Project description:C. glutamicum strains adapted to higher growth temperatures were obtained through an adaptive laboratory evolution experiment. To elucidate molecular basis for thermotolerance acquired by the evolved strains, we examined transcriptional responses of the evolved and parental strains to thermal stress using microarray technology. Each strain was grown at the optimal growth temperature (33 M-bM-^DM-^C). When OD610 reached around 7, the growth temperature increased to 41 M-bM-^DM-^C, and transcriptional changes of the evolved and parental strains were examined with microarray technology.

Project description:To investigate the molecular basis of fluctuating temperature induced phenotypic plasticity, we ran genome-wide transcriptomic analysis on Drosophila melanogaster subjected to acclimation at constant (19 +/- 0 degree Celcius) and fluctuating (19 +/- 8 degree Celcius) temperatures and contrasted the induction of molecular mechanisms in adult males, adult females, and larvae. We investigated whether fluctuations act by permanently activating the involved mechanisms, or whether fluctuations repeatedly activate and repress mechanisms, during the hot (or heating) and the cold (or cooling) phase of thermal fluctuations. We show that adult flies acclimated to fluctuating temperatures tolerate high temperatures better than the constant temperature acclimated controls. Differential gene expression indicated that responses to thermal variability rely partly on life stage and sex specific mechanisms. Our results show that some of the involved mechanisms were permanently activated, while others tracked the thermal fluctuations. Further, for a number of genes, fluctuating temperature resulted in canalization of gene expression. Molecular mechanisms related to environmental sensing and chromatin reorganization seems to be important components of adaptive responses to thermal variability.

Project description:In this work, we describe the transcriptional profiles of adapted and non-adapted one-month-old Baikal whitefish juveniles after heat shock exposure. Preadapted fish were exposed to a repeated thermal rise of 6 °C above control temperature every 3 days throughout embryonic development. One month after hatching, preadapted and non-adapted larvae were either maintained at control temperatures (12 °C) or exposed to an acute thermal stress (TS) of 12 °C above control temperature. The information on transcriptional profiles will contribute to further understanding of the mechanisms of adaptation of whitefish to the environment.

Project description:Thermally adapted Escherichia coli keeps transcriptomic response during temperature upshift exposure

Project description:Expression profile of E. coli BW25113 grown under standard laboratory atmosphere with a fine particulate matter (PM2.5) concentration of 17 mg m-3, under urban polluted atmosphere with a PM2.5 of 230 mg m-3 or under diesel exhaust atmosphere with a PM2.5 of 613 mg m-3. Expression profile of the diesel exhaust atmosphere-adapted E. coli strain T56-1 grown under diesel exhaust atmosphere.

Project description:A genome reduced E. coli strain MDS42ΔgalK::Ptet-gfp-kan were applied for the comparative transcriptome analysis. Genome-wide transcriptional changes under high osmotic prresure, high temperature condition and starvation were evaluated.

Project description:In this study, using DNA microarray analysis, we compared the comprehensive expression profiles of two yeast trains, i.e, the previously obtained ethanol-adapted yeast strain and the parental strain as control (FY834), under the ethanol stress condition (YPD medium contained 10% ethanol). As a result, we identified certain genes and functional categories of the genes that are possible involved in growth under the ethanol stress condition.

Project description:C. glutamicum strains adapted to higher growth temperatures were obtained through an adaptive laboratory evolution experiment. To elucidate molecular basis for thermotolerance acquired by the evolved strains, we examined transcriptional responses of the evolved and parental strains to thermal stress using microarray technology.

Project description:Red fruits are valued for their vitamin C and polyphenol content, but traditional heat preservation methods used in juice and nectar production can significantly reduce these components. Therefore, alternative non-thermal methods are explored to inactivate foodborne pathogens like Escherichia coli while maintaining the nutritional value. However, knowledge about the effects of these technologies on bacterial cells is limited. This study analyzed differentially expressed genes of E. coli ATCC 8739 inoculated in strawberry nectar after exposure to three treatments with two sets of parameters each, namely thermal treatment, high-pressure processing (HPP), and moderate-intensity pulsed electric field (MIPEF). The highest inactivation efficiency was achieved with HPP at 400 MPa, 1 min, reducing microbial counts by 5.0±0.3 log cfu/mL, and thermal treatment at 60°C, 200 s, achieving a reduction of 4.4±0.2 log cfu/mL, while no inactivation was observed with MIPEF at 6 kV/cm. Transcriptomic analysis showed that thermal and HPP treatments caused similar molecular stress responses in E. coli. In both cases, the most overexpressed genes encoded outer membrane proteins, which may lead to the activation of the envelope stress response. Despite no microbial inactivation was revealed after MIPEF treatment, strong transcriptomic responses were observed, particularly in genes related to membrane integrity and metabolic activity. Numerous overexpressed genes associated with ABC transporters, outer membrane proteins, and lipoproteins were identified, which could increase the strain’s virulence. This study provides insights into the stress response mechanisms induced by conventional and novel treatments. Nevertheless, further research is needed to investigate the long-term effects on bacterial populations.

Project description:High temperature adapted coli expression