Project description:High-temperature stress is a critical environmental parameter for all organisms and induces a cellular heat shock response, characterized by an upregulation of heat shock proteins. For Crenarchaeota, it is unknown how this response is regulated, given the lack of conservation of known prokaryotic or eukaryotic heat shock-regulating transcription factors and how cellular processes are affected. To this end, we studied the heat shock response of the thermoacidophilic Sulfolobus acidocaldarius, thriving in volcanic hot springs at 75°C, upon shift to 86°C, at the transcriptome and proteome level. By pulse-labeling of neosynthesized RNA and proteins upon heat shock, we show a drastic reduction of the cell’s major transcriptional activity immediately after shift and neosynthesis of certain abundant (heat shock) proteins, including the thermosome. By combining RNA-sequencing and mass spectrometry, we show that RNA levels of half of the genes are affected immediately after temperature shift and that reprogramming of the protein landscape takes at least one hour and changes are more subtle. Correlation analysis provides evidence that considerable post-transcriptional and post-translational regulation is occurring upon heat shock. Functional enrichment analysis indicates that nearly all biological processes are affected by heat shock. An overall downregulation is observed for transcription, translation, DNA replication and cell division. However, quality control of translation and of the protein landscape is increased. Many DNA repair pathways are differentially expressed, accompanied with an increase in a DNA import system. Furthermore, expression of DNA topoisomerases is investigated, coinciding with a significant differential expression of nucleoid-associated proteins. Based on these findings and considering the absence of a conserved DNA-binding motif, we propose that regulation of the heat shock response in Sulfolobales is most likely not established by a classical transcription factor, but is rather caused by changes in chromosome organization or established at the post-transcriptional level.

Project description:This SuperSeries is composed of the following subset Series: GSE24483: TR heat-shock GSE24484: RA heat-shock Refer to individual Series

Project description:aThese experiments address the effects of depleting Hsp90 upon the transcriptome of the major fungal pathogen, Candida albicans, during the heat shock response. The data show that key virulence factors are regulated in response to heat shock, and that Hsp90 exerts major effects on the heat shock transcriptome.a

Project description:To understand how microRNAs are involved in stress response, we examined their expression changes in C. elegans animals that were exposed to stress conditions, including heat shock, oxidation, hypoxia and starvation. Total RNAs were purified from young adult animals that were exposed to each stress, and used for cDNA library preparation for small RNAs. In this experiment, spe-9(hc88), a temperature sensitive sterile mutant, that were cultured at 23dC, was used in order to avoid the effect from developing embryos. Stress conditions we examined include: Heat shock (32M-BM-0C, 6 hrs), Recovery from heat shock (6 hrs recovery at 23M-BM-0C after heat shock treatment at 32M-BM-0C for 6 hrs), Hypoxia (0.01%, 6 hrs), Oxidation (Juglone 750 M-NM-<M, 6 hrs), Starvation (complete food deprivation, 12 hrs). In addition to these stress conditions, RNAs were prepared from normally cultured, untreated animals at three time points, 0 hr (baseline), 6 hrs (as controls for heat shock, hypoxia and oxidation) and 12 hrs (as controls for heat shock recovery and starvation) after starting stress exposure. These cDNA libraries established were sequenced with Illumina Genome Analyzer II.

Project description:The repertoire of transcripts that are differentially regulated in response to Heat-shock were studied using Illumina WG-6 v2.0 BeadChip. Study was undertaken with 3 biological replicates for each condition of Heat-Shock Treated and Untreated condition.

Project description:Subspecies of the Atlantic killifish, Fundulus heteroclitus, differ in their maximum thermal tolerance. To determine whether there is a link between the heat shock response (HSR) and maximum thermal tolerance, we exposed 20ºC acclimated killifish from these subspecies to a 2hr heat shock at 34ºC and examined gene expression during heat shock and recovery using real time quantitative PCR and a heterologous cDNA microarray designed for salmonid fishes. Keywords: Expression profiling by array Microarray analyses were performed on four individual fish per subspecies of killifish (northern and southern) prior to heat shock (control) and after 60 minutes of heat shock, hybridized (one slide per individual) against a common reference RNA pool composed of an equal amount of RNA from all samples in the analysis.

Project description:The transcriptional response to heat shock is essential for cells to function effectively under stress. This is a highly heritable trait but the nature and extent of inter-individual variation in heat shock response are not well established. This dataset consists of the global transcription profiles for a panel of lymphoblastoid cell lines established from 60 founder individuals in the Yoruba HapMap population that have been exposed to heat shock. RNA was extracted from resting cells as well as cells that were exposed to heat shock at 42°C for 1 hour and then allowed to recover for 6 hours at 37°C. In combination with the HapMap genotypes for these individuals this enables the study of the effect of genetic variation on the heat shock response.

Project description:In somatic cells elevated temperature induces activation of the heat shock transcription factor 1 (HSF1) what leads to heat shock proteins synthesis and cytoprotection. However, in the male germ cells (spermatocytes) upon HSF1 activation, caspase-3 dependent apoptosis is induced and spermatogenic cells are actively eliminated. To find out molecular targets of HSF1 in all promoter regions, and to elucidate a mechanism of such diverse HSF1 activity we carried out genome-wide HSF1 binding analysis in control and heat-shocked cells, either spermatogenic or somatic. As model somatic cells we used hepatocytes that respond to hyperthermia in a classical way by induction of heat shock genes transcription. As spermatogenic cells we used a fraction of cells enriched with spermatocytes, which are the most sensitive to damage in elevated temperatures. Using isolated spermatocytes we avoided the influence of the somatic testicular component on the our final results. On Affymetrix GeneChipM-BM-. Mouse Promoter 1.0R Arrays we analyzed DNA immunoprecipitated (using anty-HSF1 antibody) from spermatocytes or hepatocytes, either untreated (control) or immediately after heat shock performed in vitro for 5-20 minutes. ChIP on chip analyses were done in triplicate.

Project description:In somatic cells elevated temperature induces activation of the heat shock transcription factor 1 (HSF1) what leads to heat shock proteins synthesis and cytoprotection. However, in the male germ cells (spermatocytes) upon HSF1 activation, caspase-3 dependent apoptosis is induced and spermatogenic cells are actively eliminated. To elucidate a mechanism of such diverse HSF1 activity we carried out genome-wide transcriptional analysis in control and heat-shocked cells, either spermatogenic or somatic. As model somatic cells we used hepatocytes that respond to hyperthermia in a classical way by induction of heat shock genes transcription. As spermatogenic cells we used a fraction of cells enriched with spermatocytes, which are the most sensitive to damage in elevated temperatures. Using isolated spermatocytes we avoided the influence of the somatic testicular component on the our final results. Genes that are differently regulated during hyperthermia in both types of cells have been identified. On Affymetrix gene chip arrays we analyzed RNA isolated from spermatocytes or hepatocytes, either untreated (control) or after heat shock and 2h of recovery at physiological temperature. Analyses were done in triplicate.

Project description:Identification of proteins that associate with chromatin (fraction) upon heat shock by SILAC-based quantitative proteomics