Tony Romeo

Global regulation by the small RNA‐binding protein CsrA and the non‐coding RNA molecule CsrB

Csr (carbon storage regulator) is a recently discovered global regulatory system that controls bacterial gene expression post‐transcriptionally. Its effector is a small RNA‐binding protein referred to as CsrA or, in phytopathogenic Erwinia species, RsmA (repressor of stationary phase metabolites). Numerous genes whose expression occurs in the stationary phase of growth are repressed by csrA/rsmA, and csrA activates certain exponential‐phase metabolic pathways. Glycogen synthesis and catabolism, gluconeogenesis, glycolysis, motility, cell surface properties and adherence are modulated by csrA in Escherichia coli, while the production of several secreted virulence factors, the plant hypersensitive response elicitor HrpNEcc and, potentially, other secondary metabolites are regulated by rsmA in Erwinia carotovora. CsrA represses glycogen synthesis by binding to and destabilizing glgCAP mRNA and is hypothesized to repress other genes by a similar mechanism. The second component of the Csr system is CsrB (AepH in Erwinia species), a non‐coding RNA molecule that forms a large globular ribonucleoprotein complex with approximately 18 CsrA subunits and antagonizes the effects of CsrA in vivoHighly repeated sequence elements found within the loops of predicted stem–loops and other single‐stranded segments of CsrB RNA may facilitate CsrA binding. Current information supports a model in which CsrA exists in an equilibrium between CsrB and CsrA‐regulated mRNAs, which predicts that CsrB levels may be a key determinant of CsrA activity in the cell. The presence of csrA homologues in phylogenetically diverse species further suggests that this novel kind of regulatory system is likely to play a broad role in modulating eubacterial gene expression.

The RNA Molecule CsrB Binds to the Global Regulatory Protein CsrA and Antagonizes Its Activity in Escherichia coli

The RNA-binding protein CsrA (carbon storage regulator) is a new kind of global regulator, which facilitates specific mRNA decay. A recombinant CsrA protein containing a metal-binding affinity tag (CsrA-H6) was purified to homogeneity and authenticated by N-terminal sequencing, matrix-assisted laser desorption/ionization time of flight mass spectrometry, and other studies. This protein was entirely contained within a globular complex of approximately 18 CsrA-H6 subunits and a single ∼350-nucleotide RNA, CsrB. cDNA cloning and nucleotide sequencing revealed that thecsrB gene is located downstream from syd in the 64-min region of the Escherichia coli K-12 genome and contains no open reading frames. The purified CsrA-CsrB ribonucleoprotein complex was active in regulating glg(glycogen biosynthesis) gene expression in vitro, as was the RNA-free form of the CsrA protein. Overexpression ofcsrB enhanced glycogen accumulation in E. coli, a stationary phase process that is repressed by CsrA. Thus, CsrB RNA is a second component of the Csr system, which binds to CsrA and antagonizes its effects on gene expression. A model for regulatory interactions in Csr is presented, which also explains previous observations on the homologous system in Erwinia carotovora. A highly repeated nucleotide sequence located within predicted stem-loops and other single-stranded regions of CsrB, CAGGA(U/A/C)G, is a plausible CsrA-binding element.

A novel sRNA component of the carbon storage regulatory system of Escherichia coli.

Small untranslated RNAs (sRNAs) perform a variety of important functions in bacteria. The 245 nucleotide sRNA of Escherichia coli, CsrC, was discovered using a genetic screen for factors that regulate glycogen biosynthesis. CsrC RNA binds multiple copies of CsrA, a protein that post‐transcriptionally regulates central carbon flux, biofilm formation and motility in E. coli. CsrC antagonizes the regulatory effects of CsrA, presumably by sequestering this protein. The discovery of CsrC is intriguing, in that a similar sRNA, CsrB, performs essentially the same function. Both sRNAs possess similar imperfect repeat sequences (18 in CsrB, nine in CsrC), primarily localized in the loops of predicted hairpins, which may serve as CsrA binding elements. Transcription of csrC increases as the culture approaches the stationary phase of growth and is indirectly activated by CsrA via the response regulator UvrY. Because CsrB and CsrC antagonize CsrA activity and depend on CsrA for their synthesis, a csrB null mutation causes a modest compensatory increase in CsrC levels and vice versa. Homologues of csrC are apparent in several Enterobacteriaceae. The regulatory and evolutionary implications of these findings are discussed.

