ROLE OF CARBOXY-TERMINAL REGION IN PROOFREADING FUNCTION OF METHIONYL-TRANSFER-RNA SYNTHETASE IN ESCHERICHIA-COLI

The synthetic and editing functions of three forms of Escherichia coli methionyl-tRNA synthetase with different C-terminal sequences have been compared in vivo and in vitro. These forms include a full-length wird-type dimer (MRS676), a truncated monomer (MRS547) believed to be equivalent to the biologically active large tryptic fragment, and a third form denoted MRS581*. DNA sequencing revealed that MRS581* is predicted to contain 18 additional amino acids from the wird-type full-length sequence at the carboxy terminus of truncated form MRS547, and this is then fused to an additional 16 amino acids encoded by vector pBR322. Both MRS676 and MRS581* were found to edit endogenous homocysteine about 20-fold more efficiently than MRS547 in vivo. However, the three methionyl-tRNA synthetases edited exogenously supplied homocysteine in bacterial cultures to similar extents. Purified proteins exhibited no significant differences in editing function in vitro. Synthetic activity of purified MRS676 in vitro was found to be about 2.5-fold higher per subunit compared to the shorter forms of the enzyme. The C-terminal region in E. coli methionyl-tRNA synthetase is thus suggested to pray an important role in editing in vivo, most likely by allowing interaction of the enzyme with the methionine biosynthetic pathway. These data support a model of channeling of at least some metabolites in bacterial protein synthesis.