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Chapter 22 Gluconeogenesis, Glycogen Metabolism, and the Pentose Phosphate Pathway Biochemistry by Reginald Garrett and Charles Grisham Essential Question 1. What is the nature of gluconeogenesis, the pathway that synthesizes glucose from noncarbohydrate precursors 2. How is glycogen synthesized from glucose 3. How are electrons from glucose used in biosynthesis? Outline of chapter 22 1. What Is Gluconeogenesis, and How Does It Operate? 2. How Is Gluconeogenesis Regulated? 3. How Are Glycogen and Starch Catabolized in Animals? 4. How Is Glycogen Synthesized? 5. How Is Glycogen Metabolism Controlled? 6. Can Glucose Provide Electrons for Biosynthesis? 22.1 – What Is Gluconeogenesis, and How Does It Operate? • • • • • 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! Why? • Most fatty acids yield only acetyl-CoA – Except fatty acids with odd numbers of carbons • Acetyl-CoA (through TCA cycle) cannot provide for net synthesis of sugars in animal, but plants do! Why? Substrates for Gluconeogenesis 1. 2. 3. 4. Lactate Amino acids Glycerol Propionyl-CoA Gluconeogenesis • Occurs mainly in liver (90%) and kidneys (10%) • Not the mere reversal of glycolysis for 2 reasons: – Energetics: must change to make gluconeogenesis favorable (DG of glycolysis = -74 kJ/mol) – Reciprocal regulation: Gluconeogenesis must turn one on and the other off, and vice versa Gluconeogenesis 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 (DG negative in the direction of sugar synthesis), and they provide new mechanisms of regulation Figure 22.1 The pathways of gluconeogenesis and glycolysis. Species in blue, green, and peach-colored shaded boxes indicate other entry points for gluconeogenesis (in addition to pyruvate). Pyruvate Carboxylase Pyruvate is converted to oxaloacetate • The reaction requires ATP and bicarbonate as substrates • Biotin as a coenzyme and Acetyl-CoA is an allosteric activator Biotin is covalently linked to the e-amino group of a lysine residue Figure 22.3 Covalent linkage of biotin to an activesite lysine in pyruvate carboxylase. • The mechanism is typical of biotin Figure 22.4 A mechanism for the pyruvate carboxylase reaction. Bicarbonate must be activated for attack by the pyruvate carbanion. This activation is driven by ATP and involves formation of a carbonylphosphate intermediate—a mixed anhydride of carbonic and phosphoric acids. (Carbonylphosphate and carboxyphosphate are synonyms.) Pyruvate Carboxylase • Acyl-CoA is an allosteric activator • The conversion is in mitochondrial matrix • Regulation: – If levels of ATP and/or acetyl-CoA are low, pyruvate is converted to acetyl-CoA and enters TCA cycle – If levels of ATP and/or acetyl-CoA are high, pyruvate is converted to oxaloacetate and enters gluconeogenesis glucose • Pyruvate carboxylase is found only in mitochondrial matrix • Oxaloacetate cannot be transported across the mitochondrial membrane Figure 22.5 Pyruvate carboxylase is a compartmentalized reaction. Pyruvate is converted to oxaloacetate in the mitochondria. Because oxaloacetate cannot be transported across the mitochondrial membrane, it must be reduced to malate, transported to the cytosol, and then oxidized back to oxaloacetate before gluconeogenesis can continue. PEP Carboxykinase Conversion of oxaloacetate to PEP • Lots of energy needed to drive this reaction • Energy is provided in 2 ways: – Decarboxylation is a favorable reaction – GTP is hydrolyzed • GTP used here is equivalent to an ATP PEP Carboxykinase • The overall DG for the pyruvate carboxylase and PEP carboxykinase reactions under physiological conditions in the liver is -22.6 kJ/mol • Once PEP is formed in this way, the other reactions act to eventually form fructose-1,6bisphosphate Fructose-1,6-bisphosphatase Hydrolysis of