Project description:HMF and furfural were pulse added to xylose-utilizing Saccharomyces cerevisiae during either the glucose consumption phase or the xylose consumption phase. Transcriptome samples were collected before and one hour after pulsing of inhibitors.

Project description:HMF and furfural were pulse added to xylose-utilizing Saccharomyces cerevisiae during either the glucose consumption phase or the xylose consumption phase. Transcriptome samples were collected before and one hour after pulsing of inhibitors.

Project description:The inhibitors hydroxymethylfurfural (HMF) and furfural were added to the feed-medium of carbon-limited anaerobic chemostat cultures. Samples were taken for transcriptome analysis at steady-state from cultures with inhibitors and without inhibitors. Three biological replicates from each condition (inhibitors, no inhibitors) were analyzed.

Project description:Adapted tolerant yeast strain Y-50049 is able to in situ detoxify furfural and HMF while the wild type control Y-12632 repressed to loss function under challenges of 20 mM each of furfural and HMF A time course study during the lag phase with cells harvested at 18, 24, 28, and 42 h after 20 mM furfural and 20 mM HMF treatment

Project description:The inhibitors hydroxymethylfurfural (HMF) and furfural were added to the feed-medium of carbon-limited anaerobic chemostat cultures. Samples were taken for transcriptome analysis at steady-state from cultures with inhibitors and without inhibitors.

Project description:Adapted tolerant yeast strain Y-50049 is able to in situ detoxify furfural and HMF while the wild type control Y-12632 repressed to loss function under challenges of 20 mM each of furfural and HMF

Project description:Transcriptional profiling of adapted tolerant industrial yeast Saccharomyces cerevisiae NRRL Y-50049 compared with its parental wild type NRRL Y-12632 in response to challenge of furfural and HMF each at 20 mM. Y-50049 is able to detoxify toxic furan aldehydes in situ while produce ethanol. Under the same conditions, the wild type Y-12632 was repressed and unable to grow and function.

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:The data explore the transcriptional response of strain LY180 and the furfural-resistant derivative EMFR9 to 0.5 g/L furfural LY180 and EMFR9 and differences in their expression profiles are described in Miller, E. N., L. R. Jarboe, L. P. Yomano, S. W. York, K. T. Shanmugam, and L. O. Ingram. 2009. Silencing of NADPH-dependent oxidoreductase genes (yqhD and dkgA) in furfural-resistant ethanologenic Escherichia coli. Appl Environ Microbiol 75:4315-23. The response of LY180 to furfural is described in Miller, E. N., L. R. Jarboe, P. C. Turner, P. Pharkya, L. P. Yomano, S. W. York, D. Nunn, K. T. Shanmugam, and L. O. Ingram. 2009. Furfural Inhibits Growth by Limiting Sulfur Assimilation in Ethanologenic Escherichia coli strain LY180. Appl Environ Microbiol., 2009. Total RNA was prepared from cultures of LY180 and EMFR9 immediately before and 15 min after addition of furfural to 0.5 g/L. The Nimblegen TI83333 chip measures expression of 4,237 genes, with 5 replicates, and 18 probes average per gene. Data from replicate 1 (OID 8641) and replicate 2 (OID 14117) was analyzed independently.

Project description:Furfural is the prevalent microbial inhibitor generated during pretreatment and hydrolysis of lignocellulosic biomass to monomeric sugars, but the molecular response of Clostridium beijerinckii NCIMB 8052 to this compound is unknown. To discern the effect of furfural on C. beijerinckii and to gain insights into the molecular mechanisms of action and detoxification, we studied the physiological changes of furfural-stressed cultures during acetone-butanol-ethanol (ABE) fermentation, and profiled differentially expressed genes by genome-wide transcriptional analysis. C. beijerinckii exposed to furfural stress during the acidogenic growth phase produced 13% more ABE than the unstressed control. The growth and ABE by C. beijerinckii ceased following exposure to furfural stress during the solventogenic growth phase. By comparing gene expression of furfural-stressed cultures to that of the unstressed control, at both the acidogenic and solventogenic phases, we ascertained that furfural induces expression of several genes including those that code for heat shock proteins, redox enzymes and cofactor associated proteins, and ATP-binding cassette transporters, and represses genes belonging to the phosphotransferase system, two-component system, chemotaxis and cell motility. Based on these results, we discuss the underpinning for furfural-mediated change in ABE fermentation by the solventogenic Clostridium species. C. beijerinckii 8052 pre-culture was incubated anaerobically to attain acidogenic or solventogenic growth phase. The culture was then subdivided into two bottles. One bottle was challenged with furfural and the other bottle was left unchallenged. After 3 h growth, C. beijerinckii 8052 samples were collected, during which the original concentration of furfural in the growth medium was reduced to more than half. Total RNA was isolated, purified, converted to enriched mRNA, and dye-coupled (Alexa Fluor 555) complementary cRNA. This was followed by hybridization and microarray data analysis.