Volume 9, Issue 8, Pages (August 2002)

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Volume 9, Issue 8, Pages 915-924 (August 2002) Structure-Activity Analysis of the Purine Binding Site of Human Liver Glycogen Phosphorylase Jennifer L Ekstrom, Thomas A Pauly, Maynard D Carty, Walter C Soeller, Jeff Culp, Dennis E Danley, Dennis J Hoover, Judith L Treadway, E.Michael Gibbs, Robert J Fletterick, Yasmina S.N Day, David G Myszka, Virginia L Rath Chemistry & Biology Volume 9, Issue 8, Pages 915-924 (August 2002) DOI: 10.1016/S1074-5521(02)00186-2

Figure 1 SPR Analysis of the Caffeine/HLGPa Interactions (A) Binding responses were measured for caffeine (500 μM–2 μM by 2-fold dilutions) injected over a surface to which 21,000 RU HLGPa had been coupled. (B) Equilibrium analysis of the caffeine/HLGPa interaction. Equilibrium binding responses for caffeine in the absence (filled squares) and presence (filled circles) of 50 mM glucose were independently fit to a 1:1 interaction model (solid lines) to determine equilibrium dissociation constants. Chemistry & Biology 2002 9, 915-924DOI: (10.1016/S1074-5521(02)00186-2)

Figure 2 Purine Site Screen For each of the 18 compounds tested, the RU values at equilibrium versus ligand concentration were fitted to a 1:1 interaction model. The resulting fitted curves are superimposed and listed in order on the right starting from the curve closest to the upper left (riboflavin) to the curve closest to the lower right (allantoin), with the labels color coded to match their respective binding isotherms. For clarity, only the curves for riboflavin, caffeine, and uric acid are labeled directly. Chemistry & Biology 2002 9, 915-924DOI: (10.1016/S1074-5521(02)00186-2)

Figure 3 Crystal Structure of HLGPa/Purine Site Ligands (A), Uric acid bound at the purine site; (B), caffeine bound at the purine site; (C), riboflavin bound at the purine site. The 2Fo-Fc difference electron density for each ligand is contoured at 1σ above the mean. The figures were prepared using Ribbons [31], and each panel is colored as follows: structural elements of the N-terminal domain, red; those of the C-terminal domain, blue; oxygen atoms, red; nitrogen atoms, blue; carbon atoms, green; and water molecules are shown as red spheres. Chemistry & Biology 2002 9, 915-924DOI: (10.1016/S1074-5521(02)00186-2)