Project description:Pseudomonas aeruginosa displays tremendous metabolic diversity, controlled in part by the abundance of transcription regulators in the genome. We have been investigating P. aeruginosa’s response to the host, particularly changes regulated by the host-derived quaternary amines choline and glycine betaine (GB). We previously identified GbdR as an AraC-family transcription factor that directly regulates choline acquisition from host phospholipids (via binding to plcH and pchP promoters), is required for catabolism of the choline metabolite GB, and is an activator that induces transcription in response to GB or dimethylglycine. Our goal was to characterize the GbdR regulon in P. aeruginosa using genetics and chemical biology in combination with transcriptomics and in vitro DNA-binding assays. Here we show that GbdR activation regulates transcription of 26 genes from 12 promoters; 11 of which have measureable binding to GbdR in vitro. The GbdR regulon includes the genes encoding GB, dimethylglycine, sarcosine, glycine, and serine catabolic enzymes, and the BetX and CbcXWV quaternary amine transport proteins. . Additionally, identification of two uncharacterized regulon members suggests roles for these proteins in response to choline metabolites. The conditions for inclusion in the gbdR regulon were: (i) called present in the array, (ii) changed more than 2.5-fold in signal in a statistically significant manner, (iii) altered in all three 'inducing' conditions (ethylcholine, choline+propargylcholine, and choline in the dgcA mutant), but (iv) not induced in the wild-type choline or diethylcholine treatments.

Project description:The response of bacteria to the conditions at the site of infection is a key part of the transcriptional program that will determine the sucess of the infectious agent. To model the environment of the distal airway, we used bovine pulmonary surfactant (Survanta). P. aeruginosa transcript levels were measured in the presence or absence of Survanta in MOPS minimal medium to identify transcripts altered in response to surfactant. The most highly induced transcript in Survanta was PA5325, renamed sphA based on our findings that the gene was specifically induced by sphingosine derived from the sphingomyelin present in pulmonary surfactant. A divergently transcribed transcription factor, PA5324, was demonstrated to be critical for the sphingosine dependent induction of sphA and was therefore renamed SphR. Microarrays of the sphR mutant cells were compared to wild type to determine the likely SphR regulon. Wild type and sphR mutant cells were pre-grown in MOPS minimal media and then split and resuspended in MOPS pyruvate or MOPS pyruvate + surfactant

Project description:Analysis of the RNA-seq reads confirmed that transcription of many of the previously identified Pho-regulon genes of Sinorhizobium meliloti was regulated by the availability of inorganic phosphate in the media. The transcriptional start sites of many of the Pho-regulon genes as determined by RNA-seq reads were found to correspond to those determined from primer extension analysis. mRNA from S. meliloti RmP110 grown in MOPS + 2 mM Pi and MOPS + 20 M-BM-5M Pi M-bM-^@M-^S directional RNA-seq via Illumina sequencing

Project description:To investigate whether salt-stress dependent activation of SigB is mitigated when cells are pre-loaded with the compatible solute glycine betaine, we analyzed salt induction of the SigB regulon in the presence of the precursor choline at a genome-wide level. The median expression value of SigB-regulated genes was 1.7-fold higher in cells that received choline immediately before salt stress compared to cells where choline was added 60 minutes prior to the salt stress.

Project description:Glycine betaine (GB) is a potent osmoprotectant for salt stressed Bacillus subtilis cells, which possess three high-affinity uptake systems for GB. OpuA is the dominant transporter for this compatible solute. Northern blot analysis, primer extension experiments and opuA-treA reporter gene fusion studies demonstrated that opuA expression is strongly induced at high osmolality from a single SigA-type promoter. Promoter mutations that improve the match of the opuA promoter to the consensus sequence substantially increase basal-level expression but reduce inducibility by high salinity. Expression of opuA is sensitively controlled by GB, which causes significant repression of opuA transcription at low and high salinity. GB influences the kinetics as well as the final level of high salinity induction of opuA in a concentration-dependent fashion. The repressing effect of GB on opuA transcription requires the intracellular presence of GB, regardless whether it is taken up via OpuA or other transporters or synthesized from choline. Genome-wide transcriptional profiling of salt-stressed B. subtilis cells demonstrated that the repressive effect of GB targets only a subset of high-salinity induced genes. This group of GB-responsive genes comprises in essence the full set of genes with demonstrated functions in either the uptake or synthesis of compatible solutes. Four different samples (untreated, GB, NaCl, and GB + NaCl treated) were analyzed and each sample was hybridized in triplicate.

