Heat shock factor can activate transcription while bound to nucleosomal DNA in Saccharomyces cerevisiae

Interaction between heat shock transcription factors (HSFs) and divergent binding sequences: binding specificities of yeast HSFs and human HSF1

The target genes of the heat shock transcription factor (HSF) contain a cis-acting sequence, the heat shock element (HSE), which consists of multiple inverted repeats of the sequence 5'-nGAAn-3'. Using data acquired in this and a previous study, we have identified the HSEs in 59 of 62 target genes of Saccharomyces cerevisiae Hsf1. The Hsf1 protein recognizes continuous and discontinuous repeats of the nGAAn unit; the nucleotide sequences and configuration of the units diverge slightly among functional HSEs. When Schizosaccharomyces pombe HSF was expressed in S. cerevisiae cells, heat shock induced S. pombe HSF to bind to various HSE types, which properly activated transcription from almost all target genes, suggesting that the S. pombe genome also contains divergent HSEs. Human HSF1 induced the heat shock response via HSEs with continuous units in S. cerevisiae cells but failed to do so via HSEs with discontinuous units. Binding of human HSF1 to the discontinuous type of HSE was observed in vitro but was significantly inhibited in vivo. These results show that human HSF1 recognizes HSEs in a slightly different way than yeast HSFs and suggest that the configuration of the unit is an important determinant for HSF-HSE interactions.

Tissue-specific expression, heat inducibility, and biological roles of two hsp16 genes in Caenorhabditis elegans

In this report we have examined two new heat shock protein (HSP16) proteins in the nematode Caenorhabditis elegans encoded by the open reading frames F08H9.3 and F08H9.4. The F08H9.3 and F08H9.4 genes are oriented in the same direction next to each other on the chromosome, not sharing any promoter region, unlike other hsp16 genes that share common promoters in pairs. The F08H9.3 and F08H9.4 proteins were expressed in a tissue-specific manner, unlike the other four HSP16 proteins. F08H9.3 was expressed in the pharynx, and F08H9.4 in the excretory canal and a few neuronal cells. While F08H9.3 was weakly induced by heat shock only in the same tissue as under the normal condition, F08H9.4 was newly induced in the intestine. RNA interference experiments showed that these two proteins are required for survival under the heat shock condition.

Evidence that partial unwrapping of DNA from nucleosomes facilitates the binding of heat shock factor following DNA replication in yeast

In the yeast Saccharomyces cerevisiae, heat shock transcription factor (HSF) binds heat shock element (HSE) DNA shortly after DNA replication, independently of its activation by heat shock. To determine if HSF binding occurs before newly replicated DNA is packaged into nucleosomes, we inserted an HSE into a DNA segment that normally forms a positioned nucleosome in vivo. Transcription from constructs designed to create steric competition between binding of HSF and histone H2A-H2B dimers was generally poor, suggesting that nucleosome assembly precedes and inhibits HSF binding. However, one such construct was as transcriptionally active as a nucleosome-free control. Structural analyses suggested that approximately 40 base pairs of DNA, including the HSE, had unwrapped from the 3' edge of the histone octamer, allowing HSF to bind; approximately 100 base pairs remained in association with the histone octamer, with the same translational and rotational orientation as was seen for the poorly transcribed constructs. Modeling studies suggest that the active and inactive constructs differ from one another in the ease with which the HSE and flanking sequences can adopt the curvature needed to form a stable nucleosome. These differences may influence the probability of DNA unwrapping from already assembled nucleosomes and the subsequent binding of HSF.

Synergistic transcriptional-activation by the papillomavirus E2 protein occurs after DNA binding and correlates with a change in chromatin structure

The papillomavirus E2 protein only activates transcription strongly when two or more of its binding-sites, each of which bind an E2 dimer, are present upstream of a minimal promoter. Such synergy has been observed both in mammalian and yeast cells. In an attempt to understand the molecular basis of this synergy we carried out genomic footprinting to monitor the binding in vivo of native or mutant E2 proteins to different templates in yeast. We show that in vivo E2 binds to its site even under conditions where it does not activate a reporter gene. Binding occurs at each site independently of the number of sites and even in the absence of the activation domain. In contrast, analysis of the chromatin structure around the E2 binding-site(s) showed that a pronounced change in chromatin structure occurs under conditions in which E2 dimers activate transcription synergistically.

Methylation-associated transcriptional silencing of the major histocompatibility complex-linked hsp70 genes in mouse cell lines

The MHC-linked hsp70 locus consists of duplicated genes, hsp70.1 and hsp70.3, which in primary mouse embryo cells are highly heat shock-inducible. Several mouse cell lines in which hsp70 expression is not activated by heat shock have been described previously, but the basis for the deficiency has not been identified. In this study, genomic footprinting analysis has identified a common basis for the deficient response of the hsp70.1 gene to heat shock in four such cell lines, viz., the promoter is inaccessible to transcription factors, including heat shock transcription factor. Southern blot analyses reveal extensive CpG methylation of a 1.2-kilobase region spanning the hsp70.1 transcription start site and hypermethylation of the adjacent hsp70.3 gene, which is presumably also inaccessible to regulatory factors. Of four additional, randomly chosen mouse cell lines, three show no or minimal hsp70.3 heat shock responsiveness and CpG methylation of both hsp70 genes, and two of the three lines exhibit a suboptimal hsp70.1 response to heat shock as well. In all three lines, the accessibility of the hsp70.1 promoter to transcription factors is detectable but clearly diminished (relative to that in primary mouse cells). Our results suggest that the tandem hsp70 genes are concomitantly methylated and transcriptionally repressed with high frequency in cultured mouse cells.