Lecture 21

1. Lecture 21 • Quiz on Friday-Glycolysis, Amino acids • Bonus seminar on Friday: Prof. Candace Haigler, 148 Baker, 3-4:30PM; use same format for Extra Credit as previous seminars or if you cannot make it, write a summary of the Haigler Paper on our webpage. • Glycolysis • Fermentation (anaerobic metabolism)

3. H-C=O H-C-OH CH2-O- PO3-2 5th reaction of glycolysis (Gº’ = +1.83 kcal/mol) H 4 (1) 1(3) H-C-O- PO3-2 5 (2) C=O 2 CH2-OH 6 (3) Triose phosphate isomerase (TIM) 3(1) Glyceraldehyde-3-phosphate (GAP) Dihydroxyacetone phosphate (DHAP) H-C-OH H-C-OH CH2-O- PO3-2 enediol intermediate

4. Triose phosphate isomerase (TIM) Only GAP continues on the glycolytic pathway and TIM catalyzes the interconversion of DHAP to GAP Mechanism is through a general acid-base catalysis Final reaction of the first stage of glycolysis. Invested 2 mol of ATP to yield 2 mol of GAP.

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6. H-C=O C-O H-C-OH H-C-OH CH2-O- CH2-O- PO3-2 PO3-2 6th reaction of glycolysis (Gº’ = +1.5 kcal/mol) 1 Glyceraldehyde-3-phosphate (GAP) 2 3 Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) NAD+ + Pi NADH + H+ O 1 1,3-Bisphosphoglycerate (1,3-BPG) -PO3-2 2 3

7. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) Tetramer (4 subunits) Catalyzes the oxidation and phosphorylation of GAP by NAD+ and Pi Used several experiments to decipher the reaction mechanism GAPDH inactivated by carboxymethylcysteine-suggests that GAPDH has active site Cys GAPDH quantitatively transfers 3H from C1 of GAP to NAD+- this is a direct hydride transfer. Catalyzes the exchange of 32P and an analog acetyl phosphate-reaction proceeds through an acyl intermediate

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9. C-O H-C-OH CH2-O- PO3-2 7th reaction of glycolysis (Gº’ = -4.5 kcal/mol) O 1 1,3-Bisphosphoglycerate (1,3-BPG) -PO3-2 2 3 ADP 3-Phosphogylcerate kinase (PGK) Mg2+ ATP O C-O- 3-Phosphoglycerate (3-PG) H-C-OH CH2-O- PO3-2

10. Phosphoglycerate kinase (PK) First ATP generating step of glycolysis nucleophilic attack

11. Phosphoglycerate kinase (PK) Although the preceeding reaction (oxidation of GAP) is endergonic (energetically unfavorable), when coupled with the PK catalyzed reaction, it is highly favorable. in kcal/mol GAP + Pi + NAD+ 1,3-BPG + NADH Gº’ = +1.6 1,3-BPG + ADP 3PG + ATP Gº’ = -4.5 3PG + NADH+ ATP GAP + Pi + NAD+ + ADP Gº = -2.9 Net reaction

12. 8th reaction of glycolysis (Gº’ = +1.06 kcal/mol) O C-O- 3-Phosphoglycerate (3-PG) H-C-OH CH2-O- PO3-2 phosphoglycerate mutase (PGM) O C-O- 2-Phosphoglycerate (2-PG) H-C-O- PO3-2 CH2-OH

13. Phosphogylcerate mutase (PGM) Catalyzes the transfer of the high energy phosphoryl group on phosphoglycerate. Requires catalytic amounts of 2,3-bisphosphoglycerate (2,3-BPG) -acts as the reaction primer. Requires a phosphorylated His in the active site

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15. Glycolysis 1. Hexokinase (HK): (Glucose  G6P), req.Mg-ATP 2. Phosphoglucoisomerase (PGI): (G6P  F6P) 3. Phosphofructokinase (PFK): (F6P  FBP),req.Mg-ATP 4. Aldolase: (FBP  GAP and DHAP) 5. Triose posphate isomerase(TIM): (DHAP  GAP) Called the first stage of glycolysis • First 5 steps-require 2 mol ATP to get 2 mol GAP.

