Project description:Gene regulation at the post-transcriptional level is prevalent in all domains of life. In bacteria, ProQ-like proteins have emerged as important RNA chaperones facilitating RNA stability and RNA duplex formation. In the major human pathogen V. cholerae, post-transcriptional gene regulation is key for virulence, biofilm formation, and antibiotic resistance, yet the role of ProQ has not been studied. Here, we show that ProQ interacts with hundreds of transcripts in V. cholerae, including the highly abundant FlaX small RNA (sRNA). Global analyses of RNA duplex formation using RIL-Seq (RNA interaction by ligation and sequencing) revealed a vast network of ProQ-assisted interactions and identified a role for FlaX in motility regulation. Specifically, FlaX base-pairs with multiple sites on the flaB flagellin mRNA, preventing 30S ribosome binding and translation initiation. V. cholerae cells lacking flaX display impaired motility gene expression, altered flagella composition, and reduced swimming in liquid environments. Our results provide a global view on ProQ-mediated RNA duplex formation and pinpoint the mechanistic and phenotypic consequences associated with ProQ-associated sRNAs in V. cholerae.

Project description:Gene regulation at the post-transcriptional level is prevalent in all domains of life. In bacteria, ProQ-like proteins have emerged as important RNA chaperones facilitating RNA stability and RNA duplex formation. In the major human pathogen V. cholerae, post-transcriptional gene regulation is key for virulence, biofilm formation, and antibiotic resistance, yet the role of ProQ has not been studied. Here, we show that ProQ interacts with hundreds of transcripts in V. cholerae, including the highly abundant FlaX small RNA (sRNA). Global analyses of RNA duplex formation using RIL-Seq (RNA interaction by ligation and sequencing) revealed a vast network of ProQ-assisted interactions and identified a role for FlaX in motility regulation. Specifically, FlaX base-pairs with multiple sites on the flaB flagellin mRNA, preventing 30S ribosome binding and translation initiation. V. cholerae cells lacking flaX display impaired motility gene expression, altered flagella composition, and reduced swimming in liquid environments. Our results provide a global view on ProQ-mediated RNA duplex formation and pinpoint the mechanistic and phenotypic consequences associated with ProQ-associated sRNAs in V. cholerae.

Project description:RIPseq of proQ-3XFLAG in V. cholerae

Project description:RILseq of proQ-3XFLAG in V. cholerae

Project description:Spirochetes are long, thin, motile, helical or flat wave bacteria that are unique among the prokaryotes by having flagella or axial filaments confined to an internal periplasmic space. These flagella are complex organelles that can play major roles in bacterial pathogenicity and are used as propellers allowing bacteria to move through liquids, viscous environments or along surfaces. While most bacteria species use transcriptional regulatory cascades to regulate the synthesis and assembly of their flagella, spirochetes employ an unusual post-transcriptional mechanism. Using next generation sequencing, we characterized a natural mutant of the relapsing fever spirochete Borrelia hermsii lacking the flagellar export apparatus protein FliH. The mutant was non-motile, uncoiled and straight compared to the wild-type spirochetes. The B. hermsii fliH mutant produced only a residual amount of the major flagellin protein FlaB, which was correlated with a reduced number of periplasmic flagella. The amounts of flaB transcript were comparable in the fliH mutant and the wild-type strain. The synthesis of FlaB, the motility and the infectivity of the fliH mutant were rescued by trans-complementation. This report reveals a new function for FliH, and we propose that this regulator of the flagellar export apparatus influences the post-transcriptional processing of the flagella, motility and virulence of the relapsing fever spirochete Borrelia hermsii. Spirochetes are bacteria characterized in part by rotating periplasmic flagella that impart their flat-wave morphology and motility. While other bacteria rely on a transcriptional cascade to regulate the expression of motility genes, spirochetes employ posttranscriptional mechanism(s) that are only partially known. In the present study, we characterize a non-motile mutant of the relapsing fever spirochete Borrelia hermsii that was straight, non-motile and deficient in flagella. We used next generation DNA sequencing of the mutant’s genome, which when compared to the wild-type genome identified a 142 bp deletion in the chromosomal gene encoding the flagellar export apparatus protein FliH. Immunoblot and transcriptome analyses showed that the mutant phenotype was linked to the posttranscriptional deficiency in the synthesis of the major flagellar filament core protein FlaB. The turnover of the residual pool of FlaB produced by the fliH mutant was comparable to the wild-type spirochete while the amount of FlaA was similar to the wild-type level. The non-motile mutant was not infectious in mice and its inoculation did not induce an antibody response. Trans-complementation of the mutant with an intact fliH gene restored the synthesis of FlaB, a normal morphology, motility and infectivity in mice. Therefore, we propose that the flagellar export apparatus protein regulates motility of B. hermsii at the posttranscriptional level by influencing the synthesis of FlaB. Borrelia hermsii wild type vs. motility mutant