Project description:Human fecal communities were dosed with either choline, carnitine, butyrobetaine, or glycine betaine to measure the microbial response to quaternary amine addition. Samples were digested with trypsin, and analyzed by LC-MS/MS. Data was searched with MS-GF+ using PNNL's DMS Processing pipeline.

Project description:Glycine betaine (GB) is a potent osmoprotectant for salt stressed Bacillus subtilis cells, which possess three high-affinity uptake systems for GB. OpuA is the dominant transporter for this compatible solute. Northern blot analysis, primer extension experiments and opuA-treA reporter gene fusion studies demonstrated that opuA expression is strongly induced at high osmolality from a single SigA-type promoter. Promoter mutations that improve the match of the opuA promoter to the consensus sequence substantially increase basal-level expression but reduce inducibility by high salinity. Expression of opuA is sensitively controlled by GB, which causes significant repression of opuA transcription at low and high salinity. GB influences the kinetics as well as the final level of high salinity induction of opuA in a concentration-dependent fashion. The repressing effect of GB on opuA transcription requires the intracellular presence of GB, regardless whether it is taken up via OpuA or other transporters or synthesized from choline. Genome-wide transcriptional profiling of salt-stressed B. subtilis cells demonstrated that the repressive effect of GB targets only a subset of high-salinity induced genes. This group of GB-responsive genes comprises in essence the full set of genes with demonstrated functions in either the uptake or synthesis of compatible solutes.

Project description:Glycinebetaine-induced water-stress tolerance in codA-expressing transgenic indica rice is associated with up-regulation of several stress responsive genes. Rice (Oryza sativa L.), a non-accumulator of glycinebetaine (GB), is highly susceptible to abiotic stress. Transgenic rice with chloroplast-targeted choline oxidase encoded by the codA gene from Arthrobacter globiformis has been evaluated for inheritance of transgene up to R5 generation and water-stress tolerance. During seedling, vegetative and reproductive stages, transgenic plants could maintain higher activity of photosystem II and they show better physiological performance, e.g. enhanced detoxification of reactive oxygen species compared to wild-type plants under water-stress. Survival rate and agronomic performance of transgenic plants is also better than wild-type following prolonged water-stress. Choline oxidase converts choline into glycinebetaine and H2O2 in a single step. It is possible that H2O2 /GB might activate stress response pathways and prepare transgenic plants to mitigate stress. To check this possibility, microarray-based transcriptome analysis of transgenic rice has been done. It unraveled altered expression of many genes involved in stress responses, signal transduction, gene regulation, hormone signaling and cellular metabolism. Overall, 165 genes show more than 2 folds up-regulation at P value <0.01 in transgenic rice. Out of these, at least 50 genes are known to be involved in plant stress response. Exogenous application of H2O2 or GB to wild-type plants also induces such genes. Our data show that metabolic engineering for GB is a promising strategy for introducing stress tolerance in crop plants and which could be imparted, in part, by H2O2- and/or GB-induced stress response genes. Experiment Overall Design: Rice (Oryza sativa L.), transgenic plants expressing codA gene from Arthrobacter globiformis were compared with untransformed plants at seedling level

Project description:Pseudomonas aeruginosa is a virulent opportunistic pathogen responsible for high morbity in COPD, burns , implanted medical devices and cystic fibrosis. Pseudomonas aeruginosa is a problematic colonizer of the human lung. P. aeruginosa produces a phospholipase C (PlcH) that degrades choline-containing lipids such as phosphatidylcholine and sphingomylein that are found in lung surfactant and in host membranes. In this study, we analyzed gene expression in mutants defective in PlcH production (delta-plcH and delta-gbdR) and the wild type when growing in medium with lung surfactant. Pseudomonas aeruginosa was cultured in liquid cultures with aeration in a defined medium with Survanta, a lung surfactant replacement. Cultures were harvested during mid-exponential phase, and RNA was isolated for microarray analysis. The P. aeruginosa strain PAO1 wild type gene expression was compared to expression profiles from delta-gbdR and delta-plcHR deletion mutants, two mutants defective in PlcH production.

Project description:Pseudmonas aeruginosa PAO1 wild-type cultured in MOPS Glycerol compared to MOPS Glycerol Hypoxia (restricted oxygen). P. aeruginosa strain PAO1 was grown in 40 ml MOPS with glycerol as sole carbon source (triplicate), 37 °C with shaking (250 rpm) in baffled flasks (500 ml). For the restricted oxygen condition, P. aerugionosa was cultured in the same conditions, except non-baffled flasks were used, and the shaking speed was 80 rpm (gentle aggitation). A thin layer 10 ml of mineral oil was overlaid on top of these cultures to restrict oxygen transfer.