Developmental patterns of chromatin structure and DNA methylation responsible for epigenetic expression of a maize regulatory gene.

Epigenetic regulatory mechanisms heritably alter patterns of gene expression without changes in DNA sequence. Epigenetic states are often correlated with developmentally imposed alterations in genomic DNA methylation and local chromatin structure. Pl-Blotched is a stable epigenetic allele of the maize anthocyanin regulatory gene, purple plant1(pl). Pl-Blotched plants display a variegated pattern of pigmentation that contrasts sharply with the uniformly dark purple pigmentation of plants carrying the dominant Pl-Rhoades allele. Previously, we showed that the lower level of pigmentation in Pl-Blotched is correlated with lower pl mRNA levels and increased DNA methylation at some sites. To explore how DNA methylation, chromatin structure, and developmental stage might contribute to the expression of Pl-Blotched, we used methylation-sensitive restriction enzymes and DNaseI sensitivity assays to compare the methylation status and chromatin structure of Pl-Blotched and Pl-Rhoades at different stages in development. Both alleles exhibit developmentally sensitive changes in methylation. In Pl-Blotched, methylation of two diagnostic HpaII/MspI sites increases progressively, coincident with the juvenile-to-adult transition in growth. In seedlings, the chromatin encompassing the coding region of the gene is less sensitive to DNaseI digestion in Pl-Blotched than in Pl-Rhoades. Developmental maturation from seedling to adult is accompanied by expansion of this closed chromatin domain to include the promoter and downstream flanking sequences. We provide evidence to show that chromatin structure, rather than DNA methylation, is the primary epigenetic determinant for the phenotypic differences between Pl-Blotched and Pl-Rhoades.