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After studying this chapter you will be able to know the binding change mechanism of ATP formation. Know the properties of the ADP/ATP translocator and the Pi/H+ symport. Understand how the transport of these compounds across the inner envelope relates to PMF and energy consumption. Know how ETC and oxidative Phosphorylation are regulated by ADP and ATP levels. | Chapter 14 (part 2) Oxidative phosphorylation ATP Synthase Racker & Stoeckenius confirmed Mitchell’s hypothesis using vesicles containing the ATP synthase and bacteriorhodopsin Binding Change Mechanism ATPase is a Rotating Motor How does proton flow cause rotation? Transport of ATP, ADP and Pi | Chapter 14 (part 2) Oxidative phosphorylation ATP Synthase Racker & Stoeckenius confirmed Mitchell’s hypothesis using vesicles containing the ATP synthase and bacteriorhodopsin Binding Change Mechanism ATPase is a Rotating Motor How does proton flow cause rotation? Transport of ATP, ADP and . | Chapter 14 (part 2) Oxidative phosphorylation ATP Synthase Racker & Stoeckenius confirmed Mitchell’s hypothesis using vesicles containing the ATP synthase and bacteriorhodopsin Binding Change Mechanism ATPase is a Rotating Motor How does proton flow cause rotation? Transport of ATP, ADP and Pi | Chapter 14 (part 2) Oxidative phosphorylation ATP Synthase Racker & Stoeckenius confirmed Mitchell’s hypothesis using vesicles containing the ATP synthase and bacteriorhodopsin Binding Change Mechanism ATPase is a Rotating Motor How does proton flow cause rotation? Transport of ATP, ADP and . | Chapter 14 (part 2) Oxidative phosphorylation ATP Synthase Racker & Stoeckenius confirmed Mitchell’s hypothesis using vesicles containing the ATP synthase and bacteriorhodopsin Binding Change Mechanism ATPase is a Rotating Motor How does proton flow cause rotation? Transport of ATP, ADP and Pi
