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Transcript
Goals Lecture 10: Chemistry of Metabolism • Understand basics of how different foods are turned into energy Nutrition 150 • DO NOT memorize complex reaction chains Shallin Busch, Ph.D. • Understand why fats are more energy dense than proteins and carbohydrates Catabolic Reactions Anabolic Reactions ANABOLIC REACTIONS CATABOLIC REACTIONS Glycogen Uses energy Triglycerides Uses energy Glucose + Glucose Glycerol Protein Uses energy + Fatty acids Amino acids + Amino acids Glycogen Glucose Yields energy Anabolic reactions require energy and combine simple compounds into complex compounds. Triglycerides Glycerol Yields energy Protein Fatty acids Yields energy Amino acids Yields energy Catabolic reactions release energy and break large molecules into smaller one. Coenzymes Coenzymes: Complex organic molecules that work with enzymes to facilitate the enzyme’s activity. Transfer of Energy by ATP Uses energy ADP + P Energy from food is used to attach a phosphate group to adenosine diphosphate (ADP), making ATP. Yields energy ATP ATP captures and stores this energy. ADP + P Energy from ATP is released when a phosphate bond is broken. This energy fuels the body’s work. ATP is a high energy compound used to 1) store energy and 2) yield energy Adenosine Triphosphate (ATP) Generating ATP • ATP can be made when breaking down food directly Adenosine + 3 phosphate groups • ATP can also be made by the “electron transport chain”, the process by which the energy in free electrons is captured as ATP. Requires oxygen, makes water and carbon dioxide. Aerobic Catabolism of Glucose Pyruvate Acetyl CoA The TCA Cycle Glucose Aerobic: Reaction using oxygen (from carbon dioxide) Uses energy (ATP) Oxaloacetate Coenzyme Coenzyme Coenzyme Yields energy (ATP) Coenzyme Coenzyme 2 Pyruvate CoA Coenzyme Coenzyme To Electron Transport Chain Coenzyme Coenzyme Coenzyme Coenzyme Coenzyme Coenzyme 2 CoA Coenzyme Coenzyme Coenzyme To Electron Transport Chain Coenzyme Coenzyme Coenzyme 2 Carbon dioxide Yields energy (captured in high-energy compound similar to ATP) To TCA Cycle Glucose Coenzyme 16-C fatty acid Glucose returns to the muscles Coenzyme Coenzyme Glucose Uses energy (ATP) CoA Coenzyme Uses energy (ATP) Coenzyme Lactic acid travels to the liver 2 Pyruvate To Electron Transport Chain In the liver: Coenzyme Yields energy (ATP) (as carbon dioxide) Catabolism of Fatty Acid Anaerobic Catabolism of Glucose In the muscle: Coenzyme To Electron Transport Chain CoA CoA 2 Acetyl CoA (as carbon dioxide) CoA 2 Lactic acid Coenzyme Coenzyme Anaerobic: Reaction which doesn’t use oxygen Coenzyme CoA Coenzyme To Electron Transport Chain Catabolism of a Triglyceride Metabolism of Fatty Acid CoA + CoA To TCA Cycle Glucose Net result from a 16-C fatty acid: 14-C fatty acid CoA + 1 acetyl CoA Cycle repeats, leaving: 12-C fatty acid CoA + 2 acetyl CoA Cycle repeats, leaving: 10-C fatty acid CoA + 3 acetyl CoA Cycle repeats, leaving: 8-C fatty acid CoA + 4 acetyl CoA Cycle repeats, leaving: 6-C fatty acid CoA + 5 acetyl CoA Cycle repeats, leaving: 4-C fatty acid CoA + 6 acetyl CoA + 7 acetyl CoA Cycle repeats, leaving: 2-C fatty acid CoA Glycerol Fatty acids Pyruvate CoA CoA Carbon dioxide Coenzyme CoA Co CoA Acetyl CoA A Coenzyme Co Co A Co A Co Co A A CoA To TCA Cycle Pyruvate Acetyl CoA (from carbon dioxide) The TCA Cycle CoA CoA Oxaloacetate Coenzyme Ketone Body Formation from Fatty Acids Acetyl CoA Coenzyme + CoA Acetyl CoA 2 CoA OH Coenzyme Coenzyme Coenzyme Coenzyme Coenzyme Coenzyme Coenzyme Coenzyme (as carbon dioxide) A ketone, acetoacetate CO2 Coenzyme To Electron Transport Chain Yields energy (captured in high-energy compound similar to ATP) (as carbon dioxide) To Electron Transport Chain A ketone, acetone + H2O A To Electron Transport Chain Catabolism of Amino Acids Pyruvate Amino acids Acetyl CoA (from carbon dioxide) Pyruvate CoA Coenzyme Carbon dioxide CoA Oxaloacetate Coenzyme Coenzyme The TCA Cycle Coenzyme Coenzyme To Electron Transport Chain Coenzyme Coenzyme Coenzyme Coenzyme CoA Acetyl CoA Coenzyme Coenzyme Coenzyme Coenzyme To TCA Cycle Coenzyme To Electron Transport Chain Yields energy (captured in high-energy compound similar to ATP) Urea Excretion Figure 7-17 Page 229 Amino acids When an amino acid is used for energy, the amine (NH3) group is disposed of as urea. Bloodstream Ammonia (NH3) + CO2 Liver (as carbon dioxide) (as carbon dioxide) To Electron Transport Chain Fatty Acids can generate more energy than Glucose WHY? Fatty acid Urea Bloodstream Kidney Urea Glucose Adding oxygen to carbon atoms yields energy To bladder and out of body Feasting Starving Ketosis suppresses the appetite Metabolism slows during starvation Fasting
![NEC313N, ACETYL COENZYME A, [ACETYL-1- C]](http://s1.studyres.com/store/data/003392842_1-f84d6512b3156ee480c7453e33ca6834-150x150.png)
