Cellular Respiration

1. Cellular Respiration

2. Life is work, which requires E • In most ecosystems, E enters as sunlight • Light E trapped in O-molecules is available to both photosynthetic organisms and others that eat them

3. Cellular respiration and fermentation are catabolic, energy-yielding pathways • E is stored in molecules • Enzymes catalyze the hydrolysis of high E molecules to low E products • Some of the released E is used to do work; the rest is lost as heat

4. Fermentation – leads to the partial degradation of sugars in the absence of O2 • Cellular respiration – A more efficient and widespread catabolic process; uses O2 as a reactant to complete the breakdown of a variety of organic molecules • Carbohydrates, fats, and proteins can all be used as the fuel

5. ATP: pivotal molecule in cellular energetics • It is the chemical equivalent of a loaded spring: • The close packing of 3 negatively-charged phosphate groups is an unstable, E-storing arrangement • Loss of the end phosphate group “relaxes” the “spring”

6. Most cellular work converts ATP to ADP and inorganic phosphate (Pi) • Animal cells regenerate ATP from ADP and Pi by the catabolism of organic molecules

7. The transfer of the last phosphate group from ATP to another molecule is phosphorylation • The receiving molecule changes shape, performing work (transport, mechanical, or chemical) • When the phosphate groups leaves the molecule, the molecule returns to its original shape

8. Catabolic pathways relocate e-s stored in food molecules, releasing E used to synthesize ATP • Redox rxns: • Oxidation: loss of e-s • Reduction: addition of e-s • More generally: Xe- + Y  X + Ye- • X, the e- donor, is the reducing agent which is oxidized and reduces Y • Y, the e- recipient, is the oxidizing agent which is reduced and oxidizes X • Redox reactions require both a donor and acceptor

9. O2: very potent oxidizing agent • An electron loses E as it shifts from a less electronegative atom to a more electronegative one • A redox rxn that relocates e-s closer to O2 releases chemical E that can do work • To reverse the process, E must be added to pull an e- away from an atom

10. e-s “fall” from organic molecules to O2 during cellular respiration • C6H12O6 + 6O2 6CO2 + 6H2O • Glucose is oxidized, O2 is reduced, and e-s lose potential E • Molecules that have an abundance of hydrogen are excellent fuels because their bonds are a source of “hilltop” e-s that “fall” closer to O2

11. The cell has a rich reservoir of e-s associated with hydrogen, especially in carbohydrates and fats • However, these fuels don’t spontaneously combine with O2 because they lack the activation E • Enzymes lower the barrier of activation E, allowing these fuels to be oxidized slowly • The “fall” of e-s during respiration is stepwise, via an ETC and NAD+

12. Glucose and other fuels are broken down gradually in a series of steps, each catalyzed by a specific enzyme • At key steps, H atoms are stripped from glucose and passed first to a coenzyme, like NAD+ (nicotinamide adenine dinucleotide) • Dehydrogenase enzymes strip two H atoms from the fuel, pass two e-s and one proton to NAD+ and release H+

13. O2 and H2 could either combust and lose all of the E as heat, or through a step-by-step process, the E could be harnessed to form ATP

14. Mitochondrion • Double membrane-bound organelle • Outer membrane • Inter- membrane space • Inner membrane • Matrix • Cristae: folds of inner membrane

15. Cellular Respira-tion • 3 phases: • Glyco- lysis • Krebs cycle • ETC

16. Substrate-level phosphorylation • Enzymes transfer phosphate from O-molecule to ADP • Occurs in glycolysis and the Krebs cycle

17. Oxidative phosphorylation • Occurs due to the ETC • The transfer of e-s down the ETC to O2 powers the phosphorylation of ADP to ATP • Produces almost 90% of the ATP generated by respiration

18. Glycolysis • Occurs in the cytoplasm • Glucose (6-C sugar) is split ultimately into two pyruvates • Process occurs regardless of the presence of O2 • No CO2 is produced • Net E yield per glucose: • 2 ATP • 2 NADH

19. Glycolysis • Each of the ten steps in glycolysis is catalyzed by a specific enzyme • Kinase: phosphorylates • Isomerase: rearranges molecules to form isomers • Dehydrogenase: oxidizes O-molecules • 10 steps can be divided into two phases: • an E investment phase • an E payoff phase

20. E investment phase • ATP provides activation E by phosphorylating glucose with 2 ATPs

21. E payoff phase

23. Krebs Cycle • Pyruvate can now enter the mitochondrion • The Krebs cycle can only accept a 2-C molecule • So, a multi-enzyme complex breaks down the 3-C pyruvate to the 2-C acetate • This process is known as pyruvic acid breakdown

