Homologues of csrC are apparent in several Enterobacteriaceae. The regulatory and evolutionary implications of these findings are discussed.
SummaryThe RNA-binding protein CsrA represses biofilm formation, while the non-coding RNAs CsrB and CsrC activate this process by sequestering CsrA. We now provide evidence that the pgaABCD transcript,
The global Csr regulatory system controls bacterial gene expression post-transcriptionally. CsrA of Escherichia coli is an RNA binding protein that plays a central role in repressing several stationary phase processes and activating certain exponential phase functions. CsrA regulates translation initiation of several genes by binding to the mRNA leaders and blocking ribosome binding. CsrB and CsrC are noncoding regulatory RNAs that are capable of sequestering CsrA and antagonizing its activity. Each of the known target transcripts contains multiple CsrA binding sites, although considerable sequence variation exists among these RNA targets, with GGA being the most highly conserved element. High-affinity RNA ligands containing single CsrA binding sites were identified from a combinatorial library using systematic evolution of ligands by exponential enrichment (SELEX). The SELEXderived consensus was determined as RUACARGGAUGU, with the ACA and GGA motifs being 100% conserved and the GU sequence being present in all but one ligand. The majority (51/55) of the RNAs contained GGA in the loop of a hairpin within the most stable predicted structure, an arrangement similar to several natural CsrA binding sites. Strikingly, the identity of several nucleotides that were predicted to form base pairs in each stem were 100% conserved, suggesting that primary sequence information was embedded within the base-paired region. The affinity of CsrA for several selected ligands was measured using quantitative gel mobility shift assays. A mutational analysis of one selected ligand confirmed that the conserved ACA, GGA, and GU residues were critical for CsrA binding and that RNA secondary structure participates in CsrA-RNA recognition.
Human oral cavity harbors the second most abundant microbiota after the gastrointestinal tract. The expanded Human Oral Microbiome Database (eHOMD) that was last updated on November 22, 2017, contains the information of approximately 772 prokaryotic species, where 70% is cultivable, and 30% belong to the uncultivable class of microorganisms along with whole genome sequences of 482 taxa. Out of 70% culturable species, 57% have already been assigned to their names. The 16S rDNA profiling of the healthy oral cavity categorized the inhabitant bacteria into six broad phyla, viz. Firmicutes, Actinobacteria, Proteobacteria, Fusobacteria, Bacteroidetes and Spirochaetes constituting 96% of total oral bacteria. These hidden oral micro-inhabitants exhibit a direct influence on human health, from host's metabolism to immune responses. Altered oral microflora has been observed in several diseases such as diabetes, bacteremia, endocarditis, cancer, autoimmune disease and preterm births. Therefore, it becomes crucial to understand the oral microbial diversity and how it fluctuates under diseased/perturbed conditions. Advances in metagenomics and next-generation sequencing techniques generate rapid sequences and provide extensive information of inhabitant microorganisms of a niche. Thus, the retrieved information can be utilized for developing microbiome-based biomarkers for their use in early diagnosis of oral and associated diseases. Besides, several apex companies have shown keen interest in oral microbiome for its diagnostic and therapeutic potential indicating a vast market opportunity. This review gives an insight of various associated aspects of the human oral microbiome.
CsrA is a global regulator that binds to two sites in the glgCAP leader transcript, thereby blocking ribosome access to the glgC Shine-Dalgarno sequence. The upstream CsrA binding site (GCACACGGAU) was used to search the Escherichia coli genomic sequence for other genes that might be regulated by CsrA. cstA contained an exact match that overlapped its Shine-Dalgarno sequence. cstA was previously shown to be induced by carbon starvation and to encode a peptide transporter. Expression of a cstA-lacZ translational fusion in wild-type and csrA mutant strains was examined. Expression levels in the csrA mutant were approximately twofold higher when cells were grown in Luria broth (LB) and 5-to 10-fold higher when LB was supplemented with glucose. It was previously shown that cstA is regulated by the cyclic AMP (cAMP)-cAMP receptor protein complex and transcribed by ⌭ 70 . We investigated the influence of S on cstA expression and found that a S deficiency resulted in a threefold increase in cstA expression in wild-type and csrA mutant strains; however, CsrA-dependent regulation was retained. The mechanism of CsrA-mediated cstA regulation was also examined in vitro. Cross-linking studies demonstrated that CsrA is a homodimer. Gel mobility shift results showed that CsrA binds specifically to cstA RNA, while coupled-transcription-translation and toeprint studies demonstrated that CsrA regulates CstA synthesis by inhibiting ribosome binding to cstA transcripts. RNA footprint and boundary analyses revealed three or four CsrA binding sites, one of which overlaps the cstA ShineDalgarno sequence, as predicted. These results establish that CsrA regulates translation of cstA by sterically interfering with ribosome binding.
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