Project description:The strain bdf1Δ+HAL2 improved salt resistance of bdf1∆. To gain further insight into the mechanism of bdf1∆ salt sensitivity, DNA microarray analysis was performed to determine the reason for the salt sensitivity of bdf1∆ cells and the process of how HAL2 overexpression and HDA1 deletion improves salt resistance. Transcriptomic analysis under salt treatment (0.5 mol.L-1 NaCl for 45 min) was performed using four different strains: bdf1∆, W303, bdf1Δ+HAL2 and bdf1∆hda1∆. The transcription of 1,393 genes were significantly changed( > 2-fold) in bdf1∆ compared with W303 upon NaCl stress (0.5 mol.L-1 NaCl for 45 min). Only 108 genes were significantly changed ( > 2-fold) in bdf1Δ+HAL2 compared with bdf1∆ upon NaCl stress (0.5 mol.L-1 NaCl for 45 min). Only 88 genes were significantly changed ( > 2-fold) in bdf1Δ+HAL2 compared with bdf1∆ upon NaCl stress (0.5 mol.L-1 NaCl for 45 min).

Project description:In the analysis of a carbohydrate metabolite pathway, we found that a mutant strain of Corynebacterium glutamicum deficient in pfkB1, which encodes fructose-1-phosphate kinase, showed interesting characteristics. After aerobically cultivated with fructose as a carbon source, this mutant consumed glucose and produced lactate more than 2-fold as compared with the wild-type under conditions of oxygen deprivation. This considerably higher fermentation capacity was unique for the combination of the pfkB1 deletion and fructose cultivation. On the basis of the metabolome and transcriptome analyses, we identified marked intracellular accumulation of fructose-1-phosphate and significant upregulation of several genes related to the phosphoenolpyruvate:carbohydrate phosphotransferase system, glycolysis, and organic acid synthesis in this strain. Therefore, the considerably enhanced glucose consumption and organic acid production presumably resulted from a relief of transcriptional repression driven by global regulator SugR owing to the accumulated fructose-1-phosphate. Furthermore, we demonstrated that engineered strains overexpressing the above upregulated genes showed enhanced glucose consumption and organic acid production. The ppc deletion mutant of the engineered strain consumed 1,250 mM glucose and produced 2,390 mM lactate in 48 h under oxygen deprivation, which are 2.6- and 2.7-fold higher than the corresponding parameters of the ppc-deleted wild-type.

Project description:The strain bdf1∆bdf2∆[BDF2 L][SIR2 H] improved salt resistance of bdf1∆. To gain further insight into the mechanism of BDF1 in suppressing bdf1∆ salt sensitivity, DNA microarray analysis was performed to determine the reason for the salt sensitivity of bdf1∆ cells and the process of how coexpression of SIR2 and BDF2 improves salt resistance. Transcriptomic analysis under salt treatment (0.6 mol.L-1 NaCl for 45 min) was performed using three different strains: bdf1∆bdf2∆[BDF2 L][SIR2 H], bdf1∆bdf2∆[BDF2 L][pYX242] and bdf1∆[pRS316][pYX242]. The transcription of 3244 genes were significantly changed( > 2-fold) in bdf1∆bdf2∆[BDF2 L][SIR2 H] compared with bdf1∆[pRS316][pYX242] upon NaCl stress (0.6 mol.L-1 NaCl for 45 min). Only 281 genes were significantly changed ( > 2-fold) in bdf1∆bdf2∆[BDF2 L][pYX242] compared with bdf1∆[pRS316][pYX242] upon NaCl stress (0.6 mol∙L-1 NaCl for 45 min). BF2:bdf1∆[pRS316][pYX242]. BF2B: bdf1∆bdf2∆[BDF2 L][pYX242]. BF2S:bdf1∆bdf2∆[BDF2 L][SIR2 H].