Project description:FinO-domain proteins such as ProQ of the model pathogen Salmonella enterica have emerged as a new class of major RNA-binding proteins in bacteria. ProQ has been shown to target hundreds of transcripts including mRNAs from many virulence regions but its role, if any, in bacterial pathogenesis has not been studied. Here, using a Dual RNA-seq approach to profile ProQ-dependent gene expression changes as Salmonella infects human cells, we reveal dysregulation of bacterial motility, chemotaxis and virulence genes which is accompanied by altered mitogen-activated protein kinase signaling in the host. Comparison with Hfq, Salmonella’s other major RNA chaperone, reinforces the notion that these two global RNA binding proteins work in parallel to ensure full virulence. Of newly discovered infection-associated ProQ-bound small noncoding RNAs, we show that STnc540 represses a virulence-related magnesium transporter mRNA in a ProQ-dependent manner. Together, this comprehensive study uncovers the relevance of ProQ for Salmonella infection and highlights the importance of RNA-binding proteins in regulating bacterial virulence programs.

Project description:FinO-domain proteins such as ProQ of the model pathogen Salmonella enterica have emerged as a new class of major RNA-binding proteins in bacteria. ProQ has been shown to target hundreds of transcripts including mRNAs from many virulence regions but its role, if any, in bacterial pathogenesis has not been studied. Here, using a Dual RNA-seq approach to profile ProQ-dependent gene expression changes as Salmonella infects human cells, we reveal dysregulation of bacterial motility, chemotaxis and virulence genes which is accompanied by altered mitogen-activated protein kinase signaling in the host. Comparison with Hfq, Salmonella’s other major RNA chaperone, reinforces the notion that these two global RNA binding proteins work in parallel to ensure full virulence. Of newly discovered infection-associated ProQ-bound small noncoding RNAs, we show that STnc540 represses a virulence-related magnesium transporter mRNA in a ProQ-dependent manner. Together, this comprehensive study uncovers the relevance of ProQ for Salmonella infection and highlights the importance of RNA-binding proteins in regulating bacterial virulence programs.

Project description:FinO-domain proteins such as ProQ of the model pathogen Salmonella enterica have emerged as a new class of major RNA-binding proteins in bacteria. ProQ has been shown to target hundreds of transcripts including mRNAs from many virulence regions but its role, if any, in bacterial pathogenesis has not been studied. Here, using a Dual RNA-seq approach to profile ProQ-dependent gene expression changes as Salmonella infects human cells, we reveal dysregulation of bacterial motility, chemotaxis and virulence genes which is accompanied by altered mitogen-activated protein kinase signaling in the host. Comparison with Hfq, Salmonella’s other major RNA chaperone, reinforces the notion that these two global RNA binding proteins work in parallel to ensure full virulence. Of newly discovered infection-associated ProQ-bound small noncoding RNAs, we show that STnc540 represses a virulence-related magnesium transporter mRNA in a ProQ-dependent manner. Together, this comprehensive study uncovers the relevance of ProQ for Salmonella infection and highlights the importance of RNA-binding proteins in regulating bacterial virulence programs.

