1 / 30

How Cells Release Chemical Energy

How Cells Release Chemical Energy. Chapter 8. Cellular or Aerobic Respiration. Cellular respiration evolved to enable organisms to utilize energy stored in glucose. Taps the energy found in the bonds of organic compounds (carbohydrates, lipids, proteins). Comparison of the Main Pathways.

tim
Download Presentation

How Cells Release Chemical Energy

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. How Cells Release Chemical Energy Chapter 8

  2. Cellular or Aerobic Respiration • Cellular respiration evolved to enable organisms to utilize energy stored in glucose. • Taps the energy found in the bonds of organic compounds (carbohydrates, lipids, proteins)

  3. Comparison of the Main Pathways • Aerobic respiration • Aerobic metabolic pathways (using oxygen) are used by most eukaryotic cells • Ends in the mitochondria • Aerobes use oxygen as the final electron acceptor • Fermentation • Anaerobic metabolic pathways (occur in the absence of oxygen) are used by prokaryotes and protists in anaerobic habitats • Anaerobes use nitrate or sulfate as the final e- acceptor

  4. Comparison of the Main Pathways • Aerobic respiration and fermentation both begin with glycolysis, which converts one molecule of glucose into two molecules of pyruvate • After glycolysis, the two pathways diverge • Fermentation is completed in the cytoplasm, yielding 2 ATP per glucose molecule • Aerobic respiration is completed in mitochondria, yielding 36 ATP per glucose molecule (liberates the most energy)

  5. Overview of Aerobic Respiration • Three sequential stages • Glycolysis • Acetyl-CoA formation and Krebs cycle • Electron transfer phosphorylation (ATP formation) C6H12O6 (glucose) + O2 (oxygen) → CO2 (carbon dioxide) + H2O (water) • Coenzymes NADH and FADH2

  6. Fig. 8-3b, p. 125

  7. Animation: Overview of aerobic respiration

  8. 8.2 Glycolysis – Glucose Breakdown Starts • Glycolysis starts and ends in the cytoplasm of all prokaryotic and eukaryotic cells • An energy investment/input of ATP (2) starts glycolysis • Requires a continous supply of glucose and NAD+ (reduced in both glycolysis and the kreb cycle)

  9. Glycolysis • Two ATP’s are used to split glucose (6 carbon compound) and form 2 PGAL (3 carbon compound) • Enzymes convert 2 PGAL to 2 PGA, forming 2 NADH • Four ATP are formed by substrate-level phosphorylation (net yield of 2 ATP)

  10. Fig. 8-4a (2), p. 126

  11. ATP-Requiring Steps Glycolysis A An enzyme transfers a phosphate group from ATP to glucose, forming glucose-6-phosphate. glucose ATP ADP B A phosphate group from a second ATP is transferred to the glucose- 6- phosphate. The resulting molecule is unstable, and it splits into two three- carbon molecules. The molecules are interconvertible, so we will call them both PGAL (phosphoglyceraldehyde). glucose-6-phosphate ATP ADP fructose-1,6-bisphosphate (intermediate) So far, two ATP have been invested in the reactions. Fig. 8-4b (1), p. 127

  12. ATP-Generating Steps C Enzymes attach a phosphate to the two PGAL, and transfer two electrons and a hydrogen ion from each PGAL to NAD+. Two PGA (phosphoglycerate) and two NADH are the result. 2 PGAL 2 NAD+ + 2 Pi NADH 2 reduced coenzymes D Enzymes transfer a phosphate group from each PGA to ADP. Thus, two ATP have formed by substrate-level phosphorylation. 2 PGA 2 ADP ATP The original energy investment of two ATP has now been recovered. 2 ATP produced by substrate-level phosphorylation E Enzymes transfer a phosphate group from each of two intermediates to ADP. Two more ATP have formed by substrate-level phosphorylation. 2 PEP 2 ADP ATP 2 ATP produced by substrate-level phosphorylation Two molecules of pyruvate form at this last reaction step. 2 pyruvate F Summing up, glycolysis yields two NADH, two ATP (net), and two pyruvate for each glucose molecule. Net 2 ATP + 2 NADH to second stage Fig. 8-4b (2), p. 127

  13. 8.3 Second Stage of Aerobic Respiration • The second stage of aerobic respiration finishes breakdown of glucose that began in glycolysis • Occurs in mitochondria (inner compartment) begans with the chemical pyruvate to continue respiration • Includes two stages: acetyl CoA formation and the Krebs cycle (each occurs twice in the breakdown of one glucose molecule)

  14. The Krebs Cycle • Krebs cycle • A sequence of enzyme-mediated reactions that break down 1 acetyl CoA (transition stage) into 2 CO2 • Oxaloacetate (last intermediate) is used and regenerated • 3 NADH and 1 FADH2 are formed, 1 ATP is formed • Substrate level phosphorylation occurs • Electrons and hydrogens are transferred to coenzymes in both glycolysis and the Kreb cycle • Energy, CO2, and H+ are released • Cycle turns 2x to break down glucose

