Genome-Wide Reconstitution of Chromatin Transactions: RSC Preferentially disrupts H2A.Z-Containing Nucleosomes

Chromatin transactions are typically studied in vivo, or in vitro using artificial chromatin lacking the epigenetic complexity of the natural material. Attempting to bridge the gap between these approaches, we established a system for isolating the yeast genome as a library of mono-nucleosomes harboring the natural epigenetic signature, suitable for biochemical manipulation. Combined with deep sequencing, this library was used to investigate the intrinsic stability of individual nucleosomes, and, as proof of principle, the nucleosome preference of the chromatin remodeling complex, RSC. Our data indicate that the natural stability of nucleosomes differs greatly, with nucleosomes on tRNA genes and on promoters of protein-coding genes standing out as intrinsically unstable. Interestingly, RSC shows a distinct preference for nucleosomes derived from regions with a high density of histone variant H2A.Z, and this preference is indeed markedly diminished using nucleosomes from cells lacking H2A.Z. Importantly, the preference for H2A.Z remodeling/nucleosome ejection can also be reconstituted with recombinant nucleosome arrays. Together, our data indicate that, despite being separated from their genomic context, individual nucleosomes can retain their original identity as promoter- or TSS-nucleosomes. Besides shedding new light on nucleosome stability and the chromatin remodeler RSC, the simple experimental system outlined here should be generally applicable to the study of chromatin transactions.