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     

Cooperative binding of Drosophila heat shock factor to arrays of a conserved 5 bp unit

Drosophila heat shock factor (HSF) exists as a multimer in solution and when bound to its regulatory element (HSE). We have previously reported evidence that subunits of HSF associate to form homotrimers and that each subunit contacts a conserved 5 bp DNA sequence repeated within an HSE. Here we show that HSF binding is highly cooperative at two distinct levels: between subunits of the HSF multimer, and between multimers. The binding of HSF to one of a pair of adjacent trimeric binding sites facilitates HSF binding to the second by over 2000-fold. This cooperativity is particularly important in binding HSF at 37 degrees C, and could account for the requirement for multiple binding sites in vivo and, in part, for the differential expression of heat shock genes.     

In Vitro Interaction of Nuclear Proteins with the Promoter of Soybean Heat Shock Gene Gmhsp17.5E

Proteins present in crude nuclear extracts of soybean (Glycine max) plumules were shown to bind in vitro to the 5′ flanking sequences of the soybean heat shock gene Gmhsp17.5E. The specificity of binding activity present in extracts from both control (28°C) and heat shocked (40°C) tissues was demonstrated by reciprocal competition experiments using gel mobility retardation assays. Footprinting experiments using DNase I with crude nuclear extracts indicated that a continuous stretch of 5′ flanking sequences extending from −40 to −153 was protected from digestion in vitro. Nuclear proteins that were partially purified by heparin agarose chromatography were shown to bind specific TATA-proximal sequences containing the heat shock consensus elements (HSEs) (−73 to −49; −107 to −84) and AT-rich motifs (−119 to −153). Other binding sites within AT-rich sequences (−906 to −888, −868 to 863, −859 to 853, and −841 to −830), distal HSE elements (−568 to −532) and a TATA/dyad (−234 to −207) were also identified by DNase I footprinting of TATA-distal probes. DNA binding activities specific for the HSE and AT-rich sequences were present in nuclear extracts from both control and heat shocked tissues. Both types of binding activity were increased after heat shock treatment; HSE binding increased from 1.8- to 2.7-fold, and binding to AT-rich sequences showed an increase from 1.3- to 1.7-fold.