ESR probing of macromolecules: spin label study of the conformational integrity and transitions in modified alpha-chymotrypsin

Solvent dielectric effects on protein dynamics

Electron paramagnetic resonance (EPR) spectroscopy and molecular dynamics (MD) simulations were used to investigate the dynamics of alpha-chymotrypsin in solvents ranging in dielectric constant from 72 to 1.9. EPR measurements showed that motions in the vicinity of two spin-labeled amino acids (Met-192 and Ser-195) decreased dramatically with decreasing solvent dielectric constant, a trend consistent with changes in the electrostatic force between charged residues of the protein. EPR results and MD simulations revealed a very similar functional dependence between rates of motion in the protein and the dielectric constant of the bulk solvent; however, predicted motions of protein atoms were markedly faster than measured motions of the spin labels. MD calculations for dielectric constants of 5 and 72 showed the greatest differences near the outer surface of the protein. In general, at the lower dielectric constant many atoms of the protein move more slowly, and many of the slowest residues are near the exterior. These results suggest that altered dynamics may contribute to the unusual properties--e.g., modified stereoselectivities--of enzymes in nearly dry organic solvents.

Deactivation of alpha-chymotrypsin and alpha-chymotrypsin-CNBr-Sepharose 4B conjugates in aliphatic alcohols

Several characterization methods have been used to study the deactivation in aliphatic alcohols of alpha-chymotrypsin and alpha-chymotrypsin-CNBr-Sepharose 4B conjugates. Active-site titration measurements, which were used to determine the amount of catalytically active enzyme, revealed appreciable differences between the deactivation kinetics of free and immobilized chymotrypsin. In all cases for the immobilized enzyme, the kinetics of active-enzyme disappearance differed significantly from first-order. Interestingly, the estimated intrinsic activity of immobilized chymotrypsin remaining active after different exposure times to 50% n-propanol solution increased somewhat as a result of exposure to alcohol. These findings were complemented by direct information, provided by EPR spectroscopy, on the effects of alcohols on the active-site configuration of spin-labeled chymotrypsin. EPR spectra of the free enzyme illustrated the appearance in different alcohol solutions of different enzyme forms with different active-site structures. EPR experiments also showed that denaturation of immobilized chymotrypsin was accompanied by unfolding of the active site that followed similar multi-step kinetics as the loss of active enzyme.

The effects of chemical modification on the refolding transition of alpha-chymotrypsin

The role of several active site residues of alpha-chymotrypsin in the prototypical refolding transition between active and inactive forms of this enzyme is examined using chemical modification. Oxidation of Met-192 to the sulfoxide results in a derivative which remains entirely in an active state from pH 6 to 9. The derivative becomes inactive only at high pH with pKa = 10.3, delta H0 = 9.5 kcal and delta S0 = -15 eu., indicating the sulfoxide group supplies about 2.1 kcal of active state stabilization relative to the unoxidized methionine side chain. The refolding transition of N-methyl-His-57-alpha-chymotrypsin, in which a nitrogen of the "charge relay" histidine is methylated, displays one ionization process with an apparent pKa of 9.45. The absence of an additional ionization process with a pKa near 7 provides evidence that one of the ionizations in the six state mechanism which describes this transition in alpha-chymotrypsin is linked to the charge relay system. We also demonstrate, using alpha-chymotrypsin, Met-192-sulfoxide-alpha-chymotrypsin and N-methyl-His-57-alpha-chymotrypsin, that the 230 nm circular dichroism band is a quantitative probe of the active-inactive equilibrium, although the chromophore or chromophores responsible for this and another very large negative band at 202 nm have not been identified. Circular dichroism was used to observe the active-inactive equilibrium in methan sulfonyl-alpha-chymotrypsin and phenylmethane sulfonyl-alpha-chymotrypsin. The enhanced stability of the active state of these derivatives relative to alpha-chymotrypsin can be rationalized in terms of steric effects in the substrate side chain binding site.

Gamma-irradiated chymotrypsin-like proteins. I. Structural changes

The chymotrypsin-like proteins (chymotrypsin-CT,chymotrypsinogen-CTG, trypsin-T and modified chymotrypsins-at Met 192-MCT and at Tyr 146, 171-TCT), gamma-irradiated in the presence of air, were investigated. Irradiation leads to the unfolding of the native structure of CT-like proteins both in solution and in the dry state, which was shown by the tryptophan fluorescence, viscosimetry and microcalorimetry. The radiation yield of unfolded molecules Gconf was estimated and compared with (1) the rate constants for the reactions of OH-radicals with the proteins as determined by the p-nitrosodimethylaniline, (2) general stability of protein globule using the difference of the energies of the unfolded and globular conformations and (3) the radiation yield of tryptophan destruction in proteins-G-trp. There was a correlation between the values of Gconf and G-trp. The ratio G-trp/Gconf, which defines the number of destroyed tryptophan residues for one unfolded protein molecule, was constant within the limits of error. For CT, MCT, TCT and CTG, this ratio was on the average 3-2, and for T it was 2-2 residues. These facts point to the role of tryptophan destruction in the unfolding of the native structure of CT-like proteins on irradiation.