CsrA post‐transcriptionally represses pgaABCD, responsible for synthesis of a biofilm polysaccharide adhesin of Escherichia coli

The 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, required for the synthesis of the polysaccharide adhesin PGA (poly‐β‐1,6‐N‐acetyl‐d‐glucosamine) of Escherichia coli, is the key target of biofilm regulation by CsrA. csrA disruption causes an approximately threefold increase in PGA production and an approximately sevenfold increase in expression of a pgaA′–′lacZ translational fusion. A ΔcsrBΔcsrC mutant exhibits a modest decrease in pgaA′–′lacZ expression, while the response regulator UvrY, a transcriptional activator of csrB and csrC, stimulates this expression. Biofilm formation is not regulated by csrA, csrB or uvrY in a ΔpgaC mutant, which cannot synthesize PGA. Gel mobility shift and toeprint analyses demonstrate that CsrA binds cooperatively to pgaA mRNA and competes with 30S ribosome subunit for binding. CsrA destabilizes the pgaA transcript in vivo. RNA footprinting and boundary analyses identify six apparent CsrA binding sites in the pgaA mRNA leader, the most extensive arrangement of such sites in any mRNA examined to date. Substitution mutations in CsrA binding sites overlapping the Shine–Dalgarno sequence and initiation codon partially relieve repression by CsrA. These studies define the crucial mechanisms, though not the only means, by which the Csr system influences biofilm formation.

CsrA regulates glycogen biosynthesis by preventing translation of glgC in Escherichia coli

The carbon storage regulatory system of Escherichia coli controls the expression of genes involved in carbohydrate metabolism and cell motility. CsrA binding to glgCAP transcripts inhibits glycogen metabolism by promoting glgCAP mRNA decay. CsrB RNA functions as an antagonist of CsrA by sequestering this protein and preventing its action. In this paper, we elucidate further the mechanism of CsrA‐mediated glgC regulation. Results from gel shift assays demonstrate that several molecules of CsrA can bind to each glgC transcript. RNA footprinting studies indicate that CsrA binds to the glgCAP leader transcript at two positions. One of these sites overlaps the glgC Shine–Dalgarno sequence, whereas the other CsrA target is located further upstream in an RNA hairpin. Results from toeprint and cell‐free translation experiments indicate that bound CsrA prevents ribosome binding to the glgC Shine–Dalgarno sequence and that this reduces GlgC synthesis. The effect of two deletions in the upstream binding site was examined. Both of these deletions reduced, but did not eliminate, CsrA binding in vitro and CsrA‐dependent regulation in vivo. Our findings establish that bound CsrA inhibits initiation of glgC translation, thereby reducing glycogen biosynthesis. This inhibition of translation probably contributes to destabilization of the glgC transcript that was observed previously.

CsrA Regulates Translation of the Escherichia coli Carbon Starvation Gene, cstA, by Blocking Ribosome Access to the cstA Transcript

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 Esigma(70). We investigated the influence of sigma(S) on cstA expression and found that a sigma(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 Shine-Dalgarno sequence, as predicted. These results establish that CsrA regulates translation of cstA by sterically interfering with ribosome binding.

CsrA Inhibits Translation Initiation of Escherichia coli hfq by Binding to a Single Site Overlapping the Shine-Dalgarno Sequence

Csr (carbon storage regulation) of Escherichia coli is a global regulatory system that consists of CsrA, a homodimeric RNA binding protein, two noncoding small RNAs (sRNAs; CsrB and CsrC) that function as CsrA antagonists by sequestering this protein, and CsrD, a specificity factor that targets CsrB and CsrC for degradation by RNase E. CsrA inhibits translation initiation of glgC, cstA, and pgaA by binding to their leader transcripts and preventing ribosome binding. Translation inhibition is thought to contribute to the observed mRNA destabilization. Each of the previously known target transcripts contains multiple CsrA binding sites. A position-specific weight matrix search program was developed using known CsrA binding sites in mRNA. This search tool identified a potential CsrA binding site that overlaps the Shine-Dalgarno sequence of hfq, a gene that encodes an RNA chaperone that mediates sRNA-mRNA interactions. This putative CsrA binding site matched the SELEX-derived binding site consensus sequence in 8 out of 12 positions. Results from gel mobility shift and footprint assays demonstrated that CsrA binds specifically to this site in the hfq leader transcript. Toeprint and cell-free translation results indicated that bound CsrA inhibits Hfq synthesis by competitively blocking ribosome binding. Disruption of csrA caused elevated expression of an hfq-lacZ translational fusion, while overexpression of csrA inhibited expression of this fusion. We also found that hfq mRNA is stabilized upon entry into stationary-phase growth by a CsrA-independent mechanism. The interaction of CsrA with hfq mRNA is the first example of a CsrA-regulated gene that contains only one CsrA binding site.

