Project description:HuntingtonM-bM-^@M-^Ys disease (HD) is a neurodegenerative disorder that is associated with the deposition of proteinaceous aggregates in the brains of HD patients and mouse models. Previous studies have suggested that wide-scale disruption of protein homeostasis occurs in protein folding diseases. Protein homeostasis can be maintained by activation of the heat shock response (HSR) via the transcription factor heat shock factor 1 (HSF1), the pharmacological activation of which can be achieved by Hsp90 inhibition and has been demonstrated to be beneficial in cell and invertebrate models of HD. Whether the HSR is functional in HD and whether its activation has therapeutic potential in mammalian HD models is currently unknown. To address these issues, we used a novel, brain penetrant Hsp90 inhibitor to activate the HSR in brain after systemic administration. Microarrays, quantitative PCR and western blotting showed that the HSR becomes impaired with disease progression in two mouse models of HD and that this originates at the level of transcription. HuntingtonM-bM-^@M-^Ys disease (HD) is a neurodegenerative disorder that is associated with the deposition of proteinaceous aggregates in the brains of HD patients and mouse models. Previous studies have suggested that wide-scale disruption of protein homeostasis occurs in protein folding diseases. Protein homeostasis can be maintained by activation of the heat shock response (HSR) via the transcription factor heat shock factor 1 (HSF1), the pharmacological activation of which can be achieved by Hsp90 inhibition and has been demonstrated to be beneficial in cell and invertebrate models of HD. Whether the HSR is functional in HD and whether its activation has therapeutic potential in mammalian HD models is currently unknown. To address these issues, we used a novel, brain penetrant Hsp90 inhibitor to activate the HSR in brain after systemic administration. Microarrays, quantitative PCR and western blotting showed that the HSR becomes impaired with disease progression in two mouse models of HD and that this originates at the level of transcription. mRNA expression analysis was performed by microarray in 12 week old R6/2 and WT mice treated with vehicle or HSP990 for 4h (12mg/kg).The following number of replicates was analysed for each genotype: 7 for WT+vehicle, 10 for WT+HSP990, 7 for R6/2+vehicle and 8 for R6/2+HSP990. Microarray quality control was performed using the software package provided on RACE (http://race.unil.ch).

Project description:Environmental stress, such as oxidative or heat stress, induces the activation of the heat shock response (HSR) and leads to an increase in the heat shock proteins (HSPs) level. These HSPs act as molecular chaperones to maintain cellular proteostasis. Controlled by highly intricate regulatory mechanisms, having stress-induced activation and feedback regulations with multiple partners, the HSR is still incompletely understood. In this context, we propose a minimal molecular model for the gene regulatory network of the HSR that reproduces quantitatively different heat shock experiments both on heat shock factor 1 (HSF1) and HSPs activities. This model, which is based on chemical kinetics laws, is kept with a low dimensionality without altering the biological interpretation of the model dynamics. This simplistic model highlights the titration of HSF1 by chaperones as the guiding line of the network. Moreover, by a steady states analysis of the network, three different temperature stress regimes appear: normal, acute, and chronic, where normal stress corresponds to pseudo thermal adaption. The protein triage that governs the fate of damaged proteins or the different stress regimes are consequences of the titration mechanism. The simplicity of the present model is of interest in order to study detailed modelling of cross regulation between the HSR and other major genetic networks like the cell cycle or the circadian clock. Sivéry, A., Courtade, E., Thommen, Q. (2016). A minimal titration model of the mammalian dynamical heat shock response. Physical biology, 13(6), 066008.

Project description:How heat shock induces the heat shock response (HSR) - a gene expression program encoding chaperones and other protein homeostasis (proteostasis) factors - remains an unresolved question in eukaryotic cell biology. Here we show that subcellular localization of the conserved J-protein Sis1 is a key regulator of the HSR in yeast. Under nonstress conditions, nucleoplasmic Sis1 promotes interaction between the chaperone Hsp70 and the transcription factor Hsf1 to repress the HSR. Heat shock triggers Sis1 to localize to the periphery of the nucleolus and to condense on the ER surface. Sis1 recruits the proteasome to this spatial network along with disaggregases and the ribosome quality control complex. Through localization dynamics, Sis1 relays the condition of the proteome to Hsf1. We conclude that the activation state of the HSR is determined by the spatial organization of the proteostasis network.

Project description:How heat shock inducesthe heat shock response (HSR) – a gene expression program encoding chaperones and other protein homeostasis (proteostasis) factors –remains an unresolved question in eukaryotic cell biology. Here we show that subcellular localization of the conserved J-protein Sis1 is a key regulator of the HSRin yeast. Under nonstress conditions, nucleoplasmic Sis1 promotes interaction between the chaperone Hsp70 and the transcription factor Hsf1to repress the HSR. Heat shock triggers Sis1 to localize to the nucleolar periphery and condense on the ER surface with the ribosome quality control complex. Sis1 recruits the proteasome to this spatial network.Through localization dynamics, Sis1 relaysthe condition of the proteome to Hsf1.Thus, the activation state of the HSR is built into spatial organization of the proteostasis network.

