Two large clusters with thirty-seven transfer RNA genes adjacent to ribosomal RNA gene sets in Bacillus subtilis. Sequence and organization of trrnD and trrnE gene clusters

Analysis of tRNA Cys processing under salt stress in Bacillus subtilis spore outgrowth using RNA sequencing data

Background: In spore-forming bacteria, the molecular mechanisms of accumulation of transfer RNA (tRNA) during sporulation must be a priority as tRNAs play an essential role in protein synthesis during spore germination and outgrowth. However, tRNA processing has not been extensively studied in these conditions, and knowledge of these mechanisms is important to understand long-term stress survival.    Methods:To gain further insight into tRNA processing during spore germination and outgrowth, the expression of the single copy tRNA ^Cys gene was analyzed in the presence and absence of 1.2 M NaCl in Bacillus subtilis using RNA-Seq data obtained from the Gene Expression Omnibus (GEO) database. The CLC Genomics work bench 12.0.2 (CLC Bio, Aarhus, Denmark, https://www.qiagenbioinformatics.com/) was used to analyze reads from the tRNA ^Cys gene.  Results:The results show that spores store different populations of tRNA ^Cys-related molecules.  One such population, representing 60% of total tRNA ^Cys, was composed of tRNA ^Cys fragments.  Half of these fragments (3´-tRF) possessed CC, CCA or incorrect additions at the 3´end. tRNA ^Cys with correct CCA addition at the 3´end represented 23% of total tRNA ^Cys, while with CC addition represented 9% of the total and with incorrect addition represented 7%. While an accumulation of tRNA ^Cys precursors was induced by upregulation of the rrnD operon under the control of  σ ^A -dependent promoters under both conditions investigated, salt stress produced only a modest effect on tRNA ^Cys expression and the accumulation of tRNA ^Cys related species. Conclusions:The results demonstrate that tRNA ^Cys molecules resident in spores undergo dynamic processing to produce functional molecules that may play an essential role during protein synthesis.

Ancient adaptation of the active site of tryptophanyl-tRNA synthetase for tryptophan binding

The amino acid binding domains of the tryptophanyl (TrpRS)- and tyrosyl-tRNA synthetases (TyrRS) of Bacillus stearothermophilus are highly homologous. These similarities suggest that conserved residues in TrpRS may be responsible for both determining tryptophan recognition and discrimination against tyrosine. This was investigated by the systematic mutation of TrpRS residues based upon the identity of homologous positions in TyrRS. Of the four residues which interact directly with the aromatic side chain of tryptophan (Phe5, Met129, Asp132, and Val141) replacements of Asp132 led to significant changes in the catalytic efficiency of Trp aminoacylation (200-1250-fold reduction in k(cat)/K(M)) and substitution of Val141 by the larger Glu side chain reduced k(cat)/K(M) by 300-fold. Mutation of Pro127, which determines the position of active-site residues, did not significantly effect Trp binding. Of the mutants tested, D132N TrpRS also showed a significant reduction in discrimination against Tyr, with Tyr acting as a competitive inhibitor but not a substrate. The analogous residue in B. stearothermophilusTyrRS (Asp176) has also been implicated as a determinant of amino acid specificity in earlier studies [de Prat Gay, G., Duckworth, H. W., and Fersht, A. R. (1993) FEBS Lett. 318, 167-171]. This striking similarity in the function of a highly conserved residue found in both TrpRS and TyrRS provides mechanistic support for a common origin of the two enzymes.

The structure of ribonuclease P protein from Staphylococcus aureus reveals a unique binding site for single-stranded RNA

Ribonuclease P (RNaseP) catalyses the removal of the 5'-leader sequence from pre-tRNA to produce the mature 5' terminus. The prokaryotic RNaseP holoenzyme consists of a catalytic RNA component and a protein subunit (RNaseP protein), which plays an auxiliary but essential role in vivo by binding to the 5'-leader sequence and broadening the substrate specificity of the ribozyme. We determined the three-dimensional high-resolution structure of the RNaseP protein from Staphylococcus aureus (117 amino acid residues) by nuclear magnetic resonance (NMR) spectroscopy in solution. The protein has an alphabeta-fold, similar to the ribonucleoprotein domain. We used small nucleic acid molecules as a model for the 5'-leader sequence to probe the propensity for generic single-stranded RNA binding on the protein surface. The NMR results reveal a contiguous interaction site, which is identical with the previously identified leader sequence binding site in RNaseP holoenzyme. The conserved arginine-rich motif does not bind single-stranded RNA. It is likely that this peptide segment binds selectively to double-stranded sections of P RNA, which are conformationally more rigid. Given the essentiality of RNaseP for the viability of the organism, knowledge of the S. aureus protein structure and insight into its interaction with RNA will help us to develop RNaseP and RNaseP protein as targets for novel antibiotics against this pathogen.

