Abstract
Our genome is assembled into and array of highly dynamic nucleosome structures allowing spatial and temporal access to DNA. The nucleosomes are subject to a wide array of post-translational modifications, altering the DNA-histone interaction and serving as docking sites for proteins exhibiting effector or “reader” modules. The nuclear proteins SPBP and RAI1 are composed of several putative “reader” modules which may have ability to recognise a set of histone modification marks. Here we have performed a phylogenetic study of their putative reader modules, the C-terminal ePHD/ADD like domain, a novel nucleosome binding region and an AT-hook motif. Interactions studies in vitro and in yeast cells suggested that despite the extraordinary long loop region in their ePHD/ADD-like chromatin binding domains, the C-terminal region of both proteins seem to adopt a cross-braced topology of zinc finger interactions similar to other structurally determined ePHD/ADD structures. Both their ePHD/ADD-like domain and their novel nucleosome binding domain are highly conserved in vertebrate evolution, and construction of a phylogenetic tree displayed two well supported clusters representing SPBP and RAI1, respectively. Their genome and domain organisation suggest that SPBP and RAI1 have occurred from a gene duplication event. The phylogenetic tree suggests that this duplication has happened early in vertebrate evolution, since only one gene was identified in insects and lancelet. Finally, experimental data confirm that the conserved novel nucleosome binding region of RAI1 has the ability to bind the nucleosome core and histones. However, an adjacent conserved AT-hook motif as identified in SPBP is not present in RAI1, and deletion of the novel nucleosome binding region of RAI1 did not significantly affect its nuclear localisation.
Highlights
Packaging genetic information into nucleosome structures represents barrier to any cellular process that needs to access DNA, including replication, repair, recombination, transcription, gene silencing and RNA maturation
Fragments containing the F box region of SPBP and RAI1 were fused in frame with the GAL4 activation domain (GAL4-AD), and tested against different ePHD domain constructs of RAI1 and SPBP, fused to the GAL4 DNA binding domain (GAL4DBD), in the yeast two-hybrid interaction system
Two conserved regions for chromatin interaction were identified in RAI1, a novel nucleosome binding region located between amino acids 1523 and 1627, and the C-terminal atypical plant homeodomain (PHD) finger connected to a GATA-1 like zinc finger structure
Summary
Packaging genetic information into nucleosome structures represents barrier to any cellular process that needs to access DNA, including replication, repair, recombination, transcription, gene silencing and RNA maturation. There exist two main regulatory mechanisms, chromatin modifying activity and chromatin remodeling activity, which increase accessibility of genome to DNA binding proteins. Chromatin modifying activities lead post-translational modifications (PTMs) on histone tails and histone core, whereas chromatin remodeling activities modify non-covalent interactions between DNA and histones (reviewed in 1). The PTMs of histones and other chromatin proteins, form dynamic platforms that are able to assemble the machineries involved in DNA metabolism and to recruit chromatin modifying activities. Important players are chromatin binding proteins containing so-called “reader” modules recognizing specific PTMs on the histones. Coactivator complexes generally exhibit several “reader” and effector modules, linking in a combinatorial way particular PTM marks to defined downstream events. Several structural studies highlighting the combinatorial read out of multiple histone marks by single or tandemly arranged reader modules are reported [6,7,8,9,10,11,12,13,14,15,16,17]
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