Reversible trifluoroacetic acid-induced conformational changes in glycophorin A as detected by proton nuclear magnetic resonance spectroscopy

Effect of temperature and low pH on structure and stability of matrix porin in micellar detergent solutions

Thermal and low pH stabilities of matrix porin (Omp F) solubilized in the micellar solutions of ionic (SDS) and nonionic detergents were investigated by the methods of circular dichroism, intrinsic fluorescence, light scattering and sedimentation velocity. The stability of porin structure in solution is much higher in the presence of beta-octyl glucoside than with SDS. In the presence of SDS, sharp transitions were detected by all parameters measured, above 55 degrees C at neutral pH and below pH 4.5 at 20 degrees C. These transitions involve at least three concomitant processes: unfolding of protein, dissociation of trimers to monomers and the disruption of the protein-detergent micellar complexes, all events being irreversible in the presence of SDS. The nonionic detergent, beta-octyl glucoside, increases the stability of porin in acidic conditions, since neither dissociation nor denaturation was observed in the pH region between 7.5 and 2.0. However, at pH less than 3.5, small, reversible changes in protein structure became evident. The thermal stability of porin is also increased by beta-octyl glucoside as evidenced by a transition temperature 15-20 degrees C higher as compared to SDS. A considerable degree of native porin structure was regained after heat treatment in the presence of beta-octyl glucoside, though the reconstituted trimers were not identical to the native ones. The addition of lipopolysaccharide and divalent cations (Ca2+, Mg2+) to the experimental system did not improve the thermal reversibility.

pH and temperature effects on the molecular conformation of the porcine pancreatic secretory trypsin inhibitor as detected by hydrogen-1 nuclear magnetic resonance

1H NMR spectra of the porcine pancreatic secretory trypsin inhibitor (PSTI) have been recorded vs. pH and temperature. Of the two tyrosines, one titrates with a pK of 11.25, while the resonances from the other are pH insensitive in the investigated range 4.8 less than or equal to pH less than or equal to 12. This is consistent with PSTI having one Tyr solvent exposed (Tyr-20) and the other buried (Tyr-31). The resonances from the lysyl epsilon-CH2 protons titrate with a pK of 10.95. The titration is accompanied by a pronounced line broadening, which starts near pH 8.5. Between pH 11.5 and pH 12 the epsilon-CH2 resonances recover their low pH line width. Titration curves for the lysines and Tyr-20 reflect single proton ionization equilibria, suggesting that these residues do not interact among themselves. On the basis of double resonance experiments, combined with analysis of chemical shifts, spin-spin couplings, and line widths, all methyl resonances are identified and followed as functions of pH and temperature. The gamma-CH3 doublet from the N-terminal Thr-1 is assigned by comparison between spectra of forms I and II of the inhibitor, the latter lacking the first four residues of form I. The beta-CH3 resonance from Ala-7 is also assigned. Proton resonance parameters of methyl groups are shown to afford useful NMR probes for the characterization of local nonbonded interactions, microenvironments, and mobilities.