Physicochemical Changes in Phosphorylase Kinase Induced by Its Cationic Activator Mg(2+)

Overview

Journal Protein Sci

Specialty Biochemistry

Date 2013 Jan 30

PMID 23359552

Citations 1

Authors

Weiya Liu

Owen W Nadeau

Jessica Sage

Gerald M Carlson

Affiliations

Soon will be listed here.

Abstract

For over four decades free Mg(2+) ions, that is, those in excess of MgATP, have been reported to affect a wide variety of properties of phosphorylase kinase (PhK), including its affinity for other molecules, proteolysis, chemical crosslinking, phosphorylation, binding to certain monoclonal antibodies, and activity, which is stimulated. Additionally, for over three decades Mg(2+) has been known to act synergistically with Ca(2+) , another divalent activator of PhK, to affect even more properties of the enzyme. During all of this time, however, no study has been performed to determine the overall effects of free Mg(2+) ions on the physical properties of PhK, even though the effects of Ca(2+) ions on PhK's properties are well documented. In this study, changes in the physicochemical properties of PhK induced by Mg(2+) under nonactivating (pH 6.8) and activating (pH 8.2) conditions were investigated by circular dichroism spectroscopy, zeta potential analyses, dynamic light scattering, second derivative UV absorption, negative stain electron microscopy, and differential chemical crosslinking. The effects of the activator Mg(2+) on some of the properties of PhK measured by these techniques were found to be quite different at the two pH values, and displayed both differences and similarities with the effects previously reported to be induced by the activator Ca(2+) (Liu et al., Protein Sci 2008;17:2111-2119). The similarities may reflect the fact that both cations are activators, and foremost among their similarities is the dramatically less negative zeta potential induced by their binding to PhK.

Citing Articles

The regulatory α and β subunits of phosphorylase kinase directly interact with its substrate, glycogen phosphorylase.

Thompson J, Carlson G Biochem Biophys Res Commun. 2016; 482(2):221-225.

PMID: 27845042 PMC: 5195864. DOI: 10.1016/j.bbrc.2016.11.044.

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