DIPG-45. ELONGIN B REGULATES H3K27M CHROMATIN INCORPORATION TO PROMOTE MALIGNANCY IN DIFFUSE MIDLINE GLIOMA

Abstract

Abstract Chromatin dysregulation is both a cause and consequence of aberrant RNA Polymerase II (Pol2) transcription in cancer. Some of the most striking examples of chromatin disruption in cancer include somatic mutations in genes encoding histone H3 (H3.3/H3.1K27M) observed in ~80% of diffuse midline glioma (DMG). H3K27M mutant histones act in a dominant manner to disrupt chromatin regulation and Pol2-dependent transcription in DMG. How H3K27M impinges on the Pol2 transcriptional machinery and whether aberrant Pol2 transcription can reciprocally induce chromatin dysregulation in DMG remain open questions. We conducted epigenome-focused CRISPR dropout screens and identified multiple regulators of Pol2 elongation, including Elongin B and C (ELOB/ELOC) as DMG genetic dependencies. Follow-up studies confirm that knockout (KO) of ELOB inhibits DMG proliferation in neurosphere culture and abrogates DMG tumorigenesis in orthotopic xenografts. Additional chromatin profiling studies reveal that ELOB binding sites are enriched in H3K27M mutant histones, suggesting that ELOB works together with H3K27M to promote malignant gene expression in DMG. Indeed, reciprocal knockout studies suggest that while ELOB chromatin binding patterns were not altered by H3K27M KO, ELOB KO significantly reduced H3K27M chromatin incorporation at thousands of genomic loci. Further RNAseq and PROseq analyses reveal that ELOB KO alters Pol2 transcription resulting in the up-regulation of genes associated with neuronal and muscle differentiation and the repression of glial stem cell genes. Together, these findings suggest that H3K27M chromatin binding patterns and aberrant gene regulation in DMG are, in part, dictated by ELOB and the Pol2 elongation machinery. Finally, analyses of patient datasets indicate that ELOB complex genes are overexpressed in high grade glioma and DMG and correlate with decreased patient survival. Collectively, these studies suggest that a functional interaction between ELOB and H3K27M mutant histones induces DMG-specific aberrations in chromatin and gene regulation to drive malignancy.