Mutated Yeast Heat Shock Transcription Factor Activates Transcription Independently of Hyperphosphorylation

Hashikawa, Naoya; Mizukami, Yu; Imazu, Hiromi; Sakurai, Hiroshi

doi:10.1074/jbc.m510827200

Cited by 37 publications

(52 citation statements)

References 53 publications

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“…Temperatureresistant mutations near the DBD enable Hsf1 lacking its C-terminal AD to activate transcription (Hashikawa et al 2006). These suppressors implicate the DBD in mediating the response, as did single point mutations that constitutively enhanced transcription (Bulman et al 2001).…”

Section: Hsf1 Regulation Through Conformational Changementioning

confidence: 99%

“…The N-and C-terminal ADs activate different sets of genes in the Hsf1 regulon during heat shock (Eastmond and Nelson 2006). Stress-induced activation is accompanied by Hsf1 hyperphosphorylation, but whether it is important for activation or for return to an inactive state is unclear (Sorger 1990;Jakobsen and Pelham 1991;Hoj and Jakobsen 1994;Hashikawa et al 2006).…”

Section: Hsf1 Regulation Through Conformational Changementioning

confidence: 99%

“…Stress, such as increased temperature or oxidative damage, induces binding to new targets ) and activation of Hsf1 through two differentially acting ADs, one N-and one C-terminal to the central DBD (Nieto-Sotelo et al 1990;Sorger 1990). The essential C-terminal AD modulates the response to high temperature (Nieto-Sotelo et al 1990;Sorger 1990) and is indispensable for response to heat stress for genes containing a single heat shock element (Hashikawa et al 2006). The N-and C-terminal ADs activate different sets of genes in the Hsf1 regulon during heat shock (Eastmond and Nelson 2006).…”

Section: Hsf1 Regulation Through Conformational Changementioning

confidence: 99%

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Transcriptional Regulation inSaccharomyces cerevisiae: Transcription Factor Regulation and Function, Mechanisms of Initiation, and Roles of Activators and Coactivators

2011

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Here we review recent advances in understanding the regulation of mRNA synthesis in Saccharomyces cerevisiae. Many fundamental gene regulatory mechanisms have been conserved in all eukaryotes, and budding yeast has been at the forefront in the discovery and dissection of these conserved mechanisms. Topics covered include upstream activation sequence and promoter structure, transcription factor classification, and examples of regulated transcription factor activity. We also examine advances in understanding the RNA polymerase II transcription machinery, conserved coactivator complexes, transcription activation domains, and the cooperation of these factors in gene regulatory mechanisms. TABLE OF CONTENTS Abstract 705Introduction 706

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Section: Hsf1 Regulation Through Conformational Changementioning

confidence: 99%

Section: Hsf1 Regulation Through Conformational Changementioning

confidence: 99%

Section: Hsf1 Regulation Through Conformational Changementioning

confidence: 99%

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Transcriptional Regulation inSaccharomyces cerevisiae: Transcription Factor Regulation and Function, Mechanisms of Initiation, and Roles of Activators and Coactivators

2011

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“…Mammalian, fly, and plant HSFs have just a single trans-activation domain, whereas the HSFs of yeasts possess two distinct trans-activation domains: one close to the amino terminus and the other adjacent to the carboxy terminus (NTA and CTA, respectively). Loss of the C-terminal (CT) domain of Hsf1 (sequences 583 to 833, containing the CTA and modulator sequences) leads to a compromised induction of certain genes, but not others, in response to heat shock (8,16,18,35,43,45). It also causes loss of the ability to grow above about 35°C, revealing that gene expression directed by the Hsf1 CT domain is required for yeast to grow at high temperature.…”

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confidence: 99%

In the Yeast Heat Shock Response, Hsf1-Directed Induction of Hsp90 Facilitates the Activation of the Slt2 (Mpk1) Mitogen-Activated Protein Kinase Required for Cell Integrity

