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Physiological Control of Liver Glycogen Metabolism: Lessons from Novel Glycogen Phosphorylase Inhibitors

[ Vol. 10 , Issue. 12 ]


L. Agius   Pages 1175 - 1187 ( 13 )


Liver glycogen is synthesized in the postprandial state in response to elevated concentrations of glucose and insulin or by activation of neuroendocrine signals and it is degraded in the postabsorptive state in response to changes in the concentrations of insulin and counter-regulatory hormones. Dysregulation of either glycogen degradation or synthesis through changes in allosteric control or covalent modification of glycogen phosphorylase and glycogen synthase leads to disturbance of blood glucose homeostasis. Liver glycogen phosphorylase has a dual role in the control of glycogen metabolism by regulation of both glycogen degradation and synthesis. The phosphorylated form (GPa) is the active form and determines the rate of degradation of glycogen and it is also a potent allosteric inhibitor of the protein complex, involving the glycogen targeting protein GL and protein phosphatase-1, which catalyses dephosphorylation (activation) of glycogen synthase. Drug discovery programmes exploring the validity of glycogen phosphorylase as a therapeutic target for type 2 diabetes have generated a wide array of selective phosphorylase ligands that modulate the catalytic activity and / or the phosphorylation state (interconversion of GPa and GPb) as well as the binding of GPa to the allosteric site of GL. Glycogen phosphorylase inhibitors that act in hepatocytes either exclusively by dephosphorylating GPa (e.g. indole carboxamides) or by allosteric inhibition of GPa (1,4-dideoxy-1,4-D-arabinitol) are very powerful experimental tools to determine the relative roles of covalent modification of glycogen phosphorylase and / or cycling between glycogen synthesis and degradation in the mechanism(s) by which insulin and neurotransmitters regulate hepatic glycogen metabolism.


Glycogen, glycogen phosphorylase, inhibitors, hepatocytes, liver, Liver Glycogen Metabolism, Glycogen Phosphorylase Inhibitors, neuroendocrine signals, insulin, blood glucose homeostasis, glycogen synthase, allosteric inhibitor, dephosphorylation, TYPE 2 DIABETES, glycogenolysis and gluconeogensis, neuroendocrine mechanisms, glucosyl residues, -1,4 bonds, -1,6 bonds, 1,4-glucanotransferase, amylo-1,6-glucosidase, hexokinase, glucokinase, phosphoglucomutase, ATP-dependent phosphorylation, glucokinase regulatory protein, allosteric activator of glycogen, protein kinase A, phosphorylase kinase, glycogen synthase kinase, AMP-activate protein kinase, allosteric inhibitor of the glycogen, indole carboxamide ligands, purine nucleoside inhibitor, AICAR-monophosphate, synthase phosphatase, glucokinase inhibitor, chronic hyperglycaemia, GPa-allosteric site, indole carboxamides, isofogamine, AMP ACTIVATOR SITE, Maslinic acid, hepatocytes S1048, indole carboxamide, R-state inhibitor, T-state inhibitors, cyclin dependent kinases, flavopiridol, GL-GPa COMPLEX, AICAR, CP-91149, F2-glc, 1-GlcNAc, protein phosphatase-1


Institute of Cellular Medicine, The Medical School, Newcastle University, Newcastle upon Tyne NE2 4HH, UK.

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