F-1,6-bisPase to F-6-P • Thermodynamically favorable - DG in liver is -8.6 kJ/mol • Allosteric regulation: – citrate stimulates – fructose-2,6-bisphosphate inhibits – AMP inhibits (enhanced by F-2,6-bisP) Glucose-6-Phosphatase • • • • Conversion of Glucose-6-P to Glucose G-6-Pase is present in ER membrane of liver and kidney cells Muscle and brain do not do gluconeogenesis G-6-P is hydrolyzed as it passes into the ER ER vesicles filled with glucose diffuse to the plasma membrane, fuse with it and open, releasing glucose into the bloodstream. Figure 22.8 Glucose-6-phosphatase is localized in the endoplasmic reticulum membrane. Conversion of glucose-6-phosphate to glucose occurs during transport into the ER. DG = -5.1 kJ/mol Figure 22.9 The glucose-6-phosphatase reaction involves formation of a phosphohistidine intermediate. Lactate Recycling – Cori cycle • • • • How your liver helps you during exercise.... Recall that vigorous exercise can lead to a buildup of pyruvate and NADH, due to oxygen shortage and the need for more glycolysis NADH can be reoxidized during the reduction of pyruvate to lactate Lactate is then returned to the liver, where it can be reoxidized to pyruvate by liver LDH Liver provides glucose to muscle for exercise and then reprocesses lactate into new glucose (about 700) Figure 22.10 The Cori cycle. 22.2 – How Is Gluconeogenesis Regulated? • • • • Reciprocal control with glycolysis When glycolysis is turned on, gluconeogenesis should be turned off, and vice versa When energy status of cell is high, glycolysis should be off and pyruvate, etc., should be used for synthesis and storage of glucose When energy status is low, glucose should be rapidly degraded to provide energy The regulated steps of glycolysis are the very steps that are regulated in the reverse direction Figure 22.11 The principal regulatory mechanisms in glycolysis and gluconeogenesis. Activators are indicated by plus signs and inhibitors by minus signs. Allosteric and Substrate-Level Control • Glucose-6-phosphatase – is under substrate-level control by G-6-P, not allosteric control • Pyruvate carboxylase – Activated by acetyl-CoA – The fate of pyruvate depends on acetyl-CoA; pyruvate kinase (-), pyruvate dehydrogenase (-), and pyruvate carboxylase (+) • F-1,6-bisPase – is inhibited by AMP and Fructose-2,6-bisP – Activated by citrate - the reverse of glycolysis (w/o AMP) (w/ 25mM AMP) (F-2,6-BP) (F-2,6-BP) (AMP) Figure 22.12 Inhibition of fructose-1,6-bisphosphatase by fructose-2,6-bisphosphate in the (a) absence and (b) presence of 25 mM AMP. In (a) and (b), enzyme activity is plotted against substrate (fructose-1,6-bisphosphate) concentration. Concentrations of fructose-2,6-bisphosphate (in mM) are indicated above each curve. (c) The effect of AMP (0, 10, and 25 mM) on the inhibition of fructose-1,6-bisphosphatase by fructose-2,6-bisphosphate. Activity was measured in the presence of 10 mM fructose-1,6-bisphosphate. • Fructose-2,6-bisP – is an allosteric inhibitor of F-1,6-bisPase – is an allosteric activator of PFK – synergistic effect with AMP • The cellular levels Fructose-2,6-bisP are controlled by phosphofructokinase-2 and fructose-2,6-bisPase which is bifunctional enzyme – F-6-P allosterically activates PFK-2 and inhibits F2,6-BisPase – Phosphorylation by cAMP-dependent protein kinase inhibits PFK-2 and activates F-2,6-bisPase Figure 22.13 Synthesis and degradation of fructose-2,6-bisphosphate are catalyzed by the same bifunctional enzyme. 