et al. 2007

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Yeast is rendered temperature sensitive with loss of the C-terminal (CT) domain of heat shock transcription factor (Hsf1). This domain loss was found to abrogate heat stimulation of Slt2 (Mpk1), the mitogen-activated protein kinase that directs the reinforced cell integrity gene expression needed for high-temperature growth. In Hsf1 CT domain-deficient cells, Slt2 still undergoes Mkk1/2-directed dual-Thr/Tyr phosphorylation in response to the heat stimulation of cell integrity pathway signaling, but the low Hsp90 expression level suppresses any corresponding increase in Slt2 kinase activity due to Slt2 being a "client" of the Hsp90 chaperone. A non-Hsf1-directed Hsp90 overexpression restored the heat induction of Slt2 activity in these cells, as well as both Slt2-dependent (Rlm1, Swi4) and Slt2-independent (MBF) transcriptional activities. Their high-temperature growth was also rescued, not just by this Hsp90 overexpression but by osmotic stabilization, by the expression of a Slt2-independent form of the Rlm1 transcriptional regulator of cell integrity genes, and by a multicopy SLT2 gene vector. In providing the elevated Hsp90 needed for an efficient activation of Slt2, heat activation of Hsf1 indirectly facilitates (Slt2-directed) heat activation of yet another transcription factor (Rlm1). This provides an explanation as to why, in earlier transcript analysis compared to chromatin immunoprecipitation studies, many more genes of yeast displayed an Hsf1-dependent transcriptional activation by heat than bound Hsf1 directly. The levels of Hsp90 expression affecting transcription factor regulation by Hsp90 client protein kinases also provides a mechanistic model for how heat shock factor can influence the expression of several non-hsp genes in higher organisms.The heat shock response is a stress response almost universally present among living organisms (reviewed in references 36 and 49). In eukaryotic cells, the transcriptional events of this response are due mainly to heat shock transcription factor (HSF). In vitro studies using the purified, recombinant HSFs of Drosophila melanogaster and Saccharomyces cerevisiae have indicated that HSF can directly sense changes to the temperature and the oxidative state within cells (28,59). Mammalian HSF1 undergoes a reversible formation of two redox-sensitive disulfide bonds in response to heat and hydrogen peroxide, an intramolecular bonding that is associated with the homotrimerization of this transcription factor (2). Formation of these HSF1 homotrimers leads, in turn, to this HSF1 undergoing nuclear import and acquiring its DNA binding activity (37). The levels of molecular chaperones are yet another important control over the activity of HSF1 (49).Higher organisms generally have more than one form of HSF (37). In contrast, just a single, essential HSF (Hsf1) is present in yeasts (9). The S. cerevisiae Hsf1 is regulated rather differently than the heat shock-responsive HSF1 of mammals, being constitutively homotrimerized and devoid of the redoxsensitive sulfhydryl groups ...

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“…Although the molecular weight of the peptides recognized do not precisely correspond to the molecular weight of the predicted EhHSTF, in the literature has been reported that these proteins may occur postranslational modifications as phosphorylation provoking changes in their molecular weights [36]. Perhaps, have been reported that the HSTF requires being homotrimerized to binds to the HSE [37].…”

Section: Discussionmentioning

confidence: 99%

A Novel Heat Shock Transcription Factor Family in Entamoeba histolytica

García¹,

Argüelles²,

Ishiwara³

et al. 2007

American J. of Infectious Diseases

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Abstract:The HSTF is a master molecule involved in the transcriptional control of several genes during different types of stress. This transcription factor is a very conserved protein identified in different organisms from bacterial to human. Entamoeba histolytica is the protozoan responsible for the human amoebiasis. This parasite is exposed to different kind of stress as changes in the pH, temperature, drugs, all that situations in where the parasite needs survive. Here we identified and isolated a novel gene family of HSTFs in the protozoan parasite E. histolytica. Three members that we called Ehhstf1, Ehhstf2 and Ehhstf3 compose this family. Amino acid alignments and domain architecture analysis revealed that the EhHSTFs presents a conserved DNA-binding domain composed of approximately 25 residues. Interestingly this domain is shorter than the domain of the human, mouse and yeast HSTFs. Heterologous antibodies recognized four peptides of 73, 66, 47 and 23 kDa in total extracts from trophozoites growth under normal conditions. The 73, 47 and 23 kDa peptides increased their intensity when the cells were growth at 42°C by 2 h. All results together demonstrate that the amoeba present HSTFs, which may be, controlled the gene expression of this parasite under different stress situations.

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Mutated Yeast Heat Shock Transcription Factor Activates Transcription Independently of Hyperphosphorylation

Cited by 37 publications

References 53 publications

Transcriptional Regulation inSaccharomyces cerevisiae: Transcription Factor Regulation and Function, Mechanisms of Initiation, and Roles of Activators and Coactivators

Transcriptional Regulation inSaccharomyces cerevisiae: Transcription Factor Regulation and Function, Mechanisms of Initiation, and Roles of Activators and Coactivators

In the Yeast Heat Shock Response, Hsf1-Directed Induction of Hsp90 Facilitates the Activation of the Slt2 (Mpk1) Mitogen-Activated Protein Kinase Required for Cell Integrity

A Novel Heat Shock Transcription Factor Family in Entamoeba histolytica

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