Kai Papenfort

Deep Sequencing Analysis of Small Noncoding RNA and mRNA Targets of the Global Post-Transcriptional Regulator, Hfq

Recent advances in high-throughput pyrosequencing (HTPS) technology now allow a thorough analysis of RNA bound to cellular proteins, and, therefore, of post-transcriptional regulons. We used HTPS to discover the Salmonella RNAs that are targeted by the common bacterial Sm-like protein, Hfq. Initial transcriptomic analysis revealed that Hfq controls the expression of almost a fifth of all Salmonella genes, including several horizontally acquired pathogenicity islands (SPI-1, -2, -4, -5), two sigma factor regulons, and the flagellar gene cascade. Subsequent HTPS analysis of 350,000 cDNAs, derived from RNA co-immunoprecipitation (coIP) with epitope-tagged Hfq or control coIP, identified 727 mRNAs that are Hfq-bound in vivo. The cDNA analysis discovered new, small noncoding RNAs (sRNAs) and more than doubled the number of sRNAs known to be expressed in Salmonella to 64; about half of these are associated with Hfq. Our analysis explained aspects of the pleiotropic effects of Hfq loss-of-function. Specifically, we found that the mRNAs of hilD (master regulator of the SPI-1 invasion genes) and flhDC (flagellar master regulator) were bound by Hfq. We predicted that defective SPI-1 secretion and flagellar phenotypes of the hfq mutant would be rescued by overexpression of HilD and FlhDC, and we proved this to be correct. The combination of epitope-tagging and HTPS of immunoprecipitated RNA detected the expression of many intergenic chromosomal regions of Salmonella. Our approach overcomes the limited availability of high-density microarrays that have impeded expression-based sRNA discovery in microorganisms. We present a generic strategy that is ideal for the systems-level analysis of the post-transcriptional regulons of RNA-binding proteins and for sRNA discovery in a wide range of bacteria.

σE-dependent small RNAs of Salmonella respond to membrane stress by accelerating global omp mRNA decay

The bacterial envelope stress response (ESR) is triggered by the accumulation of misfolded outer membrane proteins (OMPs) upon envelope damage or excessive OMP synthesis, and is mediated by the alternative sigma factor, σE. Activation of the σE pathway causes a rapid downregulation of major omp mRNAs, which prevents further build‐up of unassembled OMPs and liberates the translocation and folding apparatus under conditions that require envelope remodelling. The factors that facilitate the rapid removal of the unusually stable omp mRNAs in the ESR were previously unknown. We report that in Salmonella the ESR relies upon two highly conserved, σE‐controlled small non‐coding RNAs, RybB and MicA. By using a transcriptomic approach and kinetic analyses of target mRNA decay in vivo, RybB was identified as the factor that selectively accelerates the decay of multiple major omp mRNAs upon induction of the ESR, while MicA is proposed to facilitate rapid decay of the single ompA mRNA. In unstressed bacterial cells, the two σE‐dependent small RNAs function within a surveillance loop to maintain envelope homeostasis and to achieve autoregulation of σE.

Quorum sensing signal-response systems in Gram-negative bacteria

Bacteria use quorum sensing to orchestrate gene expression programmes that underlie collective behaviours. Quorum sensing relies on the production, release, detection and group-level response to extracellular signalling molecules, which are called autoinducers. Recent work has discovered new autoinducers in Gram-negative bacteria, shown how these molecules are recognized by cognate receptors, revealed new regulatory components that are embedded in canonical signalling circuits and identified novel regulatory network designs. In this Review we examine how, together, these features of quorum sensing signal–response systems combine to control collective behaviours in Gram-negative bacteria and we discuss the implications for host–microbial associations and antibacterial therapy.

