Project description:Here we use a transcriptomic approach to investigate the molecular underpinnings of thermal stress in the model cyanobacteria species Synechocystis. We impose gradual heat stress by increasing the temperature in a stepwise fashion (1.5 °C h-1) from their optimal growth temperature of 30 °C to a maximum temperature of 46.5 °C over a period of 12h.

Project description:Stress represents a major factor negatively affecting fish welfare in aquaculture. The objective of the present study was to identify and evaluate informative indicators for the welfare of maraena whitefish (Coregonus maraena) exposed to inconvenient temperatures. The present study compares the physiological impact of either acute or gradual temperature rise from 18 °C to 24 °C on maraena whitefish in aquaculture. We analysed microarray-based transcriptome profiles in liver, spleen and kidney and identified a common set of diagnostic biomarkers each indicating thermal stress induced by acute or gradual temperature rise in the selected tissues. We identified common and unique tissue- and stress mode-specific pathways reflecting metabolic, cell signalling and immunologic crossroads to cope with thermal stress.

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:Proteases present in milk are heat-sensitive, and their activities increase or decrease depending on the intensity of the thermal treatment applied. The thermal effects on the protease activity are well-known for bovine milk but poorly understood for ovine and caprine milk. This study aimed to determine the nonspecific and specific protease activities in casein and whey fractions isolated from raw bovine, ovine and caprine milk collected in early lactation, and to determine the effects of low-temperature, long-time (63°C for 30 min) and high-temperature, short-time (85°C for 5 min) treatments on protease activities within each milk fraction.

Project description:Transcriptional profiling of fully developed leaves of Arabidopsis Col0 plants heat-stressed for 25 min at 27.7 degrees Celsius. Goal was to isolate and study the influence of temperature and vpd change in the 30 min high light-stress experiments, since the Isolight rises leaf temperature to 27.5C and increases the vpd from 5 min of exposure.

Project description:We used microarrays to investigate the transcriptome of 6 days old male flies exposed to either 15 or 25 C development at either constant or fluctuating temperatures. Further, we investigated gene expression at benign (20C) and high (35C) temperatures With global climate change temperature means and variability are expected to increase. Thus, exposures to elevated temperatures are expected to become an increasing challenge for terrestrial ectotherm populations. While evolutionary adaptation seems to be constrained or proceed at an insufficient pace, many populations are expected to rely on phenotypic plasticity (thermal acclimation) for coping with the predicted changes. However, the effects of fluctuating temperature on the molecular mechanisms and the implications for heat tolerance are not well understood. To understand and predict consequences of climate change it is important to investigate how different components of the thermal environment, including fluctuating thermal conditions, contribute to changes in thermal acclimation. In this study we investigated the impact of mean and diurnal fluctuation of temperature on heat tolerance in Drosophila melanogaster and on the underlying molecular mechanisms in adult male flies. Flies from two constant and two ecologically relevant fluctuating temperature regimes were tested for their critical thermal maxima (CTmax) and associated global gene expression profiles at benign and thermally stressful conditions. Both temperature parameters contributed independently to the thermal acclimation, with regard to heat tolerance as well as the global gene expression profile. Although the independent transcriptional effects caused by fluctuations were relatively small, they are likely to be essential for our understanding of thermal adaptation. Thus, high temperature acclimation ability might not be measured correctly and might even be underestimated at constant temperatures. Our data suggests that the particular mechanisms affected by thermal fluctuations are related to phototransduction and environmental sensing. Thus genes and pathways involved in those processes are likely to be of major importance in a future warmer and more fluctuating climate.

Project description:Fusarium graminearum (teleomorph Gibberella zeae) is a prominent pathogen that infects major cereal crops, such as wheat, barley, and maize. To dissect cellular responses toward heat stress in the plant pathogenic fungus F. graminearum, we compared transcriptomes of the fungal cultures incubated in normal temperature condition (25 ºC) and in high temperature condition (37 ºC) for 15 min. 6 samples examined: 24 h-old mycelia from complete medium (CM) of Fusarium graminearum wild-type Z-3639 were incubated in normal temperature condition (25 ºC) and in high temperature condition (37 ºC) for 15 min.

Project description:Thermal condition is an important envrionment factor to produce healthy pig. A mineral heat ware, RAVI is a regenerative far-infrared heating system. The purpose of this sutyd was to evaluate immunostimulating effects in pigs when RAVI was applied to maintain thermal condition compared with gasoline heater.

Project description:Coral bleaching and coral reef degradation become severe as the surface seawater temperature rises. Much research to date has focused on the bacterial community composition properties within the coral holobiont, but less attention has been paid to the interactions of bacteria and corals under thermal stress. We investigated the changes of coral symbiotic bacteria and metabolites under thermal stress, and analyzed the internal relationship between bacteria and metabolites as well as their relationship with coral health. We found obvious signs of coral bleaching after heating treatment, and the interaction within symbiotic bacterial community became closer. The coral symbiotic bacterial community and metabolites changed significantly under thermal stress, and bacteria such as Flavobacterium, Shewanella and Psychrobacter increased significantly. Bacteria associated with stress tolerance, biofilm formation and mobile elements decreased, and bacterial DMSP metabolism increased slightly after heating treatment. Differential metabolites in corals after heating treatment were associated with cell cycle regulation and antioxidant. This study revealed the correlation between differential metabolites and bacterial community composition changes in corals under thermal stress, and providing valuable insight on metabolomics research of corals.

Project description:Soil high temperature heating