A novel sporulation-control gene (spo0M) of Bacillus subtilis with a sigmaH-regulated promoter

A novel sporulation-control gene (spo0M) of Bacillus subtilis was cloned, sequenced and analyzed. The spo0M gene is located at the end of large tRNA gene clusters including rrnD and codes for a 257-amino-acid protein with a calculated size of 29.6kDa. The protein Spo0M has a strong negative charge (calculated pI=4.3) and shows no significant sequence homology to any known proteins. Gene disruption experiments revealed that spo0M is not essential for cell viability, but its disruption results in considerable impairments (decreasing by 20- to 100-fold) in sporulation. The morphological stage blocked in sporulation was stage 0 as observed by electron microscopy, and expression analysis using spo0Aps-bgaB fusion revealed an impaired gene expression of spo0A in the spo0M mutant. In contrast, spo0M disruption had no effect on antibiotic productivity. Propagation of the spo0M gene in wild-type cells using a high-copy-number plasmid also impaired sporulation, indicating that overproduction of Spo0M exerts certain negative effects on sporulation. spo0M gene expression is controlled by sigmaH, as demonstrated: (1) by monitoring expression of a bgaB transcriptional fusion integrated into the amyE locus on the chromosome of the wild-type or spo0H mutant cells, and (2) by in-vitro transcription of spo0M gene with EsigmaH.

Recognition of the 5' leader and the acceptor stem of a pre-tRNA substrate by the ribozyme from Bacillus subtilis RNase P

The catalysis by the ribozyme from bacterial RNase P involves specific interactions with the structure of the tRNA substrate. Recognition of the T stem-loop by this ribozyme occurs in a groove-like structure dictated by the tertiary folding of tRNA [Loria, A., and Pan, T. (1997) Biochemistry 36, 6317]. Effects of 2'-OH --> 2'-H modifications within the acceptor stem and the 5' leader on substrate binding and catalysis are determined using a tRNAPhe substrate that is significantly cleaved at more than one site. In all but one case, the 2'-deoxy substitution has little effect on binding for cleavage at the correct and incorrect sites. Substitution of the 2'-OH group at the correct site, however, decreases the cleavage chemistry by more than 3.4 kcal/mol for cleavage at both the correct and incorrect sites. Substitutions of the 2'-OH groups at the incorrect sites have no effect for cleavage at the incorrect and correct sites. Truncation of the 5' leader results in differential effects on cleavage at different sites. These observations lead to a model in which cleavage at the correct and incorrect sites involves formation of different ribozyme-substrate complexes depending on binding of specific nucleotides in the 5' leader. Binding of the T stem-loop of tRNA and the 2'-OH group at the correct cleavage site is common for all ES complexes. An A/U-rich 5' leader significantly promotes formation of the ES complex and accelerates the cleavage chemistry over those of a C/G-rich 5' leader, but only moderately enhances cleavage at the correct site over cleavage at the incorrect sites. Since cleavage at different sites requires formation of different ES complexes, cleavage site selection can occur at the level of the ES complex and at the chemical step.

