Project description:Isobutanol has emerged as a potential biofuel due to recent metabolic engineering efforts. Here we used gene expression and transcription factor(TF)-gene interaction data, genetic knockouts, and Network Component Analysis (NCA) to map the isobutanol response network of Escherichia coli under aerobic conditions. A transcriptional response network consisting of 2004 genes/TFs and 2600 interactions was identified. Through further investigation ArcA, Fur, and PhoB were demonstrated to be important mediators of this response. In addition, the ethanol, n-butanol, and isobutanol response networks were compared in order to identify common and distinct toxicity features associated with these three alcohol based biofuels.

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Project description:Isobutanol has emerged as a potential biofuel due to recent metabolic engineering efforts. Here we used gene expression and transcription factor(TF)-gene interaction data, genetic knockouts, and Network Component Analysis (NCA) to map the isobutanol response network of Escherichia coli under aerobic conditions. A transcriptional response network consisting of 2004 genes/TFs and 2600 interactions was identified. Through further investigation ArcA, Fur, and PhoB were demonstrated to be important mediators of this response. In addition, the ethanol, n-butanol, and isobutanol response networks were compared in order to identify common and distinct toxicity features associated with these three alcohol based biofuels. E. coli was grown aerobically at 37C in minimal MOPS media with 0.2% glucose as the sole carbon source. At mid-log, the cultures were split in half with one half receiving a 1% isobutanol, 1% n-butanol, or 3% ethanol (vol/vol) treatment, while the other half remained unperturbed. After 10 minutes of continued growth cultures were harvested. Total RNA was purified using a Qiagen RNeasy midikit, and labeled indirectly with amino-allyl dUTP. Every experiment had a minimum of 4 biological replicates, each with 2 technical replicates (8 arrays/experiment). Normalized log10 expression ratios were obtained from lcDNA implemented with quality filtering (receptor.seas.ucla.edu/lcDNA; Hyduke DR, Rohlin L, Kao KC, Liao JC. 2003 A software package for cDNA microarray data normalization and assessing confidence intervals. OMICS 7(3):227-234.)

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Project description:BACKGROUND:Isobutanol is a promising next generation biofuel with demonstrated high yield microbial production, but the toxicity of this molecule reduces fermentation volumetric productivity and final titers. Organic solvent tolerance is a complex, multigenic phenotype that has been recalcitrant to rational engineering approaches. We apply experimental evolution followed by genome resequencing and a gene expression study to elucidate genetic bases on adaptation to exogenous isobutanol stress. RESULTS:The adaptations acquired in our evolved lineages exhibit antagonistic pleiotropy between minimal and rich medium, and appear to be specific to the effects of longer chain alcohols. By examining genotypic adaptation in multiple independent lineages, we find evidence of parallel evolution in hfq, mdh, acrAB, gatYZABCD, and rph genes. Many isobutanol tolerant lineages show reduced rpoS activity, perhaps related to mutations in hfq or acrAB. Consistent with the complex, multigenic nature of solvent tolerance, we observe adaptations in a diversity of cellular processes. Many adaptations appear to involve epistasis between different mutations, implying a rugged fitness landscape for isobutanol tolerance. We observe a trend of evolution targeting post-transcriptional regulation and high centrality nodes of biochemical networks. Collectively, the genotypic adaptations we observe suggest mechanisms of adaptation to isobutanol stress based on remodelling the cell envelope and surprisingly, stress response attenuation. CONCLUSIONS:We have discovered a set of genotypic adaptations that confer increased tolerance to exogenous isobutanol stress. Our results are immediately useful to efforts to engineer more isobutanol tolerant host strains of E. coli for isobutanol production. We suggest that rpoS and post-transcriptional regulators, such as hfq, RNA helicases, and sRNAs may be interesting mutagenesis targets for futurue global phenotype engineering.

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