Virginia L. Rath

Structure-Activity Analysis of the Purine Binding Site of Human Liver Glycogen Phosphorylase

Human liver glycogen phosphorylase (HLGP) catalyzes the breakdown of glycogen to maintain serum glucose levels and is a therapeutic target for diabetes. HLGP is regulated by multiple interacting allosteric sites, each of which is a potential drug binding site. We used surface plasmon resonance (SPR) to screen for compounds that bind to the purine allosteric inhibitor site. We determined the affinities of a series of compounds and solved the crystal structures of three representative ligands with K(D) values from 17-550 microM. The crystal structures reveal that the affinities are partly determined by ligand-specific water-mediated hydrogen bonds and side chain movements. These effects could not be predicted; both crystallographic and SPR studies were required to understand the important features of binding and together provide a basis for the design of new allosteric inhibitors targeting this site.

Purification and crystallization of glycogen phosphorylase from Saccharomyces cerevisiae

Glycogen phosphorylase from Saccharomyces cerevisiae is activated by the covalent phosphorylation of a single threonine residue in the N terminus of the protein. We have hypothesized that the structural features that effect activation must be distinct from those characterized in rabbit muscle phosphorylase because the two enzymes have unrelated phosphorylation sites located in dissimilar protein contexts. To understand this potentially novel mechanism of activation by phosphorylation, we require information at atomic resolution of the phosphorylated and unphosphorylated forms of the enzyme. To this end, we have purified, characterized and crystallized glycogen phosphorylase from S. cerevisiae. The enzyme was isolated from a phosphorylase-deficient strain harboring a multicopy plasmid containing the phosphorylase gene under the control of its own promoter. One liter of cultured cells yields 12 mg of crystallizable material. The purified protein was not phosphorylated and had an activity of 4.7 units/mg in the presence of saturating amounts of substrate. Yeast phosphorylase was crystallized in four different crystal forms, only one of which is suitable for diffraction studies at high resolution. The latter belongs to space group P4(1)2(1)2 with unit cell constants of a = 161.1 A and c = 175.5 A Based on the density of the crystals, the solvent content is 49.7%, indicating that the asymmetric unit contains the functional dimer of yeast phosphorylase.

The evolution of an allosteric site in phosphorylase

BACKGROUND Glycogen phosphorylases consist of a conserved catalytic core onto which different regulatory sites are added. By comparing the structures of isozymes, we hope to understand the structural principles of allosteric regulation in this family of enzymes. Here, we focus on the differences in the glucose 6-phosphate (Glc-6-P) binding sites of two isozymes. RESULTS We have refined the structure of Glc-6-P inhibited yeast phosphorylase b to 2.6 A and compared it with known structures of muscle phosphorylase. Glc-6-P binds in a novel way, interacting with a distinct set of secondary elements. Structural links connecting the Glc-6-P binding sites and catalytic sites are conserved, although the specific contacts are not. CONCLUSIONS Our comparison reveals that the Glc-6-P binding site was modified over the course of evolution from yeast to vertebrates to become a bi-functional switch. The additional ability of muscle phosphorylase to be activated by AMP required the recruitment of structural elements into the binding site and sequence changes to create a binding subsite for adenine, whilst maintaining links to the catalytic site.