The protein component of Bacillus subtilis ribonuclease P increases catalytic efficiency by enhancing interactions with the 5' leader sequence of pre-tRNAAsp

Ribonuclease P (RNase P) is a ribonucleoprotein complex that catalyzes the formation of the mature 5' end of tRNA. To investigate the role of the protein component in enhancing the affinity of Bacillus subtilis RNase P for substrate (Kurz, J. C., Niranjanakumari, S., Fierke, C. A. (1998) Biochemistry 37, 2393), the kinetics and thermodynamics of binding and cleavage were analyzed for pre-tRNAAsp substrates containing 5' leader sequences of varying lengths (1-33 nucleotides). These data demonstrate that the cleavage rate constant catalyzed by the holoenzyme is not dependent on the leader length; however, the association rate constant for substrate binding to holoenzyme increases as the length of the leader increases, and this is reflected in enhanced substrate affinity of up to 4 kcal/mol. In particular, the protein component of RNase P stabilizes interactions with nucleotides at -2 and -5 in the 5' leader sequence of the pre-tRNA substrate. A 1 nucleotide leader decreases substrate affinity >/=15-fold compared to tRNAAsp due to ground-state destabilization of the enzyme-substrate complex. This destabilization is overcome by increasing the length of the leader to 2 nucleotides due to P RNA-pre-tRNA contacts that are stabilized by the P protein. The affinity of RNase P holoenzyme (but not RNA alone) for pre-tRNAAsp is further enhanced with a substrate containing a 5 nucleotide leader. These data indicate that novel direct or indirect interactions occur between the 5' leader sequence of pre-tRNAAsp and the protein component of RNase P.

Identification of N2-fixing plant- and fungus-associated Azoarcus species by PCR-based genomic fingerprints

Most species of the diazotrophic Proteobacteria Azoarcus spp. occur in association with grass roots, while A. tolulyticus and A. evansii are soil bacteria not associated with a plant host. To facilitate species identification and strain comparison, we developed a protocol for PCR-generated genomic fingerprints, using an automated sequencer for fragment analysis. Commonly used primers targeted to REP (repetitive extragenic palindromic) and ERIC (enterobacterial repetitive intergenic consensus) sequence elements failed to amplify fragments from the two species tested. In contrast, the BOX-PCR assay (targeted to repetitive intergenic sequence elements of Streptococcus) yielded species-specific genomic fingerprints with some strain-specific differences. PCR profiles of an additional PCR assay using primers targeted to tRNA genes (tDNA-PCR, for tRNA(IIe)) were more discriminative, allowing differentiation at species-specific (for two species) or infraspecies-specific level. Our protocol of several consecutive PCR assays consisted of 16S ribosomal DNA (rDNA)-targeted, genus-specific PCR followed by BOX- and tDNA-PCR; it enabled us to assign new diazotrophic isolates originating from fungal resting stages (sclerotia) to known species of Azoarcus. The assignment was confirmed by phylogenetic analysis of 16S rDNA sequences. Additionally, the phylogenetic distances and the lack of monophyly suggested emendment of the genus Azoarcus: the unnamed species Azoarcus groups C and D and a new group (E) of Azoarcus, which was detected in association with fungi, are likely to have the taxonomic rank of three different genera. According to its small subunit rRNA, the sclerotium-forming basidiomycete was related to the Ustilagomycetes, facultatively biotrophic parasites of plants. Since they occurred in a field which was under cultivation with rice and wheat, these fungi might serve as a niche for survival for Azoarcus in the soil and as a source for reinfection of plants.

Glu-tRNAGln amidotransferase: a novel heterotrimeric enzyme required for correct decoding of glutamine codons during translation

The three genes, gatC, gatA, and gatB, which constitute the transcriptional unit of the Bacillus subtilis glutamyl-tRNAGln amidotransferase have been cloned. Expression of this transcriptional unit results in the production of a heterotrimeric protein that has been purified to homogeneity. The enzyme furnishes a means for formation of correctly charged Gln-tRNAGln through the transamidation of misacylated Glu-tRNAGln, functionally replacing the lack of glutaminyl-tRNA synthetase activity in Gram-positive eubacteria, cyanobacteria, Archaea, and organelles. Disruption of this operon is lethal. This demonstrates that transamidation is the only pathway to Gln-tRNAGln in B. subtilis and that glutamyl-tRNAGln amidotransferase is a novel and essential component of the translational apparatus.

The Staphylococcus aureus ileS gene, encoding isoleucyl-tRNA synthetase, is a member of the T-box family

The Staphylococcus aureus ileS gene, encoding isoleucyl-tRNA synthetase (IleRS), contains a long mRNA leader region. This region exhibits many of the features of the gram-positive synthetase gene family, including the T box and leader region terminator and antiterminator. The terminator was shown to be functional in vivo, and readthrough increased during growth in the presence of mupirocin, an inhibitor of IleRS activity. The S. aureus ileS leader structure includes several critical differences from the other members of the T-box family, suggesting that regulation of this gene in S. aureus may exhibit unique features.

