Analysis of isoaccepting transfer ribonucleic acid species of Bacillus subtilis: changes in chromatography of transfer ribonucleic acids associated with stage of development

Translation activity of chimeric ribosomes composed of Escherichia coli and Bacillus subtilis or Geobacillus stearothermophilus subunits

Ribosome composition, consisting of rRNA and ribosomal proteins, is highly conserved among a broad range of organisms. However, biochemical studies focusing on ribosomal subunit exchangeability between organisms remain limited. In this study, we show that chimeric ribosomes, composed of Escherichia coli and Bacillus subtilis or E. coli and Geobacillus stearothermophilus subunits, are active for β-galactosidase translation in a highly purified E. coli translation system. Activities of the chimeric ribosomes showed only a modest decrease when using E. coli 30 S subunits, indicating functional conservation of the 50 S subunit between these bacterial species.

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A highly sensitive translation assay was established.

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B. subtilis 50S subunit is active for translation in an E. coli system.

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G. stearothermophilus 50S subunit is active for translation in an E. coli system.

Functional characterization of the YmcB and YqeV tRNA methylthiotransferases of Bacillus subtilis

Methylthiotransferases (MTTases) are a closely related family of proteins that perform both radical-S-adenosylmethionine (SAM) mediated sulfur insertion and SAM-dependent methylation to modify nucleic acid or protein targets with a methyl thioether group (-SCH(3)). Members of two of the four known subgroups of MTTases have been characterized, typified by MiaB, which modifies N(6)-isopentenyladenosine (i(6)A) to 2-methylthio-N(6)-isopentenyladenosine (ms(2)i(6)A) in tRNA, and RimO, which modifies a specific aspartate residue in ribosomal protein S12. In this work, we have characterized the two MTTases encoded by Bacillus subtilis 168 and find that, consistent with bioinformatic predictions, ymcB is required for ms(2)i(6)A formation (MiaB activity), and yqeV is required for modification of N(6)-threonylcarbamoyladenosine (t(6)A) to 2-methylthio-N(6)-threonylcarbamoyladenosine (ms(2)t(6)A) in tRNA. The enzyme responsible for the latter activity belongs to a third MTTase subgroup, no member of which has previously been characterized. We performed domain-swapping experiments between YmcB and YqeV to narrow down the protein domain(s) responsible for distinguishing i(6)A from t(6)A and found that the C-terminal TRAM domain, putatively involved with RNA binding, is likely not involved with this discrimination. Finally, we performed a computational analysis to identify candidate residues outside the TRAM domain that may be involved with substrate recognition. These residues represent interesting targets for further analysis.

Transfer ribonucleic acid synthesis during sporulation and spore outgrowth in Bacillus subtilis studied by two-dimensional polyacrylamide gel electrophoresis

The synthesis of transfer ribonucleic acid (tRNA) was examined during spore formation and spore outgrowth in Bacillus subtilis by two-dimensional polyacrylamide gel electrophoresis of in vivo 32P-labeled RNA. The two-dimensional gel system separated the B. subtilis tRNA's into 32 well-resolved spots, with the relative abundances ranging from 0.9 to 17% of the total. There were several spots (five to six) resolved which were not quantitated due to their low abundance. All of the tRNA species resolved by this gel system were synthesized at every stage examined, including vegetative growth, different stages of sporulation, and different stages of outgrowth. Quantitation of the separated tRNA's showed that in general the tRNA species were present in approximately the same relative abundances at the different developmental periods. tRNA turnover and compartmentation occurring during sporulation were examined by labeling during vegetative growth followed by the addition of excess phosphate to block further 32P incorporation. The two-dimensional gels of these samples showed the same tRNA's seen during vegetative growth, and they were in approximately the same relative abundances, indicating minimal differences in the rates of turnover of individual tRNA's. Vegetatively labeled samples, chased with excess phosphate into mature spores, also showed all of the tRNA species seen during vegetative growth, but an additional five to six minor spots were also observed. These are hypothesized to arise from the loss of 3'-terminal residues from preexisting tRNA's.

Post-transcriptional modifications of the anticodon loop region: alterations in isoaccepting species of tRNA's during development in Bacillus subtilis

Structural similarities of tRNA's were compared using three sets of isoaccepting species that had previously been shown to undergo significant changes in chromatographic elution properties as a function of developmental stage in Bacillus subtilis. Comparisons of the structures of the tRNA's were based on the composition of their modified nucleosides, comparisons of oligonucleotide elution profiles from RPC-5 columns, and two-dimensional electrophoretic fingerprint analysis of oligonucleotides. The tRNA's studied were tRNA(Lys) (1) and tRNA(Lys) (3); tRNA(Tyr) (1) and tRNA(Tyr) (2); and tRNA(Trp) (1) and tRNA(Trp) (2). The results suggest that the difference among these pairs of isoaccepting species is a difference in the degree of post-transcriptional modifications of the anticodon loop region. The nucleosides involved were N(6)-(Delta(2)-isopentenyl)adenosine (i(6)A), 2-methylthio-N(6)-(Delta(2)-isopentenyl)adenosine (ms(2)i(6)A), and an unknown nucleoside K, which occurred in a position analogous to N-[9-(beta-d-ribofuranosyl)purin-6-ylcarbamoyl]threonine. The amounts of i(6)A and ms(2)i(6)A, determined using total tRNA from exponential-or stationary-phase cells, suggest that the thiomethylation of i(6)A is a pleiotropic phenomenon affecting several tRNA species. As opposed to the situation in Escherichia coli tRNA, where ms(2)i(6)A constitutes about 90% of the total hydrophobic nucleosides at all growth stages, B. subtilis tRNA's have i(6)A as the predominant hydrophobic nucleoside in exponential growth and ms(2)i(6)A as the predominant nucleoside in stationary phase. Thus, the enzyme system which forms i(6)A and the enzyme system which thiomethylates i(6)A are not coordinated during growth in B. subtilis as they are in E. coli. It is suggested that these changes in anticodon loop modifications in B. subtilis may be related to changes in the translational apparatus which occur during sporulation.

