Undermodification in the first position of the anticodon of supG-tRNA reduces translational efficiency.

Two mutants of Escherichia coli, trmC1 and trmC2, which are both defective in the synthesis of 5-methylaminomethyl-2-thiouridine (mnm5s2U) were utilized to study the function of this complex modified nucleoside. Transfer RNAs specific for glutamine, glutamic acid and lysine as well as a specific ochre suppressor derived from lysine tRNA (tRNAUAAlys encoded by the supG allele), contain this modified nucleoside at position 34 (the wobble position). It was found that two different undermodified derivatives of mnm5s2U were present in the two trmC mutants, which suggests that the two mutations affect two different enzymatic activities. Using the lacI-Z fusion system (Miller and Albertini 1983), we found that the efficiency of supG-mediated suppression was reduced to 30%-90% of the wild-type value in the trmC mutants. The modification-deficient supG-tRNA in the mutants showed a higher sensitivity to codon context than the normal tRNAUAAlys.

Genetic mapping and cloning of the gene (trmC) responsible for the synthesis of tRNA (mnm5s2U)methyltransferase in Escherichia coli K12.

The trmC gene, responsible for the formation of 5-methylaminomethyl-2-thiouridine (mnm5s2U) from 2-thiouridine, present in the first position in the anticodon of some tRNAs, has been located at 50.5 min on the Escherichia coli K12 chromosome. Results from transductional mapping suggest that the trmC gene is located counter-clockwise of aroC. A ColE1 hybrid plasmid carrying the aroC+, trmC+ and hisT+ genes was isolated, and the gene order was established, by subcloning, to be hisT-trmC-aroC. The trmC gene is located 1.9 kb from the aroC gene. Two mutations (trmC1 and trmC2) were shown to be recessive, suggesting that the trmC gene is the structural gene for the tRNA-(mnm5s2U)methyltransferase.

Isolation of single-site Escherichia coli mutants deficient in thiamine and 4-thiouridine syntheses: identification of a nuvC mutant.

A method is described to rapidly select and classify many independent near-UV irradiation-resistant Escherichia coli mutants, which include tRNA modification and RNA synthesis control mutants. One class of these mutants was found to be simultaneously deficient in thiamine biosynthesis and in the ability to modify uridine in tRNA to 4-thiouridine, known to be the target for near-UV irradiation. These mutants were found to be unable to make thiazole, a thiamine precursor. The addition of thiazole restores the thiamine deficiency but does not render the cells near-UV irradiation sensitive. In vitro studies on one of these mutants indicated a deficiency in protein factor C (nuvC), required for the 4-thiouridine modification of tRNA. In P1 transduction, the thiazole marker cotransduced with the histidine marker, which places the thiazole marker between 42 and 46 min on the E. coli chromosome map. Both thiamine production and 4-thiouridine production were resumed by 87% of the spontaneous reversions, suggesting a single-point mutation. Our results indicate that we have isolated nuvC mutants and that the nuvC polypeptide is involved in two functions, tRNA modification and thiazole biosynthesis.