Comprehensive Alanine-scanning Mutagenesis of Escherichia coli CsrA Defines Two Subdomains of Critical Functional Importance

The RNA-binding protein CsrA (carbon storage regulator) of Escherichia coli is a global regulator of gene expression and is representative of the CsrA/RsmA family of bacterial proteins. These proteins act by regulating mRNA translation and stability and are antagonized by binding to small noncoding RNAs. Although the RNA target sequence and structure for CsrA binding have been well defined, little information exists concerning the protein requirements for RNA recognition. The three-dimensional structures of three CsrA/RsmA proteins were recently solved, revealing a novel protein fold consisting of two interdigitated monomers. Here, we performed comprehensive alanine-scanning mutagenesis on csrA of E. coli and tested the 58 resulting mutants for regulation of glycogen accumulation, motility, and biofilm formation. Quantitative effects of these mutations on expression of glgCA`-lacZ, flhDC `-lacZ, and pgaA`-lacZ translational fusions were also examined, and eight of the mutant proteins were purified and tested for RNA binding. These studies identified two regions of the amino acid sequence that were critical for regulation and RNA binding, located within the first (β1, residues 2-7) and containing the last (β5, residues 40-47) β-strands of CsrA. The β1 and β5 strands of opposite monomers lie adjacent and parallel to each other in the three-dimensional structure of this protein. Given the symmetry of the CsrA dimer, these findings imply that two distinct RNA binding surfaces or functional subdomains lie on opposite sides of the protein.

CsrA of Bacillus subtilis regulates translation initiation of the gene encoding the flagellin protein (hag) by blocking ribosome binding

The global regulatory Csr (carbon storage regulator) and the homologous Rsm (repressor of secondary metabolites) systems of Gram‐negative bacteria typically consist of an RNA‐binding protein (CsrA/RsmA) and at least one sRNA that functions as a CsrA antagonist. CsrA modulates gene expression post‐transcriptionally by regulating translation initiation and/or mRNA stability of target transcripts. While Csr has been extensively studied in Gram‐negative bacteria, until now Csr has not been characterized in any Gram‐positive organism. csrA of Bacillus subtilis is the last gene of a flagellum biosynthetic operon. In addition to the previously identified σD‐dependent promoter that controls expression of the entire operon, a σA‐dependent promoter was identified that temporally controls expression of the last two genes of the operon (fliW‐csrA); expression peaks 1u2003h after cell growth deviates from exponential phase. hag, the gene encoding flagellin, was identified as a CsrA‐regulated gene. CsrA was found to repress hag′–′lacZ expression, while overexpression of csrA reduces cell motility. In vitro binding studies identified two CsrA binding sites in the hag leader transcript, one of which overlaps the hag Shine–Dalgarno sequence. Toeprint and cell‐free translation studies demonstrate that bound CsrA prevents ribosome binding to the hag transcript, thereby inhibiting translation initiation and Hag synthesis.

Disruption of a Global Regulatory Gene to Enhance Central Carbon Flux into Phenylalanine Biosynthesis in Escherichia coli

Genetic engineering of microbes for commercial metabolite production traditionally has sought to alter the levels and/or intrinsic activities of key enzymes in relevant biosynthetic pathway(s). Microorganisms exploit similar strategies for flux control, but also coordinate flux through sets of related pathways by using global regulatory circuits. We have engineered a global regulatory system of Escherichia coli, Csr (carbon storage regulator), to increase precursor for aromatic amino acid biosynthesis. Disruption of csrA increases gluconeogenesis, decreases glycolysis, and thus elevates phosphoenolpyruvate, a limiting precursor of aromatics. A strain in which the aromatic (shikimate) pathway had been optimized produced twofold more phenylalanine when csrA was disrupted. Overexpression of tktA (transketolase) to increase the other precursor, erythrose-4-phosphate, yielded ∼1.4-fold enhancement, while both changes were additive. These effects of csrA were not mediated by increasing the regulatory enzymes of phenylalanine biosynthesis. This study introduces the concept of “global metabolic engineering” for second-generation strain improvement.