Project description:Integration host factor (IHF) sites are largely absent from intergenic regions of ORFs encoding central metabolic functions in Pseudomonas putida mt-2. To gain an insight into this unequal distribution of otherwise abundant IHF-binding sequences, the transcriptome of IHF-plus and IHF-minus cells growing exponentially on glucose as sole carbon source was examined. In parallel, the cognate metabolic fluxes of the wild-type P. putida strain and its ihfA derivative were determined by culturing cells to a steady-state physiological regime with (13) C-labelled glucose. While expression of many transcripts was altered by the lack of IHF, flux balance analysis revealed that the ihfA mutation did not influence central carbon metabolism. Identification of multiple IHF sites adjacent to genes responsive to the factor allowed a refinement of the consensus and the mapping of the preferred binding positions for activation or repression of associated promoters. That few (if any) of the genes affected by IHF involved core pathways suggested that the central carbon metabolism tolerates the loss of the factor. Instead, IHF controlled various cell surface-related functions and downregulated genes encoding ribosomal proteins, the alpha subunit of RNA polymerase and components of the ATP synthase. These results were confirmed with lacZ fusions to a suite of promoters detected in the transcriptome as affected by IHF. Taken together, the data suggest that IHF plays a role in the physiological shift that sets P. putida for entering stationary phase. We compared the transcriptional profiles of P. putida mt-2 and the ihfA mutant. Samples were hybridized on a P. putida genome-wide oligonucleotide-based DNA microarray (Progenika Biopharma SA). RNA samples of seven independent biological samples were mixed in three pools. A dye-swap was performed.

Project description:Pseudomonas putida KT2440 is a metabolically versatile soil bacterium useful both as a model biodegradative organism and as a host of catalytic activities of biotechnological interest. In this report, we present the high-resolution transcriptome of P. putida grown in different carbon sources as revealed by deep sequencing of the corresponding RNA pools. Examination of the data from growth on glycolytic (glucose, fructose) and gluconeogenic (succinate or glycerol) substrates revealed that > 20% of the P. putida genome is differentially expressed depending on the ensuing metabolic regime. Changes affected not only metabolic genes but also a suite of global regulators, e.g. the rpoS sigma subunit of RNAP, various cold-shock proteins and the three HU histone-like proteins. Specifically, the genes encoding HU subunit variants hupA, hupB and hupN drastically altered their expression levels (and thus their ability to form heterodimeric combinations) under the different growth conditions. Furthermore, we found that the two small RNAs crcZ and crcY, known to inhibit the Crc protein that mediates catabolite repression in P. putida, were both down-regulated by glucose. cDNA libraries from Pseudomonas supplemented with different carbon sources (glucose, glycerol, fructose, succinate) were sequenced using HiSeq 2000 to yield 91 paired-end reads. Gene expression values were compared.

Project description:Pseudomonas putida KT2440 is a metabolically versatile soil bacterium useful both as a model biodegradative organism and as a host of catalytic activities of biotechnological interest. In this report, we present the high-resolution transcriptome of P. putida grown in different carbon sources as revealed by deep sequencing of the corresponding RNA pools. Examination of the data from growth on glycolytic (glucose, fructose) and gluconeogenic (succinate or glycerol) substrates revealed that > 20% of the P. putida genome is differentially expressed depending on the ensuing metabolic regime. Changes affected not only metabolic genes but also a suite of global regulators, e.g. the rpoS sigma subunit of RNAP, various cold-shock proteins and the three HU histone-like proteins. Specifically, the genes encoding HU subunit variants hupA, hupB and hupN drastically altered their expression levels (and thus their ability to form heterodimeric combinations) under the different growth conditions. Furthermore, we found that the two small RNAs crcZ and crcY, known to inhibit the Crc protein that mediates catabolite repression in P. putida, were both down-regulated by glucose.

Project description:The integration host factor, IHF, is a DNA-binding and -bending protein with roles in local DNA structural organization and transcriptional regulation in Gram-negative bacteria. This heterodimeric protein is composed of the two highly homologous subunits IHF alpha and IHF beta. DNA microarray analysis was used to define the regulon of genes subject to IHF control in Salmonella enterica serovar Typhimurium. The transcription profile of the wild type was compared with those of mutants deficient in IHF alpha, IHF beta, or both IHF alpha and IHF beta. Our data reveal a new connection between IHF and the expression of genes required by the bacterium to undergo the physiological changes associated with the transition from exponential growth to stationary phase. When a mutant lacking IHF entered stationary phase, it displayed downregulated expression of classic stationary-phase genes in the absence of any concomitant change in expression of the RpoS sigma factor. Purified IHF was found to bind to the regulatory regions of stationary-phase genes indicating an auxiliary and direct role for IHF in RpoS-dependent gene activation. Loss of IHF also had a profound influence on expression of the major virulence genes and epithelial cell invasion, indicating a role in co-ordinating regulation of the pathogenic traits with adaptation to stationary phase. Although the three mutants showed considerable overlaps in the genes affected by the ihf lesions, the observed patterns were not identical, showing that S. Typhimurium has not one but three overlapping IHF regulons.

