Project description:Sphingomonas limnosediminicola strain:PT-12 Genome sequencing

Project description:Investigation of whole genome gene expression level in motile strain of Sphingomonas. sp A1 All flagellar genes in motile strain of Sphingomonas. sp A1 are highly transcribed.

Project description:Investigation of whole genome gene expression level in motile strain of Sphingomonas. sp A1 All flagellar genes in motile strain of Sphingomonas. sp A1 are highly transcribed. A two chip study using total RNA recovered from wild-type and motile strains of Sphingomonas. sp A1 grown in 0.5% alginate medium.

Project description:Sphingomonas sp. SFZ2018-12 Genome sequencing and assembly

Project description:Sphingomonas sp. KR1UV-12 Genome sequencing and assembly

Project description:Clostridium chrysemydis strain:PT Genome sequencing and assembly

Project description:Platinum-based drugs (Pt drugs) are widely used in cancer chemotherapy, yet their genome-wide DNA binding patterns remain incompletely understood. Here, we present Pt-seq, an antibody-assisted, genome-wide method for mapping Pt-DNA adducts at single-base resolution. By employing exo- and endo- nucleases to remove background DNA, Pt-seq enables highly robust and sensitive profiling of binding sites for cisplatin, oxaliplatin, lobaplatin, and a Pt(IV) complex. Using Pt-seq, we identified hundreds to a few thousand binding clusters that are 10-20 kb in length and highly consistent among different Pt drugs. Notably, these binding clusters predominantly localize to centromeric and rDNA regions. In cisplatin-resistant cells, we found significantly reduced binding within these regions, suggesting a potential role in drug resistance. Moreover, we found that de novo mutations in cancer cells can create novel binding sites for Pt drugs. Based on this, we demonstrated that ICR-191, an acridine orange compound capable of inducing G insertions, enhances cisplatin-DNA crosslinking and sensitizes cells to Pt drugs. Collectively, Pt-seq sensitively profiles Pt drug-DNA interactions and deepens our understanding of the genome-wide effect of chemotherapeutic drugs.

Project description:Sphingomonas wittichii RW1 is a bacterium isolated for its ability to degrade the toxic polyaromatic hydrocarbon dibenzofuran (dbf) and its polychlorinated derivatives. Its genome consists of a chromosome and two plasmids, encoding for more than 5300 genes. We studied genome-wide expression of strain RW1 to dbf in three different experimental setups, including both batch cultures and chemostats, comparing in all cases to the transcriptome of cells grown on phenylalanine as carbon source. A short exposure to DBF in chemostat or in batch, provoked the up-regulation of the ECF sigma 24, catalases, peroxiredoxins, chaperones, an aquaporin, several OmpA domain-containing proteins and the down-regulation of genes involved in TCA cycle, oxidative phosphorylation, amino acid metabolism and ribosomal proteins. When growing strain RW1 on DBF, genes known to be involved in DBF degradation were induced 2 to 4 fold. Additionally, two cluster of genes, putatively participating in the gentisate and meta-cleavage branches of the DBF degradation pathway, were induced from 12 to 19 fold.

Project description:Fusarium sp. isolate PT

Project description:Rothia nasimurium strain:PT-32 Genome sequencing and assembly