Residue-specific insights into (2x)72 kDa tryptophan synthase obtained from fast-MAS 1H-detected solid-state NMR

Solid-state NMR has emerged as a potent technique in structural biology, suitable for the study of fibrillar, micro-crystalline, and membrane proteins. Recent developments in fast-magic-angle-spinning and proton-detected methods have enabled detailed insights into structure and dynamics, but molecular-weight limitations for the asymmetric part of target proteins have remained at ~30-40 kDa. Here we employ solid-state NMR for atom-specific characterization of the 72 kDa (asymmetric unit) microcrystalline protein tryptophan synthase, an important target in pharmacology and biotechnology, chemical-shift assignments of which we obtain via higher-dimensionality, 4D and 5D solid-state NMR experiments. The assignments for the first time provide comprehensive data for assessment of side chain chemical properties involved in the catalytic turnover, and, in conjunction with first-principles calculations, precise determination of thermodynamic and kinetic parameters is demonstrated for the essential acid-base catalytic residue βK87. The insights provided by this study expand by nearly a factor of two the size limitations widely accepted for NMR today, demonstrating the applicability of solid-state NMR to systems that have been thought to be out of reach due to their complexity.