SRP108636 PRJNA389314 GSE99693 Locus-specific control of the de novo DNA methylation pathway [ChIP-seq] Abstract: Cytosine DNA methylation plays crucial roles in gene regulation, transposon silencing, and diverse developmental processes. While methylation patterns are known to differ between cell-types, tissues, and disease states, how these differences arise remains poorly understood. In plants, DNA methylation is established via the RNA-directed DNA methylation pathway (RdDM), wherein 24-nucleotide small interfering RNAs (siRNAs) guide methylation at cognate genomic loci1. RNA POLYMERASE-IV (Pol-IV), a plant-specific polymerase, initiates the biogenesis of these methylation-targeting RNAs, thus understanding how Pol-IV is regulated is critical in determining how specific patterns of DNA methylation are generated. Here we show roles for four Pol-IV-associated factors, CLASSY (CLSY) 1-42,3, in both locus-specific and global regulation of Pol-IV function. Individually, each CLSY protein controls siRNA production and Pol-IV chromatin association at unique set of loci. This translates into locus-specific DNA methylation losses and the release of silencing. In addition to locus-specific effects, several layers of redundancy were identified: The clsy1,2 and clsy3,4 mutants act synergistically, regulating thousands more siRNA loci than the single mutants. Furthermore, the clsy1,2- and clsy3,4-dependent loci are mutually exclusive and geographically distinct, revealing a striking division of labor amongst the CLSY family. Finally, the clsy quadruple mutant causes global siRNA losses, demonstrating that Pol-IV is completely dependent on the CLSY family. Investigation into the mechanisms underlying the CLSY specificity revealed connections between clsy1,2- and clsy3,4-dependent loci and either SAWADEE HOMEODOMAIN HOMOLOG 1 or DNA METHYLTRANSFERASE 1, demonstrating a reliance on different chromatin modifications, H3K9 or CG DNA methylation, respectively4,5. Together, these findings not only shed light on Pol-IV function, but also reveal an additional layer of complexity to the RdDM pathway that enables the locus-specific control of DNA methylation patterns. Given the parallels between methylation systems in plants and mammals1, these findings will be informative for analogous processes in a broad range of organisms. Overall design: 14 ChIP-seq libraries were sequenced GSE99693 pubmed 29736015 parent_bioproject PRJNA389306