Project description:Small RNAs use a diversity of well-characterized mechanisms to repress mRNAs, but how they activate gene expression at the mRNA level remains not well understood. The predominant activation mechanism of Hfq-associated small RNAs has been translational control whereby base-pairing with the target prevents the formation of an intrinsic inhibitory structure in the mRNA and promotes translation initiation. Here, we report a translation-independent mechanism whereby the small RNA RydC selectively activates the longer of two isoforms of cfa mRNA (encoding cyclopropane fatty acid synthase) in Salmonella enterica. Target activation is achieved through seed pairing of the pseudoknot-exposed, conserved 5' end of RydC to an upstream region of the cfa mRNA. The seed pairing stabilizes the messenger, likely by interfering directly with RNase E-mediated decay in the 5' untranslated region. Intriguingly, this activation mechanism is fully generic in that it can be reprogrammed to other seed pairing small RNAs, suggesting this mechanism may be utilised in the design of RNA-controlled synthetic circuits. Physiologically, RydC is the first small RNA known to regulate membrane stability. To determine the targets of the small regulatory RNA RydC in S. Typhimurium, we looked at the effect of a short pulse of RydC over-expression on the Salmonella transcriptome. To achieve over-expression, the rydC gene was cloned in the pBAD plasmid and induced with 0.2% L-arabinose for 10 min. We then extracted the total RNA for transcriptional profiling. A strain carrying the pBAD plasmid w/o insert was used as negative control (also induced by L-arabinose). 2 biological replicates were performed. This sRNA target identification strategy has been described in Papenfort et al; Molecular Microbiology (2006) 62(6), 1674M-bM-^@M-^S1688.

Project description:SgrS RNA is a model for the large class of Hfq-associated small RNAs that act to post-transcriptionally regulate bacterial mRNAs. The function of SgrS is well-characterized in non-pathogenic Escherichia coli where it was originally shown to counteract glucose-phosphate stress by acting as a repressor of ptsG mRNA which encodes the major glucose transporter. We have discovered new SgrS targets in Salmonella Typhimurium, a pathogen related to E. coli, which recently acquired a quarter of all genes by horizontal gene transfer. We demonstrate that the conserved short seed region of SgrS that recognizes ptsG was recruited to target the Salmonella-specific sopD mRNA of a secreted virulence protein. The SgrS-sopD interaction is exceptionally selective; we find that sopD2 mRNA whose gene arose from sopD duplication during Salmonella evolution, is deaf to SgrS owing to a non-productive G:U pair in the potential SgrS-sopD2 RNA duplex versus G:C in SgrS-sopD. In other words, SgrS discriminates the two virulence factor mRNAs at the level of a single hydrogen bond. Our study suggests that bacterial pathogens employ their large suites of conserved Hfq-associated regulators to integrate horizontally acquired genes into existing post-transcriptional networks, just as conserved transcription factors are recruited to tame foreign genes at the DNA level. The results graphically illustrate the importance of the seed regions of bacterial small RNAs to select new targets with high fidelity, and argue that target predictions must consider all-or-none decisions by individual seed nucleotides. To determine the targets of the small regulatory RNA SgrS in S. Typhimurium, we looked at the effect of a short pulse of SgrS over-expression on the Salmonella transcriptome. To achieve over-expression, the sgrS gene was cloned in the pBAD plasmid and induced with 0.2% L-arabinose for 10 min. We then extracted the total RNA for transcriptional profiling. A strain carrying the pBAD plasmid w/o insert was used as negative control. 3 biological replicates were performed. This sRNA target identification strategy has been described in Papenfort et al; Molecular Microbiology (2006) 62(6), 1674–1688.

Project description: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 of unknown function. 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 degree of pleiotropic regulation might in part be caused by titration of Hfq binding by ArcZ. This study used three different approaches to identify target genes and biological role of the small RNA ArcZ in Salmonella Typhimurium. Transcriptomic analysis of ArcZ overexpression: Strain JVS-0082 (ΔarcZ) was transformed with plasmids pJV300 (control) and pKP48-1 (parcZ), and grown in liquid culture (LB broth) inoculated 1:100 from an overnight culture for 6h after cells had reached an OD600=2.0 to attain late stationary phase. Transcriptomic analysis of arcZ mutant strain: Strains JVS-007 (WT) and JVS-0082 (ΔarcZ) were transformed with plasmid pJV300 (control) and grown in liquid culture (LB broth) inoculated 1:100 from an overnight culture for 6h after cells had reached an OD600=2.0 to attain late stationary phase. Transcriptional effects of ArcZ pulse expression: Strain SL1344 was transformed with plasmids pKP8-35 (pBAD-control) and pKP4-13 (pBAD-ArcZ), and grown in liquid culture (LB broth) inoculated 1:100 from an overnight culture to an OD600 of 1.5. Expression of the insert was induced with L-arabinose (0.2% final concentrations) for 10 min. Three biological replicates were performed for each strain/condition.