Nucleotide sequence of a lysine tRNA from Bacillus subtilis

A lysine tRNA (tRNA1Lys) was purified from Bacillus subtilis W168 by a consecutive use of several column chromatographic systems. The nucleotide sequence was determined to be pG-A-G-C-C-A-U-U-A-G-C-U-C-A-G-U-D-G-G-D-A-G-A-G-C-A-U-C-U-G-A-C-U-U(U*)-U-U-K-A-psi-C-A-G-A-G-G-m7G(G)-U-C-G-A-A-G-G-T-psi-C-G-A-G-U-C-C-U-U-C-A-U-G-G-C-U-C-A-C-C-AOH, where K and U* are unidentified nucleosides. The nucleosides of U34 and m7G46 were partially substituted with U* and G, respectively. The binding ability of lysyl-tRNA1Lys to Escherichia coli ribosomes was stimulated with ApApA as well as ApApG.

Study of tyrosine transfer ribonucleic acid modification in relation to sporulation in Bacillus subtilis

A reversal in the relative amounts of the two major species of tyrosine transfer ribonucleic acid (tRNATyr) (I and II) has been previously observed by others during the development of Bacillus subtilis. These species have been purified by benzoylated diethylaminoethyl-cellulose chromatography and were shown to differ by the modification of an adenosine residue (species I contains i6A and species II ms2i6A). As suggested by competitive hybridization assays, they might possess the same nucleotide sequence. A tRNATyr species lacking isopentenyl and methylthio moieties was not detected. The structural difference between species I and II was shown to be important for ribosome binding but not for charging. The extent of alteration during growth was studied in parallel with physiological events. Like sporulation, tRNATyr change is iron dependent. Moreover, when sporulation is prevented by an excess of glucose, the tRNATyr change is delayed as is the synthesis of enzymatic systems required for the onset of sporulation. tRNATyr change also demands unceasing protein synthesis.

Changes in transfer ribonucleic acids of Bacillus subtilis during different growth phases

The transfer ribonucleic acids (tRNAs) of B. subtilis at different growth phases are examined for changes in the composition and the methylation of minor constituents. The composition of the tRNAs indicates about equal amounts of adenosine and uridine, and of guanosine and cytidine. About 3-4 residues are present as modified bases in the average tRNA molecule. The net composition of tRNAs appears to remain unaltered during different growth phases. In vitro methylation of tRNAs indicates lack of methyl groups in both exponentially growing cells and spores. In vivo methylation studies show tRNA methylation occurs during the stationary phase in the absence of net tRNA synthesis. Thus, both in vitro and in vivo methylation indicate that the tRNAs in exponentially growing cells do not contain their full complement of modified bases. More complete modification is noted in tRNAs from stationary cells or spores. Hence, tRNA mofifications in general are preserved with fidelity even in the dormant spore but the possibility is left open that specific modifications of selected isoacceptors of tRNAs may occur.

Antibiotic-resistant mutants of Bacillus subtilis conditional for sporulation

Among spontaneously occurring antibiotic-resistant mutants of Bacillus subtilis 168 we have identified a sub-class that is conditionally sporulative. Mutants in this sub-class are resistant to antibiotic during vegetative growth but are sensitive during sporulation. Mutants conditionally-resistant to erythromycin, kanamycin, spectinomycin, and streptomycin have been isolated and characterized by phase contrast microscopy and with respect to their ability to synthesize heat-resistant endospores or the sporulation-associated enzyme alkaline phosphatase. The results suggest that several entirely different genetic lesions may result in this single phenotype. This group includes mutants whose properties suggest that both th 30S and 50S ribosomal subunits may be altered concomitant with early spore specific metabolism. The blockage imposed by antibiotic may be at or near Stage 2 of sporulation.

Properties and developmental roles of the lysyl- and tryptophanyl-transfer ribonucleic acid synthetases of Bacillus subtilis: common genetic origin of the corresponding spore and vegetative enzymes

The lysyl-transfer ribonucleic acid synthetase (LRS) and tryptophanyl-transfer ribonucleic acid synthetases (TRS) (l-lysine:tRNA ligase [AMP], EC 6.1.1.6; and l-tryptophan:tRNA ligase [AMP], EC 6.1.1.2) have been purified 60- and 100-fold, respectively, from vegetative cells and spores of Bacillus subtilis. There are no significant differences between the corresponding spore and vegetative enzymes with respect to their elution characteristics from columns of phosphocellulose or hydroxylapatite, their molecular weight (~130,000 for LRS and ~87,000 for TRS as determined by gel filtration), their kinetic constants for substrates (in the amino acid-dependent adenosine triphosphate-pyrophosphate exchange reaction), and the kinetics of inactivation by heat and by antibody. The Mg(2+) requirement for optimal enzyme activity of the corresponding spore and vegetative enzyme differ slightly. Mutants having defective (temperature sensitive) vegetative LRS or TRS activities produce spores in which these enzymes are also defective. The mutant spores are more heat sensitive than the parental type, but contain normal levels of dipicolinic acid. They germinate normally at the restrictive temperature (43 C), but are blocked at specific developmental stages in outgrowth. No modification in temperature sensitivity phenotype occurs during outgrowth, nor is there a change in molecular weight of the two enzymes. The implication is that the LRS and TRS activities of the vegetative and spore stages are each coded (at least in part) by the same structural gene. The temperature sensitivity of mutant spores is discussed with respect to those factors which are involved in the formation of the heat-resistant state.