Project description:Pseudomonas aeruginosa, a human opportunistic pathogen, is a common cause of nosocomial infections. Its ability to survive under different conditions relies on a complex regulatory network engaging transcriptional regulators controlling metabolic pathways and capabilities to efficiently use the available resources. P. aeruginosa PA3973 encodes a putative TetR family transcriptional regulator, with a helix-turn-helix motif involved in DNA binding. We applied transcriptome profiling (RNA-seq), and genome-wide identification of binding sites using ChIP-seq to unravel the biological role of PA3973.

Project description:Pseudomonas aeruginosa, a facultative human pathogen causing nosocomial infections, has complex regulatory systems involving many transcriptional regulators. The LTTR family (LysR-Type Transcriptional Regulators) consists of proteins involved in regulation of various processes including stress response, motility, virulence or amino acid metabolism. The aim of this study was characterization of the LysR-type regulator BsrA (PA2121), identified previously as a negative regulator of biofilm formation in P. aeruginosa. To identify the BsrA binding sites in P. aeruginosa the ChIP-seq analysis was performed. It revealed 765 BsrA binding sites in P. aeruginosa PAO1161 genome, among them 367 was localized in the intergenic regions. Parallel transcriptomic analysis identified altered expression of 157 genes in response to BsrA excess, among them 35 had a BsrA binding site in the corresponding promoter regions, indicating direct influence of BsrA on expression of these genes. BsrA-repressed loci encompass genes encoding proteins engaged in key metabolic pathways including the tricarboxylic acid cycle. A group of directly activated genes by BsrA, consists of several loci encoding proteins involved in pili/fimbriae assembly as well as secretion and transport systems. Results also confirmed that BsrA acts as an autorepressor. Presented data uncover the regulon of BsrA protein with its role as transcriptional regulator of genes engaged in vital cellular processes in P. aeruginosa.

Project description:Pseudomonas aeruginosa, a facultative human pathogen causing nosocomial infections, has complex regulatory systems involving many transcriptional regulators. The LTTR family (LysR-Type Transcriptional Regulators) consists of proteins involved in regulation of various processes including stress response, motility, virulence or amino acid metabolism. The aim of this study was characterization of the LysR-type regulator BsrA (PA2121), identified previously as a negative regulator of biofilm formation in P. aeruginosa. To identify the BsrA binding sites in P. aeruginosa the ChIP-seq analysis was performed. It revealed 765 BsrA binding sites in P. aeruginosa PAO1161 genome, among them 367 was localized in the intergenic regions. Parallel transcriptomic analysis identified altered expression of 157 genes in response to BsrA excess, among them 35 had a BsrA binding site in the corresponding promoter regions, indicating direct influence of BsrA on expression of these genes. BsrA-repressed loci encompass genes encoding proteins engaged in key metabolic pathways including the tricarboxylic acid cycle. A group of directly activated genes by BsrA, consists of several loci encoding proteins involved in pili/fimbriae assembly as well as secretion and transport systems. Results also confirmed that BsrA acts as an autorepressor. Presented data uncover the regulon of BsrA protein with its role as transcriptional regulator of genes engaged in vital cellular processes in P. aeruginosa.

Project description:Previous work identified the winged helix-turn-helix DNA binding transcription factor (TF) RosR (encoded by VNG0258H gene), which dynamically regulates expression of more than 300 genes in response to oxidative stress in Halobacterium salinarum (Sharma 2012). RosR is required for survival of oxidants from multiple sources (e.g. H2O2 and paraquat), as deletion mutants are impaired for ROS outgrowth. Genes directly and indirectly controlled by RosR in response to ROS encode macromolecular repair functions. In the current study, we ask which of these genes are direct targets of RosR regulation. Dynamic chromatin immunoprecipitation combined with microarray (ChIP-chip) analysis validates that genes encoding these functions are direct targets of RosR binding and control. In addition, new RosR direct target genes are identified, including those encoding central cellular functions and a surprisingly high number of other TFs. The majority of the 252 sites throughout the genome are RosR-bound in the absence of stress and cleared of RosR binding in the presence of H2O2. However, binding is dynamic, with promoter-specific differences in the timing of RosR-DNA release and re-binding relative to ROS exposure.

Project description:We firstly found that DsbRS TCS (encoded by PA2479-PA2480) was involved in counteracting the toxic effects of copper. The identification of two DsbR binding reigions in dsbD-dsbR intergenic region DNA led us to globally characterize all DsbR-binding loci on the chromosome of Pseudomonas aeruginosa. In order to express C-terminal flag-tagged DsbR, we first constructed the ΔdsbRS::DsbR-Flag strain. We next investigated DsbR-binding to the chromosome of this strain during exponential growth by ChIP-Seq, chromatin immunoprecipitation followed by ultra-high throughput DNA sequencing. Sequence reads obtained from three independent ChIP-Seq experiments using Flag-specific antibodies were mapped to the genome of the ΔdsbRS::DsbR-Flag strain. Using MACS software, we identified 18 reproducible peaks of DsbR binding, which were enriched by >2 fold.Approximately 83% (15 peaks) are in the promoter regions of 23 genes (within 600 bp upstream of the translational start site) involved or potentially involved in various biological processes including protein folding (e.g., dsbDEG operon and dsbB), protein secretion (e.g.., hxcU, hxcP, hcpC), transport (e.g., opdT, pa2911, and pstS), and regulation of transcription (i.e., dsbRS, pa3398). Collectively, this study thus uncover a new signal transduction pathway in P. aeruginosa, DsbS/DsbR/DsbDEG and DsbB, for the regulation of Dsb system in response to copper stress.