Project description:It is well established that small noncoding RNAs (sRNAs) of bacteria recognize the 5â?? regions of target mRNAs, generally at the ribosome binding site. Until now, the translated coding sequence (CDS) of mRNA appeared to be refractory to sRNA interactions. We have discovered that Salmonella MicC RNA silences ompD mRNA by targeting the CDS, at codons 23-26. Analyses of MicC-ompD RNA complexes in vitro, and of chimeric sRNAs and ompD reporter fusions in vivo, show that interactions are confined to the CDS, and that a â?¤12 bp RNA duplex involving the conserved 5â?? end of MicC is essential and sufficient for target repression. MicC cannot act as a translational repressor at this downstream position being unable to inhibit 30S or 70S ribosome activity on the ompD mRNA. Instead, MicC accelerates RNase E-dependent ompD mRNA decay. The degradosome contributes to target destabilization, and facilitates the efficient degradation of processed ompD mRNA. Our data show that bacterial gene silencing by sRNAs can take place downstream of the translational initiation site by triggering irreversible mRNA decay. This ability of sRNAs allows targets in the CDS to be silenced without interference from the strong RNA helicase activity of elongating ribosomes. To determine the targets of the small regulatory RNA MicC in S. Typhimurium, we looked at the effect of a short pulse of MicC over-expression on the Salmonella transcriptome. To achieve over-expression, the micC gene was cloned in the pBAD plasmid and induced with 0.2% L-arabinose for 10 min. We then extracted the total RNA for transcriptional profiling. A strain carrying the pBAD plasmid w/o insert was used as negative control. 3 biological replicates were performed. This sRNA target identification strategy has been described in Papenfort et al; Molecular Microbiology (2006) 62(6), 1674â??1688.

Project description:The control of amino acid synthesis and transport in bacteria has been well-investigated at the transcriptional level. The discovery of a small Hfq-dependent regulatory RNA, GcvB, added another layer of gene expression control at the post-transcriptional level. GcvB RNA has been shown to directly regulate multiple ABC transporters for amino acids in E. coli and Salmonella using a highly conserved G/U-rich domain, R1. To identify additional GcvB targets, we have combined a sRNA pulse-expression and microarray analysis of whole transcriptome changes with biocomputational target searches for C/A- rich target sites in Salmonella. Moreover, we have included GcvB mutant RNAs in our microarray approach providing a new target search approach by inactivating conserved domains or target interaction sites. This dual approach revealed further amino acid transporters and, in addition, genes involved in amino acid metabolism as consensus R1-dependent GcvB targets. Moreover, GcvB RNA seems to bind with at least two binding sites to an R1-independent target, the glycine transporter cycA. Using GFP reporter gene fusions we have now validated 21 GcvB targets which is best to our knowledge with ~1% of all Salmonella protein coding genes, the largest bacterial sRNA-controlled regulon. Intriguingly, GcvB rewires many primary control circuits and, thus, constitutes an important metabolic knot. To predict direct GcvB targets with better confidence, we expanded the sRNA pulse-expression approach to assay effects of several versions of GcvB sRNA. We cloned GcvB wild-type and mutants RNAs deleted for the conserved regions R1 or R2 (Fig. 1A) under control of an arabinose-inducible PBAD promoter, yielding plasmid pBAD-GcvB (pKP1-1), pBAD-GcvB delta R1 (pKP2-6) and pBAD-GcvB delta R2 (pKP30-1). For confirmation of inducible expression, Salmonella wild-type carrying pBAD control vector (pKP8-35), and Salmonella ΔgcvB carrying either control vector (Ctr) or the above GcvB expression plasmids were grown to mid-exponential phase (OD600 of 1) and treated with L-arabinose for up to 15 min. We used whole-genome S. typhimurium microarrays to determine relative mRNA expression changes at 10 min of induction, comparing the mRNA profiles of the pBAD-GcvB, pBAD-GcvB delta R1 or pBAD-GcvB delta R2 strains to that of the delta gcvB deletion mutant strain carrying the control vector. Microarrays used in this study were produced by in-situ synthesis as 8x15k multipack format from Agilent Technologies. Each microarray comprises 13268 60-mer S. typhimurium strain SL1344 specific oligonucleotides supplemented with 319 60-mer S. enterica subsp. serovar Typhimurium 14028S specific oligonucleotides, 360 60-mer S. typhimurium LT2 specific oligonucleotides and 360 60-mer oligonucleotides specific for 149 Salmonella sRNAs. The experimental design involves the use of Salmonella enterica serovar Typhimurium genomic DNA as the co-hybridized control for one channel on all microarrays. Two independent biological eperiments were analyzed.

