Abstract
A truncated form of the methionyl-tRNA synthetase (delta MTS), which has been cloned, overproduced, and characterized, was used in an attempt to better understand the role of the enzyme-bound zinc in the amino-acylation process. Apo-, Zn(2+)-, Co(2+)-, and 113Cd(2+)-substituted delta MTS proteins were prepared in vivo and purified to homogeneity. Apo-delta MTS was devoid of enzymatic activity in the aminoacylation of tRNA(fMet) and in the methionine-dependent ATP-pyrophosphate exchange reactions. Kinetic constants in both the aminoacylation and ATP-pyrophosphate exchange reactions for the Co(2+)- and 113Cd(2+)-substituted delta MTS proteins were found to be identical with those of the native Zn2+ protein. The low energy absorption spectrum of Co(2+)-substituted delta MTS resembles the d-d transition bands characteristic of tetrahedrally coordinated Co(2+)-substituted proteins. A strong S-->Co2+ charge transfer absorption at 350 nm was clearly evident having a molar absorptivity consistent with four thiolate ligands. The environment of the metal center was further probed by measuring the 113Cd chemical shift of 113Cd(2+)-substituted delta MTS. A single resonance at 759.6 ppm was observed. This chemical shift is consistent with Cd2+ coordinated to four thiolate ligands. The Escherichia coli methionyl-tRNA synthetase contains a potential metal binding sequence Cys-X2-Cys-X9-Cys-X2-Cys in a connecting polypeptide within the nucleotide fold. Titration of a 21-amino acid peptide corresponding to this putative metal binding site, Cys145-Cys161, was shown to bind Co2+ with a Kd of 120 +/- 11 microM. These results demonstrate that the isolated zinc finger binding domain is capable of specifically forming a stoichiometric complex with the divalent cation. Taken together, our studies identify the 4 cysteine residues in the zinc finger-like domain as the metal binding ligands in the E. coli methionyl-tRNA synthetase. The role of the enzyme-bound metal appears to be structural and not directly involved in catalysis.
Highlights
From the Department of Biochemistry and Molecular Biology, University of Texas Medical School at Houston, Houston
A truncated formof the methionyl-tRNA synthetase aminoacyladenylate and transfer of the activated aminoacid (AMTS), which has been cloned, overproduced, and totheir cognate tRNAs (1).This reaction occurs in two characterized, wasused in an attempt to better under- separate steps, and the specificity exhibited toward the substand therole of the enzyme-bound zinc in theamino- strates ineach step is essential in maintainingthe fidelity of acylation process
Sequence comparisons have stituted AMTS proteins were prepared in vivo and permitted this family of enzymes to be divided into two purifiedto homogeneity
Summary
Materiak+"-[methyl-14C]Methionine and [32P]pyrophosphate were purchased from Du Pont-New England Nuclear. Cobalt and cadmium substituted AMTS pro- three broad bands assigned to thed-d transition at 650, 700, teins were prepared in vivo using zinc-depleted media supple- and 730 nm with molar absorptivities of 234, 593, and 625 mented with either 30 PM CoC12or 15 PM CdCl, 20 min prior M" cm", respectively This spectrum is consistent with teto induction. 1200 M" cm", observed for Co2+-S-Cys bonds in rubredoxin, Since apoenyme free from trace amountsof zinc-substituted alcohol dehydrogenase, other Co2+-substituted proteins, and protein could not be prepared in vivo, rate constants for the model systems (28, 30, 31) Characteristics of both the aminoacylation, ATP-PP exchange, and a-proton exchange S-+ Co2+charge transfer band and thosoef the d-d transition activities were determined for apoenzyme preparations con- bands strongly suggest that the enzyme-bound Co2+is tetrataining varying amounts of the zinc-substitutedprotein (Table 11). '13Cd NMR Spectrum-Cadmium chemical shiftscan be used to determine the number of sulfur ligands coordinating the enzyme-bound metal, since sulfur induces large downfield
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