In response to hyperthermia, heat shock transcription factor (HSF) activates transcription of a set of genes encoding heat shock proteins (HSPs). The promoter regions of HSP genes contain the HSF binding sequence called the heat shock element (HSE), which consists of contiguous inverted repeats of the sequence 5-nGAAn-3 (where n is any nucleotide). We have constructed an hsf1 mutant of Saccharomyces cerevisiae and analyzed genome-wide changes in heat shock response in the mutant cells. The results have revealed that Hsf1 is necessary for heat-induced transcription of not only HSP but also genes encoding proteins involved in diverse cellular processes such as protein degradation, detoxification, energy generation, carbohydrate metabolism, and maintenance of cell wall integrity. Approximately half of the Hsf1-regulated genes lacked the typical HSE in their promoter regions. Instead, several of these genes have a novel Hsf1 binding sequence that contains three direct repeats of nTTCn (or nGAAn) interrupted by 5 bp. The number and spacing of the repeating units are critical determinants for heat-induced transcription as well as for recognition by Hsf1. In the yeast genome, the presence of the sequence is enriched in Hsf1-regulated genes, suggesting that it is generally used as an HSE in the Hsf1 regulon.
The homotrimeric heat shock transcription factor (HSF) binds to the heat shock element of target genes and regulates transcription in response to various stresses. The Hsf1 protein of Saccharomyces cerevisiae is extensively phosphorylated upon heat shock; a modification that is under positive regulation by its C-terminal regulatory domain (CTM). Hyperphosphorylation has been implicated in gene-specific transcriptional activation. Here, we surveyed genes whose heat shock response is reduced by a CTM mutation. The CTM is indispensable for transcription via heat shock elements bound by a single Hsf1 trimer but is dispensable for transcription via heat shock elements bound by Hsf1 trimers in a cooperative manner. Intragenic mutations located within or near the wing region of the winged helix-turn-helix DNA-binding domain suppress the temperature-sensitive growth phenotype associated with the CTM mutation and enable Hsf1 to activate transcription independently of hyperphosphorylation. Deletion of the wing partially restores the transcriptional defects of the unphosphorylated Hsf1. These results demonstrate a functional link between hyperphosphorylation and the wing region and suggest that this modification is involved in a conformational change of a single Hsf1 trimer to an active form.The eukaryotic heat shock transcription factor HSF regulates the transcription of various genes under numerous stressful conditions. HSF proteins share common structural motifs, including a winged helix-turn-helix DNA-binding domain (DBD), 3 a hydrophobic repeat region essential for three-stranded coiled-coil formation, and a C-terminal transactivation domain (1-3). HSF binds to a conserved DNA sequence motif termed the heat shock element (HSE) by forming a homotrimer through the hydrophobic repeat regions, and the DBD of each monomer recognizes a 5-bp sequence, 5Ј-nGAAn-3Ј. The organization of the three nGAAn units varies among functional HSEs (4 -13). The perfect-type HSE consists of three or more contiguous inverted repeats of the unit (nTTCnnGAAnnTTCn), the gap-type HSE consists of two inverted units separated from a third unit by a 5-bp gap (nTTCnnGAAn(5 bp)nGAAn), and the step-type HSE consists of direct repeats of the nGAAn or nTTCn motif separated by 5 bp (nGAAn(5 bp)nGAAn(5 bp)nGAAn).In the yeast Saccharomyces cerevisiae, the HSF encoded by the HSF1 gene regulates transcription under normal physiological conditions as well as under stress conditions, and it is essential for cell viability. The genes targeted by Hsf1 encode proteins that function in a broad range of biological processes, including protein folding and degradation, detoxification, energy generation, carbohydrate metabolism, and cell wall organization (12, 13). Mammalian cells contain three HSF isoforms, HSF1, HSF2, and HSF4. Among these, HSF1 has roles in stress-induced transcription, extra-embryonic development, and postnatal growth (14, 15). Both S. cerevisiae Hsf1 and mammalian HSF1 are inducibly phosphorylated concomitant with activation (16 -22). Phosphoryla...
Gene transcription changes dramatically in response to various stresses. This event is an obligatory step for adaptation of cells to certain environments. Endoplasmic reticulum (ER) oxidoreductin encoded by the ERO1 gene of the yeast Saccharomyces cerevisiae is essential for the formation of protein disulfide bonds in the ER and for cell viability. We show that transcription of ERO1 is regulated by two transcriptional activators in response to different stresses. In the unfolded protein response induced by the reductant dithiothreitol, transcription factor Hac1 activates ERO1 transcription through a sequence that diverges from the consensus Hac1-binding sequence. Heat shock transcription factor Hsf1 activates ERO1 in response to heat, ethanol, and oxidative stresses. Using cells containing mutations in the Hac1- and Hsf1-binding sequences of the chromosomal ERO1 promoter, we demonstrate that Hac1-regulated transcription of ERO1 confers resistance to dithiothreitol. Although mutations in the Hsf1-binding sequences do not affect the sensitivity of cells to heat, ethanol, or oxidative stresses, both the Hac1- and Hsf1-regulated pathways are critical for normal growth under complex stress conditions.
Static stretching (SS) is an effective intervention to reduce muscle stiffness and is also performed for the iliopsoas muscle. The iliopsoas muscle consists of the iliacus and psoas major muscles, among which the former has a greater physiological crosssectional area and hip flexion moment arm. Static stretching time required to reduce muscle stiffness can differ among muscles, and the required time for the iliacus muscle remains unclear. The purpose of this study was to investigate the time required to reduce iliacus muscle stiffness. Twenty-six healthy men participated in this study. A 1-min hip extension SS was performed five times. Shear elastic modulus, an index of muscle stiffness, of the iliacus muscle was measured using ultrasonic shear wave elastography before SS and immediately after each SS. One-way repeated analysis of variance showed a statistical effect of time on the shear elastic modulus. A paired t-test with Holm adjustment revealed that the shear elastic moduli after 1-5 SS were statistically lower than that before SS. In addition, the shear elastic modulus after 5 SS was statistically lower than that after 1 SS. The results suggested that the stiffness of the iliacus muscle decreased with 1-min SS and further decreased with 5-min SS.
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