Litcius/Paper detail

Millisecond Time-Resolved Solid-State NMR Initiated by Rapid Inverse Temperature Jumps

C. Blake Wilson, Robert Tycko

2022Journal of the American Chemical Society25 citationsDOIOpen Access PDF

Abstract

Elucidation of the detailed mechanisms by which biological macromolecules undergo major structural conversions, such as folding, complex formation, and self-assembly, is a central concern of biophysical chemistry that will benefit from new experimental methods. We describe a simple technique for initiating a structural conversion process by a rapid decrease in the temperature of a solution, i.e., a rapid inverse temperature jump. By pumping solutions through copper capillary tubes that are thermally anchored to heated and cooled blocks, solution temperatures can be switched from 95 to 30 °C (or lower) in about 0.8 ms. For time-resolved solid-state nuclear magnetic resonance (ssNMR), solutions can then be frozen rapidly by spraying into cold isopentane after a variable structural evolution time τe. As an initial demonstration, we use this “inverse T-jump” technique to characterize the kinetics and mechanism by which the 26-residue peptide melittin converts from its primarily disordered, monomeric state at 95 °C to its α-helical, tetrameric state at 30 °C. One- and two-dimensional ssNMR spectra of frozen solutions with various values of τe, recorded at 25 K with signal enhancements from dynamic nuclear polarization, show that both helical secondary structure and intermolecular contacts develop on the same time scale of about 6 ms. The dependences on τe of both intraresidue crosspeak patterns and inter-residue crosspeak volumes in two-dimensional spectra can be fit with a unidirectional dimerization model, consistent with dimerization being the rate-limiting step for melittin tetramer formation.

Topics & Concepts

ChemistryMelittinTemperature jumpTetramerKineticsSolid-state nuclear magnetic resonanceChemical physicsMillisecondCrystallographyNuclear magnetic resonancePhysical chemistryPeptideOrganic chemistryQuantum mechanicsBiochemistryEnzymePhysicsAstronomySolid-state spectroscopy and crystallographyAdvanced NMR Techniques and ApplicationsMolecular spectroscopy and chirality