Cellular processes mediated through nuclear DNA must contend with chromatin. Chromatin structural assays can efficiently integrate information across diverse regulatory elements, revealing the functional noncoding genome. In this study, we use a differential nuclease sensitivity assay based on micrococcal nuclease (MNase) digestion to discover open chromatin regions in the maize genome. We find that maize MNase-hypersensitive (MNase HS) regions localize around active genes and within recombination hotspots, focusing biased gene conversion at their flanks. Although MNase HS regions map to less than 1% of the genome, they consistently explain a remarkably large amount (∼40%) of heritable phenotypic variance in diverse complex traits. MNase HS regions are therefore on par with coding sequences as annotations that demarcate the functional parts of the maize genome. These results imply that less than 3% of the maize genome (coding and MNase HS regions) may give rise to the overwhelming majority of phenotypic variation, greatly narrowing the scope of the functional genome.A ll cellular processes involving the nuclear DNA, including transcription, recombination, and replication, must contend with local chromatin states. Each of these processes can affect phenotypic variation, either directly or through constraints on natural selection. To date, humans and several model systems with small genomes have had their chromatin landscapes wellcharacterized (1-4). However, with a limited number of wellstudied large, complex genomes, many general principles relating chromatin structure to genome regulation remain unknown. Here, we examine the large genome of maize (Zea mays L.), a model crop species. The importance of maize within international agriculture motivates our central question: Which portions of the genome contribute to quantitative trait variation? Several features of maize biology, such as the capacity for large controlled crosses, rapid decay of linkage disequilibrium (LD), high genetic diversity, and substantial spacing between genes, make it an excellent experimental system for pursuing this question.Fine-scale characterization of the chromatin structural landscape requires an assay that can distinguish accessible (open) from condensed chromatin at the nucleosomal to subnucleosomal scales. In general, chromatin accessibility may be assayed through in situ digestion of the nuclear DNA with a non-sequence-specific nuclease, followed by quantification of the resulting DNA fragments (5). Micrococcal nuclease (MNase) cleaves DNA between nucleosomes, revealing genome-wide nucleosome occupancy (6, 7). However, differential sensitivity to MNase digestion also reveals chromatin accessibility, with genomic regions of open chromatin preferentially recovered under light-digestion relative to heavydigestion conditions (8). In maize, a differential MNase sensitivity assay with microarray quantification [differential nuclease sensitivity (DNS)-chip] demonstrated that MNase hypersensitive (MNase HS) regions are positively assoc...
