Project description:This is a mathematical model of Hsp70 induction. To model heat shock effects, the model incorporates temperature dependencies in transcirption to Hsp70 mRNA and in dissociation of transcriptional complexes, in addition to a formal expression relating temperature to protein denaturation.

Project description:We examined the RNA binding ability of the 70-kDa heat shock protein (HSP70) family member HSPA1A and identified the RNA species bound to HSP70 in vivo. We used a UV-crosslinkiung and immunoprecipitation based approach named FLASH-seq (Aktaş et al., 2017) using 3xFLAG-Histidine-Biotin tagged ectopically expressed protein in HEK293T cells.

Project description:We examined the RNA binding ability of the 70-kDa heat shock protein (HSP70) family member HSPA1A and identified the RNA species bound to HSP70 in vivo. We used a UV-crosslinkiung and immunoprecipitation based approach named FLASH-seq (Aktaş et al., 2017) using 3xFLAG-Histidine-Biotin tagged ectopically expressed protein in HEK293T cells.

Project description:We examined the RNA binding ability of the 70-kDa heat shock protein (HSP70) family member HSPA1A and HSP8 and identified the RNA species bound to HSP70 or HSP8 in vivo. We used a UV-crosslinkiung and immunoprecipitation based approach named FLASH-seq (Akta? et al., 2017) using 3xFLAG-Histidine-Biotin tagged ectopically expressed protein in HEK293T cells.

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:RNA-seq and ribosome footprinting libraries of mouse 3T3 and human 293T cellsrelated to Shalgi et al. 2013 36bases paired-end RNA-seq, and ribosome footprinting libraries for: 3T3 cells - Control, 8 hours of mild heat shock (42) and 2 hours of severe heat shock (44) - in replicates, as well as 3T3 cells treated by mild followed by severe heat shock. In addition, 3T3 cells treated with Hsp70 inhibitor VER-155008 (Massey et al. 2010), and 293T cells transfected with Hspa1a or GFP, before and after 2 hours of severe heat shock.

Project description:Regulatory factors play important roles in cardiac hypertrophy by regulating gene expression in cardiomyocytes.HSP70, a heat shock protein encoded by HSPA1A ,is induced by hypertrophic stimulation and then causes cardiac hypertrophy. However, the regulation mechanism of HSP70 in cardiac hypertrophy is unknown. In this study, we established the cardiac hypertrophy mouse model to explore the differentially expressed genes and found Hspa1a was significantly increased in treated samples. Then Hspa1a was overexpressed in mouse cardiac HL-1 cells and we analyzed the changes of transcriptome expression by high throughput sequencing. The results showed that HSPA1A selectively regulates the expression of ncRNAs (Rn7sk,Rmrp), negatively regulates the expression of genes involved in inflammatory and immune response, including Cxcl1，Ccl2，Ccl7,Cxcl5, Fas andC3, which were also validated by RT-qPCR experiment. The HSPA1A-regulated genes and ncRNAs are highly associated with cardiac hypertrophy. Alternative splicing analysis revealed HSPA1A preferred to regulate genes enriched in transcriptional regulation, including Asxl2 and Runx1. These results indicate that the heat shock protein-HSPA1A may play a role in the occurrence and development of myocardial hypertrophy by regulating the expression of immune inflammatory response related pathway genes and ncRNAs related to myocardial hypertrophy.

Project description:Eukaryotic cells respond to heat shock through several regulatory processes including upregulation of stress responsive chaperones and reversible shutdown cellular activities through formation of protein assemblies. However, the underlying regulatory mechanisms of the recovery of these heat-induced protein assemblies remain largely elusive. Here, we measured the proteome abundance and solubility changes during recovery from severe heat shock in the mouse Neuro2a cell line. We found that prefoldins and translation machinery are rapidly down-regulated as the first step in the heat shock response. Analysis of proteome solubility reveals a rapid mobilization of protein quality control machineries, changes in cellular energy metabolism, changes in translational activity and nucleocytoplasmic transport are fundamental to the early stress responses, while the longer term adaptation to stress involves renewal of core cellular components. Hsp70 inhibition negatively affects the ribosomal machinery and delays the solubility recovery of many nuclear proteins.

Project description:By using a 44k chicken Agilent microarray, we systematically analyzed the chicken hypothalamus transcriptome response to thermal stress. Twelve hypothalamus samples were chosen from three groups (four samples per group) to be used in chicken genome microarray to examine differential gene expression.We compared the expression profiles between each pairs of the three groups using the microarray data. Totally, 2474 genes were found to be differentially expressed in the three comparisons with pM-oM-<M-^\0.05 and fold change (FC) higher than 1.5 and the genes were mainly involved in self-regulation and compensation required to maintain homeostasis, including heat shock protein family, enzyme and the hormone, neurotransmitter, cell-cell signaling, metabolism and cytokines. The transcripts of heat shock protein including Hsp 40 and Hsp 90 were significantly changed respond to thermal stress and genes involved in regulation of cell morphogenesis were significantly upregulated in heat stressed group with comparison to control and temperature recovery group. Additionally, the down-regulated genes in both heat stress and temperature recovery groups compared to control group were enriched in muscle organ development, striated muscle tissue development, cardiac muscle tissue development and muscle tissue development, which indicates that muscle development was inhibited during and in short-term after heat treatment. Most of genes dysregulated in heat stress group were found to be recovered in temperature recovery group, which confirmed their roles they could play in coping with heat stress. The present study provides a broader understanding of molecular mechanisms underlying the stress response in chicken and discovery of novel genes that are regulated in a thermal stress specific manner. Hypothalamus samples were collected from non-heat treated group (reared at 25C, used as control), 24h 34C treated group (heat stress treated group) and temperature recovery group (25C for 24h followed heat stress).

Project description:Using murine embryonic stem (mES) cells, here we show that two RNAi factors, Dgcr8 and the RNAseIII Drosha, physically associate with chromatin. We found that these known microRNA-processing factors associate with a subset of actively transcribed genes, as well as non-coding genes, including snoRNA, and lncRNA genes. Dgcr8 recruitment to chromatin was dependent on Methyltransferase-like 3 (Mettl3), which catalyzes N6-methyladenosine (m6A) of RNAs. Chemical inhibition of RNA polymerase II (RNAPII) disrupted the association of Dgcr8 and Mettl3 with chromatin, strongly suggesting RNA methylation and processing events occur co-transcriptionally. We also found that temperature stress causes a radical relocalization of Dgcr8 and Mettl3 to stress-induced genes including Hsp70. Genetic ablation of Dgcr8 or Mettl3 led to the accumulation of Hsp70 mRNA, elongation of its half-life, and increased protein levels only in cells subjected to acute heat stress. This indicates that acute heat-stress co-transcriptionally marks Hsp70 mRNAs by Mettl3 and Dgcr8 for subsequent RNA degradation to control the timing and magnitude of the heat shock response.