Project description:Previous work identified the winged helix-turn-helix DNA binding transcription factor (TF) RosR (encoded by VNG0258H gene), which dynamically regulates expression of more than 300 genes in response to oxidative stress in Halobacterium salinarum (Sharma 2012). RosR is required for survival of oxidants from multiple sources (e.g. H2O2 and paraquat), as deletion mutants are impaired for ROS outgrowth. Genes directly and indirectly controlled by RosR in response to ROS encode macromolecular repair functions. In the current study, we ask which of these genes are direct targets of RosR regulation. Dynamic chromatin immunoprecipitation combined with microarray (ChIP-chip) analysis validates that genes encoding these functions are direct targets of RosR binding and control. In addition, new RosR direct target genes are identified, including those encoding central cellular functions and a surprisingly high number of other TFs. The majority of the 252 sites throughout the genome are RosR-bound in the absence of stress and cleared of RosR binding in the presence of H2O2. However, binding is dynamic, with promoter-specific differences in the timing of RosR-DNA release and re-binding relative to ROS exposure. Halobacterium salinarum harboring VNG0258H(rosR)::myc was grown to mid-logarithmic phase (OD600 ~ 0.2 - 0.4) and either left untreated or exposed to 25 mM H2O2 for 10, 20, and 60 minutes. Transcription factor-chromatin complexes from each treated time point and untreated cultures were then cross-linked in vivo with 1% formaldehyde for 30 min at room temperature and subjected to immunoprecipitation (IP) by virtue of the myc epitope tag as described previously (Schmid et al. 2011). One M-BM-5g of each IP sample was hybridized against matched, mock-treated controls on a custom 2 x 105,000 feature 60-mer oligonucleotide microarray (Agilent Technologies, AMADID 026819). On this high-resolution array, the entire H. salinarum genome was tiled every 30 bp in triplicate. Randomly selected regions of the genome were spotted in quadruplicate. Dye swaps were conducted to correct for bias in incorporation. Seven biological replicate experiments were conducted for VNG0258::myc in the absence of H2O2 and three in the presence of H2O2. Four biological replicate experiments in an H. salinarum strain harboring the empty vector control plasmid were conducted to detect background peaks resulting from technical aspects of the protocol. This yielded a total of at least 18 replicate intensity data points per 30-bp genomic region per condition. DNA fragments were directly labeled with Cy3 and Cy5 dyes (Kreatech) as described previously (Facciotti et al., 2007). Microarray slide hybridization and washing protocols were conducted according to the manufacturerM-bM-^@M-^Ys instructions (Agilent technologies) with the exception that hybridization was conducted in the presence of 37.5% formamide at 68M-KM-^ZC to ensure proper stringency.

Project description:RpoD is a houskeeping sigma factor and RpoN is an alternative one. It was identified their intragenic and intergenic binding sites and association with the RNA polymerase.

Project description:RpoD is a houskeeping sigma factor and RpoN is an alternative one. It was identified their intragenic and intergenic binding sites and association with the RNA polymerase.

Project description:We have applied next-generation sequencing technology to obtain high through-put profiling of glucocorticoid receptor (GR) DNA binding in whole hippocampus from male rat brain. By obtaining sequence from immunoprecipitated, sonicated chromatin, we have generated genome-wide binding maps for GR in two contexts, testing whether chromatin is primed for GR binding according to the animal's acute experience. In one context (stressed) adrenalectomised rats are infused with corticosterone while undergoing restraint stress. In the second context (non-stressed control) rats are infused with the same corticosterone profile but restraint stress is omitted. We find that GR binding was highly similar suggesting factors other than GR binding may account for any context-dependent alterations in GR function associated with acute stress. We show that GR is positioned near to genes associated with structural and functional organisation of the hippocampus at largely intergenic and intronic sites. Glucocorticoid response element sequences support a majority of GR binding in this tissue but may be reinforced by NF-1 and/or basic-helix loop helix transcription factors binding their nearby recognition motifs. We found little evidence for tethering of GR to other factors, or for the usage of negative glucocorticoid response elements.

Project description:ParA and ParB homologs are involved in accurate chromosome segregation in bacteria. ParBs participate in proper folding and initial separation of ori domains by binding to specific parS sites (palindromic centromere-like sequences), mainly localized close to oriC. Bioinformatic analyses identified 10 parS sequences in the Pseudomonas aeruginosa PAO1 genome. One parS from the parS1-parS4 cluster is required for ParB mediated chromosome segregation. To verify the binding of ParB to all known parSs in vivo as well as to identify additional ParB binding sites we performed chromation immunoprecipitation (ChIP) using polyclonal anti-ParB antibodies followed by high throughput sequencing. ChIP was performed with P. aeruginosa PAO1161 (WT) cells, PAO1161 pKB9 (ParB+++) cells with a slight, non-toxic ParB overproduction as well as with 3 strains containing parS modifications impairing ParB binding to these sites. The data confirmed ParB binding to all known parS sequences with the exception of parS5. Moreover, we identified more than a 1000 of new ParB-bound regions, majority of which contained a DNA motif corresponding to inner 7 nt from one arm of the parS palindrome. ParB interactions with these numerous sites could affect chromosome topology, compaction and gene expression classifying P. aeruginosa ParB as a Nucleoid Associated Protein (NAP).