Glycogen phosphorylase inhibition

L. Nprskov-Lauritsen, and L. Agius, Iminosugars as potential inhibitors of glycogenolysis Structural insights into the molecular basis of glycogen phosphorylase inhibition,./. Med. Chem., 49 (2006) 5687-5701. 

Glucagon causes the activation of glycogen phosphorylase, inhibition of glycogen synthase, and inhibition of phosphofructokinase-I. 

The cAMP formed by adenylyl cyclase (Figure 15.20) does not persist because 5 -phosphodiesterase activity prevalent in cells hydrolyzes cAMP to give 5 -AMP. Caffeine inhibits 5 -phosphodi-esterase activity. Describe the effects on glycogen phosphorylase activity that arise as a consequence of drinking lots of caffeinated coffee. 

Khan MTH (2007) Recent Advances on the Sugar-Derived Heterocycles and Their Precursors as Inhibitors Against Glycogen Phosphorylases (GP). 9 33-52 Khan MTH (2007) Heterocyclic Compounds Against the Enzyme Tyrosinase Essential for Melanin Production Biochemical Features of Inhibition. 9 119-138 Khan MTH (2007) Molecular Modeling of the Biologically Active Alkaloids. 10 75-98 Khan MTH, Ather A (2007) Microbial Transformation of Nitrogenous Compoimds. 10 99-122... 

Glycogen phosphorylase isoenzymes have been isolated from liver, brain and skeletal muscle. All forms are subject to covalent control with conversion of the inactive forms (GP-b) to the active forms (GP-a) by phosphorylation on specific serine residues. This phosphorylation step, mediated by the enzyme phosphorylase kinase, is initiated by glucagon stimulation of the hepatocyte. Indeed, the same cAMP cascade which inhibits glycogen synthesis simultaneously stimulates glycogenolysis, giving us an excellent example of reciprocal control. 

The glucose concentration is the major factor regulating glycogen synthesis in liver. Glucose activates glucokinase directly as a substrate and indirectly via an increase in the concentration of fructose 6-phosphate. It also activates glycogen synthase but it inhibits glycogen phosphorylase (see text). 

Fig. 7.18. Regulation of glycogen metabolism in muscle. Phosphorylase kinase stands at the center of regulation of glycogen metabolism. Phosphorylase kinase may exist in an active, phosphorylated form and an inactive, unphosphorylated form. Phosphorylation of phosphorylase kinase is triggered by hormonal signals (e.g. adrenahne) and takes place via an activation of protein kinase A in the cAMP pathway. In the absence of hormonal stimulation, phosphorylase kinase can also be activated by an increase in cytosolic Ca. The active phosphorylase kinase stimulates glycogen degradation and inhibits glycogen synthesis, in that, on the one side, it activates glycogen phosphorylase by phosphorylation, and on the other side, it inactivates glycogen synthase by phosphorylation.

Fig. 7.21. Activation of glycogen-bound protein phosphatase I by insulin. Insulin has a stimulating effect on glycogen synthesis by initiating the dephosphorylation and activation of glycogen synthase and the dephosphorylation and inhibition of glycogen phosphorylase. Both enzymes (substrate S in the figure) are dephosphorylated by protein phosphatase PPIG. Insulin mediates the activation of a protein kinase (insulin-sensitive protein kinase) within an insulin-stimulated signal pathway, which phosphorylates and thus activates protein phosphatase PPIG at the PI site.

Promotes glucose storage as glycogen (induces glucokinase and glycogen synthase, inhibits phosphorylase)... 

In the well-fed state, glycogen synthase is allosterically activated by glucose 6-phosphate when it is present in elevated concentrations (Figure 11.9). In contrast, glycogen phosphorylase is allosterically inhibited by glucose 6-phosphate, as well as by ATP,... 

Allosteric Enzymes Typically Exhibit a Sigmoidal Dependence on Substrate Concentration The Symmetry Model Provides a Useful Framework for Relating Conformational Transitions to Allosteric Activation or Inhibition Phosphofructokinase Allosteric Control of Glycolysis Is Consistent with the Symmetry Model Aspartate Carbamoyl Transferase Allosteric Control of Pyrimidine Biosynthesis Glycogen Phosphorylase Combined Control by Allosteric Effectors and Phosphorylation... 

The rate of the reaction catalyzed by glycogen phosphorylase, as a function of the concentration of its main allosteric activator, AMR The curves shown in color were obtained in the presence of ATR Phosphorylase b (lower two curves) is almost completely inactive in the absence of AMR Its activity is half maximal at an AMP concentration of about 40 yuM. ATP greatly increases the concentration of AMP required for activity. Phosphorylase a (upper two curves) has about 80% of its maximal activity in the absence of AMP and reaches full activity at very low AMP concentrations it also is relatively insensitive to inhibition by ATP. 

The same cAMP-dependent protein kinase that is responsible for phosphorylating phosphorylase kinase also catalyzes the phosphorylation of glycogen synthase. Whereas phosphorylation of glycogen phosphorylase leads to increased activity, the phosphorylation of glycogen synthase decreases its activity. As a result when glycogen breakdown is stimulated in response to glucagon, glycogen synthesis is inhibited. In this way the simultaneous operation of both enzymes associated with pseudocycle la is prevented. 

The same protein kinase that phosphorylates glycogen phosphorylase and glycogen synthase does not phosphorylate the enzymes of pseudocycle II. Rather an enzyme gets phos-phorylated that catalyzes the synthesis of a potent allosteric effector of the two relevant enzymes, phosphofructokinase and fructose bisphosphate phosphatase. In the liver the un-phosphorylated form this enzyme synthesizes fructose-2,6-bisphosphate. Phosphorylation converts it into a degradative enzyme for the same compound. Fructose-2,6-bisphosphate is an activator of phosphofructokinase and an inhibitor of fructose bisphosphate phosphatase. As a result the net effect of glucagon on pseudocycle II is to stimulate fructose bisphosphate phosphatase while inhibiting phosphofructokinase (see table 12.2 and fig. 12.30). 

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