Project description:The strain bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][SIR2 H] improved salt resistance of bdf1M-bM-^HM-^F. To gain further insight into the mechanism of BDF1 in suppressing bdf1M-bM-^HM-^F salt sensitivity, DNA microarray analysis was performed to determine the reason for the salt sensitivity of bdf1M-bM-^HM-^F cells and the process of how coexpression of SIR2 and BDF2 improves salt resistance. Transcriptomic analysis under salt treatment (0.6 mol.L-1 NaCl for 45 min) was performed using three different strains: bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][SIR2 H], bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][pYX242] and bdf1M-bM-^HM-^F[pRS316][pYX242]. The transcription of 3244 genes were significantly changed( > 2-fold) in bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][SIR2 H] compared with bdf1M-bM-^HM-^F[pRS316][pYX242] upon NaCl stress (0.6 mol.L-1 NaCl for 45 min). Only 281 genes were significantly changed ( > 2-fold) in bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][pYX242] compared with bdf1M-bM-^HM-^F[pRS316][pYX242] upon NaCl stress (0.6 molM-bM-^HM-^YL-1 NaCl for 45 min). BF2:bdf1M-bM-^HM-^F[pRS316][pYX242]. BF2B: bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][pYX242]. BF2S:bdf1M-bM-^HM-^Fbdf2M-bM-^HM-^F[BDF2 L][SIR2 H]. BF2B vs BF2 under salt treatment (0.6 mol.L-1 NaCl for 45 min); BF2S vs BF2 under salt treatment (0.6 mol.L-1 NaCl for 45 min).

Project description:Root tip: WT vs. rss3 and -NaCl vs. +NaCl

Project description:0.3M NaCl vs Control and 2M NaCl vs Control

Project description:af09_lignin - dml6 - Transcriptome analysis of lignin mutants and UV stress effect on secondary wall synthesis - DML6 vs S DML6+UV vs S+UV S vs S+UV DML6 vs DML6+UV Keywords: normal vs disease comparison,treated vs untreated comparison

Project description:AdHBx UV vs AdEasy UV vs HepG2

Project description:Production of D-xylonate in the yeast S. cerevisiae represents an example of bioprocess development for more sustainable production of value-added chemicals from cheap raw material or waste. Previously it was shown that the production of D-xylonate led to its significant intracellular accumulation and to dramatic loss of viability during the production process. In order to identify the physiological or pathological responses associated with D-xylonate production, we performed a time-course transcriptome analysis of D-xylonate production in yeast cultivated in a bioreactor. Comparison of the transcriptomes of D-xylonate producing strain with control strain showed considerably higher expression in the xylonate producing strain of the genes controlled by the cell wall integrity pathway (CWI) and of some genes previously identified as upregulated in response to the organic acid stress. Surprisingly, also genes encoding proteins involved in translation, ribosome structure and RNA metabolism – the processes commonly found to be down-regulated under virtually every condition causing cellular stress – were upregulated during the D-xylonate production. The overall transcriptional responses were, therefore, very dissimilar to those previously reported as being associated with diverse stresses including the organic acid treatment and production. In addition, it was observed that the consumption of ethanol was slower and the level of trehalose was lower in the D-xylonate producing strain. Validation experiments including Slt2 kinase phosphorylation profiles and the quantitative PCR analyses of selected gene showed remarkably good match with our findings and confirmed the observations made in the transcriptome analysis. The production of organic acids has a major impact on the physiology of yeast cells. There is, however, very limited overlap at the transcriptional level in responses to treatment or production of different acids. The loss of viability, observed during production and accumulation of D-xylonate, seems to be caused by erroneous interpretation of environmental signals causing a failure in entering the stationary phase and eventually leading to depletion of scarce resources by the affected cells. This, together with intracellular acidification, inevitably results in cell death.

Project description:Selenium (Se) is an essential nutrient for beef cattle health and commercial production. The molecular mechanisms responsible for the physiological responses of the animal to dietary Se supplementation, however, have not been evaluated. Furthermore, the potential effect of two chemical forms (organic vs. inorganic) of Se on gene expression by Se-sufficient cattle has not been evaluated. Microarray analysis using the GeneChip Bovine Genome Array (Affymetrix, Inc., Santa Clara, CA) was conducted to determine if dietary Se supplementation in organic vs. inorganic form (OSe vs. ISe) differentially affects the liver gene expression profile in growing beef heifers.