Abstract
H3K36 methylation is a key epigenetic mark with critical roles in development and disease. Here, we systematically dissect its functions using CRISPR-engineered mouse mesenchymal stem cells lacking combinations of the five H3K36 methyltransferases, culminating in quintuple knockout cells devoid of H3K36me2/3. We show that H3K36me2 influences enhancer activity, supports the expression of their target genes, and safeguards active genes from encroachment of the repressive marks, H3K27me2/3. In addition, we find that the loss of H3K36me triggers redistribution of large heterochromatic H3K9me3 domains into euchromatin, in part mediated by SUV39H1, leading to global epigenomic remodelling, constitutive heterochromatin erosion, and a collapse of 3D genome organization. Parallel analyses in human HNSCC cells overexpressing the H3K36M oncohistone reveal conserved disruptions to the epigenome and chromatin architecture. Together, these results establish H3K36 methylation as a pivotal regulator of chromatin state and genomic structure.