Project description:Pseudomonas aeruginosa is a Gram-negative bacterium able to survive and adapt in a multitude of niches as well as thriving within many different hosts. This versatility lies within a large genome of ca 6Mbp and a tight control in the expression of thousands of genes. Among the regulatory mechanisms widely spread in bacteria, cyclic-di-GMP signaling is one which influences all levels of control. It is made by diguanylate cyclases and broken by phosphodiesterases while the intracellular level of this molecule drives phenotypic responses. The signaling involve modification of enzymes or proteins function upon c-di-GMP binding, including modifying the activity of regulators which in turn will impact the transcriptome. In P. aeruginosa, there are ca 40 genes encoding putative DGC or PDE. The combined activity of those enzymes should reflect the c-di-GMP concentration while specific phenotypic output could be correlated to a given set of dgc/pde. This notion of specificity has been addressed in several studies and different strains of P. aeruginosa. Here, we engineered a mutant library for the 41 individual dgc/pde genes in P. aeruginosa PAO1. In most cases, we observed a significant to slight variation in the global c-di-GMP pool, with essentially an impact on biofilm phenotypes including initial attachment and maturation, while very little is observed on motility which differs from previous studies. We observe that minor changes in c-di-GMP level have a drastic phenotypic impact thus supporting the idea of local vs global c-di-GMP pool. Our RNA-seq analysis indicates that all PAO1 dgc/pde genes are expressed in both planktonic and biofilm growth conditions and our work suggests that c-di-GMP networks owe to be reconstructed in one single strain and cannot be built by cross-comparison with studies in other strains.

Project description:Francisella tularensis is a Gram-negative bacterium that is highly virulent in humans, causing the disease tularemia. F. novicida is closely related to F. tularensis and exhibits high virulence in mice, but is avirulent in healthy humans. A F. novicida-specific gene cluster (FTN0451-FTN0456) encodes two proteins with diguanylate cyclase (DGC) and phosphodiesterase (PDE) domains that modulate synthesis and degradation of cyclic di-GMP (cdGMP). No DGC or PDE containing proteins are present in the F. tularensis genome. F. novicida strains lacking either the two DGC/PDE genes cdgA and cdgB or the entire gene cluster (KKF457) are defective for biofilm formation. In addition, expression of CdgB or a heterologous DGC in KKF457 stimulated F. novicida biofilms, even in a strain lacking the biofilm regulator QseB. Genetic evidence suggests that CdgA is predominantly a PDE, while CdgB is predominantly a DGC. The F. novicida qseB strain has reduced cdgA and cdgB transcript levels, demonstrating a F. novicida biofilm signaling cascade that controls cdGMP levels. Interestingly, KKF457 with elevated cdGMP levels exhibited a decrease in intramacrophage replication and virulence in mice, as well as increased growth yield and biofilm formation in vitro. Microarray analyses revealed that cdGMP stimulated the transcription of a chitinase (ChiB) known to contribute to biofilm formation. Our results indicate that elevated cdGMP in F. novicida stimulates biofilm formation and inhibits virulence. We suggest that differences in human virulence between F. novicida and F. tularensis may be due in part to the absence of cdGMP signaling in F. tularensis.

Project description:Francisella tularensis is a Gram-negative bacterium that is highly virulent in humans, causing the disease tularemia. F. novicida is closely related to F. tularensis and exhibits high virulence in mice, but is avirulent in healthy humans. A F. novicida-specific gene cluster (FTN0451-FTN0456) encodes two proteins with diguanylate cyclase (DGC) and phosphodiesterase (PDE) domains that modulate synthesis and degradation of cyclic di-GMP (cdGMP). No DGC or PDE containing proteins are present in the F. tularensis genome. F. novicida strains lacking either the two DGC/PDE genes cdgA and cdgB or the entire gene cluster (KKF457) are defective for biofilm formation. In addition, expression of CdgB or a heterologous DGC in KKF457 stimulated F. novicida biofilms, even in a strain lacking the biofilm regulator QseB. Genetic evidence suggests that CdgA is predominantly a PDE, while CdgB is predominantly a DGC. The F. novicida qseB strain has reduced cdgA and cdgB transcript levels, demonstrating a F. novicida biofilm signaling cascade that controls cdGMP levels. Interestingly, KKF457 with elevated cdGMP levels exhibited a decrease in intramacrophage replication and virulence in mice, as well as increased growth yield and biofilm formation in vitro. Microarray analyses revealed that cdGMP stimulated the transcription of a chitinase (ChiB) known to contribute to biofilm formation. Our results indicate that elevated cdGMP in F. novicida stimulates biofilm formation and inhibits virulence. We suggest that differences in human virulence between F. novicida and F. tularensis may be due in part to the absence of cdGMP signaling in F. tularensis. A whole genome NibleGen microarray was developed for multiple Francisella subspecies, using shared probes for common genes as well as unique probes for subspecies-specific genes. Included were probes representing the F. novicida U112 genome, with a maximum of 6 probes/gene. RNA was isolated from bacteria and purified as described above. The double-strand cDNA was generated and labeled with Cy3 according to the NimbleGen Gene Expression Array protocol (www.nimblegen.com), using SuperScript Double-Stranded cDNA Synthesis Kit (Invitrogen) and the DNA Labeling Kit (NimbleGen). Microarray results were analyzed using the ArrayStar software (DNASTAR).

