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A unique chromatin profile defines adaptive genomic regions in a fungal plant pathogen

David E. Cook, H. Martin Kramer, David E. Torres, Michael Seidl, Bart P. H. J. Thomma

2020eLife61 citationsDOIOpen Access PDF

Abstract

Genomes store information at scales beyond the linear nucleotide sequence, which impacts genome function at the level of an individual, while influences on populations and long-term genome function remains unclear. Here, we addressed how physical and chemical DNA characteristics influence genome evolution in the plant pathogenic fungus Verticillium dahliae . We identified incomplete DNA methylation of repetitive elements, associated with specific genomic compartments originally defined as Lineage-Specific (LS) regions that contain genes involved in host adaptation. Further chromatin characterization revealed associations with features such as H3 Lys-27 methylated histones (H3K27me3) and accessible DNA. Machine learning trained on chromatin data identified twice as much LS DNA as previously recognized, which was validated through orthogonal analysis, and we propose to refer to this DNA as adaptive genomic regions. Our results provide evidence that specific chromatin profiles define adaptive genomic regions, and highlight how different epigenetic factors contribute to the organization of these regions.

Topics & Concepts

BiologyChromatinGenomeEpigeneticsDNA methylationGeneticsComputational biologyHistoneGenomicsLineage (genetic)genomic DNADNA sequencingHost adaptationGenomic organizationDNAGeneGene expressionPlant Disease Resistance and GeneticsGenomics and Phylogenetic StudiesChromosomal and Genetic Variations
A unique chromatin profile defines adaptive genomic regions in a fungal plant pathogen | Litcius