1. GLYCOGEN METABOLISM 1

2. Glycogen Structure Most of the glucose residues in glycogen are linked by  -1,4-glycosidic bonds. Branches at about every tenth residue are created by  - 1,6-glycosidic bonds. 2

3. Glycogen is an important fuel reserve for several reasons Glycogen serves as a buffer to maintain blood- glucose levels – Especially important because glucose is virtually the only fuel used by the brain. – Is good source of energy for sudden, strenuous activity Unlike fatty acids, it can provide energy in the absence of oxygen 3

4. The major sites of glycogen storage 1.liver 2. The skeletal muscles Glycogen is present in the cytosol in the form of granules ranging in diameter from 10 to 40 nm 4

5. Glycogen Metabolism Glycogenesis Addition of α1-4 linkages to non- reducing ends. 1 ATP per linkage. Branching enzymes. Inactivated by cAMP Glycogenolysis Cleave α1-4 linkages at non-reducing ends. Phosphorolysis (Pi in place of H 2 O. Debranching enzymes. Activated by cAMP 5

6. Glycogen degradation Consists of three steps e 1.release of G1-P from glycogen 2.The remodeling of the glycogen substrate to permit further degradation 3.The conversion of G1-P into G6-P. It is the initial substrate for glycolysis 1.it can be processed by the pentose phosphate pathway to yield NADPH and ribose derivatives 2.it can be converted into free glucose for release into the bloodstream. 6

7. Glycogen degradation 7

8. Regulation of Glycogen metabolism Allosterically: – By adjustment of enzyme activity to meet the needs of the cell. Hormones stimulate cascades that lead to reversible phosphorylation of the enzymes, which alters their kinetic properties. – Regulation by hormones allows glycogen metabolism to adjust to the needs of the entire organism. 8

9. Glycogen Breakdown Requires the Interplay of Several Enzymes Four enzyme activities: – one to degrade glycogen, – two to remodel glycogen so that it remains a substrate for degradation – one to convert the product of glycogen breakdown into a form suitable for further metabolism. 9

10. Glycogen Phosphorylase: A key enzyme Cleaves its substrate by the addition of orthophosphate (Pi) to yield G1-P (phosphorolysis) Catalyzes the sequential removal of glycosyl residues from the nonreducing ends of the glycogen molecule (the ends with a free 4-OH groups) 10

11.  G°´ for this reaction is small because a glycosidic bond is replaced by a phosphoryl ester bond that has a nearly equal transfer potential. Phosphorolysis proceeds far in the direction of glycogen breakdown in vivo because the [Pi]/[G6-P] ratio is usually >100, substantially favoring phosphorolysis. The phosphorolytic cleavage of glycogen is energetically advantageous because the released sugar is already phosphorylated 11

12. Two Remodeling Enzymes Transferase: – Shifts a block of three glycosyl residues from one outer branch to the other  -1,6-glucosidase (debranching enzyme) – Hydrolyzes the  -1, 6-glycosidic bond, resulting in the release of a free glucose molecule. – Glucose is phosphorylated by hixokinase (glycolysis) 12

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14. This paves the way for further cleavage by phosphorylase. In eukaryotes, the transferase and the  - 1,6-glucosidase activities are present in a single polypeptide chain, in a bifunctional enzyme 14

15. Phosphoglucomutase G1-P formed in the phosphorolytic cleavage of glycogen must be converted into G6-P to enter the metabolic mainstream. This enzyme is also used in galactose metabolism 15

16. G1-PG6-P G1,6-BP Serine 16

17. You may recall that the enzyme glucose-6- phosphatase (G6Pase) catalyzes the last step of gluconeogenesis - conversion of G6P to glucose + phosphate. This enzyme necessary also for release of glucose into the bloodstream from glycogen metabolism (glycogen -> G1P -> G6P -> Glucose). It is interesting to note that G6Pase is ABSENT FROM MUSCLE. This is because muscle does NOT export glucose. the liver, on the other hand, DOES export glucose and thus has abundant supplies of the enzyme. 17

