Peter J. Kasvinsky scite author profile

Synergistic regulation of glycogen phosphorylase a by the competitive inhibitors glucose and caffeine in vitro indicates a possible physiological role for the negative effector site which binds caffeine (nucleoside site). In intact viable hepatocytes glucose promotes the phosphorylase a to be conversion by phosphorylase phosphatase. This conversion is considered to be a necessary prelude to the activation of glycogen synthase by phosphatase and of importance in hepatic regulation of glucose homeostasis. The effects of glucose and(or) caffeine on the conversion of phosphorylase a to b and synthase b to a were studied. Assays of phosphorylase a were used which limited synergistic inhibition (in the assay) by these ligands. Such an approach is necessary to achieve an accurate measure of phosphatase activity in the viable hepatocyte when the combination of ligands is used. The data indicate that in the presence of caffeine and glucose together, the rate of loss of phosphorylase a is significantly increased (1.7-fold) over that in the presence of glucose alone. Phosphorylase phosphatase is activated. The sequential activation of glycogen synthase was also accelerated in the presence of both ligands. The results are consistent with an in vivo function for the nucleoside site, similar to that of glucose. A controlling role or phosphorylase in the regulation of glycogen metabolism by glucose is supported. Although the existence and nature of an intracellular effector is as yet unknown, crystallographic analyses of phosphorylase a crystals soaked in perchloric acid extracts of liver demonstrate that the negative effector site binds a natural metabolite.

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Identical structural changes induced in glycogen phosphorylase by two nonexclusive allosteric inhibitors

Withers¹,

Sykes²,

Madsen³

et al. 1979

Biochemistry

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The regulation of glycogen phosphorylase alpha by nucleotide derivatives. Kinetic and x-ray crystallographic studies.

Kasvinsky¹,

Madsen²,

Sygusch³

et al. 1978

Journal of Biological Chemistry

121

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Synergistic regulation of phosphorylase a by glucose and caffeine.

Kasvinsky¹,

Shechosky²,

Fletterick³

1978

Journal of Biological Chemistry

116

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Location of pyridoxal phosphate in glycogen phosphorylase a.

Sygusch¹,

Madsen²,

Kasvinsky³

et al. 1977

Proc. Natl. Acad. Sci. U.S.A.

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The pyridoxal 5'-phosphate cofactor of glycogen phosphorylase a (1,4-a-D-glucan:orthophosphate a-glucosyltransferase, EC 2.4.1.1.) has been positioned on the protomer with x-ray diffraction data, chemical markers, and sequence information. The electron density was computed from 3.0-A resolution phases calculated from four heavy-atom derivatives. The cofactor is buried inside the protomer adjacent to the glucose-binding site.The phosphoryl substrates Pi and glucose-i-P each bind at two sites on the protomer. At low concentrations, Pi and glucose-i-P bind in the same location as does the allosteric effector AMP, near the monomer-monomer interface and some 30 A from the glucose site. At high concentrations glucose-i-P also binds strongly at the glucose site, with its phosphate only 7.2 A from that of the cofactor. Inorganic phosphate can also bind at this site. Implications for the participation of the pyridoxal phosphate in the catalytic mechanism are discussed in the light of these structural findings as well as the wealth of indirect evidence in the literature.

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