Project description:Global transcriptional profiles of Saccharomyces cerevisiae were studied following changes in growth conditions to high hydrostatic pressure and low temperature. These profiles were quantitatively very similar, encompassing 561 co-upregulated genes and 161 co-downregulated genes. In particular, expression of the DAN/TIR cell wall mannoprotein genes, which are generally expressed under hypoxia, were markedly upregulated by high pressure and low temperature, suggesting the overlapping regulatory networks of transcription. In support of the role of the mannoproteins in cell wall integrity, cells acquired resistance against treatment with SDS, Zymolyase and lethal level of high pressure when preincubated under high pressure and low temperature. Keywords: stress response

Project description:Several reports have investigated the effects of future climate conditions on photosynthesis and biomass production in woody plants but none combining temperature and atmospheric CO2 concentration. We used grow chambers to expose Eucalyptus grandis and E. globulus seedlings to three temperature regimes (10-12°C - low temperature, 20-22°C - control temperature and 33-35°C - high temperature) combined with two CO2 concentration (390 ppm – normal and 700 ppm - high). After 35 days the stems were used for transcriptome (RNAseq) analysis aiming to understand  changes in the expression of genes related with biosynthesis and remodeling of the cell wall, as well as genes related with carbon partitioning and hormonal regulation. E. globulus, a species adapted to low temperature, was more responsive to the treatments compared to E. grandis. The most relevant biological processes affected by the treatments were related to stress, secondary metabolism, hormonal response, and signaling. We also analyzed in depth all cell wall biopolymer synthetic genes and their regulation by innumerous transcriptional factors. There was an upregulation of ethylene and auxin biosynthetic genes in both species, but it was stronger under high and low temperature in E.globulus. Temperature was more effective to change cell wall biosynthetic genes than CO2 and CO2 stimulated lignin biosynthetic pathway. We also analyzed lignin composition and structure. There was an increase in F5H and COMT expression and the S/G ratio also increased under high CO2 in E.globulus. Thus, the species responded differently to treatments and stem composition and development was highly affected by temperature and CO2 concentration.

Project description:We assesed the transcriptional response of wild-type and isogenic lrgAB mutant to growth in the presence of three different stress conditions (aerobiosis, high-temperature, and the cell-wall active antibiotic vancomycin) by using RNA-seq

Project description:We performed global scale microarray analysis to identify detailed mechanisms by which nonpermissive temperature induces cell growth arrest and differentiation in astrocyte RCG-12 cells harboring temperature-sensitive simian virus 40 large T-antigen by using an Affymetrix GeneChip system. Astrocyte RCG-12 cells used in this study were derived from primary cultured rat cortical glia cells infecting with a temperature-sensitive simian virus 40 large T-antigen. Although the cells grew continuously at the permissive temperature, the nonpermissive temperature led to cell growth arrest and differentiation. Of the 15,923 probe sets analyzed, nonpermissive temperature differentially expressed 556 probe sets by >2.0-fold. Keywords: Astrocyte cell; growth arrest; differentiation; temperature-sensitive simian virus 40 large T-antigen; nonpermissive temperature

Project description:We compared two groups of abalones (from the same population) with different temperature acclimation history, through their survival at acute heat treatment and metabolites changes. The results indicated significantly higher survival for the high temperature acclimation group. Both groups experienced mitochondrial homeostasis break down during heat treatment, while the higher temperature acclimation group accumulated more metabolites beneficial to metabolic homeostasis, including various dipeptides, antioxidants, and neuroprotective substances.