The Bacillus subtilis 168 chromosome from sspE to katA

We have cloned and sequenced a 24.5 kb region of the Bacillus subtilis 168 chromosome spanning the sspE and katA genes. The region contains a ribosomal RNA operon, rrnD, a tRNA gene set, trnD and 17 ORFs, 16 with putative ribosome-binding sites. Four of the ORFs (ORF2, ORF14, ORF16 and ORF17) match to known B. subtilis genes (sspE, thiA, senS and katA). Eight of the remaining ORF products show similarities with proteins present in the databases, including an ATP-binding transport protein, a glutamate-1-semialdehyde aminotransferase, a thiol-specific antioxidant protein, a mitomycin radical oxidase and a ferric uptake regulation protein.

Specificity of tRNA-mRNA interactions in Bacillus subtilis tyrS antitermination

The Bacillus subtilis tyrS gene, encoding tyrosyl-tRNA synthetase, is a member of the T-box family of genes, which are regulated by control of readthrough of a leader region transcriptional terminator. Readthrough is induced by interaction of the cognate uncharged tRNA with the leader; the system responds to decreased tRNA charging, caused by amino acid limitation or insufficient levels of the aminoacyl-tRNA synthetase. Recognition of the cognate tRNA is mediated by pairing of the anticodon of the tRNA with the specifier sequence of the leader, a codon specifying the appropriate amino acid; a second interaction between the acceptor end of the tRNA and an antiterminator structure is also important. Certain switches of the specifier sequence to a new codon result in a switch in the specificity of the amino acid response, while other switches do not. These effects may reflect additional sequence or structural requirements for the mRNA-tRNA interaction. This study includes investigation of the effects of a large number of specifier sequence switches in tyrS and analysis of structural differences between tRNA(Tyr) and tRNA species which interact inefficiently with the tyrS leader to promote antitermination.

A CUC triplet confers leucine-dependent regulation of the Bacillus subtilis ilv-leu operon

Regulation of the ilv-leu operon probably involves interaction of a tR NA(GAG) with leader region mRNA. Conversion of a CUC (Leu) triplet located within the leader region to UUC (Phe), CGC (Arg), or UAC (Tyr) converted reporter gene expression to control by corresponding amino acids. Conversion of the CUC triplet to CUU (Leu) decreased expression and disrupted regulation. The results suggested that other tRNAs can substitute for tRNA(Leu) but that interactions in addition to pairing of the anticodon with the CUC triplet are important for proper control.

Characterization of Streptomyces venezuelae ATCC 10595 rRNA gene clusters and cloning of rrnA

Streptomyces venezuelae ATCC 10595 harbors seven rRNA gene clusters which can be distinguished by BglII digestion. The three rRNA genes present in each set are closely linked with the general structure 16S-23S-5S. We cloned rrnA and sequenced the 16S-23S spacer region and the region downstream of the 5S rRNA gene. No tRNA gene was found in these regions.

Transfer RNA gene organization and RNase P

Mature tRNAs are remarkably similar in all cells. However, the primary transcripts from tRNA genes can vary considerably due to differences in gene organization. RNase P must be able to recognize the elements that are common to all tRNA precursors to accurately remove the 5'-leader sequences.

A conserved sequence in tRNA and rRNA promoters of Lactococcus lactis

A tRNA operon (trnA) from Lactococcus lactis consisting of seven tRNA genes and a 5S rRNA gene was cloned and sequenced. Promoter-fusion of the trnA promoter to a promoter-less beta-galactosidase gene of Leuconostoc mesenteroides resulted in high levels of beta-galactosidase activity in L. lactis. Searching for sequences with similarity to the sequence of the promoter region revealed a consensus sequence of promoters preceeding rRNA operons and tRNA operons from Lactococcus species including a not previously described conserved sequence (AGTT).

