Project description:Histidine is a good source of nutrient for many bacteria, but its utilization poses a significant challenge as it delivers excess nitrogen over carbon. The rate of histidine catabolism (hut) must thus be tightly regulated. Here, in Pseudomonas fluorescens SBW25, we show that the CbrAB two-component system directly activates the transcription of hut genes, while mediating succinate-induced carbon catabolite repression of hut at the translational level via the CbrAB-CrcYZ-Hfq/Crc regulatory cascade. When growing in minimal salt medium supplemented with histidine and succinate (the most preferred carbon source), the CbrAB-mediated promoter activity is weak; and the global nitrogen regulator NtrBC plays the dominant role in directly activating hut transcription.

Project description:HutC in Pseudomonas is a representative member of the HutC/GntR family of transcriptional regulators, which possess a N-terminal winged helix-turn-helix (wHTH) DNA-binding domain and a C-terminal substrate binding domain. HutC is generally known to represses expression of histidine utilization (hut) genes through binding to the PhutU promoter with urocanate (the first intermediate of the histidine degradation pathway) as the direct inducer. Here we first describe the detailed molecular interactions between HutC and its PhutU target site in a plant growth promoting bacterium P. fluorescens SBW25, and further show that HutC possesses specific DNA-binding activities with many targets in SBW25 genome. Subsequent RNA-seq analysis and phenotypic assays revealed an unexpected global regulatory role of HutC for successful bacterial colonization in planta.

Project description:b-Oxidative enzymes for fatty acid degradation (Fad) of long-chain fatty acid (LCFA), a component of lung surfactant phosphatidylcholine, are induced in vivo during lung infection in cystic fibrosis patients, which could contribute to nutrient acquisition and pathogenesis of Pseudomonas aeruginosa. In addition, fatty acid biosynthesis (Fab) is essential for the syntheses of two virulence controlling acylated-homoserine-lactone molecules in this organism. We mapped the promoter regions of the fadBA5-operon (PA3014 and PA3013) and a fadE homologue (PA2815) involved in Fad and the fabAB-operon involved in Fab. Focusing on the transposon mutagenesis of strain PAO1 carrying the PfadBA5-lacZ fusion, we identified a regulator for the fadBA5-operon to be PsrA (PA3006). Transcriptome analysis of the DpsrA mutant indicates its importance in regulating b-oxidative enzymes, which confirms a previous proteomic study. We further showed that induction of the fadBA-operon responds to LCFA signals, and this induction requires the presence of PsrA, suggesting that PsrA binds to LCFA to derepress fadBA5. Electrophoresis mobility shift assay indicate specific binding of PsrA to the fadBA5-promoter region. This binding is disrupted by specific LCFA (C18:1D9, C16:0, and to a lesser extent C14:0), but not by the first intermediate of b-oxidation, acyl-CoA. We proposed that PsrA is a Fad-regulator that binds and responds to LCFA signals in Pseudomonas aeruginosa. Keywords: Pseudomonas aeruginosa, wild-type PAO1 compared to PAO1-psrA::Tn

Project description:b-Oxidative enzymes for fatty acid degradation (Fad) of long-chain fatty acid (LCFA), a component of lung surfactant phosphatidylcholine, are induced in vivo during lung infection in cystic fibrosis patients, which could contribute to nutrient acquisition and pathogenesis of Pseudomonas aeruginosa. In addition, fatty acid biosynthesis (Fab) is essential for the syntheses of two virulence controlling acylated-homoserine-lactone molecules in this organism. We mapped the promoter regions of the fadBA5-operon (PA3014 and PA3013) and a fadE homologue (PA2815) involved in Fad and the fabAB-operon involved in Fab. Focusing on the transposon mutagenesis of strain PAO1 carrying the PfadBA5-lacZ fusion, we identified a regulator for the fadBA5-operon to be PsrA (PA3006). Transcriptome analysis of the DpsrA mutant indicates its importance in regulating b-oxidative enzymes, which confirms a previous proteomic study. We further showed that induction of the fadBA-operon responds to LCFA signals, and this induction requires the presence of PsrA, suggesting that PsrA binds to LCFA to derepress fadBA5. Electrophoresis mobility shift assay indicate specific binding of PsrA to the fadBA5-promoter region. This binding is disrupted by specific LCFA (C18:1D9, C16:0, and to a lesser extent C14:0), but not by the first intermediate of b-oxidation, acyl-CoA. We proposed that PsrA is a Fad-regulator that binds and responds to LCFA signals in Pseudomonas aeruginosa. Experiment Overall Design: PAO1 and PAO1-psrA::Tn cultures grown in LB and cells were harvested at mid-log phase. Total RNA was isolated from both samples, and used for cDNA synthesis. And then, the cDNA for both samples were fragmented and labeled. The cDNA of PAO1 was used for 2 GeneChips, and PAO1-psrA::Tn cDNA was used for three GeneChips.