The transcriptional landscape and small RNAs of Salmonella enterica serovar Typhimurium

More than 50 y of research have provided great insight into the physiology, metabolism, and molecular biology of Salmonella enterica serovar Typhimurium (S. Typhimurium), but important gaps in our knowledge remain. It is clear that a precise choreography of gene expression is required for Salmonella infection, but basic genetic information such as the global locations of transcription start sites (TSSs) has been lacking. We combined three RNA-sequencing techniques and two sequencing platforms to generate a robust picture of transcription in S. Typhimurium. Differential RNA sequencing identified 1,873 TSSs on the chromosome of S. Typhimurium SL1344 and 13% of these TSSs initiated antisense transcripts. Unique findings include the TSSs of the virulence regulators phoP, slyA, and invF. Chromatin immunoprecipitation revealed that RNA polymerase was bound to 70% of the TSSs, and two-thirds of these TSSs were associated with σ70 (including phoP, slyA, and invF) from which we identified the −10 and −35 motifs of σ70-dependent S. Typhimurium gene promoters. Overall, we corrected the location of important genes and discovered 18 times more promoters than identified previously. S. Typhimurium expresses 140 small regulatory RNAs (sRNAs) at early stationary phase, including 60 newly identified sRNAs. Almost half of the experimentally verified sRNAs were found to be unique to the Salmonella genus, and <20% were found throughout the Enterobacteriaceae. This description of the transcriptional map of SL1344 advances our understanding of S. Typhimurium, arguably the most important bacterial infection model.

Regulatory RNA in bacterial pathogens.

Bacteria constitute a large and diverse class of infectious agents, causing devastating diseases in humans, animals, and plants. Our understanding of gene expression control, which forms the basis for successful prevention and treatment strategies, has until recently neglected the many roles that regulatory RNAs might have in bacteria. In recent years, several such regulators have been found to facilitate host-microbe interactions and act as key switches between saprophytic and pathogenic lifestyles. This review covers the versatile regulatory RNA mechanisms employed by bacterial pathogens and highlights the dynamic interplay between riboregulation and virulence factor expression.

An atlas of Hfq-bound transcripts reveals 3′ UTRs as a genomic reservoir of regulatory small RNAs

The small RNAs associated with the protein Hfq constitute one of the largest classes of post‐transcriptional regulators known to date. Most previously investigated members of this class are encoded by conserved free‐standing genes. Here, deep sequencing of Hfq‐bound transcripts from multiple stages of growth of Salmonella typhimurium revealed a plethora of new small RNA species from within mRNA loci, including DapZ, which overlaps with the 3′ region of the biosynthetic gene, dapB. Synthesis of the DapZ small RNA is independent of DapB protein synthesis, and is controlled by HilD, the master regulator of Salmonella invasion genes. DapZ carries a short G/U‐rich domain similar to that of the globally acting GcvB small RNA, and uses GcvB‐like seed pairing to repress translation of the major ABC transporters, DppA and OppA. This exemplifies double functional output from an mRNA locus by the production of both a protein and an Hfq‐dependent trans‐acting RNA. Our atlas of Hfq targets suggests that the 3′ regions of mRNA genes constitute a rich reservoir that provides the Hfq network with new regulatory small RNAs.

Coding sequence targeting by MicC RNA reveals bacterial mRNA silencing downstream of translational initiation

Bacterial small noncoding RNAs (sRNAs) generally recognize target mRNAs in the 5′ region to prevent 30S ribosomes from initiating translation. It was thought that the mRNA coding sequence (CDS) was refractory to sRNA-mediated repression, because elongating 70S ribosomes have an efficient RNA helicase activity that prevents stable target pairing. We report that the Hfq-associated MicC sRNA silences Salmonella typhimurium ompD mRNA via a ≤12-bp RNA duplex within the CDS (codons 23–26) that is essential and sufficient for repression. MicC does not inhibit translational initiation at this downstream position but instead acts by accelerating RNase E–dependent ompD mRNA decay. We propose an alternative gene-silencing pathway within bacterial CDS wherein sRNAs repress targets by endonucleolytic mRNA destabilization rather than by the prototypical inhibition of translational initiation. The discovery of CDS targeting markedly expands the sequence space for sRNA target predictions in bacteria.

Specific and pleiotropic patterns of mRNA regulation by ArcZ, a conserved, Hfq-dependent small RNA.