18. Liver Contains G6-Pase; a hydrolytic enzyme absent from Muscle A major function of the liver is to maintain a near constant level of glucose in the blood. The liver G6-Pase, cleaves the phosphoryl group to form free glucose and orthophosphate. This G6-Pase, is located on the lumenal side of the smooth endoplasmic reticulum membrane 18

19. Glycogen Phosphorylase Pyridoxal Phosphate integral group of the Enzyme The Pi substrate binding site 19

20. In human, liver phosphorylase and muscle phosphorylase are approximately 90% identical in amino acid sequence. The differences result in important shifts in the stability of various forms (isozymes) of the enzyme. 20

21. Phosphorylase exists in two states The R state, catalytic site is more accessible and a binding site for orthophosphate is well organized. The T state is less active because the catalytic site is partly blocked. 21

22. Phosphorylase Is Regulated by: Allosteric Interactions: – By several allosteric effectors that signal the energy state of the cell Reversible Phosphorylation: – responsive to hormones such as: Insulin Epinephrine Glucagon The glycogen metabolism regulation differs in muscle than in liver because: – The muscle uses glucose to produce energy for itself, whereas the liver maintains glucose homeostasis of the organism as a whole 22

23. phosphorylase B usually inactive ATP A usually active P Phosphorylase kinase Phosphorylase a differs from b by a phosphoryl group on each subunit 23

24. Depending on cellular conditions The equilibrium for phosphorylase a, favors the R- state The equilibrium for phosphorylase b, favors the T- state The R and T states of each of the a or b forms are in equilibrium 24

25. In muscles-Posphorylase b High AMP, binds to a nucleotide-binding site and stabilizes the conformation of phosphorylase b in the R-state. ATP acts as a negative allosteric effector by competing with AMP and so favors the T-state. G6-P also favors the T-state of phosphorylase b, an example of feedback inhibition 25

26. Under most physiological conditions, phosphorylase b is inactive because of the inhibitory effects of ATP and G6-P. In contrast, phosphorylase a is fully active, regardless of the levels of AMP, ATP, and G6-P. 26

27. Liver Phosphorylase Produces Glucose for Use by Other Tissues In contrast with the muscle enzyme, liver phosphorylase a but not b exhibits the most responsive T-to-R transition. The binding of glucose shifts the allosteric equilibrium of the a form from the R to the T state, deactivating the enzyme Unlike the enzyme in muscle, the liver phosphorylase is insensitive to regulation by AMP because the liver does not undergo the dramatic changes in energy charge seen in a contracting muscle 27

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29. Phosphorylase kinase 29

30. Phosphorylase kinase in the skeletal muscle: is (    is catalytic  are  regultory  is calmodulin 30

31. Epinephrine and Glucagon Signal the Need for Glycogen Breakdown Muscular activity or its anticipation leads to the release of epinephrine (adrenaline),from the adrenal medulla. Epinephrine markedly stimulates glycogen breakdown in muscle and, to a lesser extent, in the liver. The liver is more responsive to glucagon, a polypeptide hormone that is secreted by the  cells of the pancreas when the blood-sugar level is low. 31

32. Epinephrine binds to the  -adrenergic receptor in muscle, whereas glucagon binds to the glucagon receptor in liver. These binding events activate the  subunit of the heteromeric G s protein. A specific external signal is transmitted into the cell 32

33. Glycogen Is Synthesized and Degraded by Different Pathways glycogen is synthesized by a pathway that utilizes uridine diphosphate glucose (UDP- glucose) rather than G1-P as the activated glucose donor. 33

34. UDP-Glucose Is an Activated Form of Glucose UDP-glucose, the glucose donor in the biosynthesis of glycogen, is an activated form of glucose. The C-1 carbon atom of the glucosyl unit of UDP-glucose is activated because its hydroxyl group is esterified to the diphosphate moiety of UDP. 34

