Co-ordinate expression of the two threonyl-tRNA synthetase genes in Bacillus subtilis: control by transcriptional antitermination involving a conserved regulatory sequence

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.

Structure and regulation of expression of the Bacillus subtilis valyl-tRNA synthetase gene

We have sequenced the valyl-tRNA synthetase gene (valS) of Bacillus subtilis and found an open reading frame coding for a protein of 880 amino acids with a molar mass of 101,749. The predicted amino acid sequence shares strong similarity with the valyl-tRNA synthetases from Bacillus stearothermophilus, Lactobacillus casei, and Escherichia coli. Extracts of B. subtilis strains overexpressing the valS gene on a plasmid have increased valyl-tRNA aminoacylation activity. Northern analysis shows that valS is cotranscribed with the folC gene (encoding folyl-polyglutamate synthetase) lying downstream. The 300-bp 5' noncoding region of the gene contains the characteristic regulatory elements, T box, "specifier codon" (GUC), and rho-independant transcription terminator of a gene family in gram-positive bacteria that encodes many aminoacyl-tRNA synthetases and some amino acid biosynthetic enzymes and that is regulated by tRNA-mediated antitermination. We have shown that valS expression is induced by valine limitation and that the specificity of induction can be switched to threonine by changing the GUC (Val) specifier triplet to ACC (Thr). Overexpression of valS from a recombinant plasmid leads to autorepression of a valS-lacZ transcriptional fusion. Like induction by valine starvation, autoregulation of valS depends on the presence of the GUC specifier codon. Disruption of the valS gene was not lethal, suggesting the existence of a second gene, as is the case for both the thrS and the tyrS genes.

Control of transcription termination in prokaryotes

A growing number of genetic systems have been shown to be controlled at the level of premature termination of transcription. Genes in this class contain transcription termination signals in the region upstream of the coding sequence. The activity of these regulatory termination signals is controlled through a variety of mechanisms. These include modification of RNA polymerase to a terminator-resistant, or terminator-prone form, and alterations in the structure of the nascent transcript, to determine whether the stem-loop structure of an intrinsic terminator or an alternate antiterminator is formed. Structural alterations in the transcript can be controlled by the kinetics of translation of the RNA, by binding of specific regulatory proteins, and by mRNA-tRNA interactions. This review describes a number of variations on the termination control theme that have been uncovered in prokaryotes.

Aminoacyl-tRNA synthetase gene regulation in Bacillus subtilis

In this review, we summarize progress on the regulation of the aminoacyl-tRNA synthetase genes in Bacillus subtilis. Most of the genes encoding this set of enzymes in B subtilis are members of a large family of Gram-positive genes and operons controlled by a novel antitermination mechanism that uses their cognate uncharged tRNA as the effector. A subset of these genes is, in addition, likely to be controlled at the level of mRNA processing and degradation. We describe the key experiments leading to these conclusions.

Regulation of ptsH and ptsI gene expression in Streptococcus salivarius ATCC 25975

The transcriptional regulation of the Streptococcus salivarius ptsH and ptsI genes coding for the general energy-coupling proteins HPr and enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system were investigated. These genes form an operon with the gene order ptsH-ptsI. Three distinct mRNA species were detected: a 0.5 kb transcript specific for ptsH, and two long transcripts (2.2 and 2.4 kb) covering the whole pts operon. Transcription of all these mRNAs initiated at the same nucleotide located 9 bp downstream from a promoter located immediately upstream from the ptsH gene. The presence of a high-energy stem-loop structure (T0) located at the beginning of ptsI was responsible for the premature transcription termination generating the 0.5 kb ptsH-specific transcript. The long transcripts ended in the poly(U) region of two rho-independent-like terminators (T1 and T2) at the 3' end of ptsI. Studies with a 2-deoxyglucose-resistant spontaneous mutant of S. salivarius (L26) that produces an HPr-EI fusion protein suggest that the regulation of HPr and EI expression involves transcriptional as well as translational mechanisms.

