SummaryAmino sugars are essential precursor molecules for the biosynthesis of bacterial cell walls. Their synthesis pathway is initiated by glucosamine-6-phosphate (GlcN-6-P) synthase (GlmS) which catalyses the rate limiting reaction. We report here that expression of the Escherichia coli glmS gene is negatively feedback regulated by its product GlcN-6-P at the posttranscriptional level. Initially, we observed that mutants defective for yhbJ, a gene of the rpoN operon, overproduce GlmS. Concomitantly, a glmS mRNA accumulates that is derived from processing of the primary glmUS transcript at the glmU stop codon by RNase E. A transposon mutagenesis screen in the yhbJ mutant identified the small RNA GlmZ (formerly RyiA or SraJ) to be required for glmS mRNA accumulation. GlmZ, which is normally processed, accumulates in its full-length form in the yhbJ mutant. In the wild type, a decrease of the intracellular GlcN-6-P concentration induces accumulation of the glmS transcript in a GlmZ-dependent manner. Concomitantly, GlmZ accumulates in its unprocessed form. Hence, we conclude that the biological function of GlmZ is to positively control the glmS mRNA in response to GlcN-6-P concentrations and that YhbJ negatively regulates GlmZ. As in yhbJ mutants GlcN-6-P has no effect, YhbJ is essential for sensing this metabolite.
In Escherichia coli the glmS gene encoding glucosamine 6-phosphate (GlcN-6-P) synthase GlmS is feedback regulated by GlcN-6-P in a pathway that involves the small RNA GlmZ. Expression of glmS is activated by the unprocessed form of GlmZ, which accumulates when the intracellular GlcN-6-P concentration decreases. GlmZ stabilizes a glmS transcript that derives from processing. Overexpression of a second sRNA, GlmY, also activates glmS expression in an unknown way. Furthermore, mutations in two genes, yhbJ and pcnB, cause accumulation of full-length GlmZ and thereby activate glmS expression. The function of yhbJ is unknown and pcnB encodes poly(A) polymerase PAP-I known to polyadenylate and destabilize RNAs. Here we show that GlmY acts indirectly in a way that depends on GlmZ. When the intracellular GlcN-6-P concentration decreases, GlmY accumulates and causes in turn accumulation of full-length GlmZ, which finally activates glmS expression. In glmZ mutants, GlmY has no effect on glmS, whereas artificially expressed GlmZ can activate glmS expression also in the absence of GlmY. Furthermore, we show that PAP-I acts at the top of this regulatory pathway by polyadenylating and destabilizing GlmY. In pcnB mutants, GlmY accumulates and induces glmS expression by stabilizing full-length GlmZ. Hence, the data reveal a regulatory cascade composed of two sRNAs, which responds to GlcN-6-P and is controlled by polyadenylation.
The Lia system, a cell envelope stress response module of Bacillus subtilis, is comprised of the LiaRS two-component system and a membrane-anchored inhibitor protein, LiaF. It is highly conserved in the Firmicutes bacteria, and all orthologs investigated so far are activated by cell wall antibiotics. In response to envelope stress, the systems in Firmicutes cocci induce the expression of a number of genes that are involved in conferring resistance against its inducers. In contrast, a complete picture of the LiaR regulon of B. subtilis is still missing and no phenotypes could be associated with mutants lacking LiaRS. Here, we performed genome-wide transcriptomic, proteomic, and in-depth phenotypic profiling of constitutive "Lia ON" and "Lia OFF" mutants to obtain a comprehensive picture of the Lia response of Bacillus subtilis. In addition to the known targets liaIH and yhcYZ-yhdA, we identified ydhE as a novel gene affected by LiaR-dependent regulation. The results of detailed follow-up gene expression studies, together with proteomic analysis, demonstrate that the liaIH operon represents the only relevant LiaR target locus in vivo. It encodes a small membrane protein (LiaI) and a phage shock protein homolog (LiaH). LiaH forms large oligomeric rings reminiscent of those described for Escherichia coli PspA or Arabidopsis thaliana Vipp1. The results of comprehensive phenotype studies demonstrated that the gene products of the liaIH operon are involved in protecting the cell against oxidative stress and some cell wall antibiotics. Our data suggest that the LiaFSR system of B. subtilis and, presumably, other Firmicutes bacilli coordinates a phage shock protein-like response.
