Examination of changes in the gene expression profile in response

Examination of changes in the gene expression profile in response to these stresses can provide mechanistic insight Screening Library supplier to the physiological response. RNA Sequencing (RNA-seq) is an established technology for quantifying gene expression that has much greater sensitivity and dynamic range than conventional microarray technology

[15]. RNA-seq is particularly relevant for controlled experiments comparing the expression in wild type and mutant strains of an organism [16]. Moreover, combining RNA-seq with genomic data can help identify genetic loci responsible for variation in gene expression between individuals [16]. The development of a Populus hydrolysate tolerant strain of C. thermocellum, which grows as well in 17.5% v/v Populus hydrolysate as the wild type (WT) does in STA-9090 in vivo Selleck Belinostat standard medium, has been reported [17]. Genomic analysis of the mutant strain (termed PM for Populus mutant) revealed several mutations in the strain that may be responsible for its faster growth rate and tolerance to Populus hydrolysate with selected mutations related to the transcriptional

changes [17]. The extent of the growth, end product production and Populus hydrolysate tolerance was described by kinetic modeling [18]. In the present study, the WT and PM strains were grown in various concentrations of Populus hydrolysate (0% or standard medium, 10% and 17.5% v/v Populus hydrolysate) and a genome-wide transcriptomic analysis was conducted at mid-log and late-log time points via RNA-seq. In addition to changes in transcription levels, post-transcriptional regulation of gene expression through the action of sRNA molecules has been demonstrated to play a key role in stress response in Clostridia [19]; however, the focus of this paper is on changes in gene regulation at the transcriptional

level. Two types of comparisons were used to further elucidate the potential mechanism(s) of tolerance for the PM strain: a comparison of the strains in standard and hydrolysate media and a comparison of each strain’s response to Populus hydrolysate-containing media using its gene expression profile in standard medium as a baseline. Results Fermentative growth Batch fermentations were conducted for the Populus mutant Ribose-5-phosphate isomerase (PM) and wild type (WT) strains of C. thermocellum as previously reported in Linville et al. [17]. Samples were taken at regular intervals from each fermentation unit based on their growth rate and analyzed for optical density (OD600) and metabolite concentration by HPLC. The dry cell weight (DCW) of the samples was determined by calibration curve (data not shown). In brief, the PM had approximately twice the growth rate when compared to the WT in standard medium [17,18]. The PM also produced 1.1-1.3 times more ethanol and the same amount of acetic acid than the WT under the same test conditions [17,18].

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