Project description:Clostridium difficile is an emergent human pathogen and the most common cause of nosocomial diarrhea. Our recent deep-sequencing data strongly suggest the importance of RNA-based mechanisms for the control of gene expression in C. difficile. The RNA chaperon protein Hfq is a key component of post-transcriptional regulatory network in various bacterial systems. In an effort to understand the function of Hfq in C. difficile, we have constructed and characterized an Hfq-depleted strain in this bacterium. We present evidence that Hfq is necessary for the normal cell growth, for the establishment of bacillary form and might be involved in metabolic adaptations, stress response and sporulation, important during C. difficile infection cycle. In accordance to these phenotypic changes, our transcriptome analysis revealed pleiotropic effects of Hfq on gene expression in C. difficile. This microarray analysis showed altered expression of genes encoding cell wall and membrane transport components, sporulation proteins, as well as stress response, transcriptional regulator genes and genes of unknown function. Remarkably, a great number of genes belonging to the regulon dependent on sporulation-specific sigma K factor were generally up-regulated in the strain depleted for Hfq. Many important metabolic pathways were also affected by Hfq depletion. Finally, the altered accumulation of several previously identified sRNAs suggests potential involvement of Hfq in these regulatory RNA function. Altogether, these results provide evidence for the pleiotropic role of Hfq protein in C. difficile physiology expanding our knowledge of Hfq-dependent regulation in Gram-positive bacteria. Two-conditions experiments, 630E strain vs. hfQ mutant grown in TYt, 4 biological replicates for each condition.

Project description:Transcriptional profiling of C. difficile 630E strain vs. an Hfq antisense after 7.5h of growth inTYt.

Project description:Transcriptional profiling of C. difficile 630E strain vs. an Hfq antisense after 7.5h of growth inTYt. Two-conditions experiments, 630E strain vs. Hfq antisense grown in TYt, 4 biological replicates for each condition.

Project description:The obligate anaerobic, enteric pathogen Clostridioides difficile persists in the intestinal tract by forming antibiotic resistant endospores that contribute to relapsing and recurrent infections. Despite the importance of sporulation for C. difficile pathogenesis, environmental cues, and molecular mechanisms regulating sporulation initiation remain ill defined. Here, using RIL-seq to capture the Hfq-dependent RNA-RNA interactome, we discovered a network of small RNAs that bind to mRNAs encoding sporulation-related genes. We show that two of these small RNAs, SpoX and SpoY, regulate translation of the master regulator of sporulation, Spo0A, in an opposing manner, which ultimately leads to altered sporulation rates. Infection of antibiotic-treated mice with SpoX and SpoY deletion mutants revealed a global effect on gut colonization and intestinal sporulation. Our work uncovers an elaborate RNA-RNA interactome controlling the physiology and virulence of C. difficile and identifies a complex post-transcriptional layer in the regulation of spore formation in this important human pathogen.

Project description:Compartment-specific control of gene expression during Bacillus subtilis sporulation is governed by a cascade of four sigma factors, sigmaF and sigmaG in the forespore and sigmaE and sigmaK in the mother cell. In this work, we combined transcriptional analyses and transcriptional start site mapping to define the sigmaF, sigmaE, sigmaG and sigmaK regulons in Clostridium difficile. A total of about 225 genes were under the control of these sigma factors: 25 in the sigmaF regulon, 97 sigmaE-dependent genes, 50 sigmaG-governed genes and 56 genes specifically controlled by sigmaK. A significant fraction of genes in each regulon are of unknown function and we can propose new candidates for spore coat proteins synthesized under the control of sigmaE and sigmaK among proteins previously detected in the spore proteome (Lawley et al., 2009 (PMID 19542279)). Global analysis of developmental gene expression under the control of these sigma factors indicate deviations from the B. subtilis model regarding the communication between mother cell and forespore in C. difficile. We show that the expression of the sigmaE regulon in the mother cell is not strictly under the control of sigmaF despite the fact that the forespore product SpoIIR is required for the processing of pro-sigmaE. In addition, the sigmaK regulon is not controlled by sigmaG in C. difficile in connection with the lack of pro-sigmaK processing in this bacterium. However, a control of the forespore on sigmaK targets is maintained through a sigmaF-dependent regulation of sigmaK-controlled genes, a process that bypasses sigmaG. Here, transcriptional profiling of the Clostridium difficile 630E strain vs. a sigE mutant after 14h of growth in MS is performed. Two-condition experiment: 630E strain 14h vs. sigE mutant 14h. 4 biological replicates for each condition, including dye-swaps.