22.3 – How Are Glycogen and Starch Catabolized in Animals? Getting glucose from storage (or diet) -Amylase is an endoglycosidase -- (1→4) cleavage b-Amylase is an exoglycosidase (In plants) • It cleaves dietary amylopectin or glycogen to maltose, maltotriose and other small oligosaccharides • It is active on either side of a branch point, but activity is reduced near the branch points and stops four residues from any branch point • limit dextrins Figure 22.14 Hydrolysis of glycogen and starch by -amylase and bamylase. • Debranching enzyme cleaves "limit dextrins" • Two activities of the debranching enzyme – Oligo(1,4→1,4)glucanotransferase – (1→6)glucosidase Figure 22.15 The reactions of glycogen debranching enzyme. Transfer of a group of three -(1 4)-linked glucose residues from a limit branch to another branch is followed by cleavage of the -(1 6) bond of the residue that remains at the branch point. Metabolism of Tissue Glycogen • • • • • Digestive breakdown is unregulated - 100%! But tissue glycogen is an important energy reservoir - its breakdown is carefully controlled Glycogen consists of "granules" of high MW range from 6 x 106 ~ 1600 x 106 Glycogen phosphorylase cleaves glucose from the nonreducing ends of glycogen molecules This is a phosphorolysis, not a hydrolysis Metabolic advantage: product is a glucose-1-P; a "sort-of" glycolysis substrate glycogen phosphorylase (Phosphorolysis) Figure 22.16 The glycogen phosphorylase reaction. • See pages 486-491 to review glycogen phosphorylase 22.4 – How Is Glycogen Synthesized? • • • • Glucose units are activated for transfer by formation of sugar nucleotides What are other examples of "activation"? – acetyl-CoA : acetate – Biotin and THF : one-carbon group – ATP : phosphate Leloir showed that glycogen synthesis depends on sugar nucleotides UDP-glucose pyrophosphorylase catalyzes the formation of UDP-glucose ADP-glucose is for starch synthesis in plants Figure 22.17 The structure of UDP-glucose, a sugar nucleotide. Glucose-1-P + UTP → UDP-glucose + pyrophosphate. Figure 22.18 The UDP-glucose pyrophosphorylase reaction is a phosphoanhydride exchange, with a phosphoryl oxygen of glucose-1-P attacking the -phosphorus of UTP to form UDP-glucose and pyrophosphate. Glycogen Synthase Forms -(1 4) glycosidic bonds in glycogen • Glycogenin (a protein core) forms the core of a glycogen particle • First glucose is linked to a tyrosine -OH on glycogenin • Glycogen synthase transfers glucosyl units from UDP-glucose to C-4 hydroxyl at a nonreducing end of a glycogen strand. • oxonium ion intermediate (Fig. 22.19) Figure 22.19 The glycogen synthase reaction. Cleavage of the C-O bond of UDP-glucose yields an oxonium intermediate. Attack by the hydroxyl oxygen of the terminal residue of a glycogen molecule completes the reaction. Glycogen branching occurs by transfer of terminal chain segments • Glycogen branches are formed by amylo-(1,4→1,6)-transglycosylase, also called branching enzyme • -(1 6) linkages, which occurs every 8-12 residues • Transfer of 6- or 7-residue segment from the nonreducing end Figure 22.20 Formation of glycogen branches by the branching enzyme. Sixor seven-residue segments of a growing glycogen chain are transferred to the C-6 hydroxyl group of a glucose residue on the same or a nearby chain. 22.5 – How Is Glycogen Metabolism Controlled? A highly regulated process, involving reciprocal control of glycogen phosphorylase and glycogen synthase • Glycogen phosphorylase, allosterically activated by AMP and inhibited by ATP, glucose-6-P and caffeine • Glycogen synthase, is stimulated by glucose-6-P • Both enzymes are regulated by covalent modification - phosphorylation Phosphorylation of GP and GS Covalent modification • In chapter 15 showed that protein kinase converted phosphorylase b (-OH) to phosphorylase a (-OP) • Glycogen synthase also exists in two distinct forms – Active, dephosphorylated glycogen synthase I – Less active, phosphorylated glycogen synthase D (glucose-6-P dependent) • Nine Ser residues on GS are phosphorylated SPK: Synthasephosphorylase kinase ( phosphorylase b kinase) PP1: Phosphoprotein phosphatase 1 Enzyme Cascades and