Project description:Spirochetes are long, thin, motile, helical or flat wave bacteria that are unique among the prokaryotes by having flagella or axial filaments confined to an internal periplasmic space. These flagella are complex organelles that can play major roles in bacterial pathogenicity and are used as propellers allowing bacteria to move through liquids, viscous environments or along surfaces. While most bacteria species use transcriptional regulatory cascades to regulate the synthesis and assembly of their flagella, spirochetes employ an unusual post-transcriptional mechanism. Using next generation sequencing, we characterized a natural mutant of the relapsing fever spirochete Borrelia hermsii lacking the flagellar export apparatus protein FliH. The mutant was non-motile, uncoiled and straight compared to the wild-type spirochetes. The B. hermsii fliH mutant produced only a residual amount of the major flagellin protein FlaB, which was correlated with a reduced number of periplasmic flagella. The amounts of flaB transcript were comparable in the fliH mutant and the wild-type strain. The synthesis of FlaB, the motility and the infectivity of the fliH mutant were rescued by trans-complementation. This report reveals a new function for FliH, and we propose that this regulator of the flagellar export apparatus influences the post-transcriptional processing of the flagella, motility and virulence of the relapsing fever spirochete Borrelia hermsii. Spirochetes are bacteria characterized in part by rotating periplasmic flagella that impart their flat-wave morphology and motility. While other bacteria rely on a transcriptional cascade to regulate the expression of motility genes, spirochetes employ posttranscriptional mechanism(s) that are only partially known. In the present study, we characterize a non-motile mutant of the relapsing fever spirochete Borrelia hermsii that was straight, non-motile and deficient in flagella. We used next generation DNA sequencing of the mutant’s genome, which when compared to the wild-type genome identified a 142 bp deletion in the chromosomal gene encoding the flagellar export apparatus protein FliH. Immunoblot and transcriptome analyses showed that the mutant phenotype was linked to the posttranscriptional deficiency in the synthesis of the major flagellar filament core protein FlaB. The turnover of the residual pool of FlaB produced by the fliH mutant was comparable to the wild-type spirochete while the amount of FlaA was similar to the wild-type level. The non-motile mutant was not infectious in mice and its inoculation did not induce an antibody response. Trans-complementation of the mutant with an intact fliH gene restored the synthesis of FlaB, a normal morphology, motility and infectivity in mice. Therefore, we propose that the flagellar export apparatus protein regulates motility of B. hermsii at the posttranscriptional level by influencing the synthesis of FlaB.

Project description:The signaling molecule cyclic di-GMP (cdG) controls the switch between bacterial motility and biofilm production, and fluctuations in cellular levels of cdG have been implicated in Vibrio cholerae pathogenesis. Intracellular concentrations of cdG are controlled by the interplay of diguanylate cyclase (DGC) enzymes, which synthesize cdG to promote biofilms, and phosphodiesterase (PDE) enzymes, which hydrolyse cdG to drive motility. To track the complete regulatory logic of how V. cholerae responds to changing cdG levels, we followed a time course of overexpression of either the V. harveyi diguanylate cyclase QrgB or a variant of QrgB lacking catalytic activity (QrgB*). We find that QrgB increases cdG levels relative to QrgB* for 30 minutes after overexpression, but the effect of QrgB on cdG levels plateaus at 30 minutes, indicating tight adaptive control of cdG levels. In contrast, loss of VpsR, a master regulator activating biofilm formation upon binding to cdG, leads to higher baseline levels of cdG and continuously increasing cdG through 60 minutes after QrgB induction, revealing the existence of a negative feedback loop on cdG levels operating through VpsR. Through a combination of RNA polymerase ChIP-seq, RNA-seq, and genetic approaches, we show that the PDE CdgC is activated by VpsR at high cdG concentrations, mediating this negative feedback on cdG levels. We further identify a transcript encoded within, and antisense to, the cdgC open reading frame which we name sRNA negative regulator of CdgC (SnrC). RNA polymerase ChIP-seq and RNA-seq demonstrate SnrC to be expressed specifically under conditions of high cdG in the absence of VpsR. Ectopic SnrC expression increases cdG levels in a manner depending on CdgC, demonstrating that its effect on cdG levels is likely through interference with CdgC production. Further, although cells lacking cdgC exhibit enhanced biofilm formation, these mutants are outcompeted by wild type V. cholerae in colonization assays that reward a combination of attachment, dispersal, and motility. These results underscore the importance of negative feedback regulation of cdG to maintain appropriate homeostatic levels for efficient transitioning between biofilm formation and motility, both of which are necessary over the course of the V. cholerae infection cycle.