The small RNA, ArcZ (previously RyhA/SraH), was discovered in several genome‐wide screens in Escherichia coli and Salmonella. Its high degree of genomic conservation, its frequent recovery by shotgun sequencing, and its association with the RNA chaperone, Hfq, identified ArcZ as an abundant enterobacterial ‘core’ small RNA, yet its function remained unknown. Here, we report that ArcZ acts as a post‐transcriptional regulator in Salmonella, repressing the mRNAs of the widely distributed sdaCB (serine uptake) and tpx (oxidative stress) genes, and of STM3216, a horizontally acquired methyl‐accepting chemotaxis protein (MCP). Both sdaCB and STM3216 are regulated by sequestration of the ribosome binding site. In contrast, the tpx mRNA is targeted in the coding sequence (CDS), arguing that CDS targeting is more common than appreciated. Transcriptomic analysis of an arcZ deletion strain further argued for the existence of a distinct set of Salmonella loci specifically regulated by ArcZ. In contrast, increased expression of the sRNA altered the steady‐state levels of > 16% (> 750) of all Salmonella mRNAs, and rendered the bacteria non‐motile. Deep sequencing detected a dramatically changed profile of Hfq‐bound sRNAs and mRNAs, suggesting that the unprecedented pleiotropic effects by a single sRNA might in part be caused by altered post‐transcriptional regulation.

Pervasive post-transcriptional control of genes involved in amino acid metabolism by the Hfq-dependent GcvB small RNA

GcvB is one of the most highly conserved Hfq‐associated small RNAs in Gram‐negative bacteria and was previously reported to repress several ABC transporters for amino acids. To determine the full extent of GcvB‐mediated regulation in Salmonella, we combined a genome‐wide experimental approach with biocomputational target prediction. Comparative pulse expression of wild‐type versus mutant sRNA variants revealed that GcvB governs a large post‐transcriptional regulon, impacting ∼1% of all Salmonella genes via its conserved G/U‐rich domain R1. Complementary predictions of C/A‐rich binding sites in mRNAs and gfp reporter fusion experiments increased the number of validated GcvB targets to more than 20, and doubled the number of regulated amino acid transporters. Unlike the previously described targeting via the single R1 domain, GcvB represses the glycine transporter CycA by exceptionally redundant base‐pairing. This novel ability of GcvB is focused upon the one target that could feedback‐regulate the glycine‐responsive synthesis of GcvB. Several newly discovered mRNA targets involved in amino acid metabolism, including the global regulator Lrp, question the previous assumption that GcvB simply acts to limit unnecessary amino acid uptake. Rather, GcvB rewires primary transcriptional control circuits and seems to act as a distinct regulatory node in amino acid metabolism.

Systematic deletion of Salmonella small RNA genes identifies CyaR, a conserved CRP-dependent riboregulator of OmpX synthesis.

Post‐transcriptional repression of porin synthesis has emerged as a major function of Hfq‐dependent, small non‐coding RNAs (sRNAs). Many enterobacteria express OmpX‐like porins, a family of outer membrane proteins whose physiological roles and structural properties have been studied intensively. While regulatory sRNAs have been identified for most major and many minor porins of Salmonella and Escherichia coli, a post‐transcriptional regulator of OmpX levels has never been found. Here, we have taken a ‘reverse target search’ approach by systematic inactivation of Salmonella sRNA genes, and screening 35 sRNA deletion strains for effects on OmpX synthesis. We have identified the Hfq‐dependent CyaR (formerly RyeE) sRNA as an ompX repressor. Global transcriptomic profiling following induction of CyaR expression suggests that ompX mRNA is the primary target of this sRNA under standard growth conditions. The results of phylogenetic and mutational analyses suggest that a conserved RNA hairpin of CyaR, featuring a C‐rich apical loop, acts to sequester the Shine–Dalgarno sequence of ompX mRNA and to inhibit translational initiation. We have also discovered that cyaR expression is tightly controlled by the cyclic AMP receptor protein, CRP. This represents a new link between porin repression and nutrient availability that is likely to be widely conserved among enterobacteria.