Thomas Schuetz scite author profile

The human heat-shock factor (HSF) regulates heat-shock genes in response to elevated temperature. When human cells are heated to 43 degrees C, HSF is modified post-translationally from a form that does not bind DNA to a form that binds to a specific sequence (the heat-shock element, HSE) found upstream of heat-shock genes. To investigate the transduction of the heat signal to HSF, and more generally, how mammalian cells respond at the molecular level to environmental stimuli, we have developed a cell-free system that exhibits heat-induced activation of human HSF in vitro. Comparison of HSF activation in vitro and in intact cells suggests that the response of human cells to heat shock involves at least two steps. First, an ATP-independent, heat-induced alteration of HSF allows it to bind the HSE; the temperature at which activation occurs in vitro implies that a human factor directly senses temperature. Second, HSF is phosphorylated. It is possible that similar multi-step activation mechanisms play a role in the response of eukaryotic cells to a variety of environmental stimuli, and that these mechanisms evolved to increase the range and flexibility of the response.

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Facilitated binding of GAL4 and heat shock factor to nucleosomal templates: differential function of DNA-binding domains.

Taylor¹,

Workman²,

Schuetz³

et al. 1991

Genes Dev.

266

184

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Regulatory factors must contend with chromatin structure to function. Although nucleosome structure and position on promoters can be important in determining factor access, the intrinsic ability of factors to bind to nucleosomal DNA might also play an essential regulatory role. We have used templates where nucleosomes were either randomly positioned or rotationally phased to demonstrate that two transcription factors, heat shock factor (HSF) and GAL4, differ significantly in their ability to bind to nucleosomes. GAL4 was able to bind to nucleosomal templates. Surprisingly, in contrast to its behavior on naked DNA, GAL4 bound better to multiple GAL4 sites than to a single GAL4 site on these templates. HSF alone was not able to bind to nucleosomal templates. HSF was able to bind to nucleosomal templates, however, when the TATA-binding factor TFIID was present. Consequently, binding to nucleosomal templates could be facilitated by adjacent binding of the same protein in the case of GAL4 but required binding of a second protein in the case of HSF. Taken together, these data demonstrate that regulatory factors differ in their inherent ability to bind to nucleosomal templates. These differences are likely to be important to the function of these factors in vivo.

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Functional Recovery of a Human Neonatal Heart After Severe Myocardial Infarction

Haubner

Schneider

Schweigmann

et al. 2016

Circulation Research

269

183

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Rationale: Cardiac remodeling and subsequent heart failure remain critical issues after myocardial infarction despite improved treatment and reperfusion strategies. Recently, cardiac regeneration has been demonstrated in fish and newborn mice after apex resection or cardiac infarctions. Two key issues remain to translate findings in model organisms to future therapies in humans: what is the mechanism and can cardiac regeneration indeed occur in newborn humans?Objective: To assess whether human neonatal hearts can functionally recover after myocardial infarction. Methods and Results: Here, we report the case of a newborn child having a severe myocardial infarction due to coronary artery occlusion. The child developed massive cardiac damage as defined by serum markers for cardiomyocyte cell death, electrocardiograms, echocardiography, and cardiac angiography. Remarkably, within weeks after the initial ischemic insult, we observed functional cardiac recovery, which translated into long-term normal heart function. Conclusions:

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Heat-inducible human factor that binds to a human hsp70 promoter.

Kingston¹,

Schuetz²,

Larin³

1987

Mol. Cell. Biol.

213

138

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A Heat Shock-Responsive Domain of Human HSF1 That Regulates Transcription Activation Domain Function

Green

Schuetz

Sullivan

et al. 1995

Molecular and Cellular Biology

166

141

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Models for regulation of the eukaryotic heat shock response typically invoke a negative feedback loop consisting of the transcriptional activator Hsf1 and a molecular chaperone. Previously we identified Hsp70 as the chaperone responsible for Hsf1 repression and constructed a mathematical model that recapitulated the yeast heat shock response (Zheng et al., 2016). The model was based on two assumptions: dissociation of Hsp70 activates Hsf1, and transcriptional induction of Hsp70 deactivates Hsf1. Here we validate these assumptions. First, we severed the feedback loop by uncoupling Hsp70 expression from Hsf1 regulation. As predicted by the model, Hsf1 was unable to efficiently deactivate in the absence of Hsp70 transcriptional induction. Next, we mapped a discrete Hsp70 binding site on Hsf1 to a C-terminal segment known as conserved element 2 (CE2). In vitro, CE2 binds to Hsp70 with low affinity (9 mM), in agreement with model requirements. In cells, removal of CE2 resulted in increased basal Hsf1 activity and delayed deactivation during heat shock, while tandem repeats of CE2 sped up Hsf1 deactivation. Finally, we uncovered a role for the N-terminal domain of Hsf1 in negatively regulating DNA binding. These results reveal the quantitative control mechanisms underlying the heat shock response.

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Regulation of heat shock factor in Schizosaccharomyces pombe more closely resembles regulation in mammals than in Saccharomyces cerevisiae.

1991

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The heat shock response appears to be universal. All eucaryotes studied encode a protein, heat shock factor (HSF), that is believed to regulate transcription of heat shock genes. This protein binds to a regulatory sequence, the heat shock element, that is absolutely conserved among eucaryotes. We report here the identification of HSF in the fission yeast Schizosaccharomyces pombe. HSF binding was not observed in extracts from normally growing S. pombe (28C) but was detected in increasing amounts as the temperature of heat shock increased between 39 and 45°C. This regulation is in contrast to that observed in Saccharomyces cerevisiae, in which HSF binding is detectable at both normal and heat shock temperatures. The S. pombe factor bound specifically to the heat shock element, as judged by methylation interference and DNase I protection analysis. The induction of S. pombe HSF was not inhibited by cycloheximide, suggesting that induction occurs posttranslationally, and the induced factor was shown to be phosphorylated. S. pombe HSF was purified to near homogeneity and was shown to have an apparent mobility of approximately 108 kDa. Since heat-induced DNA binding by HSF had previously been demonstrated only in metazoans, the conservation of heat-induced DNA binding by HSF among S. pombe and metazoans suggests that this mode of regulation is evolutionarily ancient.

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The oxidoreductase PYROXD1 uses NAD(P)+ as an antioxidant to sustain tRNA ligase activity in pre-tRNA splicing and unfolded protein response

et al. 2021

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Thomas Schuetz

Isolation of a cDNA for HSF2: evidence for two heat shock factor genes in humans.

Activation in vitro of sequence-specific DNA binding by a human regulatory factor

Facilitated binding of GAL4 and heat shock factor to nucleosomal templates: differential function of DNA-binding domains.

Functional Recovery of a Human Neonatal Heart After Severe Myocardial Infarction

Heat-inducible human factor that binds to a human hsp70 promoter.

A Heat Shock-Responsive Domain of Human HSF1 That Regulates Transcription Activation Domain Function

Regulation of heat shock factor in Schizosaccharomyces pombe more closely resembles regulation in mammals than in Saccharomyces cerevisiae.

The oxidoreductase PYROXD1 uses NAD(P)+ as an antioxidant to sustain tRNA ligase activity in pre-tRNA splicing and unfolded protein response

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