosphorlyation

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