Solution NMR investigation of the response of the lactose repressor core domain dimer to hydrostatic pressure

Abstract

Previous investigations of the sensitivity of the lac repressor to high-hydrostatic pressure have led to varying conclusions. Here high-pressure solution NMR spectroscopy is used to provide an atomic level view of the pressure induced structural transition of the lactose repressor regulatory domain (LacI* RD) bound to the ligand IPTG. As the pressure is raised from ambient to 3kbar the native state of the protein is converted to a partially unfolded form. Estimates of rotational correlation times using transverse optimized relaxation indicates that a monomeric state is never reached and that the predominate form of the LacI* RD is dimeric throughout this pressure change. Spectral analysis suggests that the pressure-induced transition is localized and is associated with a volume change of approximately −115mlmol−1 and an average pressure dependent change in compressibility of approximately 30mlmol−1kbar−1. In addition, a subset of resonances emerge at high-pressures indicating the presence of a non-native but folded alternate state.