Project description:Quorum sensing (QS) is a communication system in bacteria that regulates gene expression in response to a small diffusible signal indicative of the bacterial population present. QS has been shown to regulate virulence genes, biofilm formation, cell division and secretion systems in a diverse set of bacteria. Brucella melitensis produces a QS signaling molecule, N-dodecanoyl homoserine lactone (C12-HSL), that interacts with a LuxR transcriptional regulator, VjbR. Deletion of vjbR has been found to highly attenuate intracellular survival of B. melitensis. The importance of QS in the regulation of genes necessary for the establishment and maintenance of B. melitensis infection has already been described for the virB and fla operons, however, a complete description of the vjbR regulon has not been described. Genome mining revealed seven luxR-like genes in B. melitensis, only one of which, vjbR, was confirmed to be attenuated for intracellular survival using macrophage assays. Using custom B. melitensis microarrays, we compared transcripts from wild type and ∆vjbR strains in the presence and absence of exogenous C12-HSL. Comparison of the transcriptomes obtained from culture-grown bacteria revealed bi-phasic gene regulation with expression peaks during exponential and early stationary growth phase; characterized by the regulation of 226 and 246 genes (respectively) by VjbR and 349 and 146 (respectively) altered by the addition of C12-HSL. Comparison of the VjbR and C12-HSL regulated genes provided confirmation that expression of 134 genes are regulated by both conditions with all but 3 genes inversely regulated. Overall, these results indicate that VjbR is an activator of gene expression at the exponential growth phase and exerts an equal effect on gene expression at the stationary growth phase; while C12-HSL has a repressive effect on gene expression at both growth stages examined and acts as an antagonist to VjbR activity. Direct transcript analysis comparing ∆vjbR with and without the addition of C12-HSL revealed that the AHL signal is able to direct gene expression in the absence of VjbR and exclusively exerted a positive influence on the expression of 56 genes, including a 93-fold increase in the expression of BabR, a second LuxR homologue. Genes regulated by these QS components included adhesins, proteases, antibiotic and toxin resistance genes, stress survival aids, including DNA repair genes and protein chaperones, transporters and porins, cellular membrane biogenesis genes, amino acid metabolism and transport, transcriptional regulators, and energy production genes. From these data, we conclude that QS is a global regulator of gene expression, and present potential virulence genes that may provide insight into the bacteria’s ability to establish and maintain the replicative vacuole (BCV) within the host cell. Keywords: Microarray comparison of a genetic deletion mutant and the addition of an effector molecule. Samples consist of RNA isolated from Brucella melitensis grown to logarithmic or stationary phase. RNA was extracted from wild type with and without exogenously added C12-HSL, and a ∆vjbR mutant. There are three biological replicates of each sample. Every Brucella melitensis open reading frame was printed in quadruplicate on each microarray. Each replicate was normalized against labeled Brucella melitensis 16M genomic DNA.

Project description:Quorum sensing (QS) is a communication system in bacteria that regulates gene expression in response to a small diffusible signal indicative of the bacterial population present. QS has been shown to regulate virulence genes, biofilm formation, cell division and secretion systems in a diverse set of bacteria. Brucella melitensis produces a QS signaling molecule, N-dodecanoyl homoserine lactone (C12-HSL), that interacts with a LuxR transcriptional regulator, VjbR. Deletion of vjbR has been found to highly attenuate intracellular survival of B. melitensis. The importance of QS in the regulation of genes necessary for the establishment and maintenance of B. melitensis infection has already been described for the virB and fla operons, however, a complete description of the vjbR regulon has not been described. Genome mining revealed seven luxR-like genes in B. melitensis, only one of which, vjbR, was confirmed to be attenuated for intracellular survival using macrophage assays. Using custom B. melitensis microarrays, we compared transcripts from wild type and ∆vjbR strains in the presence and absence of exogenous C12-HSL. Comparison of the transcriptomes obtained from culture grown bacteria revealed bi-phasic gene regulation with expression peaks during exponential and early stationary growth phase; characterized by the regulation of 226 and 246 genes (respectively) by VjbR and 349 and 146 (respectively) altered by the addition of C12-HSL. Comparison of the VjbR and C12-HSL regulated genes provided confirmation that expression of 134 genes are regulated by both conditions with all but 3 genes inversely regulated. Overall, these results indicate that VjbR is an activator of gene expression at the exponential growth phase and exerts an equal effect on gene expression at the stationary growth phase; while C12-HSL has a repressive effect on gene expression at both growth stages examined and acts as an antagonist to VjbR activity. Direct transcript analysis comparing ∆vjbR with and without the addition of C12-HSL revealed that the AHL signal is able to direct gene expression in the absence of VjbR and exclusively exerted a positive influence on the expression of 56 genes, including a 93-fold increase in the expression of BabR, a second LuxR homologue. Genes regulated by these QS components included adhesins, proteases, antibiotic and toxin resistance genes, stress survival aids, including DNA repair genes and protein chaperones, transporters and porins, cellular membrane biogenesis genes, amino acid metabolism and transport, transcriptional regulators, and energy production genes. From these data, we conclude that QS is a global regulator of gene expression, and present potential virulence genes that may provide insight into the bacteria’s ability to establish and maintain the replicative vacuole (BCV) within the host cell. Keywords: Microarray comparison of a genetic deletion mutant and the addition of an effector molecule. Samples consist of RNA isolated from Brucella melitensis grown to logarithmic or stationary phase. RNA was extracted from a ∆vjbR mutant with and without exogenously added C12-HSL. There are three biological replicates of each sample. Every Brucella melitensis open reading frame was printed in quadruplicate on each microarray. Each replicate was normalized against labeled Brucella melitensis 16M genomic DNA.

