Comparison of solution structures of mutant bovine pancreatic trypsin inhibitor proteins using two‐dimensional nuclear magnetic resonance

Abstract

Structural perturbations due to a series of mutations at the 30–51 disulfide bond of bovine pancreatic trypsin inhibitor have been explored using NMR. The mutants replaced cysteines at positions 30 and 51 by alanine at position 51 and alanine, threonine, or valine at position 30. Chemical shift changes occur in residues proximate to the site of mutation. NOE assignments were made using an automated procedure, NASIGN, which used information from the wild‐type crystal structure. Intensity information was utilized by a distance geometry algorithm, VEMBED, to generate a series of structures for each protein. Statistical analyses of these structures indicated larger averaged structural perturbations than would be expected from crystallographic and other information. Constrained molecular dynamics refinement using AMBER at 900 K was useful in eliminating structural movements that were not a necessary consequence of the NMR data. In most cases, statistically significant movements are shown to be those greater than approximately 1 Å. Such movements do not appear to occur between wild type and A30A51, a result confirmed by crystallography (Eigenbrot, C., Randal, M., & Kossiakoff, A.A., 1990, Protein Eng. 3, 591–598). Structural alterations in the T30A51 or V30A51 mutant proteins near the limits of detection occur in the β‐loop (residues 25–28) or C‐terminal α‐helix, respectively. Copyright © 1992 The Protein Society