GP/GS Hormonal regulation ( insulin, Glucagon, epinephrine, and glucocorticoids) • Glucagon and epinephrine activate adenylyl cyclase • cAMP activates kinases and phosphatases that control the phosphorylation of GP and GS – GTP-binding proteins (G proteins) mediate the communication between hormone receptor and adenylyl cyclase • Dephosphorylation is carried out by phosphoprotein phosphatase-I (PP-I) Hormonal Regulation • • • • of Glycogen Synthesis and Degradation Insulin is secreted from the pancreas (to liver) in response to an increase in blood glucose Insulin into the portal vein and traverses the liver Insulin stimulates glycogen synthesis and inhibits glycogen breakdown Other effects of insulin (Figure 22.22) Figure 22.21 The portal vein system carries pancreatic secretions such as insulin and glucagon to the liver and then into the rest of the circulatory system. (glucose uptake) (F-1,6-BP & PEPCK) (PFK & PK) Figure 22.22 The metabolic effects of insulin. As described in Chapter 32, binding of insulin to membrane receptors stimulates the protein kinase activity of the receptor. Subsequent phosphorylation of target proteins modulates the effects indicated. Hormonal Regulation • • • • Glucagon and epinephrine Glucagon and epinephrine stimulate glycogen breakdown - opposite effect of insulin Glucagon (29 AA-res) is also secreted by pancreas and acts in liver and adipose tissue only Epinephrine (adrenaline) is released from adrenal glands and acts on liver and muscles A cascade is initiated that activates glycogen phosphorylase and inhibits glycogen synthase Figure 22.23 The amino acid sequence of glucagon. Figure 22.24 Epinephrine Hormonal Regulation • The phosphorylase cascade amplifies the signal – – – – – – 10-10 to 10-8 M epinephine 10-6 M cAMP Protein kinase 30 molecules of phosphorylase b kinase 800 molecules of phosphorylase a Catalyzes the formation of many molecules of glucose-1-P • The result of these actions is tightly coordinated stimulation of glycogen breakdown and inhibition of glycogen synthesis SPK: Synthasephosphorylase kinase ( phosphorylase b kinase) PP1: Phosphoprotein phosphatase 1 • • • • The difference between Epinephrine and Glucagon Both are glycogenolytic but for different reasons Epinephrine is the fight or flight hormone – Rapid breakdown of glycogen – Inhibition of glycogen synthesis – Stimulation of glycolysis – Production of energy Glucagon is for long-term maintenance of steadystate levels of glucose in the blood – activates glycogen breakdown – activates liver gluconeogenesis Glucagon do not activate the phsphorylase cascade in mucle Cortisol and glucocorticoid • Cortisol is a typical glucocoticoid • In muscle (catabolic) – promotes protein breakdown – decrease protein synthesis • In liver – stimulates gluconeogenesis – increases glycogen synthesis – amino acid catabolism Figure 22.25 The effects of cortisol on carbohydrate and protein metabolism in the liver. 22.6 – Can Glucose Provide Electrons for Biosynthesis? Pentose Phosphate Pathway Hexose monophosphate shunt Phosphogluconate pathway • Provides NADPH for biosynthesis • Produces ribose-5-P for nucleotide synthesis • Several metabolites of the pentose phosphate pathway can also be shuttled into glycolysis Pentose phosphate pathway • Begins with glucose-6-P, a six-carbon, and produces 3-, 4-, 5-, 6, and 7-carbon sugars, some of which may enter the glycolytic pathway • Two oxidative processes followed by five nonoxidative steps • Operates mostly in cytoplasm of liver and adipose cells, but absent in muscle • NADPH is used in cytosol for reductive reaction-- fatty acid synthesis Figure 22.26 The pentose phosphate pathway. The numerals in the blue circles indicate the steps discussed in the text. Oxidative Steps • Glucose-6-P Dehydrogenase – Begins with the oxidation of