Project description:PAO1 and FRD1 were cultured planktonically and in biofilms with 10 mM calcium and no added calcium. The transcriptional response to calcium addition was determined for PAO1 cultured planktonically, for FRD1 cultured planktonically, for PAO1 cutured in biofilms, and for FRD1 cultured in biofilms. Pseudomonas aeruginosa is an opportunistic human pathogen that causes severe, life threatening infections in patients with cystic fibrosis (CF), endocarditis, wounds, or with artificial implants. During CF pulmonary infections, P. aeruginosa often encounters environments where the levels of calcium (Ca2+) are elevated. Previously, we showed that P. aeruginosa responds to externally added Ca2+ through enhanced biofilm formation, increased production of several secreted virulence factors, and by developing a transient increase in the intracellular Ca2+ followed by its removal to the basal sub-micromolar level. However, the molecular mechanisms responsible for regulating Ca2+-induced virulence factor production and Ca2+ homeostasis are not known. Here, we characterized the genome-wide transcriptional response of P. aeruginosa strains PAO1 and FRD1 to elevated [Ca2+] in both planktonic cultures and in biofilms. Among the genes induced by CaCl2 in PAO1 was an operon containing the two-component regulator PA2656-PA2657 (here called carS and carR), while the closely related two-component regulators, phoPQ and pmrAB were repressed by CaCl2 addition. To identify the regulatory targets of CarSR, we constructed a deletion mutant of carR, and performed transcriptome analysis of the mutant strain at low and high [Ca2+]. Among the genes regulated by CarSR in response to CaCl2 are the predicted periplasmic OB-fold protein, PA0320 and the inner membrane-anchored five-bladed -propeller protein, PA0327. Mutations in both PA0320 and PA0327 affected Ca2+ homeostasis, reducing the ability of P. aeruginosa to export excess Ca2+. In addition, a mutation in PA0327 had a pleotrophic effect in a Ca2+-dependent manner, altering swarming motility, pyocyanin production, and tobramycin sensitivity. Overall, the results indicate that the two-component system CarSR is responsible for sensing high levels of external Ca2+, and responding through its regulatory targets that modulate Ca2+ homeostasis, surface-associated motility, and production of the virulence factor, pyocyanin.

Project description:D-Glutamate (D-Glu), an essential component of peptidoglycans, can be utilized as carbon and nitrogen source by Pseudomonas aeruginosa. DNA microarrays were employed to identify genes involved in D-Glu catabolism. Through gene knockout and growth phenotype analysis, the divergent dguR-dguABC (D-glutamate utilization) gene cluster was shown to participate in D-Glu catabolism and regulation. The dguA gene encodes a FAD-dependent D-amino acid dehydrogenase with D-Glu as its preferred substrate, and its promoter was specifically induced by exogenous D-Glu and D-Gln. The function of DguR as transcriptional activator of the dguABC operon was demonstrated by promoter activity measurements in vivo and by mobility shift assays with purified His-tagged DguR in vitro. Although the DNA-binding activity of DguR did not require D-Glu, the presence of D-Glu in the binding reaction was found to stabilize a preferred nucleoprotein complex. The dguB gene encodes a putative enamine/imine deaminase of the RidA family, but its role in D-Glu catabolism remained to be determined. While a lesion in dguC encoding a periplasmic solute binding protein did not affect growth on D-Glu, the AatJMQP transporter for acidic amino acid uptake was found essential for D-Glu and L-Glu utilization. Expression of this uptake system was subjected to induction by exogenous DL-Glu, most likely via the AauSR two-component system. In summary, DguA was identified in this study as a new member of the FAD-dependent amino acid dehydrogenase family for D-amino acid catabolism. DguR serves as a D-Glu sensor and transcriptional activator of the dguA promoter. Pseudomonas aeruginosa PAO1 was chosen as model to study gene response with different D-amino acids.

