1 / 30

Nutrient Role in Bioenergetics

Nutrient Role in Bioenergetics. Chapter 4. Bioenergetics. Bioenergetics refers to the flow of energy within a living system. Energy is the capacity to do work. Aerobic reactions require oxygen. Anaerobic reactions do not require oxygen. Bioenergetics.

castor-slater
Télécharger la présentation

Nutrient Role in Bioenergetics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Nutrient Role in Bioenergetics Chapter 4

  2. Bioenergetics • Bioenergetics refers to the flow of energy within a living system. • Energy is the capacity to do work. • Aerobic reactions require oxygen. • Anaerobic reactions do not require oxygen.

  3. Bioenergetics • First law – Energy is neither created nor destroyed, but instead, transforms from one state to another without being used up.

  4. Bioenergetics • There are six forms of interchangeable energy states: • Chemical • Light • Electric • Mechanical • Heat • Nuclear

  5. Bioenergetics The process of photosynthesis is a chemical reaction. • Chlorophyll absorbs radiant energy: • To synthesize glucose from carbon dioxide and water • To release oxygen. • Solar energy and photosynthesis provide power to the animal world through food and oxygen.

  6. Bioenergetics

  7. Photosynthesis • What is the equation for the chemical reaction of photosynthesis?

  8. Bioenergetics • Respiration is the reverse of photosynthesis. • C6H12O6 + O2→ 6CO2 + 6H2O

  9. Cellular Respiration • Organism transforms the chemical energy into a form it can use. • Cellular Respiration-Step by step process • Glucose • Lipids • Amino acids • Heat

  10. Bioenergetics • Takes one of three forms: • Mechanical work of muscle contraction • Chemical work for synthesizing cellular molecules • Transport work that concentrates diverse substances in body fluids

  11. Bioenergetics • Potential energy • Energy associated with a substance’s structure or position. • Kinetic energy • Energy of motion. • Potential energy and kinetic energy • The total energy of any system.

  12. Bioenergetics

  13. Adenosine Triphosphate

  14. Bioenergetics • Cellular Oxidation–Reduction Reactions • Constitute the mechanism for energy metabolism • Redox reactions power the transfer process of energy

  15. Bioenergetics • Oxidation–reduction reactions couple: • Oxidation = a substance loses electrons • Transfer oxygen, hydrogen, or electrons • Reduction = a substance gains electrons • Atoms gain an electron-reducing valence

  16. Coupled Reactions

  17. Coupled Reactions • Reduction Reaction • 2C3H4O3 + 2H → 2C3H6O3 • LDH • Pyruvate (gains 2 e-) → Lactate

  18. Coupled Reactions • Oxidation Reaction • 2C3H6O3 - 2H → 2C3H4O3 • LDH • Lactate (loses 2 e-) Pyruvate

  19. Bioenergetics • ATP – energy currency • Potential energy extracted from food • ATP • Chemical energy extracted for biologic work • Cells • Muscle contraction

  20. Phosphate Bond • Stored or potential energy • High energy bonds • ATP – hydrolysis • ATP + H2O → ADP + P – 7.3 kCal/mole • ATPase

  21. Bioenergetics

  22. Bioenergetics • Phosphocreatine (PC) is also a high-energy phosphate compound. • ATP-PC (phosphagens) • Releases energy when bonds between creatine and phosphate are broken. • Sustains all out exercise ~ 5-8 s • Resynthesis of ATP used – reservoir • Stored in muscle - anaerobic

  23. Bioenergetics • Cells store 4-6 times more PCr than ATP • Muscle • Provide a reservoir of high-energy phosphate bonds • ATP + H2O  ADP + Pi • ATPase • ADP + C~P  ATP + C • Creatine kinase

  24. Bioenergetics • Phosphorylation • Refers to energy transfer through phosphate bonds • Oxidative phosphorylation • Synthesizes ATP by transfer of electrons • NADH and FADH2

  25. Cellular Oxidation-Reduction Reactions • Mechanism for energy metabolism • Involves transfer of hydrogen atoms • Loss of hydrogen: oxidation • Gain of hydrogen: reduction

  26. Cellular Oxidation • Mitochondria • NAD and FAD → NADH and FADH2 • Cytochromes – Electron Transport Chain (ETC) • Transfer of electrons (H+) • Energy conserved – high energy phosphate bonds • Figure 4.11

  27. Bioenergetics • Sources for ATP formation include: • Glucose derived from liver glycogen • Glycogenolysis • Triacylglycerol and glycogen stored in muscle • Free fatty acids - circulating • Triacylglycerol in liver, adipocytes • Lipoprotein complexes - circulating • Amino acids • Intramuscular and liver-derived carbon skeletons

  28. Bioenergetics

More Related