Abstract
It is widely accepted that transcriptional regulation of eukaryotic genes is intimately coupled to covalent modifications of the underlying chromatin template, and in certain cases the functional consequences of these modifications have been characterized. Here we present evidence that gene activation in the silent heterochromatin of the yeast Saccharomyces cerevisiae can occur in the context of little, if any, covalent histone modification. Using a SIR-regulated heat shock-inducible transgene, hsp82-2001, and a natural drug-inducible subtelomeric gene, YFR057w, as models we demonstrate that substantial transcriptional induction (>200-fold) can occur in the context of restricted histone loss and negligible levels of H3K4 trimethylation, H3K36 trimethylation and H3K79 dimethylation, modifications commonly linked to transcription initiation and elongation. Heterochromatic gene activation can also occur with minimal H3 and H4 lysine acetylation and without replacement of H2A with the transcription-linked variant H2A.Z. Importantly, absence of histone modification does not stem from reduced transcriptional output, since hsp82-ΔTATA, a euchromatic promoter mutant lacking a TATA box and with threefold lower induced transcription than heterochromatic hsp82-2001, is strongly hyperacetylated in response to heat shock. Consistent with negligible H3K79 dimethylation, dot1Δ cells lacking H3K79 methylase activity show unimpeded occupancy of RNA polymerase II within activated heterochromatic promoter and coding regions. Our results indicate that large increases in transcription can be observed in the virtual absence of histone modifications often thought necessary for gene activation.
Highlights
Transcription in eukaryotes occurs in the context of chromatin
We found that large increases in the transcription of disparate heterochromatic genes occur in the absence of covalent histone modifications
This observation is consistent with the idea that spread of the Sir2/3/4 complex from its site of recruitment is antagonized by the presence of enhancer and promoter sequences which serve as boundary elements [35,36]
Summary
Transcriptional activation is accompanied by alterations to the chromatin template, exemplified by the enhanced DNase I sensitivity of coding regions and the presence of associated DNase I hypersensitive sites at linked regulatory elements [1,2]. Histone PTMs, acting singly or in combination, may control the ultimate expression state of a gene, or the ability of the underlying DNA to be repaired, recombined or replicated. This concept has been termed the histone code [9,10]. A prime example of this is the inducible INO1 promoter in the budding yeast S. cerevisiae where phosphorylation of the Ser residue of H3
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