Project description:Enteric pathogens have developed several resistance mechanisms to survive the antimicrobial action of bile. We investigated the transcriptional profile of Vibrio cholerae O1 El Tor strain C6706 under virulence gene inducing conditions, in the presence and absence of bile. Microarray analysis revealed that the expression of 119 genes was affected by bile. The mRNA levels of genes encoding proteins involved in transport was increased in the presence of bile, whereas mRNA levels of genes encoding proteins involved in pathogenesis and chemotaxis was decreased. This study identified genes encoding transcriptional regulators from the TetR family (vexR and breR) and multidrug efflux pumps from the RND superfamily (vexB and vexD [here renamed breB]) that were induced in response to bile. Further analysis regarding vexAB and breAB expression in the presence of various antimicrobial compounds established that vexAB was induced in the presence of bile, SDS or novobiocin, whereas induction of breAB was specific to bile. BreR is a direct repressor of the breAB promoter and is able to autoregulate its own expression, as demonstrated by transcriptional and electrophoretic mobility shift assays (EMSA). Expression of breR and breAB is induced in the presence of the bile salts cholate, deoxycholate or chenodeoxycholate and EMSA showed that deoxycholate is able to abolish formation of BreR-PbreR complexes. We propose that deoxycholate is able to interact with BreR and induce a conformational change that will interfere with its DNA binding ability resulting in breAB and breR expression. These results provide new insight into a transcriptional regulator and a transport system that likely play an essential role in the ability of Vibrio cholerae to resist the action of bile in the host. Keywords: Vibrio cholerae response to bile Three independent experiments were performed for the microarray analysis. From each experiment, RNA was obtained from four different time points and was prepared for hybridization, therefore, a total of 3 slides were analyzed per time point. The growth conditions were as follows; C6706 str2 was grown 15 h in LB medium at 30 degrees C with aeration. The cultures were then diluted 100-fold into AKI medium with, or without, 0.4% crude bile (high bile concentration) and were grown at 37degrees C for 3.5 h stationary followed by 2 h with aeration to induce virulence gene expression. Then the cultures were diluted 100-fold into AKI medium with, or without, 0.02% crude bile (low bile concentration) and were grown at 37 degrees C for 2 h stationary. Samples were obtained from 4 different time points: 2, 4, and 5.5 h from the high bile cultures, and at 2 h from the low bile cultures.

Project description:Bile plays an important role in digestion, absorption of fats, and the excretion of waste products, while concurrently providing a critical barrier against colonization by harmful bacteria. Previous studies have demonstrated that gut pathogens react to bile by adapting their protein synthesis. The ability of pathogens to respond to bile is remarkably complex and still incompletely understood. Here we show that Campylobacter jejuni, a leading bacterial cause of human diarrheal illness worldwide, responds to deoxycholate, a component of bile, by altering global gene transcription in a manner consistent with a strategy to mitigate exposure to reactive oxygen stress. More specifically, continuous growth of C. jejuni in deoxycholate was found to: 1) induce the production of reactive oxygen species (ROS); 2) decrease succinate dehydrogenase activity (complex II of the electron transport chain); 3) increase catalase activity that is involved in H2O2 breakdown; and 4) result in DNA strand breaks. Congruently, by adding 4-hydroxy-TEMPO (TEMPOL), a superoxide dismutase mimic, that reacts with superoxide to cultures under deoxycholate-mediated ROS stress, C. jejuni growth in the presence of deoxycholate was rescued. We postulate that continuous exposure of a number of enteric pathogens to deoxycholate stimulates a conserved survival response to this stressor.

Project description:Clostridium difficile epidemic strain R20291 was grown in presence of the two main bile acids, Deoxycholate and Cholate.

Project description:Horizontally acquired genetic elements (HGEs) plays a major for determination of virulence, antimicrobial resistance, adaptation and evolution in pathogenic bacteria. Conserved integrative mobile genetic elements (MGEs) of Vibrio cholerae contribute in the disease development, antimicrobial resistance and metabolic functions. To understand the dynamics of integrative MGEs and cross talk between MGEs and core genome, engineered genome of V. cholerae was monitored in the presence and absence of horizontally acquired genetic elements. Deletion of more than 250 revealed that CTX contributes to the essentiality of SOS response master regulator LexA in V. cholerae. Also, he core genome encoded RecA helps CTX to bypass the host immunity and replicate in the host cell in the presence of similar prophage in the host chromosome. Finally, our multiomics data reveal importance of MGEs in modulating the level of cellular proteome and metabolome in V. cholerae. This study for the first time engineered the genome of V. cholerae strains to eliminate all the GIs, ICE and prophages from their genome and revealed new interactions between core and acquired genomes. The engineered strain could be a potential candidate for understanding evolution of cholera pathogen and development of therapeutics.

Project description:We used RNA-seq to determine transcriptional profiles of whole guts or IPCs isolated from guts infected with wild type or type VI secretion system deficient Vibrio cholerae. We found significant differences between guts and progenitor cells infected wild type or type VI secretion system deficient Vibrio cholerae.

Project description:Transcriptional profiling of Vibrio Cholerae RpoE deletion mutant in toxSL33S mutation background

Project description:In presence of high concentrations of L-arabinose, Vibrio cholerae enters into a non-proliferative state. In V. cholerae, when L-arabinose in present into the media, it is incorporated and metabolized through the galactose pathway. In the present datasets we show that in presence of L-arabinose, transposon insertions in the galactose pathway confer a resistance to the detrimental effect of L-arabinose.

Project description:Investigation of whole genome gene expression level changes in a Vibrio cholerae O395N1 delta-nqrA-F mutant, compared to the wild-type strain. Total RNA recovered from wild-type cultures of VIbrio cholerae O395N1 and its nqrA-F mutant strain. Each chip measures the expression level of 3,835 genes from Vibrio cholerae O1 biovar eltor str. N16961 with twenty average probes/gene, with five-fold technical redundancy.

Project description:Temperature is a crucial environmental signal that govers the occurrence of Vibrio cholerae and cholera outbreaks. To understand how temperature impacts the transcriptome of V. cholerae we performed whole-genome level transcriptional profiling using custom microarrays on cells grown at human body temperature (37 C) then shifted to temperatures V. cholerae experience in the environment (15 C and 25 C).

Project description:We exposed wild-type Vibrio cholerae E7496, multiple Vibrio cholerae virulence factor deleted genes with intact hemolysin A gene [CVD109] and without hemolysin A gene [CVD110] in E7946, and E.coli OP50 to wild-type C.elegans N2 for 18 hours. We used microarrays to detail the global gene expression and identified distinct classes of up-regulated and down-regulated genes during this process. C. elegans were exposed to Vibrio cholerae and E.coli then hybridization on Affymetrix microarray chips.