Abstract
Heat shock transcription factors (HSFs) regulate gene expression in response to heat shock and in physiological conditions. In mammals, HSF1 is required for heat-mediated induction of classic heat shock genes; however, we do not know the molecular mechanisms by which HSF4 regulates gene expression or the biological consequences of its binding to chromatin. Here, we identified that HSF4 binds to various genomic regions, including the introns and distal parts of protein-coding genes in vivo in mouse lenses, and a substantial numbers of the regions were also occupied by HSF1 and HSF2. HSF4 regulated expression of some genes at a developmental stage when HSF1 and HSF2 expression decreased. Although HSF4 binding did not affect expression of many genes, it induces demethylated status of histone H3K9 on the binding regions. Unexpectedly, a lot of HSF4 targets were induced by heat shock treatment, and HSF4 is required for induction of a set of non-classic heat shock genes in response to heat shock, in part by facilitating HSF1 binding through chromatin modification. These results suggest novel mechanisms of gene regulation controlled by HSF4 in non-classic heat shock response and in lens development.
Highlights
The consensus sequence nGAAn [5]
Temporal Profiles of Heat shock transcription factors (HSFs) Expression during Mouse Lens Development—We previously showed that HSF4 mRNA starts to be expressed at embryonic day 13.5 in both lens epithelial and fiber cells
HSF1 is activated by heat shock, binds to consensus HSEs located on proximal promoters of classic heat shock genes, and robustly induces their transcription [4, 6]
Summary
The consensus sequence nGAAn [5]. Heat shock triggers conversion of an HSF1 monomer that is negatively regulated by heat shock proteins into a trimer that can bind to HSE with a high affinity, and bound HSF1 rapidly induces robust activation of the heat shock genes [6]. We do not know how HSF2 and HSF4, as well as HSF1, regulate gene expression in physiological conditions, or the relationship between regulation of HSF1mediated heat shock response and regulation of genes by HSFs during development. To answer these questions, it is necessary to identify HSF-target genes comprehensively and to analyze regulation of these genes. The lens tissue is suitable for comprehensive identification of HSF4-target genes and their analysis Such analysis revealed unexpected roles of HSF4 in the regulation of gene expression during development and in the regulation of heat shock-mediated gene expression
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