Experimental Evidence for Millisecond–Timescale Structural Evolution Following the Microsecond–Timescale Folding of a Small Protein
C. Blake Wilson, Wai‐Ming Yau, Robert Tycko
Abstract
Prior work has shown that small proteins can fold (i.e., convert from unstructured to structured states) within 10 μs. Here we use time-resolved solid state nuclear magnetic resonance (ssNMR) methods to show that full folding of the 35-residue villin headpiece subdomain (HP35) requires a slow annealing process that has not been previously detected. ^{13}C ssNMR spectra of frozen HP35 solutions, acquired with a variable time τ_{e} at 30 °C after rapid cooling from 95 °C and before rapid freezing, show changes on the 3-10 ms timescale, attributable to slow rearrangements of protein sidechains during τ_{e}.
Topics & Concepts
MicrosecondMillisecondFolding (DSP implementation)Protein foldingPhysicsNuclear magnetic resonanceOpticsAstronomyElectrical engineeringEngineeringProtein Structure and DynamicsEnzyme Structure and FunctionMicrotubule and mitosis dynamics