Project description:We report the application of a high-throughput technique, RNA-seq, to study the transcriptomic pattern of P. putida KT2440 cultures using myristic acid as the sole carbon source at the exponential phase of growth compared with cultures grown with glucose as the sole carbon source. Thus, we can explore the expression of genes involved in fatty acid degradation.

Project description:Carbon catabolite repression (CCR) is a gene regulation process that allows bacteria to use carbon-energy sources in a hierarchical manner. Thus, the presence of a preferred sugar, usually D-glucose, results in downregulation of genes participating in the transport and catabolic pathways of secondary carbon sources. Further, CCR controls the expression of global regulators that control expression of many genes involved in multiple aspects of bacterial physiology such as stress response proteins and virulence factors. The human-restricted pathogen Neisseria gonorrhoeae can rely upon a limited number of carbon-energy sources, including glucose and lactate and both are available within its infection niches. We recently reported that expression of the L-lactate permease-encoding gene lctP is subjected to glucose repression within physiological concentrations. However, the transducing mechanism or the gene that connect glucose with lctP promoter repression remained unknown. To address this issue, we performed an RNA-Seq analysis to determine the transcriptional landscape of gonococci due to changes in glucose or lactate concentrations in the growth media. Glucose was found to regulate 144 genes (5.5% of total genes in the genome) while lactate influenced the expression of 434 (16.5%) genes with an overlap of 97 genes between the two sugars. Both, glucose and lactate were found to upregulate genes involved in protein translation, a high energy consumption cellular function. Individually, glucose enhanced genes participating in glycolysis and repressed genes in the tricarboxylic acid (TCA) cycle, while lactate enhanced genes encoding respiratory enzymes and ATP synthase. Interestingly, lactate was found to repress expression of several genes encoding known gonococcal virulence factors such as tbpAB encoding the transferrin-binding proteins; the tonB and exbBD genes encoding the membrane energy transfer complex TonB-ExbB-ExbD required for many outer membrane transport systems; katA encoding an important H2O2-inducible catalase and to upregulate mtrR encoding the master repressor of the mtrCDE antimicrobial efflux pump genes. Moreover, glucose repressed mntC encoding a Zn/Mn ABC transporter and lctP, both required for resistance to killing by H2O2. These results set the framework to determine important gonococci virulent factor genes whose expression can be modulated by CCR as well as to discover the corresponding CCR regulators that control such genes.

Project description:In metabolically versatile bacteria, carbon catabolite repression (CCR) facilitates the preferential assimilation of the most efficient carbon sources, improving growth rate and fitness. In Pseudomonas putida, the Crc protein and the CrcZ and CrcY small RNAs (sRNAs), which are believed to antagonise Crc, are key players in CCR. Contrary to what occurs in other bacterial species, succinate or glucose elicit a weak CCR in this bacterium. We combined metabolic, transcriptomics and constraints-based metabolic flux analyses to clarify whether P. putida prefers succinate or glucose, and the role of the Crc/CrcZ-CrcY regulatory system in their metabolization. Succinate was consumed faster than glucose and allowed a higher growth rate. However, both compounds were co-metabolised when provided simultaneously. The levels of CrcZ and CrcY were lower when both substrates were present than when only one of them was provided, suggesting a role for Crc in coordinating metabolism. Metabolic reconstructions suggested that, when both substrates are present, Crc works to organize a metabolism in which carbon compounds flow in two opposite directions: from glucose to pyruvate, and from succinate to pyruvate. Therefore, Crc serves not only to favour the assimilation of preferred compounds, but also to balance the carbon fluxes, optimising metabolism and growth.

Project description:The response of P. putida CSV86 in response to preferential carbon source and varying nitrogen levels was studied in this experiment. The culture was grown in minimal medium with either naphthalene (0.1%) alone or along with glucose (0.25%) as carbon source and different concentration of ammonium nitrate. For nitrogen limiting 0.1% NH4N03 was added in the medium and for nitrogen rich 1% NH4N03 was used. As control CSV86 was also grown in 1X Luria Broth with glucose as additional carbon source. Overall it was seen that the strain could grow efficiently in varying nitrogen conditions by adapting or regulating their metabolism without compromising on the growth rate. To ascertain how the cells were coping with the nitrogen stress, gene expression by microarray was performed. RNA extraction was done using Qiagen RNeasy minikit (Germany). Standard Affymetrix protocol was followed for hybridization with GeneChip P. aeruginosa Genome Array supplied by Affymetrix as GeneChip for P. putida were not supplied by any company.

Project description:We used Progenika oligonucleotide arrays to monitore the gene expression of P. putida during carbon source stimulus experiments. After ensuring steady state conditions on benzoate, the stimuli were introduced by changing the carbon source from benzoate to glucose, from glucose to fructose and from fructose to benzoate, respectively. The single stimuli were monitored over a time period from 10 to 120 minutes after changing the carbon source by three representative timepoints. Moreover, the steady state conditions were compared among each other. Supplementary file: Individual normalized signal intensity VALUES for each channel of each array are provided in the FullNormalizedMatrix.txt file.

Project description:DNA microarrays were carried out to compare the transcriptional profiles of P. putida KT2440 and its isogenic knock-out mutant in agmR gene (mut agmR) when grown in M9 medium with glucose as a sole carbon source and in absense of chloramphenicol or any other stressor compound.