Interaction between the acceptor end of tRNA and the T box stimulates antitermination in the Bacillus subtilis tyrS gene: a new role for the discriminator base

The Bacillus subtilis tyrS gene is a member of a group of gram-positive aminoacyl-tRNA synthetase and amino acid biosynthesis genes which are regulated by transcription antitermination. Each gene in the group is specifically induced by limitation for the appropriate amino acid. This response is mediated by interaction of the cognate tRNA with the mRNA leader region to promote formation of an antiterminator structure. The tRNA interacts with the leader by codon-anticodon pairing at a position designated the specifier sequence which is upstream of the antiterminator. In this study, an additional site of possible contact between the tRNA and the leader was identified through covariation of leader mRNA and tRNA sequences. Mutations in the acceptor end of tRNA(Tyr) could suppress mutations in the side bulge of the antiterminator, in a pattern consistent with base pairing. This base pairing may thereby directly affect the formation and/or function of the antiterminator. The discriminator position of the tRNA, an important identity determinant for a number of tRNAs, including tRNA(Tyr), was shown to act as a second specificity determinant for assuring response to the appropriate tRNA. Furthermore, overproduction of an unchargeable variant of tRNA(Tyr) resulted in antitermination in the absence of limitation for tyrosine, supporting the proposal that uncharged tRNA is the effector in this system.

Glycogen in Bacillus subtilis: molecular characterization of an operon encoding enzymes involved in glycogen biosynthesis and degradation

Although it has never been reported that Bacillus subtilis is capable of accumulating glycogen, we have isolated a region from the chromosome of B. subtilis containing a glycogen operon. The operon is located directly downstream from trnB, which maps at 275 degrees on the B. subtilis chromosome. It encodes five polypeptides with extensive similarity to enzymes involved in glycogen and starch metabolism in both prokaryotes and eukaryotes. The operon is presumably expressed by an E sigma E-controlled promoter, which was previously identified downstream from trnB. We have observed glycogen biosynthesis in B. subtilis exclusively on media containing carbon sources that allow efficient sporulation. Sporulation-independent synthesis of glycogen occurred after integration of an E sigma A controlled promoter upstream of the operon.

The Bacillus subtilis ochre suppressor sup-3 is located in an operon of seven tRNA genes

Most Bacillus subtilis tRNA genes have been isolated from lambda libraries by use of probes that hybridize to tRNA or rRNA sequences. None of those genes map to the region of the sup-3 mutation. By cloning of the sup-3 allele, a cluster of seven tRNA genes (the trnS operon) that had not been isolated by other methods was identified. In principle, this approach could be used to isolate at least one more predicted tRNA-containing operon in this bacterium. The trnS operon was shown to contain tRNA genes for Asn (GUU), Ser (GCU), Glu (UUC), Gln (UUG), Lys (UUU), Leu (UAG), and Leu (GAG). The sup-3 mutation was found to be a T-to-A transversion that changes the anticodon of the lysine tRNA from 5'-UUU-3' to 5'-UUA-3'. This result agrees with previous work that determined that the sup-3 mutation causes lysine to be inserted at ochre nonsense mutations.

Staphylococcus aureus has clustered tRNA genes

The polymerase chain reaction (PCR) was used to detect large tRNA gene clusters in Bacillus subtilis, Bacillus badius, Bacillus megaterium, Lactobacillus brevis, Lactobacillus casei, and Staphylococcus aureus. The primers were based on conserved sequences of known gram-positive bacterial tRNA(Arg) and tRNA(Phe) genes. This PCR procedure detected an unusually large tRNA gene cluster in S. aureus. PCR-generated probes were used to identify a 4.5-kb EcoRI fragment that contained 27 tRNA genes immediately 3' to an rRNA operon. Some of these 27 tRNA genes are very similar, but only 1 is exactly repeated in the cluster. The 5' end of this cluster has a gene order similar to that found in the 9- and 21-tRNA gene clusters of B. subtilis. The 3' end of this S. aureus cluster exhibits more similarity to the 16-tRNA gene cluster of B. subtilis. The 24th, 25th, and 26th tRNA genes of this S. aureus tRNA gene cluster code for three similar, unusual Gly-tRNAs that may be used in the synthesis of the peptidoglycan in the cell wall but not in protein synthesis. Southern analysis of restriction digests of S. aureus DNA indicate that there are five to six rRNA operons in this bacterium's genome and that most or all may have large tRNA gene clusters at the 3' end.