Resistance of Enterococcus faecalis against antimicrobial peptides, both of host origin and produced by other bacteria of the gut microflora, is likely to be an important factor in the bacterium's success as an intestinal commensal. The aim of this study was to identify proteins with a role in resistance against the model antimicrobial peptide bacitracin. Proteome analysis of bacitracintreated and untreated cells showed that bacitracin stress induced the expression of cell wall-biosynthetic proteins and caused metabolic rearrangements. Among the proteins with increased production, an ATP-binding cassette (ABC) transporter with similarity to known peptide antibiotic resistance systems was identified and shown to mediate resistance against bacitracin. Expression of the transporter was dependent on a two-component regulatory system and a second ABC transporter, which were identified by genome analysis. Both resistance and the regulatory pathway could be functionally transferred to Bacillus subtilis, proving the function and sufficiency of these components for bacitracin resistance. Our data therefore show that the two ABC transporters and the two-component system form a resistance network against antimicrobial peptides in E. faecalis, where one transporter acts as the sensor that activates the TCS to induce production of the second transporter, which mediates the actual resistance.
The results demonstrate that low-level bacitracin resistance in E. faecalis is mediated by a BacA-type UppP.
The genes and molecular machines that allow for a thermoalkaliphilic lifestyle have not been defined. To address this goal, we report on the improved high-quality draft genome sequence of Caldalkalibacillus thermarum strain TA2.A1, an obligately aerobic bacterium that grows optimally at pH 9.5 and 65 to 70°C on a wide variety of carbon and energy sources.Thermoalkaliphilic microorganisms are poorly understood as a group, and there is very little information available on the genes and molecular machines that allow for a thermoalkaliphilic lifestyle. To live at high pH and temperature, akin to a proton desert, these bacteria must overcome a number of thermodynamic challenges. These include capturing and retaining protons from an alkaline environment (pH 9.5) to drive endothermic reactions in the cell membrane (2), increased membrane permeability to protons at high temperature (16), and a low protonmotive force that appears to be suboptimal for growth (12). Studies of the membrane-bound F 1 F o -ATP synthase of Caldalkalibacillus thermarum strain TA2.A1 (formerly Bacillus sp. strain TA2.A1) have revealed a number of unique adaptations that enable this enzyme to function at extremes of pH and temperature by using protons as coupling ions (2,8,9,11,(13)(14)(15). Additionally, thermoalkaliphilic bacteria with a respiratory metabolism have an obligate growth requirement for iron (10). At alkaline pH, the solubility constant for iron decreases far below the requirement for living cells, and the concentration of bioavailable iron is estimated to be approximately 10 Ϫ23 M at pH 10 (3), suggesting that thermoalka-liphilic bacteria must possess powerful, yet undiscovered, mechanisms to sequester iron. Despite these apparent thermodynamic problems and the challenge of severe iron limitation, thermoalkaliphilic bacteria grow rapidly (doubling time Ͻ 60 min) under these conditions, demonstrating that these bacteria are superbly adapted to combat these challenges.
The aerobic thermoalkaliphile Caldalkalibacillus thermarum strain TA2.A1 is a member of a separate order of alkaliphilic bacteria closely related to the Bacillales order. Efforts to relate the genomic information of this evolutionary ancient organism to environmental adaptation have been thwarted by the inability to construct a complete genome. The existing draft genome is highly fragmented due to repetitive regions, and gaps between and over repetitive regions were unbridgeable. To address this, Oxford Nanopore Technology’s MinION allowed us to span these repeats through long reads, with over 6000-fold coverage. This resulted in a single 3.34 Mb circular chromosome. The profile of transporters and central metabolism gives insight into why the organism prefers glutamate over sucrose as carbon source. We propose that the deamination of glutamate allows alkalization of the immediate environment, an excellent example of how an extremophile modulates environmental conditions to suit its own requirements. Curiously, plant-like hallmark electron transfer enzymes and transporters are found throughout the genome, such as a cytochrome b6c1 complex and a CO2-concentrating transporter. In addition, multiple self-splicing group II intron-encoded proteins closely aligning to those of a telomerase reverse transcriptase in Arabidopsis thaliana were revealed. Collectively, these features suggest an evolutionary relationship to plant life.
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