Abstract
The structure of eukaryotic chromatin directly influences gene function, and is regulated by chemical modifications of the core histone proteins. Modification of the human histone H4 N-terminal tail region by the small ubiquitin-like modifier protein, SUMO-3, is associated with transcription repression. However, the direct effect of sumoylation on chromatin structure and function remains unknown. Therefore, we employed a disulfide-directed strategy to generate H4 homogenously and site-specifically sumoylated at Lys-12 (suH4ss). Chromatin compaction and oligomerization assays with nucleosomal arrays containing suH4ss established that SUMO-3 inhibits array folding and higher order oligomerization, which underlie chromatin fiber formation. Moreover, the effect of sumoylation differed from that of acetylation, and could be recapitulated with the structurally similar protein ubiquitin. Mechanistic studies at the level of single nucleosomes revealed that, unlike acetylation, the effect of SUMO-3 arises from the attenuation of long-range internucleosomal interactions more than from the destabilization of a compacted dinucleosome state. Altogether, our results present the first insight on the direct structural effects of histone H4 sumoylation and reveal a novel mechanism by which SUMO-3 inhibits chromatin compaction.
Highlights
Human histone H4 is post-translationally modified at Lys-12 by the small ubiquitin-like modifier protein (SUMO-3)
We report the application of a disulfide-directed protein modification strategy [27] to generate human histone H4 sitespecifically modified by SUMO-3 at Lys-12
In addition to ensemble sedimentation coefficient measurements that probed the effect of SUMO-3 on chromatin compaction [28], a single-molecule Försters resonance energy transfer (FRET)-based technique was adopted to measure the effect of SUMO-3 on internucleosomal interactions [20]
Summary
Human histone H4 is post-translationally modified at Lys-12 by the small ubiquitin-like modifier protein (SUMO-3). The dysregulation of histone PTMs has drastic effects, resulting in a range of human diseases including cancers of the blood [5] and brain [6], ataxias [7], and muscular dystrophy [8] Given their essential roles in normal eukaryotic development and disease initiation, it is crucial to understand how specific histone modifications influence the structure and function of chromatin. In addition to ensemble sedimentation coefficient measurements that probed the effect of SUMO-3 on chromatin compaction [28], a single-molecule Försters resonance energy transfer (FRET)-based technique was adopted to measure the effect of SUMO-3 on internucleosomal interactions [20] Corroborative results from these studies indicated that suH4ss inhibits intra- and inter-array interactions that underlie chromatin compaction and oligomerization, respectively. Our results offer the first mechanistic insights on how SUMO-3 alters the structure of chromatin in cis to form an open euchromatin-like structure, and set the stage for future biochemical studies of the in trans effects of sumoylated H4
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