The genes aroA and trnQ are located upstream of psbO in the chromosome of Synechocystis 6803

We have identified the existence of two genes, trnQ and aroA, located upstream of the psbO gene in Synechocystis sp. PCC 6803. The trnQ gene encodes a glutamine-specific transfer RNA (tRNA(Gln)) and the sequence given is the first reported for any cyanobacterium. The gene seems to exist as a single copy since its deletion results in non-viable mutation. The aroA gene encodes for 5-enolpyruvylshikimate 3-phosphate synthase and its discovery in the genome of Synechocystis 6803 is the first genetic evidence for the existence of the shikimate biosynthetic pathway in cyanobacteria. Interestingly, the partial sequence shares close homologies with the sequences of aroA from Gram-positive bacteria.

Physical mapping of stable RNA genes in Bacillus subtilis using polymerase chain reaction amplification from a yeast artificial chromosome library

A new approach for mapping genes which utilizes yeast artificial chromosome clones carrying parts of the Bacillus subtilis genome and the polymerase chain reaction technique is described. This approach was used to physically map stable RNA genes of B. subtilis. Results from over 400 polymerase chain reactions carried out with the yeast artificial chromosome clone library, using primers specific for the genes of interest and designed from published sequences, were collected. The locations of 10 known rRNA gene regions (rrnO, rrnA, rrnE, rrnD, rrnB, rrnJ-rrnW, and rrnI-rrnH-rrnG) have been determined by this method, and these results correlate with those observed by standard genetic mapping. All rRNA operons, except rrnB, are found between 0 and 90 degrees, while rrnB has been placed in the area of 270 degrees on the chromosome map. Also localized were the tRNA gene clusters associated with the following ribosomal operons: rrnB (21 tRNAs), rrnJ (9 tRNAs), rrnD (16 tRNAs), and rrnO and rrnA (2 internal tRNAs). A previously unmapped four-tRNA gene cluster, trnY, a tRNA gene region that is not associated with a ribosomal operon, was found near the origin of replication. The P-RNA gene, important for processing of tRNAs, was found between map locations 197 and 204 degrees.

Purification of hyperexpressed Bacillus subtilis tRNA(Trp) cloned in Escherichia coli

To study the effects of evolutionary sequence changes on the molecular interactions of tRNA inside the cell, the Bacillus subtilis tRNA(Trp) gene has been cloned into Escherichia coli JM109 under the control of the lac promotor. Hyperexpression of the gene in minimal medium upon induction yielded 28% of total tRNA in the form of B. subtilis tRNA(Trp). The tRNA(Trp) gene product was purified by the use of a single Vydac C4 high-performance liquid chromatography (HPLC) matrix. This experimental system provided a valuable system for the hyperexpression and purification of a heterologous tRNA for studies in vitro. Moreover, because HPLC fractionation of the heterologous tRNA(Trp) gene product yielded multiple peaks, the system made possible an analysis of the molecular mechanisms for the transcriptional modifications of the tRNA(Trp) gene product in vivo.

Molecular characterization of DNA encoding 23S rRNA and 16S-23S rRNA intergenic spacer regions of Aeromonas hydrophila

Amplification of the gene encoding 23S rRNA of Aeromonas hydrophila by polymerase chain reaction, with primers complementary to conserved regions of 16S and the 3'-end of 23S rRNA genes, resulted in a DNA fragment of approximately 3 kb. This fragment was cloned in Escherichia coli, and its nucleotide sequence determined. The region encoding 23S rRNA shows high homology with the published sequences of 23S rRNA from other members of the gamma division of Proteobacteria. The sequence of the intergenic spacer region, between the 16S and 23S rRNA genes, was determined in five clones. Three types of spacer were identified: two clones were identical and encoded tRNA(Ile) and tRNA(Ala) while the remaining three clones contained tRNA(Glu), only two had the same spacer sequences. This variation in sequence indicates that the different clones may be derived from different ribosomal RNA operons.

