Abstract
BackgroundGenetic recombination plays an important role in evolution, facilitating the creation of new, favorable combinations of alleles and the removal of deleterious mutations by unlinking them from surrounding sequences. In most mammals, the placement of genetic crossovers is determined by the binding of PRDM9, a highly polymorphic protein with a long zinc finger array, to its cognate binding sites. It is one of over 800 genes encoding proteins with zinc finger domains in the human genome.ResultsWe report a novel technique, Affinity-seq, that for the first time identifies both the genome-wide binding sites of DNA-binding proteins and quantitates their relative affinities. We have applied this in vitro technique to PRDM9, the zinc-finger protein that activates genetic recombination, obtaining new information on the regulation of hotspots, whose locations and activities determine the recombination landscape. We identified 31,770 binding sites in the mouse genome for the PRDM9Dom2 variant. Comparing these results with hotspot usage in vivo, we find that less than half of potential PRDM9 binding sites are utilized in vivo. We show that hotspot usage is increased in actively transcribed genes and decreased in genomic regions containing H3K9me2/3 histone marks or bound to the nuclear lamina.ConclusionsThese results show that a major factor determining whether a binding site will become an active hotspot and what its activity will be are constraints imposed by prior chromatin modifications on the ability of PRDM9 to bind to DNA in vivo. These constraints lead to the presence of long genomic regions depleted of recombination.Electronic supplementary materialThe online version of this article (doi:10.1186/s13072-015-0024-6) contains supplementary material, which is available to authorized users.
Highlights
Genetic recombination plays an important role in evolution, facilitating the creation of new, favorable combinations of alleles and the removal of deleterious mutations by unlinking them from surrounding sequences
There is substantial evidence from population genetic studies of humans [3,4,5], genetic crosses in mice [6, 7] and cattle [8], and molecular studies of hotspots in mice [9,10,11], that recombination hotspot locations in mammals are determined by the zinc finger, DNA-binding protein PRDM9, which binds at recombination hotspots and trimethylates lysine 4 of histone H3 [10, 11]
Analyzing the binding properties of several individual PRDM9 binding sites in vitro, we previously found that binding requires the participation of every zinc finger in the PRDM9 tandem array, those that define the computationally derived binding motif, and that individual fingers vary in their contribution to determining binding specificity [18]
Summary
Genetic recombination plays an important role in evolution, facilitating the creation of new, favorable combinations of alleles and the removal of deleterious mutations by unlinking them from surrounding sequences. The placement of genetic crossovers is determined by the binding of PRDM9, a highly polymorphic protein with a long zinc finger array, to its cognate binding sites It is one of over 800 genes encoding proteins with zinc finger domains in the human genome. Analyzing the binding properties of several individual PRDM9 binding sites in vitro, we previously found that binding requires the participation of every zinc finger in the PRDM9 tandem array, those that define the computationally derived binding motif, and that individual fingers vary in their contribution to determining binding specificity [18] To extend these studies, we developed and describe Affinity-seq as an efficient, generalized in vitro method for directly isolating and sequencing most genomic binding sites for a DNA binding protein and determining their relative binding affinities
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