Interaction of tRNA with tRNA (guanosine-1)methyltransferase: binding specificity determinants involve the dinucleotide G36pG37 and tertiary structure.

The sequence G37pG36 is present in all tRNA species recognized and methylated by the Escherichia coli modification enzyme tRNA (guanosine-1)methyltransferase. We have examined whether this dinucleotide sequence provides the base specific recognition signal for this enzyme and have assessed the role of the remaining tRNA in recognition. E. coli tRNAHis and yeast tRNAAsp were substituted with G at positions 36 and 37 and were found to be excellent substrates for methylation. This suggested that the general tRNA structure can be specifically bound by the enzyme. In addition, heterologous tRNA species including fully modified tRNA1Leu are excellent inhibitors of tRNA1Leu transcript methylation. Analyses of structural variants of yeast tRNAAsp and E. coli tRNA1Leu demonstrate clearly that the core tertiary structures of tRNA are required for recognition and that G37 must be in the correct position in space relative to important contacts elsewhere in the molecule. This latter conclusion was reached because the addition of one to three stacked base pairs in the anticodon stem of tRNA1Leu dramatically alters activity. In this case, the G37 base is rotated away from the correct position in space relative to other tRNA contact sites. The acceptor stem structure is required for optimal activity since deletion of three or five base pairs is detrimental to activity; however, specific base sequence may not be important because (i) the addition of three stacked base pairs of different sequence had little effect on activity and (ii) heterologous tRNAs with little or no sequence homology in the acceptor stem are excellent substrates. Both poly G and GpG are potent and specific inhibitors of enzyme activity and are minimal substrates which can be methylated, forming m1G. Taken together, these studies suggest that 1MGT can bind the general tRNA structure and that the crucial base-pair contacts are G37 and G36.

tRNA-m1G methyltransferase interactions: touching bases with structure.

m1G methyltransferase of Escherichia coli is being examined with regard to how specific tRNA substrates are recognized. This enzyme appears to require the entire tRNA structure of optimal activity. Recognition may require specific base contacts as well as phosphate backbone structures embodied in the tRNA structure.

Structural requirements for tRNA methylation. Action of Escherichia coli tRNA(guanosine-1)methyltransferase on tRNA(1Leu) structural variants.

The Escherichia coli enzyme tRNA(m1G)methyltransferase, one of a group of post-transcription tRNA-modifying enzymes, shows remarkable specificity in selecting the tRNA species and the specific guanosine base to be methylated. To examine the structural basis of this specificity, we synthesized a total of 15 modifications of tRNA(1Leu) and measured their methylation reaction kinetics in vitro. Elimination of any one of the three tRNA side loops, the V loop, the T loop, or the D loop, reduced the Vmax for methylation by about 1 order of magnitude. Elimination of all three side loops reduced Vmax by about 2 orders of magnitude. Clearly, gross tRNA structure is important for full enzyme activity. At the bottom of the stem proximal to the anticodon loop, in the pair at positions 31-39, substitution of a G-C for a C-G, a change that should not weaken the helical structure, had little effect on Vmax or Km. However, substitution of a G for a C increased Vmax and Km, whereas substitution of a C for G sharply reduced Vmax and, to a lesser extent, Km. These results appear to be a consequence of the principle that purines are better than pyrimidines in the stacking of adjacent bases for stability. Stacking in the stem structure appears to be important for methylation enzyme activity. In the anticodon loop itself, changing a U to a C had little effect, but changing the G of the anticodon to a C reduced Vmax over 20-fold, demonstrating the importance of the presence of the anticodon G adjacent to the G being methylated for enzyme recognition.

Use of the promoter fusion transposon Tn5 lac to identify mutations in Bordetella pertussis vir-regulated genes.

Mutants of Bordetella pertussis deficient in virulence-associated factors were identified by using the transposon Tn5 lac. Tn5 lac is a derivative of Tn5 which generates promoter fusions for beta-galactosidase. Tn5 lac insertions in the vir-regulated genes of B. pertussis were identified by selecting for kanamycin-resistant mutants that expressed beta-galactosidase when the vir-regulated genes were expressed but not when the vir-regulated genes were turned off. Fourteen different mutations in vir-regulated genes were identified. Two mutants were deficient in the production of the filamentous hemagglutinin, two mutants were deficient in the production of adenylate cyclase toxin and hemolysin, and one mutant was deficient in the production of dermonecrotic toxin. One insertion mapped adjacent to the pertussis toxin gene, but the mutant produced pertussis toxin. The phenotypes of the remaining eight mutants were not determined, but the mutants did not appear to be deficient in the production of the 69,000-dalton outer membrane protein (agglutinogen 3) or the capsule. Screening for mutations in either of the fimbrial genes proved to be problematic since the parental strain was found to switch from a fimbriated to a nonfimbriated state at a high frequency, which was suggestive of the metastable expression of pili in other bacteria. We used Southern blot analysis with a 30-mer specific for the fimbrial sequences. No bands with the predicted increase in size due to the 12 kilobases from Tn5 lac were observed, which suggests that none of these genes were mutated. Southern blot analysis also revealed that seven of the eight unidentified mutations mapped to different restriction fragments, which suggests that they could be deficient in as many as seven different genes.