35. UDP-glucose is synthesized from G1-P and (UTP) in a reaction catalyzed by UDP-glucose pyrophosphorylase. 35

36. This reaction is readily reversible. Pyrophosphate is rapidly hydrolyzed in vivo to orthophosphate by an inorganic pyrophosphatase. The essentially irreversible hydrolysis of pyrophosphate drives the synthesis of UDP-glucose. 36

37. Glycogen Synthase Catalyzes the Transfer of Glucose from UDP-Glucose to a Growing Chain 37

38. glycogen synthase, is the key regulatory enzyme in glycogen synthesis. It can add glucosyl residues only if the polysaccharide chain already contains more than four residues. Thus, glycogen synthesis requires a primer. – This priming function is carried out by glycogenin, a protein composed of two identical 37-kd subunits, each bearing an oligosaccharide of  -1,4-glucose units. – C1 of the first unit of this chain, the reducing end, is covalently attached to the phenolic hydroxyl group of a specific tyrosine in each glycogenin subunit. 38

39. How is this chain formed? Each subunit of glycogenin catalyzes the addition of eight glucose units to its partner in the glycogenin dimer. UDP-glucose is the donor in this autoglycosylation. At this point, glycogen synthase takes over to extend the glycogen molecule 39

40. A Branching Enzyme Forms  -1,6 Linkages Branching occurs after a number of glucosyl residues are joined in  -1,4 linkage by glycogen synthase. A branch is created by the breaking of an  -1,4 link and the formation of an  -1,6 link. A block of residues, typically 7 in number, is transferred to a more interior site. The block of 7 or so residues must include the nonreducing terminus and come from a chain at least 11 residues long. The new branch point must be at least 4 residues away from a preexisting one. 40

41. Branching is important because it increases the solubility of glycogen. Branching creates a large number of terminal residues, the sites of action of glycogen phosphorylase and synthase. Thus, branching increases the rate of glycogen synthesis and degradation. 41

42. Glycogen Synthase Is the Key Regulatory Enzyme in Glycogen Synthesis Glycogen synthase is phosphorylated at multiple sites by protein kinase A (PKA) and several other kinases. The resulting alteration of the charges in the protein lead to its inactivation Phosphorylation has opposite effects on the enzymatic activities of glycogen synthase and phosphorylase 42 Net charge after posphorylation

43. Phosphorylation converts the active a form of the synthase into inactive b form. The phosphorylated b form requires a high level of the allosteric activator G6-P for activity The a form is active whether or not G6-P is present 43

44. Glycogen Is an Efficient Storage Form of Glucose One ATP is hydrolyzed incorporating glucose 6- phosphate into glycogen 44 -ATP

45. Glycogen Glucose G6-P G1-P Pyruvate -1 ATP 10% branch 90% +31 ATP G1-P -1 ATP The complete oxidation of glucose 6-phosphate yields about 31 molecules of ATP. Storage consumes slightly more than one molecule of ATP per molecule of glucose 6-phosphate; so the overall efficiency of storage is nearly 97%. 45

46. Glycogen Breakdown and Synthesis Are Reciprocally Regulated By a hormone-triggered cAMP cascade acting through protein kinase A 46

47. Insulin Stimulates Glycogen Synthesis by Activating Protein Phosphatase 1 When blood-glucose levels are high, insulin stimulates the synthesis of glycogen by triggering a pathway that activates protein phosphatase 1 Different site from PKA phosphorylation in response to epinepfrine 47

48. Glycogen Metabolism in the Liver Regulates the Blood-Glucose Level After a meal rich in carbohydrates, blood-glucose levels rises, leading to an increase in glycogen synthesis in the liver Insulin is the primary signal for glycogen synthesis The liver senses the concentration of glucose in the blood, (~80 to 120 mg/100ml). The liver takes up or releases glucose accordingly. 48

49. The amount of liver phosphorylase a decreases rapidly when glucose is infused. After a lag period, the amount of glycogen synthase a increases, which results in the synthesis of glycogen. 49