16. Glycolysis 6. GAPDH (GAP  1,3-BPG), req.NAD+ + Pi 7. PGK (1,3-BPG  3-PG), ADP  ATP-1st step to make ATP. 8. PGM (3-PG  2-PG), phosphoryl shift, requires 2,3 BPG Pick up at reaction 9!

17. 9th reaction of glycolysis (Gº’ = +0.44 kcal/mol) O C-O- 2-Phosphoglycerate (2-PG) H-C-O- PO3-2 CH2-OH Enolase Mg2+ H2O O C-O- Phosphoenoylpyruvate (PEP) H-C-O- PO3-2 CH2

18. Enolase (dehydration) Catalyzes the dehydration of 2PG to phosphoenolpyruvate (PEP). Requires two divalent cations (Mg2+). Enzyme can be inhibited by F- in complex with Pi, causing a buildup in 2PG and 3PG. Mechanism: rapid formation of carbanion by removal of a proton at C2 by Lys (general base); proton exchanges with solvent Elimination of water (-OH of C3) to form PEP with general acid catalysis (Glu). This is the rate limiting step.

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20. 10th reaction of glycolysis (Gº’ = -7.5 kcal/mol) O C-O- Phosphoenoylpyruvate (PEP) H-C-O- PO3-2 CH2 ADP Pyruvate kinase (PK) K +, Mg2+ ATP O C-O- Pyruvate C=O CH3

21. Pyruvate kinase (PK) Couples free energy of PEP hydrolysis to ATP formation resulting in the formation of pyruvate. Requires both K+ and Mg2+ Allosteric enzyme- multiple isomers in different tissues hormonal control by insulin/glucogon ATP - negative feedback inhibition (allosteric inhibitor) F-1,6-bisphophate (feedforward activator) and PEP are positive + activators.

22. Figure 17-22 Mechanism of the reaction catalyzed by pyruvate kinase. Page 602

23. Overall glycolysis 2 pyruvate Glucose 2 ADP 2 ATP 2 NADH 2NAD+ + 2 Pi 4 ADP 4 ATP 2 Pyruvate + 2 NADH+ 2 ATP Glucose + 2 ADP + 2 Pi + 2 NAD+ Need to regenerate NAD+ Via O2/electron transport chain (respiration). Anaerobically (fermentation)

24. O C-O- H-C-O- H CH2 Homolactic fermentation (muscle, heart) O C-O- Pyruvate C=O CH3 NADH, H+ Lactate dehyrogenase Gº’ = -6.0 kcal/mol NAD+ Lactate

25. Lactate dehyrdogenase (fermentation) Tetramer that can compose 5 isozymes with KMVm Two sets of subunits M and H can form M4, M3H, M2H2, MH3, and H4. H-type found in aerobic tissue (heart muscle) M-type found in skeletal muscle and liver. [H-type] KM for pyruvate and  Vm - used to regenerate NAD+. Allosterically inhibited by high levels of metabolite. Used to convert lactate to pyruvate for aerobic metabolism. [M-type]  KM for pyruvate and  Vm - Not inhibited by substrate. Used to convert pyruvate to lactate.

26. Figure 17-24 Reaction mechanism of lactate dehydrogenase. Page 603

27. Alcoholic fermentation (yeast don't have Lactate DH) O CO2 CH3 C-O- H-C=O C=O 1. Pyruvate decarboxylase (TPP) Mg2+, thiamine pyrophosphate CH3 Acetaldehyde NADH, H+ Pyruvate NAD+ 2. alchohol dehydrogenase CH3 H-C-O- H H Ethanol

28. Figure 17-26 Thiamine pyrophosphate (TPP). Page 604 Involved in both oxidative and non-oxidative decarboxylation as a carrier of "active" aldehydes.

