Project description:To understand the mechanism of isopropanol tolerance of Escherichia coli for improvement of isopropanol production, we performed genome re-sequencing and transcriptome analysis of isopropanol tolerant E. coli strains obtained from parallel adaptive laboratory evolution under IPA stress.
Project description:Two genetic selection systems that couple metabolite hydroxylation or methylation of small molecules to growth of Escherichia coli are presented in this study. One system targets pterin-dependent hydroxylation (tBPt) while another focuses on S-adenosylmethionine-dependent methylation (SAM). Using adaptive laboratory evolution with growth selection, these two systems are demonstrated to not only achieve in vivo directed evolution of enzymes involved in human hormone biosynthesis but also reveal non-intuitive host factors that elude existing synthetic biology approaches. Raw sequencing data for the relevant strains generated in this study are presented here.
Project description:We generated four strains of Escherichia coli K12 MG1655 with distinct proton motive force generation potential and performed the adaptive laboratory evolution of these strains to study how the system adapts to the loss of alternate electron transfer pathways of the Electron Transport System. RNA-Seq was performed to examine the underlying transcriptional rewiring.
Project description:We have performed adaptive laboratory evolution of E. coli pdhR gene deletion strain to examine the adaptive strategies of E. coli.