CHIP interacts with heat shock factor 1 during heat stress

Heat shock factor 1 (HSF1) is a major transactivator of heat shock genes in response to stress and mediates cell protection against various harmful conditions. In this study, we identified the interaction of CHIP (carboxyl terminus of the heat shock cognate protein 70-interacting protein) with the N-terminus of HSF1. Using GST full-down assay, we found that CHIP directly interacts with C-terminal deleted HSF1 (a.a. 1-290) but not with full-length HSF1 under non-stressed conditions. Interestingly, interaction of CHIP with full-length HSF1 was induced by heat shock treatment. The structural change of HSF1 was observed under heat stressed conditions by CD spectra. These observations demonstrate the direct interaction between HSF1 and CHIP and this interaction requires conformational change of HSF1 by heat stress.     

Functional Analysis of Drosophila HSP70 Promoter with Different HSE Numbers in Human Cells

The activation of genetic constructs including the Drosophila hsp70 promoter with four and eight HSE sequences in the regulatory region has been described in human cells. The promoter was shown to be induced at lower temperatures compared to the human hsp70 promoter. The promoter activity increased after a 60-min heat shock already at 38°C in human cells. The promoter activation was observed 24 h after heat shock for the constructs with eight HSEs, while those with four HSEs required 48 h. After transplantation of in vitro heat-shocked transfected cells, the promoter activity could be maintained for 3 days with a gradual decline. The promoter activation was confirmed in vivo without preliminary heat shock in mouse ischemic brain foci. Controlled expression of the Gdnf gene under a Drosophila hsp70 promoter was demonstrated. This promoter with four and eight HSE sequences in the regulatory region can be proposed as a regulated promoter in genetic therapeutic systems.     

Temperature-dependent increase in the DNA-binding activity of a heat shock factor in an extract of tobacco cultured cells

The DNA-binding activity of a tobacco heat shock factor (HSF) was induced by heat treatment (37–40 °C) of a cell-free extract that contained extra-nuclear fraction, but not in an extract of isolated nuclei. These observations suggest that an inactive form of HSF can directly recognize and transduce the heat shock signal and that such transduction requires components of the extranuclear fraction. Addition of ATP or of most other nucleoside triphosphates reduced the binding of the HSF to the heat shock element (HSE) in the same extract, and removal of ATP by dialysis from the extract restored the ability of the HSF to bind to DNA. The restored activity of the HSF could be eliminated again by a second addition of ATP. Our observations provide the first example of the involvement of ATP in the regulation of the reversible changes in HSF that control its ability to bind to HSEs in a cell-free extract.Abbreviations AMP-PNP adenylyl imidodiphosphate - GUS -glucuronidase - HSE heat shock element - HSF heat shock factor     

Heat shock elements are involved in heat shock promoter activation during tobacco seed maturation

The soybean Gmhsp17.3-B heat shock promoter is developmentally regulated in transgenic tobacco, as indicated by the constitutive expression of a -glucuronidase reporter in seeds [16]. In this paper, we show that both the heat shock promoter-driven -glucuronidase activity and the mRNA of the endogenous Nthsp18P gene accumulate coincident with the onset of seed desiccation. Deletions of the soybean Gmhsp17.3-B promoter, encompassing the heat shock element (HSE)-containing regions, revealed a co-localization of sequences responsible for heat induction and developmental expression. Moreover, synthetic HSEs fused to a TATA box sequence had the potential to stimulate the developmental expression of a GUS reporter gene in seeds of transgenic plants.