Project description:Sphingopyxis witflariensis strain:DSM 14551 Genome sequencing and assembly

Project description:Halopseudomonas bauzanensis strain:W13Z2 Genome sequencing and assembly

Project description:Sphingopyxis terrae subsp. ummariensis strain:DSM 24316 Genome sequencing and assembly

Project description:Sphingopyxis italica DSM 25229 genome sequencing

Project description:Sphingopyxis panaciterrulae DSM 27163 genome sequencing

Project description:Sphingopyxis panaciterrae DSM 27164 genome sequencing

Project description:We performed differential RNA-sequencing (dRNA-seq) experiments in both minimal medium (MM) plus β-hydroxybutyrate (β-HB) and MM plus tetralin (THN) of Sphingopyxis granuli strain TFA. The objective was mapping the Transcription Start Site (TSS) of each gene in the genome in both conditions, detecting non-coding RNAs (ncRNAs) and comparing the gene expression profile in a preferential carbon source (β-HB) versus tetralin (an aromatic pollutant). The dRNA-seq technique consists of using a termination exonuclease (TEX) to allow the discrimination of primary and processed transcripts. Furthermore, to detect Hfq-bound RNAs we co-immunoprecipitated RNA from the wild type strain (negative control) and a TFA strain with an Hfq-3xFlag tagged version (MPO501 strain) using an anti-3xFlag antibody and performed RNA-sequencing from the precipitated RNA.

Project description:Pseudomonas bauzanensis LMG 26048 genome sequencing

Project description:Pseudomonas bauzanensis overview

Project description:Ruminiclostridium thermocellum DSM 1313 strain adhE*(EA) expression was studied along with ∆hydG and ∆hydG∆ech mutants strains deposited under GSE54082. All strains have been described in a study entitled Elimination of hydrogenase post-translational modification blocks H2 production and increases ethanol yield in Clostridium thermocellum. Biswas, et .al. Biotechnology for Biofuels 2015 8:20 Ruminiclostridium (Clostridium) thermocellum is a leading candidate organism for implementing a consolidated bioprocessing (CBP) strategy for biofuel production due to its native ability to rapidly consume cellulose and its existing ethanol production pathway. C. thermocellum converts cellulose and cellobiose to lactate, formate, acetate, H2, ethanol, amino acids, and other products. Elimination of the pathways leading to products such as H2 could redirect carbon flux towards ethanol production. Rather than delete each hydrogenase individually, we targeted a hydrogenase maturase gene (hydG), which is involved in converting the three [FeFe] hydrogenase apoenzymes into holoenzymes by assembling the active site. This functionally inactivated all three Fe-Fe hydrogenases simultaneously, as they were unable to make active enzymes. In the ∆hydG mutant, the [NiFe] hydrogenase-encoding ech was also deleted to obtain a mutant that functionally lacks all hydrogenase. The ethanol yield increased nearly 2-fold in ∆hydG∆ech compared to wild type, and H2 production was below the detection limit. Interestingly, ∆hydG and ∆hydG∆ech exhibited improved growth in the presence of acetate in the medium. Transcriptomic and proteomic analysis reveal that genes related to sulfate transport and metabolism were up-regulated in the presence of added acetate in ∆hydG, resulting in altered sulfur metabolism. Further genomic analysis of this strain revealed a mutation in the bi-functional alcohol/aldehyde dehydrogenase adhE gene, resulting in a strain with both NADH- and NADPH-dependent alcohol dehydrogenase activities, whereas the wild type strain can only utilize NADH. This is the exact same adhE mutation found in ethanol-tolerant C. thermocellum strain E50C, but ∆hydG∆ech is not more ethanol tolerant than the wild type. Targeting protein post-translational modification is a promising new approach to target multiple enzymes simultaneously for metabolic engineering. This GEO study pertains to expression profiles generated for C. thermocellum DSM 1313 strain adhE*(EA)