Project description:The Heat Shock response (HSR) is a highly conserved transcriptional program induced by the exposure to a variety of environmental stressors. Following an insult, a small subset of genes, known as the Heat Shock genes, are rapidly induced by the Heat Shock Factors (HSFs) to maintain protein homeostasis and ensure cell survival. In this study, we demonstrate that the RNAPII interactor RPRD1B is required for proper transcription of heat shock induced genes and for survival to heat shock.

Project description:The Heat Shock response (HSR) is a highly conserved transcriptional program induced by the exposure to a variety of environmental stressors. Following an insult, a small subset of genes, known as the Heat Shock genes, are rapidly induced by the Heat Shock Factors (HSFs) to maintain protein homeostasis and ensure cell survival. In this study, we demonstrate that the RNAPII interactor RPRD1B is required for proper transcription of heat shock induced genes and for survival to heat shock.

Project description:The heat shock response (HSR) is a mechanism to cope with proteotoxic stress by inducing the expression of molecular chaperones and other heat shock response genes. The HSR is evolutionarily well conserved and has been widely studied in bacteria, cell lines and lower eukaryotic model organisms. However, mechanistic insights into the HSR in higher eukaryotes, in particular in mammals, are limited. We have developed an in vivo heat shock protocol to analyze the HSR in mice and dissected heat shock factor 1 (HSF1)-dependent and -independent pathways. Whilst the induction of proteostasis-related genes was dependent on HSF1, the regulation of circadian function related genes, indicating that the circadian clock oscillators have been reset, was independent of its presence. Furthermore, we demonstrate that the in vivo HSR is impaired in mouse models of Huntington’s disease but we were unable to corroborate the general repression of transcription after a heat shock found in lower eukaryotes.

Project description:Low response rates and immune-related adverse events limit the impact of cancer immunotherapy. In the quest for improved clinical outcomes, preclinical studies have shown that combining immune checkpoint blockade therapies with N-terminal Hsp90 inhibitors resulted in improved efficacy, even though induction of an extensive heat shock response (HSR) with these inhibitors limited their clinical efficacy as monotherapies. We discovered that Enniatin A (EnnA) binds to the interface between the middle domains of the Hsp90 dimer and destabilizes Hsp90 client oncoproteins without inducing an HSR. We found that EnnA induces cancer cell immunogenic cell death in aggressive breast cancer models and exhibits superior anti-tumor activity compared to Hsp90 N-terminal inhibitors. Further, we show that EnnA reprograms the tumor microenvironment in syngeneic mouse models to promote CD8+ T cell-dependent anti-tumor activity mediated through the CX3CR1 signaling pathway. We propose that EnnA is a promising anti-tumor agent with a novel mechanism of action involving immunogenic cancer cell toxicity and the mobilization of CD8+ T cells into the tumor site.

Project description:The Heat Shock response (HSR) is a highly conserved transcriptional program induced by the exposure to a variety of environmental stressors. Following an insult, a small subset of genes, known as the Heat Shock genes, are rapidly induced by the Heat Shock Factors (HSFs) to maintain protein homeostasis and ensure cell survival. In parallel, a large portion of the genome becomes repressed. HS associated global gene repression is still largely poorly understood. In this study, we demonstrate that transcription downregulation during Heat shock is mainly achieved by premature transcription termination through the disruption of telescripting.

Project description:The role of stress-induced increases in SUMO2/3 conjugation during the Heat Shock Response (HSR) has remained enigmatic. We investigated SUMO signal transduction at the proteomic and functional level during the HSR in the context of cells depleted of proteostasis network components via chronic Heat Shock Factor 1 inhibition versus cells with normal pro-teostasis networks. In the recovery phase post-heat shock, SUMO2/3 conjugation remained high for a prolonged time in cells lacking sufficient chaperones. Similar results were obtained upon inhibiting HSP90, indicating that increased chaperone activity during the HSR is critical for the recovery of SUMO2/3 levels post-heat shock. Proteasome inhibition during the re-covery phase likewise prolonged SUMO2/3 conjugation, indicating that stress-induced SU-MO2/3 targets are subsequently degraded by the ubiquitin-proteasome system. Functionally, we show that SUMOylation profoundly enhances solubility of target proteins upon heat shock in vitro. Collectively, our results implicate SUMO2/3 as a rapid response factor protecting the proteome from aggregation upon proteotoxic stress.