Project description:Quorum-sensing (QS) is a cell-cell communication system that controls gene expression in many bacterial species, mediated by diffusible signal molecules. While the intracellular regulatory mechanisms of QS are often well-understood, the functional roles of QS remain controversial. In particular, the use of multiple signals by many bacterial species poses a serious challenge to current functional theories. Here we address this challenge by showing that bacteria can use multiple QS signals to infer both their social (density) and physical (mass-transfer) environment. Analytical and evolutionary simulation models show that the detection of and response to complex social/physical contrasts requires multiple signals with distinct half-lives and combinatorial (non-additive) responses to signal concentrations. We test these predictions using the opportunistic pathogen Pseudomonas aeruginosa, and demonstrate significant differences in signal decay between its two primary signal molecules as well as diverse combinatorial responses to dual signal inputs. QS is associated with the control of secreted factors, and we show that secretome genes are preferentially controlled by synergistic M-bM-^@M-^XAND-gateM-bM-^@M-^Y responses to multiple signal inputs, ensuring the effective expression of secreted factors in high density and low mass-transfer environments. Our results support a novel functional hypothesis for the use of multiple signals and, more generally, show that bacteria are capable of combinatorial communication. The two primary signal molecules of P. aeruginosa are the homoserine lactones N-(3-oxododecanoyl)-L-homoserine lactone (3-oxo-C12-HSL) and N-butyryl-homoserine lactone (C4-HSL). Effects of the different signal molecules was assessed using a double QS synthase mutant of Pseudomonas aeruginosa PAO1 lasI/rhlI grown at 37M-BM-0C in 25 ml LB broth and 250 ml flasks with shaking at 200 r.p.m. in four treatments, each with a replicate: (a) no addition; (b) 3-oxo- C12-HSL; (c) C4-HSL; and (d) both 3-oxo-C12-HSL and C4-HSL.

Project description:Quorum sensing system (QS) is a global regulator that regulates gene expression in response to cell density and other environmental factors. Two QS genes have been identified in Brucella, one of which (vjbR) is involved in Brucella intracellular survival and virulence. But the regulation mechanism of Brucella intracellular survival by the vjbR remains unknown.To characterize the regulation roles of vjbR, the in vitro vjbR induction conditions simulating intracellular environments were firstly defined, and then, transcriptome of the vjbR mutant is compared to that of the wild type strain. The vjbR gene was highly activated under acidified nutrition limitation condition. Comparative transcriptome analysis showed that a total of 126 genes were greatly differentially expressed in the vjbR mutant. 2 wild type samples and 2 vjbR mutant samples were analyzed.

Project description:This study reports the expression profile of intracellular B. pseudomallei following infection of human macrophage-like U937 cells. The transcriptome of intracellular B. pseudomallei harvested from macrophage cells over an infection period of 6 hr (1, 2, 4 and 6 hr post-infection) were compared to in vitro grown bacteria to identify genes whose expression is altered in response to intracellular growth. The experimental design of this study involved the total RNA from intracellular B. pseudomallei harvested from infected U937 cells at 4 selected time points with 3 biological replicates each. The microarray data from each time point was compared relative to in vitro grown bacteria in cell culture medium.

Project description:Introduction: Pantoea stewartii subsp. stewartii is a proteobacterium that causes Stewart’s wilt disease in corn plants. The bacteria form a biofilm in the xylem of infected plants and produce capsule that blocks water transport, eventually causing wilt. At low cell densities, the quorum-sensing (QS) regulatory protein EsaR is known to directly repress expression of esaR itself as well as the capsular synthesis operon transcription regulator, rcsA, and a 2,5-diketogluconate reductase, dkgA. It simultaneously directly activates expression of genes for a putative small RNA, esaS, the glycerol utilization operon, glpFKX, and another transcriptional regulator, lrhA. At high bacterial cell densities, all of this regulation is relieved when EsaR binds an acylated homoserine lactone signal, which is synthesized constitutively over growth. QS-dependent gene expression is critical for the establishment of disease in the plant. Objective: However, the identity of the full set of genes controlled by EsaR/QS is unknown. A proteomic approach previously identified around 30 proteins in the QS regulon. In this study, a whole-transcriptome, next-generation sequencing analysis of rRNA-depleted RNA from QS-proficient and -deficient P. stewartii strains was performed to identify additional targets of EsaR. Result: EsaR-dependent transcriptional regulation of a subset of differentially expressed genes was confirmed by quantitative reverse transcription-PCR (qRT-PCR). Electrophoretic mobility shift assays demonstrated that EsaR directly bound 10 newly identified target promoters. Overall, the QS regulon of P. stewartii orchestrates three major physiological responses: capsule and cell envelope biosynthesis, surface motility and adhesion, and stress response. Comparison of gene expression in two strains of Pantoea stewartii, QS-proficient DC283 ES∆IR (pSVB60) and QS-deficient DC283 ES∆IR (pBBR1MCS-3) to identify those genes that are directly regulated by the master Quorum-sensing regulator, EsaR.