Project description:To screen the potential targets of Salmonella 3’ UTR derived sRNA FadZ, we compared global mRNA profiles in FadZ-deficient and -pulse expressed strains. The 40-nt FadZ sequences was cloned onto a plasmid downstream of the pBAD promoter and expression was induced by L-arabinose for 10-min in LB broth. Transcriptomic profiles were compared with strain carrying the empty control plasmid.

Project description:To determine the targets of the small regulatory RNA DapZ in S. Typhimurium, we looked at the effect of a short pulse of DapZ over-expression on the Salmonella transcriptome, as well as a DapZ variant that lacks the GcvB-like R1 region. To achieve over-expression, the wild-type DapZ and its variant were cloned in the pBAD plasmid and induced with 0.2% L-arabinose for 10 min. We then extracted the total RNA for transcriptional profiling. A strain carrying the pBAD plasmid w/o insert was used as negative control (also induced by L-arabinose). 2 biological replicates were performed. This sRNA target identification strategy has been described in Papenfort et al; Molecular Microbiology (2006) 62(6), 1674-1688.

Project description:MicF is a textbook example of a small regulatory RNA (sRNA) that acts on a trans-encoded target mRNA through imperfect base paring. The discovery of MicF as a post-transcriptional repressor of the major Escherichia coli porin OmpF established the paradigm for a meanwhile common mechanism of translational inhibition, through antisense sequestration of a ribosome binding site. However, whether MicF regulates additional genes has remained unknown for almost three decades. Here, we have harnessed the novel superfolder variant of GFP for reporter-gene fusions to validate newly predicted targets of MicF in Salmonella. We show that the conserved 5’ end of MicF acts by seed pairing to repress the mRNAs of global transcriptional regulator Lrp, periplasmic protein YahO, and lipid A-modifying enzyme LpxR. Whilst MicF binds lrp and yahO in the 5’ UTR, it targets lpxR at both the ribosome binding site and deep within the coding sequence. Repression in the coding sequence of lpxR may be achieved by decreasing mRNA stability through exacerbating the use of a native RNase E site proximal to the short MicF-lpxR duplex. Altogether, this study assigns the classic MicF sRNA to the growing class of Hfqassociated regulators that use diverse mechanisms to impact multiple loci.

Project description:RyhB is a non-coding RNA regulated by the Fur repressor. It has previously been shown to cause the rapid degradation of a number of mRNAs that encode proteins that utilize iron. Here we examine the effect of ectopic RyhB production on global gene expression by microarray analysis. Many of the previously identified targets were found, as well as other mRNAs encoding iron-binding proteins, bringing the total number of regulated operons to at least 18, encoding 56 genes. The two major operons involved in Fe-S cluster assembly showed different behavior; the isc operon appears to be a direct target of RyhB action, while the suf operon does not. This is consistent with previous findings suggesting that the suf genes but not the isc genes are important for Fe-S cluster synthesis under iron-limiting conditions, presumably for essential iron-binding proteins. In addition, we observed repression of Fur-regulated genes upon RyhB expression, interpreted as due to intracellular iron-sparing resulting from reduced synthesis of iron-binding proteins. Our results demonstrate the broad effects of a single non-coding RNA on iron homeostasis. Experiment Overall Design: Derivatives of MG1655 carrying either pBAD-ryhB or the control vector pNM12 were used in all experiments. Experiment Overall Design: The strains used contain the (delta)ara714 allele to prevent catabolism of arabinose and the (delta)ryhB::cat allele to restrict RyhB expression to the inducible pBAD-ryhB vector. Experiment Overall Design: Overnight bacterial cultures were incubated in LB media with ampicillin at a final concentration of 50 ug/mL at 37oC and diluted 1000-fold into 50 mL of fresh LB-ampicillin media at 37oC with agitation. To induce RyhB expression, cultures carrying the pBAD-ryhB construct were grown to an O.D.600 of 0.5 and arabinose was added to the culture at a final concentration of 0.1%. In some experiments, 50 uM FeSO4 was added to the new culture after dilution from overnight culture. Total RNA was extracted from cells at the indicated time using the hot phenol procedure.

Project description:To compare the transcriptional profiling of a FimZ-expressing strain or non-expressing strain in E. coli under stationary phase. For overexpression of fimZ gene was cloned into pBAD33 plasmid under control of the arabinose-inducible PBAD promoter, which was induced by addition of 0.2% arabinose. Goal was to determine the FimZ regulon in E. coli. Biological replicates: 2 replicates.