24. Pyruvic Acid Breakdown • An enzyme rips off a carboxyl group in the form of CO2 to make acetate • In the process, NAD+ is reduced to NADH • Coenzyme A then grabs the acetate, making acetyl CoA, and carries it off to the Krebs cycle

25. Pyruvic Acid Breakdown

26. Pyruvic Acid Breakdown

27. Krebs Cycle • Occurs in the matrix of the mitochondrion • The acetate from acetyl CoA bonds to oxaloacetate to form citrate • The cycle ultimately recycles oxaloacetate, releasing CO2, ATP, NADH, and FADH2 in the process

28. Krebs Cycle

29. Krebs cycle, per glucose, produces a total of: • 8 NADH • 2 FADH2 • 2 ATP • 6 CO2 • Krebs cycle, per pyruvate, produces half of the above totals

30. ETC • Only 4 of the 38 ATPs that are formed in Cell Resp are formed by substrate-level phosphorylation • The other 34 come from the E from the e-s carried by NADH and FADH2 • ETC is a chain of proteins found in the inner membrane of the mitochondrion • It’s folded (cristae) to increase surface area

31. ETC • Thousands of ETCs are found on the cristae of a single mitochondrion • NADH and FADH2 are oxidized as they dump their e-s into the ETC • FADH2 has less free E  it dumps its e-s later in the ETC  fewer H+ move across the membrane

32. ETC

33. ETC • The e-s drop in free E as they are passed along the ETC • This loss of E drives H+ across the inner membrane from the matrix to the inter-membrane space (start of chemiosmosis) • The high [H+] creates the proton-motive force: ability of the proton gradient to do work

34. ETC • Each NADH contributes enough E to generate a maximum of 3 ATP • In some eukaryotic cells, NADH produced in the cytosol by glycolysis may only be worth 2 ATP • The e-s must be shuttled to the mitochondrion • In some shuttle systems, the e-s are passed to NAD+, in others the e-s are passed to FAD • Each FADH2 can be used to generate about 2 ATP

35. ETC

36. ETC • The high proton concentration flows through ATP synthase from inter-membrane space to the matrix • ATP synthase makes ATP from ADP and Pi

37. ETC

38. ETC • Chemiosmosis is not unique to mitochondria • Plant cells use a very similar system in the chloroplasts • Prokaryotes generate H+ gradients across their plasma membrane

39. Anaerobic Respiration • Up to 38 ATPs can be generated when O2 is present • What happens when there is no O2? • Glucose can still be oxidized to make ATP…much less ATP

40. Anaerobic Respiration • Glycolysis still takes place in the cytosol, which still produces: • 2 (net) ATP • 2 NADH • 2 pyruvate • Pyruvate is harmful to cells and must be broken down

41. Anaerobic Respiration • The process is called fermentation • Alcoholic fermentation • Lactic acid fermentation

42. Alcoholic Fermentation • The NADH made in glycolysis is used to convert pyruvate into ethanol and CO2 • Glucose  pyruvate  acetaldehyde + CO2 ethanol

43. Alcoholic Fermentation • Utilized by yeast in the absence of O2 • CO2 produced by fermentation allows bread to rise • Ethanol utilized in production of beer and wine

44. Alcoholic Fermentation

45. Lactic Acid Fermentation • The NADH made in glycolysis is used to convert pyruvate into lactate • Glucose  pyruvate  lactate

46. Lactic Acid Fermentation • Some fungi and bacteria are used to make cheese, yogurt, sour cream, sauerkraut, and pickles • Muscle cells switch from aerobic to anaerobic when O2 is depleted • NADH and FADH2cannot dump their e-s into the ETC • Krebs cycle stops making NADH and FADH2, i.e., the cycle stops • Pyruvate is not broken down

47. Lactic Acid Fermentation • Lactate may cause muscle fatigue, but it is ultimately converted back into pyruvate in the liver

48. Aer- vs. Anaerobic Respiration • Both perform glycolyis • Both generate ATP • Aerobic generates 38 ATP; both substrate-level and oxidative phosphorylation • Anaerobic generates 2 ATP; only substrate-level phosphorylation • Both use NADH as e- carrier

49. Facultative Anaerobes • Yeast and many bacteria (and humans at the cellular level) can perform either type

50. Obligates • Obligate aerobes: must live where O2 is present • Obligate anaerobes: must live where O2 is not present