Project description:Proctor2005 - Actions of chaperones and their role in ageing This model is described in the article: Modelling the actions of chaperones and their role in ageing. Proctor CJ, Soti C, Boys RJ, Gillespie CS, Shanley DP, Wilkinson DJ, Kirkwood TB. Mech. Ageing Dev. 2005 Jan; 126(1): 119-131 Abstract: Many molecular chaperones are also known as heat shock proteins because they are synthesised in increased amounts after brief exposure of cells to elevated temperatures. They have many cellular functions and are involved in the folding of nascent proteins, the re-folding of denatured proteins, the prevention of protein aggregation, and assisting the targeting of proteins for degradation by the proteasome and lysosomes. They also have a role in apoptosis and are involved in modulating signals for immune and inflammatory responses. Stress-induced transcription of heat shock proteins requires the activation of heat shock factor (HSF). Under normal conditions, HSF is bound to heat shock proteins resulting in feedback repression. During stress, cellular proteins undergo denaturation and sequester heat shock proteins bound to HSF, which is then able to become transcriptionally active. The induction of heat shock proteins is impaired with age and there is also a decline in chaperone function. Aberrant/damaged proteins accumulate with age and are implicated in several important age-related conditions (e.g. Alzheimer's disease, Parkinson's disease, and cataract). Therefore, the balance between damaged proteins and available free chaperones may be greatly disturbed during ageing. We have developed a mathematical model to describe the heat shock system. The aim of the model is two-fold: to explore the heat shock system and its implications in ageing; and to demonstrate how to build a model of a biological system using our simulation system (biology of ageing e-science integration and simulation (BASIS)). This model is hosted on BioModels Database and identified by: BIOMD0000000091. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:To mitigate the deleterious effects of temperature increases on cellular organization and proteotoxicity, organisms have developed mechanisms to respond to heat stress. In eukaryotes, HSF1 is the master regulator of the heat shock transcriptional response, but the heat shock response pathway is not yet fully understood. From a forward genetic screen for suppressors of heat shock induced gene expression in Caenorhabditis elegans, we found a new allele of hsf-1 that alters its DNA-binding domain, and we found three additional alleles of sup-45, a previously molecularly uncharacterized genetic locus. We identified sup-45 as one of the two hitherto unknown C. elegans orthologs of the human AF4/FMR2 family proteins, which are involved in regulation of transcriptional elongation rate. We thus renamed sup-45 as affl-2 (AF4/FMR2-Like). Through RNA-seq, we demonstrated that affl-2 mutants are deficient in heat shock induced transcription. Additionally, affl-2 mutants have herniated intestines, while worms lacking its sole paralog (affl-1) appear wild type. AFFL-2 is a broadly expressed nuclear protein, and nuclear localization of AFFL-2 is necessary for its role in heat shock response. affl-2 and its paralog are not essential for proper HSF-1 expression and localization after heat shock, which suggests that affl-2 may function downstream or parallel of hsf-1. Our characterization of affl-2 provides insights into the regulation of heat shock induced gene expression to protect against heat stress.

Project description:To understand the function and regulation of the C. elegans heat shock factor (HSF-1) in larval development, we have used ChIP-seq to analyze the occupancy of HSF1 and RNA Pol II in L2 larvae and young adult (YA) animals grown at 20°C or upon heat shock at 34°C for 30 min. In addition, we have used RNA-seq to analyze the transcriptomes of wild type (N2), hsf-1(ok600) mutants and hsf-1(ok600); rmSi1[hsf-1::gfp] L2 larvae grown at 20°C and characterized the gene expression change by heat shock in wild type (N2), hsf-1(sy441) and hsf-1(sy441);rmSi1[hsf-1::gfp] animals at L2 stage.

Project description:Nascent-protein ubiquitination is required for heat shock-induced gene downregulation in human cells.

Project description:To understand the function and regulation of the C. elegans heat shock factor (HSF-1) in larval development, we have used ChIP-seq to analyze the occupancy of HSF1 and RNA Pol II in L2 larvae and young adult (YA) animals grown at 20°C or upon heat shock at 34°C for 30 min. In addition, we have used RNA-seq to analyze the transcriptomes of wild type (N2), hsf-1(ok600) mutants and hsf-1(ok600); rmSi1[hsf-1::gfp] L2 larvae grown at 20°C and characterized the gene expression change by heat shock in wild type (N2) animals at L2 stage.

Project description:To understand the function and regulation of the C. elegans heat shock factor (HSF-1) in larval development, we have used ChIP-seq to analyze the occupancy of HSF1 and RNA Pol II in L2 larvae and young adult (YA) animals grown at 20°C or upon heat shock at 34°C for 30 min. In addition, we have used RNA-seq to analyze the transcriptomes of wild type (N2), hsf-1(ok600) mutants and hsf-1(ok600); rmSi1[hsf-1::gfp] L2 larvae grown at 20°C and characterized the gene expression change by heat shock in wild type (N2) animals at L2 stage.

