Upon heat stress, monomeric human heat shock transcription factor 1 (hHSF1) is converted to a trimer, acquires DNA-binding ability, is transported to the nucleus, and becomes transcriptionally competent. It was not known previously whether these regulatory changes are caused by a single activation event or whether they occur independently from one another, providing a multilayered control that may prevent inadvertant activation of hHSF1. Comparison of wild-type and mutant hHSF1 expressed in Xenopus oocytes and human HeLa cells suggested that retention of hHSF1 in the monomeric form depends on hydrophobic repeats (LZ1 to LZ3) and a carboxy-terminal sequence element in hHSF1 as well as on the presence of a titratable factor in the cell. Oligomerization of hHSF1 appears to induce DNA-binding activity as well as to uncover an amino-terminally located nuclear localization signal. A mechanism distinct from that controlling oligomerization regulates the transcriptional competence of hHSF1. Components of this mechanism were mapped to a region, including LZ2 and nearby sequences downstream from LZ2, that is clearly separated from the carboxy-terminally located transcription activation domain(s). We propose the existence of a fold-back structure that masks the transcription activation domain in the unstressed cell but is opened up by modification of hHSF1 and/or binding of a factor facilitating hHSF1 unfolding in the stressed cell. Activation of hHSF1 appears to involve at least two independently regulated structural transitions.The transcriptional enhancement of heat shock protein (hsp) genes by heat shock or other conditions that are stressful to cells is dependent on the presence of so-called heat shock element (HSE) sequences in their promoter regions (3,17,22) that consist of arrays of alternatively oriented NGAAN modules (2, 37). HSEs are binding sites for heat shock transcription factor (HSF) (21,23,36), which is inactive in unstressed cells and active in stressed cells (16,36,38). Organisms differ in their number of distinct HSF species. Whereas Saccharomyces cerevisiae and fruit flies express a single HSF species, birds, mammals, and plants express multiple HSF species (reviewed in reference 31). Furthermore, the strategies employed to regulate HSF activity differ drastically in S. cerevisiae and higher eukaryotes (30). While yeast HSF binds DNA constitutively, heat-activable HSF in higher eukaryotes is incapable of DNA binding in the absence of heat stress. Thus, in higher eukaryotes, HSF activity may be regulated mainly or exclusively at the level of DNA-binding ability. However, a number of situations involving mammalian cells, in which HSF DNAbinding ability was induced but a concomitant increase in hsp gene expression did not occur, have been described (6,14,15,24), suggesting that activation of HSF is a multistage process and that induction of DNA-binding ability may be only an early event in a complex activation process.It has been shown previously that stress activation of hsp genes in mammalian cells is ...