  15. A An enzyme splits a pyruvate molecule into a two-carbon acetyl group and CO2. Coenzyme A binds the acetyl group (forming acetyl–CoA). NAD+ combines with released hydrogen ions and electrons, forming NADH. Acetyl–CoA Formation transition from glyco pyruvate NAD+ coenzyme A NADH CO2 B The Krebs cycle starts as one carbon atom is transferred from acetyl–CoA to oxaloacetate. Citrate forms, and coenzyme A is regenerated. acetyl–CoA coenzyme A H The final steps of the Krebs cycle regenerate oxaloacetate. citrate oxaloacetate G NAD+ combines with hydrogen ions and electrons, forming NADH. C A carbon atom is removed from an intermediate and leaves the cell as CO2. NAD+ combines with released hydrogen ions and electrons, forming NADH. CO2 Krebs Cycle NAD+ NADH NADH F The coenzyme FAD com-bines with hydrogen ions and electrons, forming FADH2. NAD+ CO2 NAD+ FADH2 FAD D A carbon atom is removed from another intermediate and leaves the cell as CO2, and another NADH forms. NADH ADP + Pi E One ATP forms by substrate-level phosphorylation. ATP Pyruvate’s three carbon atoms have now exited the cell, in CO2. Stepped Art Fig. 8-6, p. 129

  16. Animation: The Krebs Cycle - details

  17. 8.4 Aerobic Respiration’s Big Energy Payoff • Many ATP’s are formed during the third and final stage of aerobic respiration (Chemiosmotic Theory = production of ATP’s) • Electron transfer phosphorylation • Occurs in mitochondria (inner membrane) • Results in attachment of phosphate to ADP to form ATP • Generates a hydrogen concentration (build up of hydrogen ions between 2 membranes) gradient

  18. Electron Transfer Phosphorylation

  19. Summary: The Energy Harvest • Typically, the breakdown of one glucose molecule yields 36 ATP • Glycolysis: 2 ATP • Acetyl CoA formation and Krebs cycle: 2 ATP • Electron transfer phosphorylation: 32 ATP

  20. Animation: Third-stage reactions

  21. 8.5 Anaerobic Energy-Releasing Pathways • Fermentation pathways break down carbohydrates without using oxygen (Ex. Bacteria that causes botulism) • The final steps in these pathways regenerate NAD+

  22. Fermentation Pathways • Glycolysis is the first stage of fermentation • Forms 2 pyruvate, 2 NADH, and 2 ATP • Pyruvate turns to lactic acid using e- from NADH (Lactate/Lactose Fermentation) • Pyruvate is converted to ethanol producing acetaldehyde and CO2 (Alcoholic Fermentation)

  23. Two Pathways of Fermentation • Alcoholic fermentation • Pyruvate produce acetaldehyde and CO2 when converted to ethanol • Acetaldehyde receives electrons and hydrogen from NADH, forming NAD+ and ethanol • Lactate fermentation • Pyruvate receives electrons and hydrogen from NADH, forming NAD+ and lactate (muscle cells, sour cream, etc)

  24. Glycolysis Glycolysis glucose glucose 2 NAD+ 2 NAD+ NADH 2 2 ATP NADH 2 ATP 2 4 ATP ATP 4 pyruvate pyruvate Lactate Fermentation Alcoholic Fermentation 2 CO2 NADH 2 acetaldehyde 2 NAD+ 2 NADH 2 NAD+ lactate ethanol Stepped Art Fig. 8-9, p. 132

  25. 8.6 The Twitchers • Slow-twitch muscle fibers (“red” muscles) make ATP by aerobic respiration • Have many mitochondria • Dominate in prolonged activity • Fast-twitch muscle fibers (“white” muscles) make ATP by lactate fermentation • Have few mitochondria and no myoglobin • Sustain short bursts of activity • Human muscles have a mixture of both fibers

  26. 8.7 Alternative Energy Sources in the Body • In humans and other mammals, the entrance of glucose and other organic compounds into an energy-releasing pathway depends on the kinds and proportions of carbohydrates (our main source of energy), fats and proteins in the diet

  27. The Fate of Glucose at Mealtimeand Between Meals • When blood glucose concentration rises, the pancreas increases insulin (hormone) secretion • Cells take up glucose faster, more ATP is formed • When blood glucose concentration falls, the pancreas increases glucagon (hormone) secretion (between meals) • Stored glycogen is converted to glucose, the brain continues to receive glucose • Triglycerides are tapped as an energy alternative.

  28. Energy From Fats • About 78% of an adult’s energy reserves is stored in fat (mostly triglycerides) • Excess glucose(carbs) in the diet = FAT; acetyl Co A exits the Kreb Cycle and enters a pathway that makes fatty acids • Enzymes cleave fats into glycerol and fatty acids • Glycerol products enter glycolysis • Fatty acid products enter the Krebs cycle

  29. Energy from Proteins • Enzymes split dietary proteins into amino acid subunits, which enter the bloodstream • Used to build proteins or other molecules • Excess amino acids are broken down into ammonia (NH3) and various products that can enter the Krebs cycle

  30. FOOD FATS COMPLEX CARBOHYDRATES PROTEINS glycerol glucose, other simple sugars fatty acids amino acids acetyl–CoA acetyl–CoA PGAL Glycolysis NADH pyruvate oxaloacetate or another intermediate of the Krebs Krebs Cycle NADH, FADH2 Electron Transfer Phosphorylation Fig. 8-12, p. 135

More Related