Differential chromatin accessibility landscape reveals the structural and functional features of the allopolyploid wheat chromosomes
AbstractBackgroundWe have a limited understanding of how the complexity of the wheat genome influences the distribution of chromatin states along the homoeologous chromosomes. Using a differential nuclease sensitivity (DNS) assay, we investigated the chromatin states in the coding and transposon element (TE) -rich repetitive regions of the allopolyploid wheat genome.ResultsWe observed a negative chromatin accessibility gradient along the telomere-centromere axis with mostly open and closed chromatin located in the distal and pericentromeric regions of chromosomes, respectively. This trend was mirrored by the TE-rich intergenic regions, but not by the genic regions, which showed similar averages of chromatin accessibility levels along the chromosomes. The genes’ proximity to TEs was negatively associated with chromatin accessibility. The chromatin states of TEs was dependent on their type, proximity to genes, and chromosomal position. Both the distance between genes and TE composition appear to play a more important role in the chromatin accessibility along the chromosomes than chromosomal position. The majority of MNase hypersensitive regions were located within the TEs. The DNS assay accurately predicted previously detected centromere locations. SNPs located within more accessible chromatin explain a higher proportion of genetic variance for a number of agronomic traits than SNPs located within closed chromatin.ConclusionsThe chromatin states in the wheat genome are shaped by the interplay of repetitive and gene-encoding regions that are predictive of the functional and structural organization of chromosomes, providing a powerful framework for detecting genomic features involved in gene regulation and prioritizing genomic variation to explain phenotypes.