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Biochemistry 432/832. August 29 Glycolysis Gluconeogenesis. Announcements: -. One of best characterized pathways Characterized in the first half of 20th century Glucose --> 2 pyruvates + energy Strategy add phosphoryl groups to glucose
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Biochemistry 432/832 August 29 Glycolysis Gluconeogenesis
One of best characterized pathways Characterized in the first half of 20th century Glucose --> 2 pyruvates + energy Strategy add phosphoryl groups to glucose convert phosphorylated intermediates into compounds with high phosphate group-transfer potentials couple the subsequent hydrolysis of reactive substances to ATP synthesis Glucose + 2NAD+ + 2 ADP + 2Pi --> 2NADH + 2 pyruvates + 2ATP + 2H2O + 4H+ Glycolysis - Overview
Overview of Glycolysis The Embden-Meyerhof (Warburg) Pathway • Essentially all cells carry out glycolysis • Ten reactions - similar in most cells - but rates differ • Two phases: • First phase converts glucose to two G-3-P • Second phase produces two pyruvates • Products are pyruvate, ATP and NADH • NADH must be recycled • Three possible fates for pyruvate
Fate of pyruvate Reduction to lactate Decarboxylation to acetaldehyde Reduction to ethanol Mitochondrial oxidation 1 NADH --> ~3 ATP
Glucose Hexokinase, glucokinase Glucose-6-phosphate Phosphoglucoisomerase Fructose-6-phosphate Phosphofructokinase Fructose-1,6-biphosphate Dihydroxyacetone phosphate Aldolase Glyceraldehyde-3-phosphate Triose phosphate isomerase
First Phase of Glycolysis The first reaction - phosphorylation of glucose • Hexokinase or glucokinase • This is a priming reaction - ATP is consumed here in order to get more later • ATP makes the phosphorylation of glucose spontaneous
Hexokinase1st step in glycolysis; G large, negative • Hexokinase (and glucokinase) act to phosphorylate glucose and keep it in the cell • Km for glucose is 0.1 mM; cell has 4 mM glucose • So hexokinase is normally active! • Glucokinase (Kmglucose = 10 mM) only turns on when cell is rich in glucose • Hexokinase is regulated - allosterically inhibited by (product) glucose-6-P -
Hexokinase • First step in glycolysis • Large negative deltaG • Hexokinase is regulated - allosterically inhibited by (product) glucose-6-P • Corresponding reverse reaction (Gluconeogenesis) is catalyzed by a different enzyme (glucose-6-phosphatase) • Is it the committed step in glycolysis ?
Glucose Glucose-6-P dehydrogenase Glycogen Glucose-6-P Ribose-5-P + NADPH Fructose-6-P Reducing power Nucleic acid synthesis Glyceraldehyde-3-P Pyruvate ATP
Rx 2: Phosphoglucoisomerase Glucose-6-P to Fructose-6-P
Rx 3: Phosphofructokinase PFK is the committed step in glycolysis! • The second priming reaction of glycolysis • Committed step and large, neg delta G - means PFK is highly regulated • ATP inhibits, AMP reverses inhibition • Citrate is also an allosteric inhibitor • Fructose-2,6-bisphosphate is allosteric activator • PFK increases activity when energy status is low • PFK decreases activity when energy status is high
Glycolysis - Second Phase Metabolic energy produces 4 ATP • Net ATP yield for glycolysis is two ATP • Second phase involves two very high energy phosphate intermediates • . • 1,3 BPG • Phosphoenolpyruvate
Glyceraldehyde-3-phosphate Glyceraldehyde-3-phosphate dehydrogenase 1,3-biphosphoglycerate Phosphoglycerate kinase 3-phosphoglycerate Phosphoglycerate mutase 2-phosphoglycerate Enolase phosphoenolpyruvate Pyruvate kinase pyruvate
Rx 10: Pyruvate Kinase PEP to Pyruvate makes ATP • These two ATP (from one glucose) can be viewed as the "payoff" of glycolysis • Large, negative G - regulation! • Allosterically activated by AMP, F-1,6-bisP • Allosterically inhibited by ATP and acetyl-CoA
The Fate of NADH and PyruvateAerobic or anaerobic?? • NADH is energy - two possible fates: • If O2 is available, NADH is re-oxidized in the electron transport pathway, making ATP in oxidative phosphorylation • In anaerobic conditions, NADH is re-oxidized by lactate dehydrogenase (LDH), providing additional NAD+ for more glycolysis
The Fate of NADH and PyAerobic or anaerobic?? • Pyruvate is also energy - two possible fates: • aerobic: citric acid cycle • anaerobic: LDH makes lactate
Energetics of Glycolysis The elegant evidence of regulation! • Standard state G values are scattered: + and - • G in cells is revealing: • Most values near zero • 3 of 10 reactions have large, negative G • Large negative G reactions are sites of regulation!
Gluconeogenesis Synthesis of "new glucose" from common metabolites • Humans consume 160 g of glucose per day • 75% of that is in the brain • Body fluids contain only 20 g of glucose • Glycogen stores yield 180-200 g of glucose • So the body must be able to make its own glucose
Substrates for Gluconeogenesis Pyruvate, lactate, glycerol, amino acids and all TCA intermediates can be utilized • Fatty acids cannot! • Most fatty acids yield only acetyl-CoA • Acetyl-CoA (through TCA cycle) cannot provide for net synthesis of sugars
Gluconeogenesis I • Occurs mainly in liver and kidneys • Not the mere reversal of glycolysis for 2 reasons: • Energetics must change to make gluconeogenesis favorable (delta G of glycolysis = -74 kJ/mol • Reciprocal regulation must turn one on and the other off - this requires something new!
Energetics of Glycolysis The elegant evidence of regulation! • G in cells is revealing: • Most values near zero • 3 of 10 reactions have large, negative G • Large negative G reactions are sites of regulation! • Reactions 1, 3 and 10 should be different to go into opposite direction
Gluconeogenesis II Something Borrowed, Something New • Seven steps of glycolysis are retained: • Steps 2 and 4-9 • Three steps are replaced: • Steps 1, 3, and 10 (the regulated steps!) • The new reactions provide for a spontaneous pathway (G negative in the direction of sugar synthesis), and they provide new mechanisms of regulation