Aminoacyl-tRNA synthetase gene regulation in Bacillus subtilis: induction, repression and growth-rate regulation

The thrS gene in Bacillus subtilis is specifically induced by starvation for threonine and is, in addition, autorepressed by the overproduction of its own gene product, the threonyl-tRNA synthetase. Both methods of regulation employ an antitermination mechanism at a factor-independent transcription terminator that occurs just upstream of the start codon. The effector of the induction mechanism is thought to be the uncharged tRNA(Thr), which has been proposed to base pair in two places with the leader mRNA to induce antitermination. Here we show that the autoregulation by synthetase overproduction is likely to utilize a mechanism similar to that characterized for induction by amino acid starvation, that is by altering the levels of tRNA charging in the cell. We also demonstrate that the base pairing interaction at the two proposed contact points between the tRNA and the leader are necessary but not always sufficient for either form of regulation. Finally, we present evidence that the thrS gene is expressed in direct proportion to the growth rate. This method of regulation is also at the level of antitermination but is independent of the interaction of the tRNA with the leader region.

tRNA-directed transcription antitermination

At least 18 aminoacyl-tRNA synthetase and amino acid biosynthesis genes in several Gram-positive genera appear to be regulated by a common transcription antitermination mechanism. Each gene is induced by limitation for the appropriate amino acid, and not by general amino acid limitation. The mRNA leader regions of these genes exhibit extensive structural conservation. Characterization of the Bacillus subtilis tyrS gene revealed that uncharged tyrosyl-tRNA promotes readthrough of a leader-region terminator; a conformational switch in the leader mRNA between a terminator structure and an antiterminator structure is postulated to mediate antitermination. Two sites of interaction between the tRNA and the leader have been identified by genetic analysis: the tRNA anticodon interacts with a single codon displayed at a precise position in the leader-region structure, and the acceptor end of the tRNA interacts with a side-bulge on the antiterminator.

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.

Expression of both Bacillus subtilis threonyl-tRNA synthetase genes is autogenously regulated

The "housekeeping" threonyl-tRNA synthetase gene (thrS) of Bacillus subtilis is shown to be transcribed in vivo and in vitro from a single promoter. In vitro, 85% of all messages transcribed from the thrS promoter are terminated at a strong factor-independent terminator localized upstream of the thrS Shine-Dalgarno sequence, within the 305-nucleotide-long leader region. Overexpression of thrS represses transcriptional and translational thrS-lacZ fusions to a similar extent, suggesting that thrS is autoregulated at the transcriptional level. We show that autogenous control does not act at the level of transcription initiation but involves antitermination of the transcription mechanism. thrZ, the second threonyl-tRNA synthetase gene, is also autogenously regulated. However, the ability of the ThrS synthetase to repress thrS as well as thrZ expression is much greater than that of the ThrZ synthetase.

Organization and regulation of genes for amino acid biosynthesis in lactic acid bacteria

The recent description of large clusters of biosynthetic genes in the chromosome of Lactococcus lactis and, to a lesser extent, of Lactobacillus, has brought some information on gene organization and control of gene expression in these organisms. The genes involved in a given amino acid biosynthetic pathway are clustered at a single chromosomal location and form an operon. Additional genes which are not required for the biosynthesis are present within some operons. Genetic signals are, in general, similar to those found in other prokaryotes. Several systems controlling gene expression have been identified and transcription attenuation seems frequent. Among the attenuation mechanisms identified, one resembles that controlling amino acid biosynthesis in many bacteria by ribosome stalling at codons corresponding to limiting amino acid. The others are different and might be related to a new class of attenuation mechanism. Preliminary evidence for a new type of regulatory mechanism, involving a metabolic shunt, is also reviewed.

tRNA as a positive regulator of transcription antitermination in B. subtilis

Most Bacillus tRNA synthetase genes are regulated by a common transcription antitermination mechanism but respond individually to limitation for the cognate amino acid. The mRNA leader regions of these genes exhibit extensive structural conservation, with a single codon specific for the appropriate amino acid at the identical position in each structure. Alteration of this sequence in the tyrS gene from UAC (tyrosine) to UUC (phenylalanine) resulted in loss of induction by tyrosine limitation and a switch to induction by phenylalanine limitation. Insertion of an extra base immediately upstream of the codon did not alter regulation, indicating a nontranslational mechanism. A nonsense codon resulted in an uninducible phenotype that was suppressible in a lysyl-tRNA nonsense suppressor mutant, indicating that tRNA acts as an effector.