Project description:Among multiple interconnected pathways for L-Lysine (L-Lys) catabolism in pseudomonads, Pseudomonas aeruginosa PAO1 employed the decarboxylase and the transaminase pathways. However, up till now several genes involved in the operation and regulation of these pathways were still missing. Transcriptome analyses coupled with promoter activity measurements and mutant growth phenotype analysis lead us to identify several new members of the L-Lys and D-Lys catabolic pathways and their regulatory elements, including argR to trigger lysine decarboxylation into cadaverine, PauR for the γ-glutamylation pathway of polyamine catabolism into 5-aminovalerate, gcdR-gcdHG for glutarate utilization, dpkA, amaR-amaAB and PA2035 for D-Lys catabolism, lysR-lysXE for L-Lys efflux, and lysP for L-Lys uptake. Gene expression microarray, including probe preparation, hybridization, fluidics run and chip scan, was performed by Georgia State University DNA/Protein Core Facility. P. aeruginosa PAO1 was grown aerobically in minimal medium P with 350 rpm shaking at 37C, in the presence of 10mM L-glutamate supplemented with 10 mM L-lysine, cadaverine, 5-amino valerate, glutaric acid, D-lysine or 5mM L-pipecolate. Cells were harvested when the optical density at 600 nm reached 0.5~0.6 by centrifugation for 5 minutes at 4C. Total RNA samples were isolated by RNeasy purification kit following instructions of the manufacturer (Qiagen). Reverse transcription for cDNA synthesis, fragmentation by DNase I treatment, cDNA probe labeling and hybridization were performed according to the instructions of GeneChip manufacturer (Affymetrix). Data were processed by Microarray Suite 5.0 software normalizing the absolute expression signal values of all chips to a target intensity of 500. GeneSpring software (Silicon Genetics) was used for expression pattern analysis and comparison. Data collection was carried out using GCOS 1.4 software (Affymetrix). Probe intensity values were normalized to a target value of 500 with normalization factor equal to 1. Data analysis was performed using GeneSpring GX 11 Software (Aglient, Palo Alto,CA). Related Research Papers: 1. Indurthi SM, Chou HT, Lu CD. Molecular Characterization of lysR-lysXE, gcdR-gcdHG, and amaR-amaAB Operons for Lysine Export and Catabolism: A Comprehensive Lysine Catabolic Network in Pseudomonas aeruginosa PAO1. Microbiology. 2015 Submitted [EMID:04803de65c782] 2. Chou HT, Li J, and Lu CD. Functional Characterization of the agtABCD and agtSR Operons for γ-Aminobutyrate and δ-Aminovalerate Uptake and Regulation in Pseudomonas aeruginosa PAO1. Curr. Microbiology. 2014 Jan;68(1):59-63. 3. Chou HT, Li JY, Peng YC, Lu CD. Molecular characterization of PauR and its role in control of putrescine and cadaverine catabolism through the γ-glutamylation pathway in Pseudomonas aeruginosa PAO1. J Bacteriol. 2013 Sep; 195(17):3906-13. 4. Chou HT, Hegazy M, Lu CD. L-lysine Catabolism is Controlled by Arginine/ArgR in Pseudomonas aeruginosa PAO1. J Bacteriol. 2010 Nov;192(22):5874-80

