A new role for CsrA: promotion of complex formation between an sRNA and its mRNA target in Bacillus subtilis

Small RNAs are ubiquitously present regulators in all kingdoms of life. Most bacterial and archaeal small RNAs (sRNAs) act by antisense mechanisms on multiple target mRNAs, thereby globally affecting essentially any conceivable trait-stress responses, adaptive metabolic changes, virulence etc. The sRNAs display many distinct mechanisms of action, most of them through effects on target mRNA translation and/or stability, and helper proteins like Hfq often play key roles. Recent data highlight the interplay between posttranscriptional control by sRNAs and transcription factor-mediated transcriptional control, and cross talk through mutual regulation of regulators. Based on the properties that distinguish sRNA-type from transcription factors-type control, we begin to glimpse why sRNAs have evolved as a second, essential layer of gene regulation. This review will discuss the prevalence of sRNAs, who they are, what biological roles they play, and how they carry out their functions.

Originally described as a repressor of gene expression in the stationary phase of growth, CsrA (RsmA) regulates primary and secondary metabolic pathways, biofilm formation, motility, virulence circuitry of pathogens, quorum sensing and stress response systems by binding to conserved sequences in its target mRNAs and altering their translation and/or turnover. While the binding of CsrA to RNA is understood at an atomic level, new mechanisms of gene activation and repression by this protein are still emerging. In the γ-proteobacteria, small non-coding RNAs (sRNAs) use molecular mimicry to sequester multiple CsrA dimers away from mRNA. In contrast, the FliW protein of Bacillus subtilis inhibits CsrA activity by binding to this protein, thereby establishing a checkpoint in flagellum morphogenesis. Turnover of CsrB and CsrC sRNAs in Escherichia coli requires a specificity protein of the GGDEF-EAL domain superfamily, CsrD, in addition to the housekeeping nucleases RNase E and PNPase. The Csr system of E. coli contains extensive autoregulatory circuitry, which governs the expression and activity of CsrA. Interaction of the Csr system with transcriptional regulatory networks results in a variety of complex response patterns. This minireview will highlight basic principles and new insights into the workings of these complex eubacterial regulatory systems. © 2012 Society for Applied Microbiology and Blackwell Publishing Ltd.

Hfq, an RNA chaperone, promotes the pairing of small RNAs (sRNAs) to target mRNAs, mediating post-transcriptional regulation of mRNA stability and translation. This regulation contributes to bacterial adaptation during stress and pathogenesis. Recent advances in sequencing techniques demonstrate the presence of sRNAs encoded not only in intergenic regions but also from the 3' and 5' UTRs of mRNAs, expanding sRNA regulatory networks. Additional layers of regulation by Hfq and its associated RNAs continue to be found. Newly identified RNA sponges modulate the activity of some sRNAs. A subset of sRNAs are proving to be bifunctional, able to pair with targets and also encoding small ORFs or binding other RNA binding proteins, such as CsrA. In addition, there are accumulating examples of Hfq inhibiting mRNA translation in the absence of sRNAs.