Energy Transfer

1. Energy Transfer

2. Adenosine TriphosphateThe Energy Currency • The energy in food does not transfer directly to the cells for biologic work. Rather, energy from macronutrient oxidation is harvested and funneled through ATP. • The energy donor - energy receiver role of ATP represents the body’s two main energy transforming activities. • Extract potential energy from food and conserve it within the bonds of ATP. • Extract and transfer the chemical energy in ATP to power biologic work.

3. ATP Structure

4. A Limited Currency • Cells store only a small quantity of ATP and must therefore continually resynthesize it at its rate of use. • ATP is a relatively heavy molecule and the average sedentary person resynthesizes enough ATP in one day to equal ~ 75% their body weight. • The body stores ~ 80-100 g of ATP at any time. • Costs about 80 kg of ATP to run a marathon in 2.5 hrs.

5. Harnessing ATP’s Potential Energy • ATP hydrolysis: • ATP + H2O ATPase ADP + Pi = 7.3 kcal/mol • ATP Resynthesis: • PCr + ADP creatine kinase Cr ATP • 2 ADP adenylate kinase ATP + AMP

6. ATP Resynthesis • Cells are very sensitive to a decrease in the ATP:ADP ratio. • Signal the enzymes involved in ATP resynthesis to kick in. • Phosphocreatine (PCr) – The energy reservoir. • Anaerobic resynthesis of ATP from ADP • Creatine can later be phosphorylated back to PCr • Cells store ~ 4-6 times more PCr than ATP

7. Important By-Products • ATP hydrolysis and resynthesis generate as by-products: • Pi • AMP • ADP • These by-products stimulate: • Glycogenolysis • Glycolysis • Respiratory pathways of mitochondria

8. Cellular Oxidation • There is not enough stored ATP to fuel all of your body’s processes. • Your body must oxidize stored macronutrients so that mitochondria can synthesize more ATP. • ATP is synthesized by coupling of electron transport and oxidative phosphorylation in the electron transport chain.

9. Energy Release From Food • Macronutrient catabolism serves one crucial purpose – to phosphorylate ADP to re-form ATP. • 3 broad stages: • Digestion, absorption, and assimilation of relatively large food macromolecules into small subunits. • Within the cytosol, AA’s, glucose, fatty acids, and glycerol units are degraded into acetyl-CoA • Within the mitochondria, acetyl-CoA degrades to CO2 and H2O with considerable ATP resynthesis.

10. Citric Acid Cycle • AKA Krebs cycle, tricarboxylic acid cycle. • A complex sequence of metabolic events that degrades acetyl-CoA to carbon dioxide and hydrogen atoms. • The hydrogen atoms are then oxidized during the electron transport chain.

11. Citric Acid Cycle

12. Electron Transport Chain • Iron-rich carrier molecules transport electrons via redox reactions. • Oxygen is the final electron acceptor. • This process is responsible for > 90% of ATP synthesis. NADH + H+ + 3 ADP + 3 Pi + ½ O2 = NAD+ + H20 + 3 ATP

13. Energy Transfer From Food • Liver releases glucose and deaminated amino acids into the bloodstream. • Adipose tissue releases fatty acids into the bloodstream. • Within the cytosol, glucose, AA’s and fatty acids get turned into acetyl-CoA. • Acetyl-CoA enters the citric acid cycle and produces NADH and H+ ions. • Hydrogen ions enter the ETC and resynthesize ADP into ATP.