Harald Putzer

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 tRNAThr, 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.

A severely truncated form of translational initiation factor 2 supports growth of Escherichia coli

We have constructed strains carrying null mutations in the chromosomal copy of the gene for translational initiation factor (IF) 2 (infB). A functional copy of the infB gene is supplied in trans by a thermosensitive lysogenic lambda phage integrated at att lambda. These strains enabled us to test in vivo the importance of different structural elements of IF2 expressed from genetically engineered plasmid constructs. We found that, as expected, the gene for IF2 is essential. However, a protein consisting of the C-terminal 55,000 Mr fragment of the wild-type IF2 protein is sufficient to allow growth when supplied in excess. This result suggests that the catalytic properties are localized in the C-terminal half of the protein, which includes the G-domain, and that this fragment is sufficient to complement the IF2 deficiency in the infB deletion strain.

Mycobacterium smegmatis RNase J is a 5-3 exo-/endoribonuclease and both RNase J and RNase E are involved in ribosomal RNA maturation

The presence of very different sets of enzymes, and in particular the presence of RNase E and RNase J, has been used to explain significant differences in RNA metabolism between the two model organisms Escherichia coli and Bacillus subtilis. However, these studies might have somewhat polarized our view of RNA metabolism. Here, we identified a RNase J in Mycobacterium smegmatis that has both 5′‐3′ exo‐ and endonucleolytic activity. This enzyme coexists with RNase E in this organism, a configuration that enabled us to study how these two key nucleases collaborate. We demonstrate that RNase E is responsible for the processing of the furA‐katG transcript in M.u2003smegmatis and that both RNase E and RNase J are involved in the 5′ end processing of all ribosomal RNAs. In contrast to B.u2003subtilis, the activity of RNase J, although required in vivo for 23S rRNA maturation, is not essential in M.u2003smegmatis. We show that the pathways for ribosomal RNA maturation in M.u2003smegmatis are quite different from those observed in E.u2003coli and in B.u2003subtilis. Studying organisms containing different combinations of key ribonucleases can thus significantly broaden our view of the possible strategies that exist to direct RNA metabolism.

The Use of Amino Sugars by Bacillus subtilis: Presence of a Unique Operon for the Catabolism of Glucosamine

B. subtilis grows more rapidly using the amino sugar glucosamine as carbon source, than with N-acetylglucosamine. Genes for the transport and metabolism of N-acetylglucosamine (nagP and nagAB) are found in all the sequenced Bacilli (except Anoxybacillus flavithermus). In B. subtilis there is an additional operon (gamAP) encoding second copies of genes for the transport and catabolism of glucosamine. We have developed a method to make multiple deletion mutations in B. subtilis employing an excisable spectinomycin resistance cassette. Using this method we have analysed the contribution of the different genes of the nag and gam operons for their role in utilization of glucosamine and N-acetylglucosamine. Faster growth on glucosamine is due to the presence of the gamAP operon, which is strongly induced by glucosamine. Although the gamA and nagB genes encode isozymes of GlcN6P deaminase, catabolism of N-acetylglucosamine relies mostly upon the gamA gene product. The genes for use of N-acetylglucosamine, nagAB and nagP, are repressed by YvoA (NagR), a GntR family regulator, whose gene is part of the nagAB yvoA(nagR) operon. The gamAP operon is repressed by YbgA, another GntR family repressor, whose gene is expressed divergently from gamAP. The nagAB yvoA synton is found throughout the Bacilli and most firmicutes. On the other hand the ybgA-gamAP synton, which includes the ybgB gene for a small protein of unknown provenance, is only found in B. subtilis (and a few very close relatives). The origin of ybgBA-gamAP grouping is unknown but synteny analysis suggests lateral transfer from an unidentified donor. The presence of gamAP has enabled B. subtilis to efficiently use glucosamine as carbon source.

RNase Y is responsible for uncoupling the expression of translation factor IF3 from that of the ribosomal proteins L35 and L20 in Bacillus subtilis.

RNase Y is a novel endoribonuclease affecting global mRNA metabolism. We show that this nuclease affects the expression of the Bacillus subtilis infC‐rpmI‐rplT operon, encoding translation initiation factor IF3 and the ribosomal proteins L35 and L20. This operon is autoregulated by a complex L20‐dependent transcription attenuation mechanism. L20 binds to a phylogenetically conserved domain on the 5′ untranslated region of the infC mRNA which mimics the L20 binding sites on 23S rRNA. We have identified a second promoter (P1) upstream of the previously identified promoter (P2). The P1, but not the P2, readthrough transcript is stabilized in a strain depleted for RNase Y. However, under these conditions infC biosynthesis is repressed threefold. We show that the unprocessed P1 transcript is non‐functional for IF3 translation but fully competent to express the co‐transcribed ribosomal protein genes. RNase Y cleavage of the P1 transcript creates an entry site for the 5′–3′ exonucleolytic activity of RNase J1 which degrades the infC mRNA when translation initiation efficiency is low. A second RNase Y cleavage is crucial for initiating degradation of the prematurely terminated infC leader RNAs, including the L20 operator complex, which permits efficient recycling of the L20 protein.

mRNA degradation and maturation in prokaryotes: the global players.

Abstract The degradation of messenger RNA is of universal importance for controlling gene expression. It directly affects protein synthesis by modulating the amount of mRNA available for translation. Regulation of mRNA decay provides an efficient means to produce just the proteins needed and to rapidly alter patterns of protein synthesis. In bacteria, the half-lives of individual mRNAs can differ by as much as two orders of magnitude, ranging from seconds to an hour. Most of what we know today about the diverse mechanisms of mRNA decay and maturation in prokaryotes comes from studies of the two model organisms Escherichia coli and Bacillus subtilis. Their evolutionary distance provided a large picture of potential pathways and enzymes involved in mRNA turnover. Among them are three ribonucleases, two of which have been discovered only recently, which have a truly general role in the initiating events of mRNA degradation: RNase E, RNase J and RNase Y. Their enzymatic characteristics probably determine the strategies of mRNA metabolism in the organism in which they are present. These ribonucleases are coded, alone or in various combinations, in all prokaryotic genomes, thus reflecting how mRNA turnover has been adapted to different ecological niches throughout evolution.

Control of Expression of the RNases J1 and J2 in Bacillus subtilis

In Bacillus subtilis, the dual activity 5 exo- and endoribonucleases J1 and J2 are important players in mRNA and stable RNA maturation and degradation. Recent work has improved our understanding of their structure and mechanism of action and identified numerous RNA substrates. However, almost nothing is known about the expression of these enzymes. Here, we have identified the transcriptional and translational signals that control the expression of the rnjA (RNase J1) and rnjB (RNase J2) genes. While the rnjB gene is transcribed constitutively from a sigma A promoter, optimal expression of RNase J1 requires cotranscription and cotranslation with the upstream ykzG gene, encoding a protein of unknown function. In the absence of coupled translation, RNase J1 expression is decreased more than 5-fold. Transcription of the ykzG operon initiates at a sigma A promoter with a noncanonical -35 box that is required for optimal transcription. Biosynthesis of RNase J1 is autocontrolled within a small range (1.4-fold) and also slightly stimulated (1.4-fold) in the absence of RNase J2. These controls are weak but might be useful to maintain the overall RNase J level and possibly also equimolar amounts of the two nucleases in the cell that primarily act as a heterodimer in vivo.