Project description:We present a detailed single cell time course of the macrophage response to Salmonella infection. By combining phenotypic fluorescent labels with single cell expression analysis we are able to identify gene modules associated with bacterial exposure and bacterial infection. We also identify other genetic clusters that are expressed heterogenously, ananlyzing both their regulation and their impact on infection Analysis of 192 single cells across 4 time points after Salmonella exposure (MOI 1:1) with one of three different fluorescent labels indicating whether a given cell contained no intracellular bacteria (non-fluorescent), contained dead intracellular bacteria (only pHrodo positive), or contained live intracellular bacteria (pHrodo and GFP positive)

Project description:Microarrays were used to determine the transcriptional profile of Y. pestis that is growing inside macrophages. J774A.1 macrophage-like cells were infected with Y. pestis KIM5 and incubated in the presence of gentamicin in tissue culture media. RNA was isolated from intracellular bacteria at various time points post infection. Control bacteria were grown for 4 hours in tissue culture medium under the same conditions without macrophages or gentamicin. The transcriptional profiles of intracellular Y. pestis at different time points were compared to those of control Y. pestis using the 70-mer oligonucleotide microarrays obtained from Pathogen Functional Genomics Resource Center/J. Craig Venter Institute (Y. pestis microarray version 2). RNA from samples of Yersinia pestis KIM5 at 3 time points in were compared to 12 Yersinia pestis in DMEM for 4 hours.

Project description:Quorum sensing (QS) is a widespread process in bacteria used to coordinate gene expression with cell density, diffusion dynamics, and spatial distribution through the production of diffusible chemical signals. To date, most studies on QS have focused on model bacteria that are amenable to genetic manipulation and capable of high growth rates, but many environmentally important bacteria have been overlooked. For example, representatives of proteobacteria that participate in nitrification, the aerobic oxidation of ammonia to nitrate via nitrite, produce QS signals called acyl-homoserine lactones (AHLs). Nitrification emits nitrogen oxide gases (NO, NO2, and N2O), which are potentially hazardous compounds that contribute to global warming. Despite considerable interest in nitrification, the purpose of QS in the physiology/ecology of nitrifying bacteria is poorly understood. Through a quorum quenching approach, we investigated the role of QS in a well-studied AHL-producing nitrite oxidizer, Nitrobacter winogradskyi.We added a recombinant AiiA lactonase to N. winogradskyi cultures to degrade AHLs to prevent their accumulation and to induce a QS-negative phenotype and then used mRNA sequencing (mRNA-Seq) to identify putative QS-controlled genes. Our transcriptome analysis showed that expression of nirK and nirK cluster genes (ncgABC) increased up to 19.9-fold under QS-proficient conditions (minus active lactonase). These data led to us to query if QS influenced nitrogen oxide gas fluxes in N. winogradskyi. Production and consumption of NOx increased and production of N2O decreased under QS-proficient conditions. Quorum quenching transcriptome approaches have broad potential to identify QS-controlled genes and phenotypes in organisms that are not genetically tractable.

Project description:Many pathogenic bacteria use a regulatory process termed Quorum Sensing (QS) to produce and detect small diffusible molecules to synchronize gene expression within a population. In Gram-negative bacteria, the detection and response to these molecules depend on transcriptional regulators belonging to the LuxR family. Such a system have been discovered in the intracellular pathogen Brucella melitensis, a Gram-negative bacteria responsible for brucellosis, a word-wide zoonosis remaining a serious public health concern in endemic countries. Two LuxR-type regulators, VjbR and BabR, have been identified in the genome of this pathogen. The vjbR mutant is highly attenuated in all tested models suggesting a crucial role of QS in the virulence of Brucella. This attenuation is at least due to the involvement of VjbR in the activation of the virB operon coding for a type four secretion system essential for Brucella to reach its intracellular replication compartment. At present, no function has been attributed to BabR. To assess the role of both Brucella QS-regulators, we performed in tandem comparative transcriptomic and proteomic analyses of vjbR and babR mutants. These experiments revealed that 10% of Brucella genome is regulated through those regulators, revealing that QS is a global regulatory system in this intracellular pathogen. The overlapping between BabR and VjbR targets suggest an unexpected cross-talk between these two regulators. Moreover, our results demonstrate that VjbR and BabR regulate many gene and/or proteins involved in stress response, metabolism and virulence. These targets are potentially involved in the adaptation of Brucella to the oxidative, pH and nutritional stresses encountered within the host. These findings highlight the involvement of QS in the virulence of Brucella and led us to suggest that this regulatory system could be implied in the spatial and sequential adaptation of Brucella to the host environment. Keywords: Quorum Sensing, Comparative gene expression, Brucella melitensis