[Regulation of thermal stability of enzymes by changing the composition of media. Native and modified alpha-chymotrypsin].

Stabilizing effect of denaturing salts on irreversible thermoinactivation of native and modified alpha-chymotrypsin at elevated temperatures is observed. The effect is caused by a shift of conformational equilibrium, at the primary step of reversible unfolding in the course of thermoinactivation, to a more unfolded form which is not able to refold "incorrectly". The stability of alpha-chymotrypsin is regulated within a wide range by medium alteration: the stabilizing effects are similar to those achieved by multipoint attachment of the enzyme to a support or by hydrophilization of protein by covalent modification.

[Unusual (saw-like) temperature dependence of the rate of irreversible thermoinactivation of enzymes].

An unusual ("zig-zag") temperature dependence of the rate of irreversible thermoinactivation of enzymes was observed for native and covalently modified alpha-chymotrypsin and trypsin. This dependence was characterized by alternation of plots with positive and negative apparent values of activation energy for the thermoinactivation process. A kinetic scheme which reflects the observed regularities in thermoinactivation for which the temperature-dependent conformational transition is an essential feature, is proposed.

[Correlation of enzyme thermostability and its surface hydrophobicity (using a modified alpha-chymotrypsin as an example)].

Basing on the hypothesis that contact of hydrophobic surface clusters of proteins with water is thermodynamically disadvantageous, it is suggested to carry out the hydrophilization of protein surface by covalent modification in order to increase its thermostability. Hydrophilic fragments were introduced into the surface of alpha-chymotrypsin using acylation by anhydrides of aromatic carboxylic acids and reductive alkylation by aliphatic aldehydes. As a result of the hydrophilization the stability of the enzyme against irreversible thermoinactivation increased thousand-fold.