glucose-6-P – The products are a cyclic ester (the lactone of phosphogluconic acid) and NADPH – Irreversible 1st step and highly regulated – Inhibited by NADPH and acyl-CoA • Gluconolactonase – Gluconolactone hydrolyzed →6-phospho-D-gluconate – Uncatalyzed reaction happens too – Gluconolactonase accelerates this reaction Figure 22.27 The glucose-6-phosphate dehydrogenase reaction is the committed step in the pentose phosphate pathway. Figure 22.28 The gluconolactonase reaction. Oxidative Steps • 6-Phosphogluconate Dehydrogenase – An oxidative decarboxylation of 6phosphogluconate – Yields ribulose-5-P and NADPH – Releases CO2 Figure 22.29 The 6-phosphogluconate dehydrogenase reaction. The Nonoxidative Steps • • • • Five steps, only 4 types of reaction... Phosphopentose isomerase – converts ketose to aldose Phosphopentose epimerase – epimerizes at C-3 Transketolase (TPP-dependent) – transfer of two-carbon units Transaldolase (Schiff base mechanism) – transfers a three-carbon unit • Phosphopentose isomerase – converts ketose to aldose – Ribose-5-P is utilized in the biosynthesis of coenzymes, nucleotides, and nucleic acids Figure 22.30 The phosphopentose isomerase reaction involves an enediol intermediate. • Phosphopentose epimerase – An inversion at C-3 Figure 22.31 The phosphopentose epimerase reaction interconverts ribulose-5-P and xylulose-5-phosphate. The mechanism involves an enediol intermediate and occurs with inversion at C-3. • Transketolase (TPP-dependent) – transfer of two-carbon units – The donor molecule is a ketose and the recipient is an aldose Figure 22.32 The transketolase reaction of step 6 in the pentose phosphate pathway. Figure 22.33 The transketolase reaction of step 8 in the pentose phosphate pathway. Figure 22.34 The mechanism of the TPPdependent transketolase reaction. Ironically, the group transferred in the transketolase reaction might best be described as an aldol, whereas the transferred group in the transaldolase reaction is actually a ketol. Despite the irony, these names persist for historical reasons. • Transaldolase (Schiff base, imine) – transfers a three-carbon unit – Yields erythrose-4-P & Fructose-6-P Figure 22.35 The transaldolase reaction. Figure 22.36 The transaldolase mechanism involves attack on the substrate by an active-site lysine. Departure of erythrose4-P leaves the reactive enamine, which attacks the aldehyde carbon of glyceraldehyde-3-P. Schiff base hydrolysis yields the second product, fructose-6-P. Variations on the Pentose Phosphate Pathway • • • • 1) 2) 3) 4) Both ribose-5-P and NADPH are needed More ribose-5-P than NADPH is needed More NADPH than ribose-5-P is needed NADPH and ATP are needed, but ribose-5-P is not Figure 22.37 When biosynthetic demands dictate, the first four reactions of the pentose phosphate pathway predominate and the principal products are ribose-5-P and NADPH. Figure 22.38 The oxidative steps of the pentose phosphate pathway can be bypassed if the primary need is for ribose-5-P. Figure 22.39 Large amounts of NADPH can be produced by the pentose phosphate pathway without significant net production of ribose-5-P. In this version of the pathway, ribose-5-P is recycled to produce glycolytic intermediates. Figure 22.40 Both ATP and NADPH (as well as NADH) can be produced by this version of the pentose phosphate and glycolytic pathways. (a) Contributions of the various energy sources to muscle activity during mild exercise. (b) Consumption of glycogen stores in fast-twitch muscles during light, moderate, and heavy exercise. (c) Rate of glycogen replenishment following exhaustive exercise. (a and c adapted from Rhodes and Pflanzer, 1992. Human Physiology. Philadelphia: Saunders College Publishing; b adapted from Horton and Terjung, 1988. Exercise, Nutrition and Energy Metabolism. New York : Macmillan.)