Two tRNA gene clusters associated with rRNA operons rrnD and rrnE in Bacillus subtilis

Sequence analysis of cloned rescued DNA fragments from a Bacillus subtilis strain with an inserted recombinant plasmid in ribosomal operon rrnE revealed the presence of two tRNA genes for Met and Asp at the 3' end of the operon. Probing chromosomal DNA from a strain carrying a plasmid inserted in rrnD with a fragment containing the genetically unassigned cluster of 16 tRNA genes revealed that the cluster is located immediately following the rrnD operon. Our findings show that all 10 rrn operons in B. subtilis are associated with tRNA gene clusters.

The 23S-5S spacer of two rRNA loci of Streptococcus salivarius subsp thermophilus includes a promoter

The nucleotide sequence of the 3' part of a ribosomal and transfer RNA locus from Streptococcus salivarius subsp thermophilus NST1403 was determined. The sequenced DNA fragment includes the 3' end of a 23S rRNA gene, a 5S rRNA gene, a tRNA(asn) gene and a potential transcriptional terminator. The tRNA gene does not encode for the CCA 3'terminus of mature tRNA. We compared this sequence to a promoter-carrying DNA fragment sequence (P20) of Streptococcus salivarius subsp thermophilus A054 [1]. We found that the P20 sequence included the 3' end of a 23S rRNA gene, a 5S rRNA gene and the 5' part of a tRNA(val) gene. The two 23S-5S spacer sequences are identical and contain a promoter and a potential 23S rRNA processing site. Therefore, 5S rRNA and tRNA genes could be transcribed from a promoter located within the 23S-5S spacer of at least two of the six rRNA loci.

A cluster of nine tRNA genes between ribosomal gene operons in Bacillus subtilis

A cluster of nine tRNA genes located in the 1-kb region between ribosomal operons rrnJ and rrnW in Bacillus subtilis has been cloned and sequenced. This cluster contains the genes for tRNA(UACVal), tRNA(UGUThr), tRNA(UUULys), tRNA(UAGLeu). tRNA(GCCGly), tRNA(UAALeu), tRNA(ACGArg), tRNA(UGGPro), and tRNA(UGCAla). The newly discovered tRNA gene cluster combines features of the 3'-end of trnI, a cluster of 6 tRNA genes between ribosomal operons rrnI and rrnH, and of the 5'-end of trnB, a cluster of 21 tRNA genes found immediately 3' to rrnB. Neither the tRNA(UAGLeu) gene nor its product has been found previously in B. subtilis. With the discovery of this new set of tRNA genes, a total of 60 such genes have now been found in B. subtilis. These known genes account for almost all of the tRNA hybridizing restriction fragments of the B. subtilis genome. The 60 known tRNA genes of B. subtilis code for only 28 different anticodons, compared with a total of 41 different anticodons for 78 tRNA genes in Escherichia coli. This may indicate that B. subtilis does not need as many anticodons because of more flexible translation rules, similar to the situation in Mycoplasma capricolum.

Nucleotide sequences of serine tRNAs from Bacillus subtilis

Three B. subitilis serine tRNAs were sequenced including modified nucleosides. All the serine tRNAs contained 1-methyl-adenosine in the D-loop. As other characteristic modified nucleosides, 5-methoxyuridine was found in the first letter of the anticodon in the tRNA(UGA).

Five transfer RNA genes lacking CCA termini are clustered in the chromosome of Streptomyces rimosus

The nucleotide sequence of a 1105 bp Streptomyces rimosus DNA fragment containing five transfer RNA genes was determined. Two tRNA(Gln) (CUG) genes, differing by 1 bp in the aminoacyl stem, and three identical tRNA(Glu) (CUC) genes were identified. The five tRNA genes, arranged in the order: Gln1-Glu1-Glu2-Gln2-Glu3, were separated by short, nonhomologous intergenic regions. Surprisingly, none of these tRNA genes encoded the CCA 3' terminus of mature tRNAs. All five encoded tRNAs for the translation of GC rich codons, which are preferentially used in Streptomyces genes (CAG and GAG, respectively). We recently reported nucleotide sequences of two initiator tRNA genes from S. rimosus, which also do not encode the CCA end of mature tRNAs. It is therefore very likely that S. rimosus represents an example of those eubacteria in which the majority of tRNA genes do not encode the 3' terminal CCA end of mature tRNAs. Evolutionary implications of this finding remain to be elucidated.

