Project description:IrrE is a unique gene in Deinococcus, which is the switch of DNA repair and celluar surival network. Expressing IrrE enhanced the salt tolence in E. coli. To understand the effect of IrrE to E. coli during salt shock, we constructed the IrrE-expressing plasmid pMG1-IrrE. And pMG1 is the empty vector used as a control. The GroESL promoter was amplified from D. radiodurans R1 genomic DNA by PCR with proper primers. The PCR product was ligated into the T-cloning site of T-vector pMD18T, generating the plasmid pMG1. RNA extracted from cells of E. coli K-12 JM109 cells with pMG1 after 4 h of growth to OD 600 achieve 0.4, or cells with pMG1 after 1mol/L NaCl shock for 10 min (and 60 min) when their OD600 achieved 0.4. RNA extracted from cells of E. coli K-12 JM109 cells with pMG1-IrrE after 4 h of growth to OD 600 achieve 0.4, or cells with pMG1-IrrE after 1mol/L NaCl shock for 10 min (and 60 min)when their OD600 achieved 0.4. pMG1 and pMG1-IrrE datasets normalized separately.
Project description:Cellular tolerance toward ethanol is a complex phenotype involved many genes, and hard to be improved by manipulating individual genes. We previously established exogenous global regulator IrrE mutants that confer Escherichia coli with significantly enhanced tolerance to stresses, including ethanol. In order to elucidate the mechanism for enhancement of ethanol tolerance in the mutants and to identify new genes and pathways that can be possible targets for engineering of ethanol tolerance, we carried out comparative transcriptomic and proteomic analyses with the representative strains E1 and E0 (harboring the ethanol-tolerant mutant E1 of IrrE and the wild type IrrE, respectively). The data from transcriptome analyses were deposited here.
Project description:Cellular tolerance toward furfural is a complex phenotype involved many genes, and hard to be improved by manipulating individual genes. We previously established exogenous global regulator IrrE mutants that confer Escherichia coli with significantly enhanced tolerance to furfural stress. In order to elucidate the mechanism for enhancement of furfural tolerance in the mutants and to identify new genes and pathways that can be possible targets for engineering of furfural tolerance, we carried out comparative transcriptomic with the representative strains F1-37 and WT (harboring the furfural-tolerant mutant F1-37 of IrrE and the wild type IrrE, respectively). The data from transcriptome analyses were deposited here.
Project description:Cellular tolerance toward ethanol is a complex phenotype involved many genes, and hard to be improved by manipulating individual genes. We previously established exogenous global regulator IrrE mutants that confer Escherichia coli with significantly enhanced tolerance to stresses, including ethanol. In order to elucidate the mechanism for enhancement of ethanol tolerance in the mutants and to identify new genes and pathways that can be possible targets for engineering of ethanol tolerance, we carried out comparative transcriptomic and proteomic analyses with the representative strains E1 and E0 (harboring the ethanol-tolerant mutant E1 of IrrE and the wild type IrrE, respectively). The data from transcriptome analyses were deposited here. Cells of ethanol-tolerant mutant E1 and wild-type strain E0 were grown in 1.5% ethanol, and the samples for both of these two strains were prepared in triplicate with biological replicates
Project description:Cellular tolerance toward furfural is a complex phenotype involved many genes, and hard to be improved by manipulating individual genes. We previously established exogenous global regulator IrrE mutants that confer Escherichia coli with significantly enhanced tolerance to furfural stress. In order to elucidate the mechanism for enhancement of furfural tolerance in the mutants and to identify new genes and pathways that can be possible targets for engineering of furfural tolerance, we carried out comparative transcriptomic with the representative strains F1-37 and WT (harboring the furfural-tolerant mutant F1-37 of IrrE and the wild type IrrE, respectively). The data from transcriptome analyses were deposited here. Cells of furfural-tolerant mutant F1-37 and wild-type strain WT were grown in LB medium supplemented with furfural, and the cells were harvested in the exponential phase. The samples for both of these two strains were prepared in triplicate with biological replicates.
Project description:IrrE is a unique gene in Deinococcus, which is the switch of DNA repair and celluar surival network. Expressing IrrE enhanced the salt tolence in E. coli. To understand the effect of IrrE to E. coli during salt shock, we constructed the IrrE-expressing plasmid pMG1-IrrE. And pMG1 is the empty vector used as a control. The GroESL promoter was amplified from D. radiodurans R1 genomic DNA by PCR with proper primers. The PCR product was ligated into the T-cloning site of T-vector pMD18T, generating the plasmid pMG1.
Project description:To undestand the mechanism involved in abitoic stress tolerance of P. Putida (NBAII-RPF 9) the bacterium was grown in liquid LB media overnight and further subjected to saline shock of (1M NaCl) for one hour seperately. The cultures were pelleted with centrifuged for total RNA. The RNA was hybridised in 8X15K Agilent array and image analysis carried out with Agilent Microarray scanner.