Project description:In Staphylococcus aureus, the role of the GGDEF domain containing protein GdpS remains poorly understood. Previous studies reported that gdpS mutant strains had decreased biofilm formation due to changes in icaADBC expression that were independent of cyclic-di-GMP levels. We deleted gdpS in three unrelated S. aureus isolates, and analyzed the resultant mutants for alterations in biofilm formation, metabolism and transcription. Dynamic imaging during biofilm development showed that GdpS inhibited early biofilm formation in only two out of the three strains examined, without affecting bacterial survival. However, quantification of biofilm formation using crystal violet staining revealed that inactivation of gdpS affected biofilm formation in all three studied strains. Extraction of metabolites from S. aureus cells confirmed the absence of cyclic-di-GMP, suggesting that biofilm formation in this species differs from that in other Gram-positive organisms. In addition, targeted mutagenesis demonstrated that the GGDEF domain was not required for GdpS activity. Transcriptomic analysis revealed that the vast majority of GGDEF-regulated genes were involved in virulence, metabolism, cell wall biogenesis and eDNA release. Finally, expression of lrgAB or deletion of cidABC in a strain lacking gdpS confirmed the role of GdpS on regulation of eDNA production that occurred without an increase in cell autolysis. In summary, S. aureus GdpS contributes to cell-to-cell interactions during early biofilm formation by influencing expression of lrgAB and cidABC mediated eDNA release. We conclude that GdpS acts as a negative regulator of eDNA release.

Project description:In Staphylococcus aureus, the role of the GGDEF domain containing protein GdpS remains poorly understood. Previous studies reported that gdpS mutant strains had decreased biofilm formation due to changes in icaADBC expression that were independent of cyclic-di-GMP levels. We deleted gdpS in three unrelated S. aureus isolates, and analyzed the resultant mutants for alterations in biofilm formation, metabolism and transcription. Dynamic imaging during biofilm development showed that GdpS inhibited early biofilm formation in only two out of the three strains examined, without affecting bacterial survival. However, quantification of biofilm formation using crystal violet staining revealed that inactivation of gdpS affected biofilm formation in all three studied strains. Extraction of metabolites from S. aureus cells confirmed the absence of cyclic-di-GMP, suggesting that biofilm formation in this species differs from that in other Gram-positive organisms. In addition, targeted mutagenesis demonstrated that the GGDEF domain was not required for GdpS activity. Transcriptomic analysis revealed that the vast majority of GGDEF-regulated genes were involved in virulence, metabolism, cell wall biogenesis and eDNA release. Finally, expression of lrgAB or deletion of cidABC in a strain lacking gdpS confirmed the role of GdpS on regulation of eDNA production that occurred without an increase in cell autolysis. In summary, S. aureus GdpS contributes to cell-to-cell interactions during early biofilm formation by influencing expression of lrgAB and cidABC mediated eDNA release. We conclude that GdpS acts as a negative regulator of eDNA release. Three strains UAMS-1, SA113 and SA564 were used in this study to compare wt with gdpS mutant after 5 hours of growth in static conditions (biofilm formation).