Project description:Compartment-specific control of gene expression during Bacillus subtilis sporulation is governed by a cascade of four sigma factors, sigmaF and sigmaG in the forespore and sigmaE and sigmaK in the mother cell. In this work, we combined transcriptional analyses and transcriptional start site mapping to define the sigmaF, sigmaE, sigmaG and sigmaK regulons in Clostridium difficile. A total of about 225 genes were under the control of these sigma factors: 25 in the sigmaF regulon, 97 sigmaE-dependent genes, 50 sigmaG-governed genes and 56 genes specifically controlled by sigmaK. A significant fraction of genes in each regulon are of unknown function and we can propose new candidates for spore coat proteins synthesized under the control of sigmaE and sigmaK among proteins previously detected in the spore proteome (Lawley et al., 2009 (PMID 19542279)). Global analysis of developmental gene expression under the control of these sigma factors indicate deviations from the B. subtilis model regarding the communication between mother cell and forespore in C. difficile. We show that the expression of the sigmaE regulon in the mother cell is not strictly under the control of sigmaF despite the fact that the forespore product SpoIIR is required for the processing of pro-sigmaE. In addition, the sigmaK regulon is not controlled by sigmaG in C. difficile in connection with the lack of pro-sigmaK processing in this bacterium. However, a control of the forespore on sigmaK targets is maintained through a sigmaF-dependent regulation of sigmaK-controlled genes, a process that bypasses sigmaG. Here, transcriptional profiling of the Clostridium difficile 630E strain vs. a sigG mutant after 19h of growth in MS is performed. Two-condition experiment: 630E strain 19h vs. sigG mutant 19h. 4 biological replicates for each condition, including dye-swaps.

Project description:Compartment-specific control of gene expression during Bacillus subtilis sporulation is governed by a cascade of four sigma factors, sigmaF and sigmaG in the forespore and sigmaE and sigmaK in the mother cell. In this work, we combined transcriptional analyses and transcriptional start site mapping to define the sigmaF, sigmaE, sigmaG and sigmaK regulons in Clostridium difficile. A total of about 225 genes were under the control of these sigma factors: 25 in the sigmaF regulon, 97 sigmaE-dependent genes, 50 sigmaG-governed genes and 56 genes specifically controlled by sigmaK. A significant fraction of genes in each regulon are of unknown function and we can propose new candidates for spore coat proteins synthesized under the control of sigmaE and sigmaK among proteins previously detected in the spore proteome (Lawley et al., 2009 (PMID 19542279)). Global analysis of developmental gene expression under the control of these sigma factors indicate deviations from the B. subtilis model regarding the communication between mother cell and forespore in C. difficile. We show that the expression of the sigmaE regulon in the mother cell is not strictly under the control of sigmaF despite the fact that the forespore product SpoIIR is required for the processing of pro-sigmaE. In addition, the sigmaK regulon is not controlled by sigmaG in C. difficile in connection with the lack of pro-sigmaK processing in this bacterium. However, a control of the forespore on sigmaK targets is maintained through a sigmaF-dependent regulation of sigmaK-controlled genes, a process that bypasses sigmaG. Here, transcriptional profiling of the Clostridium difficile 630E strain vs. a sigE mutant after 14h of growth in MS is performed. Two-condition experiment: 630E strain 14h vs. sigF mutant 14h. 4 biological replicates for each condition, including dye-swaps.