29. Mechanism of Pyruvate Decarboxylase using TPP Nucleophilic attack by the dipolar cation (ylid) form of TPP on the carbonyl carbon of pyruvate to form a covalent adduct. Loss of carbon dioxide to generate the carbanion adduct in which the thiazolium ring of TPP acts as an electron sink. Protonation of the carbanion Elimination of the TPP ylid to form acetaldehyde and regenerate the active enzyme.

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31. Figure 17-25 The two reactions of alcoholic fermentation. Page 604

32. Figure 17-30 The reaction mechanism of alcohol dehydrogenase involves direct hydride transfer of the pro-R hydrogen of NADH to the re face of acetaldehyde. Page 606

33. Alcoholic fermentation 2ADP + 2 Pi Glucose 2 Ethanol + 2 CO2 2 ATP Pyruvate decarboxylase is present in brewer's yeast but absent in muscle / lactic acid bacteria

34. Other types of fermentations also exist… Mixed acid: (2 lactate + acetate + ethanol) so, in addition to lactate production… ADP ATP CoASH pyruvate acetyl-CoA + acetyl-P acetate NADH, H+ NAD+ lactate acetaldehyde NADH, H+ NAD+ ethanol

35. O C-O- C-C-O- H CH3 CH3 O Butanediol fermentation CH3 O CO2 CO2 C-O- HC-OH C=O C=O CH3 CH3 Acetoin 2 Pyruvate Acetolactic acid NADH, H+ NAD+ CH3 HC-OH HC-OH CH3 2,3-butanediol

36. Other fermentations (Clostridium) O CH3-C-COOH CoA H2 CO2 CoA O isopropanol OH Acetic acid CH3-C-CoA CH3-C-CH3 Acetyl-CoA CoA NADH O O O CoA CH3-C-CH3 CH3-C-CH2-C-CoA acetone CO2

37. Other fermentations (Clostridium) O O CH3-C-CH2-C-CoA H2O O CH3-CH=CH-C-CoA NADH NAD O O H2O CH3-CH2CH2-C-CoA CH3-CH2CH2-C-OH 2 NADH butyric acid 2 NAD CH3-CH2CH2-CH2-OH butanol

38. What about other sugars? Fructose - fruits, table sugar (sucrose). Galactose - hydrolysis of lactose (milk sugar) Mannose - from the digestion of polysaccharides and glycoproteins. All converted to glycolytic intermediates.

39. Fructose metabolism Two pathways: muscle and liver In muscle, hexokinase also phosphorylates fructose producing F6P. Liver uses glucokinase (low levels of hexokinase) to phosphorylate glucose, so for fructose it uses a different enzyme set Fructokinase catalyzes the phosphorylation of fructose by ATP at C1 to form fructose-1-phosphate. Type B aldolase (fructose-1-phosphate aldolase) found in liver cleaves F1P to DHAP and glyceraldehyde. Glyceraldehyde kinase converts glyceraldehyde to GAP.

40. Fructose metabolism Glyceraldehyde can also be converted to glycerol by alcohol dehydrogenase. Glycerol is phosphorylated by glycerol kinase to form glycerol-3-phosphate. Glycerol-3-phosphate is oxidized to DHAP by glycerol phosphate dehydrogenase. DHAP is converted to GAP by TIM

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42. Figure 8.16c Important disaccharides formed by linking monosaccharides with O-glycosidic bonds. Lactose, milk sugar.

43. Galactose metabolism Galactose is half the sugar in lactose. Galactose and glucose are epimers (differ at C4) Involves epimerization reaction after the conversion of galactose to the uridine diphosphate (UDP) derivative. Galactose is phosphorylated at C1 by ATP (galactokinase) Galactose-1-phosphate uridylyltransferase transfers UDP-glucose’s uridylyl group to galactose-1-phosphate to make glucose-1-phosphate (G1P) and UDP-galactose. UDP-galactose-4-epimerase converts UDP-galactose back to UDP glucose. G1P is converted to G6P by phosphoglucomutase.

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