Project description:Pellicles, a type of biofilm, have gathered a renewed interest in the field of tuberculosis as a structure that mimics some characteristics occurring during M. tuberculosis infection, such as antibiotic recalcitrance and chronicity of infection. In other bacteria, it has been well documented that the second messenger c-di-GMP modulates the transition from planktonic cells to biofilm formation. In this work, we used two shotgun proteomics approaches, a label-free one to identify proteins present at two weeks of pellicle formation, and isobaric labeling to assess the differences in the proteome occurring among pellicles formed by three strains of M. bovis BCG: the parental strain (WT), a previously reported knock out in BCG1419c (∆PDE) gene and a new knock out in BCG1416c (∆DGC) gene, in order to unravel the role played by genes involved in the metabolism c-di-GMP during pellicle mode of growth. Our findings strongly suggest that in M. bovis BCG, c-di-GMP may positively correlate with enhanced tolerance to nitrosative stress and negatively to cell wall permeability, therefore suggesting hypothesis relevant for adaption to tolerance to several antibiotics.

Project description:To analyze the impact of elevated c-di-GMP concentrations in P. aeruginosa, we expressed pleD* on an inducible vector (pHERD20T) in the PAO1 wild-type strain. PleD is a DGC from Caulobacter cresentusand the pleD* construct variant encodes for a constitutively active enzyme due to four amino acid exchanges (T120N, T214A, P234H, N357Y).We aimed to analyze the cellular consequences of increased c-di-GMP levels in the opportunistic pathogen P. aeruginosa on a global scale. We therefore grew the pleD* harboring PAO1 as well as the empty vector control PAO1 in LB medium, added arabinose (0.2%) to the medium to induce pleD* expression and harvested the cells in exponential growth phase, when the cells exhibited elevated c-di-GMP levels of about two-fold (see manuscript). We are discribing the characteristics of elevated c-di-GMP with a Multi-Omics-Dataset.

Project description:Cyclic di-GMP (c-di-GMP) is a ubiquitous second messenger that regulates many biological processes in bacteria. The genome in Mycobacterium tuberculosis encodes a single copy of the diguanylate cyclase gene (dgc) responsible for c-di-GMP synthesis. To determine the role of c-di-GMP signaling in M. tuberculosis, the mutant strain of Δdgc was generated in the virulent H37Rv strain. We used whole genome microarray expression profiling as a discovery platform to identify the genes controlled by c-di-GMP in M. tuberculosis, providing molecular proof for the phenotypes modulated by the signaling.

Project description:We analyzed a deletion mutant of the ECF M-OM-^C factor SigX and applied mRNA profiling to define the SigX dependent regulon in P. aeruginosa in response to low osmolarity medium conditions. Furthermore, the combination of transcriptional data with chromatin immunoprecipitation (ChIP) followed by high-throughput sequencing led to the identification of the DNA binding motif of SigX. Genome-wide mapping of SigX-binding regions revealed enrichment of downstream genes involved in fatty acid biosynthesis, type III secretion, swarming and c-di-GMP signaling. In accordance, a sigX deletion mutant exhibited an altered fatty acid composition of the cell membrane, reduced cytotoxicity, impaired swarming activity, elevated c-di-GMP levels and increased biofilm formation. In conclusion, a combination of ChIP-seq with transcriptional profiling and bioinformatic approaches to define consensus DNA binding sequences proved to be effective for the elucidation of the regulon of the alternative M-OM-^C factor SigX revealing its role in complex virulence-associated phenotypes in P. aeruginosa. Transcriptome profiling of the SigX deletion mutant and overexpressing wildtype complemented by ChIP-seq

Project description:C-di-GMP signaling can directly influence bacterial behavior by affecting the functionality of c-di-GMP-binding proteins. In addition, c-di-GMP can exert an indirect and more global effect on gene transcription or translation, e.g. via riboswitches or by binding to transcription factors. In this study, we investigated the effects of changes in intracellular c-di-GMP levels on gene expression and protein production in the opportunistic pathogen Pseudomonas aeruginosa. We induced c-di-GMP production via an ectopically introduced diguanylate cyclase and recorded the transcriptional, translational as well as proteomic profile of the cells. We demonstrate that rising levels of c-di-GMP in P. aeruginosa under growth conditions otherwise characterized by low c-di-GMP levels immediately cause a switch to a non-motile, auto-aggregative phenotype. This switch became apparent before any c-di-GMP-dependent role on transcription, translation, or protein abundance could be observed. Our results indicate that sudden rises in global c-di-GMP pools affect the P. aeruginosa phenotype via an alteration of protein functionality, rather than an impact on global gene transcription or translation.