Project description:Sequence-specific transcription factors (TFs) are critical for specifying patterns and levels of gene expression, but the DNA elements to which they can bind are not always sufficient to specify their binding in vivo. In eukaryotes, the binding of a TF is in competition with a constellation of other proteins, including histones which package DNA into nucleosomes. Here, we examine using the ChIP-seq assay, the genome-wide distribution of Drosophila Heat Shock Factor (HSF), a TF whose binding activity is mediated by heat shock-induced trimerization. We detect HSF binding to 464 sites, the vast majority of which contain HSF Sequence-binding Elements (HSEs) in Drosophila S2 cells, but these HSF-bound sites represent only a small fraction of HSEs present in the genome. We find a strong correlation of bound HSEs to active chromatin marks present prior to HSF binding, indicating an HSE’s residence in open chromatin is a primary determinant of whether HSF can bind following heat shock.

Project description:The insulin-like signaling (ILS) pathway regulates metabolism and is known to modulate adult lifespan in C. elegans. Altered stress responses and resistance to a wide range of stressors are also associated with changes in ILS and contribute to enhanced longevity. The transcription factors DAF-16 and HSF-1 are key effectors of the longevity phenotype. We demonstrate that increased intrinsic thermotolerance, due to lower ILS, is not dependent on stress induced HSF-1 transcriptional responses but instead requires active protein translation. Translation profiling experiments reveal genes that are post-transcriptionally regulated in response to altered ILS during heat shock in a DAF-16-dependent manner. Furthermore, several novel proteins are specifically required for ILS effects on thermotolerance. We propose that lowered-ILS results in DAF-16-induced metabolic and physiological changes that precondition a translational response to modulated survival under acute stress.

Project description:To understand the roles of HSF-1 and its regulation in reproduction and heat shock response in a tissue-specific manner, we coupled tissue-specific HSF-1 depletion in C. elegans by auxin-inducible degron (AID) with genome-wide transcriptional analyses in whole animals. We used ChIP-seq to analyze the occupancy of HSF-1 (tagged with AID::GFP) and RNA Pol II in young adult (YA) animals grown at 20°C or upon heat shock (HS) at 34°C for 30 min following an acute depletion of HSF-1 by AID for 2 hours either in the somatic or in the germline cells. Depletion by AID was performed by transferring worms expressing the E3 ligase TIR1 and carrying AID insertion to endogenous HSF-1 (JTL611 or JTL621) to NGM plates containing 1mM auxin (indole- 3-acetic acid, Sigma). The mock treatment was done by transferring worms to plates only containing the vehicle ethanol (EtOH). In parallel, we used RNA-seq to analyze the heat shock respnse upon depletion of HSF-1 in the soma or the germline for 2 hours. In addition, we also analyzed the transcriptomic changes by RNA-seq upon tissue-specific depletion of HSF-1 initiated at young adult stage for different length of time. In all RNA-seq analyses, we included the strains that only express TIR1 but do not have degron insertion at HSF-1 (CA1200 and CA1199) to control for the effects of auxin treatment and AID insertion into HSF-1.

Project description:To understand the roles of HSF-1 and its regulation in reproduction and heat shock response in a tissue-specific manner, we coupled tissue-specific HSF-1 depletion in C. elegans by auxin-inducible degron (AID) with genome-wide transcriptional analyses in whole animals. We used ChIP-seq to analyze the occupancy of HSF-1 (tagged with AID::GFP) and RNA Pol II in young adult (YA) animals grown at 20°C or upon heat shock (HS) at 34°C for 30 min following an acute depletion of HSF-1 by AID for 2 hours either in the somatic or in the germline cells. Depletion by AID was performed by transferring worms expressing the E3 ligase TIR1 and carrying AID insertion to endogenous HSF-1 (JTL611 or JTL621) to NGM plates containing 1mM auxin (indole- 3-acetic acid, Sigma). The mock treatment was done by transferring worms to plates only containing the vehicle ethanol (EtOH). In parallel, we used RNA-seq to analyze the heat shock respnse upon depletion of HSF-1 in the soma or the germline for 2 hours. In addition, we also analyzed the transcriptomic changes by RNA-seq upon tissue-specific depletion of HSF-1 initiated at young adult stage for different length of time. In all RNA-seq analyses, we included the strains that only express TIR1 but do not have degron insertion at HSF-1 (CA1200 and CA1199) to control for the effects of auxin treatment and AID insertion into HSF-1.