Project description:Compartment-specific control of gene expression during Bacillus subtilis sporulation is governed by a cascade of four sigma factors, sigmaF and sigmaG in the forespore and sigmaE and sigmaK in the mother cell. In this work, we combined transcriptional analyses and transcriptional start site mapping to define the sigmaF, sigmaE, sigmaG and sigmaK regulons in Clostridium difficile. A total of about 225 genes were under the control of these sigma factors: 25 in the sigmaF regulon, 97 sigmaE-dependent genes, 50 sigmaG-governed genes and 56 genes specifically controlled by sigmaK. A significant fraction of genes in each regulon are of unknown function and we can propose new candidates for spore coat proteins synthesized under the control of sigmaE and sigmaK among proteins previously detected in the spore proteome (Lawley et al., 2009 (PMID 19542279)). Global analysis of developmental gene expression under the control of these sigma factors indicate deviations from the B. subtilis model regarding the communication between mother cell and forespore in C. difficile. We show that the expression of the sigmaE regulon in the mother cell is not strictly under the control of sigmaF despite the fact that the forespore product SpoIIR is required for the processing of pro-sigmaE. In addition, the sigmaK regulon is not controlled by sigmaG in C. difficile in connection with the lack of pro-sigmaK processing in this bacterium. However, a control of the forespore on sigmaK targets is maintained through a sigmaF-dependent regulation of sigmaK-controlled genes, a process that bypasses sigmaG. Here, transcriptional profiling of the Clostridium difficile 630E strain vs. a sigE mutant after 24h of growth in MS is performed. Two-conditions experiments, 630E strain 24h vs sigK mutant 24h, 4 biological replicates for each condition

Project description:Purpose: A goal of this study was to identify genes induced in the mother cell during Clostridium difficile sporulation (specifically in a σE-, σK-, and SpoIIID-dependent manner). Methods: Whole genome RNA sequencing was performed on wildtype, sigE-, sigK- and spoIIID- C. difficile strains (strain 630 background; JIR8094 = parent strain), and the transcriptional profiles of the different mutants during growth on 70:30 agar plates were determined using an Illumina MiSeq1000. Results: This analysis identified 200 genes whose expression is collectively activated by sporulation sigma factors: 159 were σF-dependent, 162 were σE-dependent, 28 were σG-dependent, and 36 were σK-dependent. A total of 254 genes were identified as requiring Spo0A for their expression when sporulation was induced on the 70:30 plates. Conclusions: These results provide the first genome-wide transcriptional analysis of genes whose expression is induced by specific sporulation sigma factors in the Clostridia and highlight that diverse mechanisms regulate sporulation sigma factor activity in the Firmicutes. For example, in contrast with the B. subtilis sporulation pathway, C. difficile σE was not required to fully activate σG, and σG was not required to activate σK.

Project description:Compartment-specific control of gene expression during Bacillus subtilis sporulation is governed by a cascade of four sigma factors, sigmaF and sigmaG in the forespore and sigmaE and sigmaK in the mother cell. In this work, we combined transcriptional analyses and transcriptional start site mapping to define the sigmaF, sigmaE, sigmaG and sigmaK regulons in Clostridium difficile. A total of about 225 genes were under the control of these sigma factors: 25 in the sigmaF regulon, 97 sigmaE-dependent genes, 50 sigmaG-governed genes and 56 genes specifically controlled by sigmaK. A significant fraction of genes in each regulon are of unknown function and we can propose new candidates for spore coat proteins synthesized under the control of sigmaE and sigmaK among proteins previously detected in the spore proteome (Lawley et al., 2009 (PMID 19542279)). Global analysis of developmental gene expression under the control of these sigma factors indicate deviations from the B. subtilis model regarding the communication between mother cell and forespore in C. difficile. We show that the expression of the sigmaE regulon in the mother cell is not strictly under the control of sigmaF despite the fact that the forespore product SpoIIR is required for the processing of pro-sigmaE. In addition, the sigmaK regulon is not controlled by sigmaG in C. difficile in connection with the lack of pro-sigmaK processing in this bacterium. However, a control of the forespore on sigmaK targets is maintained through a sigmaF-dependent regulation of sigmaK-controlled genes, a process that bypasses sigmaG. Here, transcriptional profiling of the Clostridium difficile 630E strain vs. a sigE mutant after 24h of growth in MS is performed.