Project description:It has been shown that the filamentous phage, Pf4, plays an important role in biofilm development, stress tolerance, genetic variant formation and virulence in Pseudomonas aeruginosa PAO1. These behaviours are linked to the appearance of superinfective phage variants. Here, we have investigated the molecular mechanism of superinfection as well as how the Pf4 phage can control host gene expression to modulate host behaviours. Pf4 exists as a prophage in PAO1 and encodes a homolog of the P2 phage repressor C. Through a combination of molecular techniques, ChIPseq and transcriptomic analyses, we show that repressor C (Pf4r) is the minimal factor for immunity against reinfection by Pf4 possibly through Pf4r binding to its putative promoter region, and that Pf4r also functions as a transcriptional regulator for expression of host genes. A binding motif for Pf4r was also identified. In wild type P. aeruginosa and Pfr4 complemented Pf4 deficient mutant strains, virulence factor related genes including phenazine and type VI secretion system effectors were upregulated, potentially explaining the reduced virulence of Pf4-deficient P. aeruginosa PAO1. X-ray crystal structure analysis shows that Pf4r forms symmetric homo-dimers homologous to the E.coli bacteriophage P2 RepC protein. A mutation associated with the superinfective Pf4r variant, found at the dimer interface, suggests dimer formation may be disrupted, which derepresses phage replication. This is supported by MALS analysis where the Pf4r* protein only shows monomer formation. Collectively, these data suggest the mechanism by which filamentous phages play such an important role in P. aeruginosa biofilm development.

Project description:Two component systems (TCSs) control a large proportion of virulence factors in Pseudomonas aeruginosa. Yet, investigations on inhibitors of regulatory pathways of TCS remain scare, despite their potential in anti-virulence strategies. This work encompasses the working mechanism of PIT4, a protein derived from the lytic P. aeruginosa phage LSL4. This viral protein inhibits bacterial motility and in particular twitching motility, while reducing the virulence of P. aeruginosa towards HeLa cells. Via differential gene expression and a yeast two-hybrid screen, PIT4 was shown to interact with components of different two component systems. In one-on-one interaction assays, it was confirmed that PIT4 interacts with the histidine kinases FleS, PilS and PA2882, through interaction with the histidine kinase domain. As such, this work highlights the potential of previously unknown phage proteins in virulence regulation of multidrug resistant pathogens that might be exploited for anti-virulence strategies and biotechnological applications.

Project description:PAO1 was cultured planktonically to stationary phase with 10 mM calcium and no added calcium. The transcriptional response to calcium addition was determined. Pseudomonas aeruginosa is an opportunistic human pathogen that causes severe, life threatening infections in patients with cystic fibrosis (CF), endocarditis, wounds, or with artificial implants. During CF pulmonary infections, P. aeruginosa often encounters environments where the levels of calcium (Ca2+) are elevated. Previously, we showed that P. aeruginosa responds to externally added Ca2+ through enhanced biofilm formation, increased production of several secreted virulence factors, and by developing a transient increase in the intracellular Ca2+ followed by its removal to the basal sub-micromolar level. However, the molecular mechanisms responsible for regulating Ca2+-induced virulence factor production and Ca2+ homeostasis are not known. Here, we characterized the genome-wide transcriptional response of P. aeruginosa strains PAO1 and FRD1 to elevated [Ca2+] in both planktonic cultures and in biofilms. Among the genes induced by CaCl2 in PAO1 was an operon containing the two-component regulator PA2656-PA2657 (here called carS and carR), while the closely related two-component regulators, phoPQ and pmrAB were repressed by CaCl2 addition. To identify the regulatory targets of CarSR, we constructed a deletion mutant of carR, and performed transcriptome analysis of the mutant strain at low and high [Ca2+]. Among the genes regulated by CarSR in response to CaCl2 are the predicted periplasmic OB-fold protein, PA0320 and the inner membrane-anchored five-bladed -propeller protein, PA0327. Mutations in both PA0320 and PA0327 affected Ca2+ homeostasis, reducing the ability of P. aeruginosa to export excess Ca2+. In addition, a mutation in PA0327 had a pleotrophic effect in a Ca2+-dependent manner, altering swarming motility, pyocyanin production, and tobramycin sensitivity. Overall, the results indicate that the two-component system CarSR is responsible for sensing high levels of external Ca2+, and responding through its regulatory targets that modulate Ca2+ homeostasis, surface-associated motility, and production of the virulence factor, pyocyanin.