Chemical Modification of Ribonuclease T1 with Ozone

Abstract

The single tryptophan residue in ribonuclease T₁ [EC 3.1.4.8] was selectively oxidized by ozone to N′-formylkynurenine, which was then converted to kynurenine by acid-catalyzed deformylation in the frozen state. The two enzyme derivatives thus formed, NFK- and Kyn-RNase T₁ lost enzymatic activity at pH 7.5, at which native RNase T₁ most efficiently catalyzes the hydrolysis of RNA. At pH 4.75, the modified enzymes retained a decreased but distinct enzymatic activity toward RNA without alteration of substrate specificity, and Kyn-RNase T₁ was four times more active than NFK-RNase T₁. The binding of 3′-GMP to these modified enzymes decreased remarkably at pH 5.5, the optimum pH for binding to the intact enzyme. The γ-carboxyl group of glutamic acid 58 was still reactive to iodoacetic acid after modification of tryptophan 59. The amounts of the carboxymethyl group introduced into NFK- and Kyn-R Nase T₁ were 0.36 and 0.59 mol, respectively, under conditions such that quantitative esterification of native RNase T₁ takes place. CD spectroscopy indicated that the tertiary structure of the molecule was disordered in NFK-RNase T₁ but not significantly in Kyn-RNase T₁. It is concluded that tryptophan 59 functions in maintaining the active conformation of the protein structure, particularly in constructing the active environment for a functionally important set of groups involved in the binding of the substrate at the active site, although direct participation of in tryptophan the catalytic function of ribonuclease T₁ is unlikely.