Showing papers by "Paul C. Whitford published in 2008"

Extracting function from a β-trefoil folding motif

Abstract: Despite having remarkably similar three-dimensional structures and stabilities, IL-1β promotes signaling, whereas IL-1Ra inhibits it. Their energy landscapes are similar and have coevolved to facilitate competitive binding to the IL-1 receptor. Nevertheless, we find that IL-1Ra folds faster than IL-1β. A structural alignment of the proteins shows differences mainly in two loops, a β-bulge of IL-1β and a loop in IL-1Ra that interacts with residue K145 and connects β-strands 11 and 12. Bioassays indicate that inserting the β-bulge from IL-1β confers partial signaling capability onto a K145D mutant of IL-1Ra. Based on the alignment, mutational assays and our computational folding results, we hypothesize that functional regions are not central to the β-trefoil motif and cause slow folding. The IL-1β β-bulge facilitates activity and replacing it by the IL-1Ra β-turn results in a hybrid protein that folds faster than IL-1β. Inserting the β11–β12 connecting-loop, which aids inhibition, into either IL-1β or the hybrid protein slows folding. Thus, regions that aid function (either through activity or inhibition) can be inferred from folding traps via structural differences. Mapping functional properties onto the numerous folds determined in structural genomics efforts is an area of intense interest. Our studies provide a systematic approach to mapping the functional genomics of a fold family.

Energy landscape along an enzymatic reaction trajectory: hinges or cracks?

Abstract: Are the most dynamically flexible regions around the equilibrium structure of an enzyme the same regions involved in the transition state for rate limiting processes involved in the enzymatic reaction? Kern and‐coworkers “Wolf‐Watz et al., 2004; Henzler‐Wildman et al., 2007a, 2007b… have shown that insights about functionally relevant motions that determine the overall enzyme turnover rate can be obtained by investigating conformational dynamics around the equilibrium basin of the enzyme adenylate kinase. An allosteric change in protein structure turns out to be the controlling process. In this commentary we compare results of this study with earlier predictions of the route by which the enzyme undergoes its conformational change. These predictions are based on the idea that the energy surface for the protein is determined by the end structures of the conformational change. A key issue is whether the protein moves by specific hinges or whether it “cracks” and accesses partially unfolded states during its ...