Pleiotropic morphological and antibiotic deficiencies result from mutations in a gene encoding a tRNA-like product in Streptomyces coelicolor A3(2)

In Streptomyces coelicolor, bldA mutants are defective in antibiotic production and the development of aerial hyphae and spores. Subcloning analysis showed that sequences spanning an NcoI site in cloned bldA+ DNA were needed to allow complementation of a bldA mutant. Nucleotide sequencing revealed a tRNA-like sequence 9 bp downstream from the NcoI site. Five independent bldA mutations all fell in a 16-bp region in the tRNA-like sequence, one of them changing the putative anticodon. In RNA dot-blot analysis, hybridization was detected with a probe specific for the tRNA-like transcript but not with a probe for "anti-tRNA-like" transcripts. The transcripts detected were all in the salt-soluble RNA fraction and accumulated relatively late in growth. It is postulated that bldA specifies a tRNA that would recognize the codon UUA (for leucine). This codon is very rare in Streptomyces genes [which generally contain greater than 70 mole% (G + C)], suggesting a possible role for bldA in translational control of development.

Species specificity of bacterial palindromic units

We described previously a family of dispersed palindromic sequences highly repeated in Escherichia coli and Salmonella typhimurium genomes. These sequences, called PU (palindromic units), are located outside structural genes. We report here observations suggesting that PU may have a role in bacterial speciation.

A single glutamyl-tRNA synthetase aminoacylates tRNAGlu and tRNAGln in Bacillus subtilis and efficiently misacylates Escherichia coli tRNAGln1 in vitro

In the presence or absence of its regulatory factor, the monomeric glutamyl-tRNA synthetase from Bacillus subtilis can aminoacylate in vitro with glutamate both tRNAGlu and tRNAGln from B. subtilis and tRNAGln1 but not tRNAGln2 or tRNAGlu from Escherichia coli. The Km and Vmax values of the enzyme for its substrates in these homologous or heterologous aminoacylation reactions are very similar. This enzyme is the only aminoacyl-tRNA synthetase reported to aminoacylate with normal kinetic parameters two tRNA species coding for different amino acids and to misacylate at a high rate a heterologous tRNA under normal aminoacylation conditions. The exceptional lack of specificity of this enzyme for its tRNAGlu and tRNAGln substrates, together with structural and catalytic peculiarities shared with the E. coli glutamyl- and glutaminyl-tRNA synthetases, suggests the existence of a close evolutionary linkage between the aminoacyl-tRNA synthetases specific for glutamate and those specific for glutamine. A comparison of the primary structures of the three tRNAs efficiently charged by the B. subtilis glutamyl-tRNA synthetase with those of E. coli tRNAGlu and tRNAGln2 suggests that this enzyme interacts with the G64-C50 or G64-U50 in the T psi stem of its tRNA substrates.

Promoter used by sigma-29 RNA polymerase from Bacillus subtilis

Gene expression during endospore formation by Bacillus subtilis is controlled in part by a sporulation-induced form of RNA polymerase, E sigma 29. The determination of the nucleotide sequences that govern utilization of promoters by E sigma 29 has been limited by the small number of available promoters that are recognized by E sigma 29. In the present report we describe a promoter that is adjacent to the rrnB region of the B. subtilis chromosome and is utilized in vitro and in vivo by E sigma 29. S1 nuclease mapping and dinucleotide priming experiments have been used to determine the start point of transcription. The nucleotide sequences near the -10 and -35 region of this promoter, bvx, are conserved, and resemble sequences at these regions for other promoters that are utilized by E sigma 29.

Nucleotide sequence of the Bacillus subtilis ribosomal RNA operon, rrnB

The primary sequence of DNA covering a complete ribosomal RNA (rRNA) operon from Bacillus subtilis, designated rrnB has been elucidated. Following a set of tandem promoters, rrnB encodes: (i) a 16S and a 23S rRNA determinant with no tRNA spacer region in between; (ii) a 5S rRNA determinant; and (iii) 21 contiguous tRNA species; before (iv) two characteristic terminator hairpins are found. More than 7 kb are included within this operon, which maps between aroG and thr5 on the B. subtilis chromosome. This represents the first report of the entire sequence of an rRNA operon from B. subtilis or from any Gram-positive organism.