Project description:Heat stress is one of the primary abiotic stresses that limit crop production . Grape is a popular cultivated fruit with high economic value throughout the world, and whose growth and development is often influenced by high temperature. Alternative splicing (AS) is a widespread mechanism increasing transcriptome complexity and proteome diversity. We conducted high temperature treatments (35oC, 40oC and 45oC) on grapevines (Vitis vinifera), and assessed proteomic and transcriptomic （especially AS）changes in leaves. We found that nearly 70% of the genes were alternatively spliced under high temperature. Intron retention (IR), exon skipping (ES) and alternative donor/acceptor sites were markedly induced under different high temperatures. IR was the most abundant up- and down-regulated AS event; moreover, IR events at 40 and 45oC were far higher than those at 35oC. These results indicated AS, especially IR, is an important posttranscriptional regulatory during grape leaf responses to high temperature. Proteomic analysis showed that protein levels of the RNA binding proteins SR45, SR30, and SR34, and the nuclear ribonucleic protein U1A in grape leaves gradually rose as ambient temperature increased. The results also revealed why AS events occurred more frequently under high temperature in grape leaves. After integrating transcriptomic and proteomic data, we found that HSPs and some important transcript factors such as MBF1c and HSFA2 were mainly involved in heat tolerance in grape through up-regulating transcriptional and translational levels, and were especially modulated by AS. The results provide the first simultaneous evidence for grape leaf responses to high temperature at transcriptional, posttranscriptional and translational levels.

Project description:Identification of proteins diferrentially accumulated under acrylamide exposure

Project description:Staphylococcus aureus is a pathogenic bacterium but also a commensal of skin and anterior nares in humans. As S. aureus transits from skins/nares to inside the human body, it experiences changes in temperature. The production and content of S. aureus extracellular vesicles (EV) have been increasingly studied over the past few years and EVs are increasingly being recognized as important to the infectious process. Nonetheless, the impact of temperature variation on S. aureus EVs has not been studied in detail as most reports that investigate EV cargoes and host cell interactions are performed using vesicles produced at 37˚C. Here we report that S. aureus vesicle production is temperature-dependent with greater vesiculation at 40˚C. We demonstrate that the temperature dependent regulation of vesicle production in S. aureus is mediated by the alpha phenol soluble modulin peptides (αPSMs). Through proteomic analysis, we observed increased packaging of virulence factors at 40˚C whereas more total proteins are present in EVs produced at 34˚C. Similar to the protein content, we perform transcriptomic analysis and demonstrate that the RNA cargo is impacted by temperature also. Finally, we demonstrate greater αPSM- and α-toxin mediated erythrocyte lysis with 40˚C EVs but 34˚C EVs are more cytotoxic toward THP-1 cells. Together our study demonstrates that small temperature variations have great impact on EV biogenesis and shape the interaction with host cells.

Project description:We investigated genome-wide changes in mRNA translation in Arabidopsis thaliana suspension cell cultures exposed to brief perids of two types of stress: elevated temperature (37 degree_C) and high salinity (200 mM NaCl). To this end, we subjected polysomal RNA and non-polysomal RNA from sucrose gradient fractionated cell lysates to the co-hybridization on Agilent Arabidopsis 3 Oligo Microarrays. The ratio of signal intensities (polysomal RNA: non-polysomal RNA) was used as an indicator of the translation state for each transcript. To inspect coordination of changes in translational profiles with transcriptional profiles, we also isolated total RNAs from the same cells used for translational profiling experiments and investigated changes in accumulated transcript levels in response to each stress using the microarray. Two biological replicates were analyzed.

Project description:We performed an in-depth proteome analysis of the haloarchaeal model organism Haloferax volcanii under standard, low and high salt and low and high temperature conditions using label-free mass spectrometry. Qualitative analysis of protein identification data from high pH/reversed phase fractionated samples indicated 61.1% proteome coverage (2,509 proteins), which is close to the maximum recorded values in archaea. Identified proteins matched to the predicted proteome in their physicochemical protein properties, with only a small bias against low molecular wright and membrane-associated proteins. Cells grown under low and high salt stress as well as low and high temperature stress were quantitatively compared to standard cultures by SWATH mass spectrometry. 2,244 proteins, or 54.7% of the predicted proteome, were quantified across all conditions at high reproducibility which allowed for global analysis of protein expression changes under these stresses. Pathway enrichment analysis by KEGG annotation showed that most major cellular pathways are part of H. volcanii’s universal stress response. In addition, specific pathways were found to be selectively affected by either salt or temperature stress.