Abstract
BACKGROUND: Diffuse midline glioma (DMG), H3K27-altered, is a lethal pediatric brain tumor driven by epigenetic dysregulation. Histone deacetylase (HDAC) inhibitors have been identified as a promising drug class; however, the precise mechanism of efficacy for these agents in DMG has not been fully explored. Furthermore, their translational potential has been limited by off-target effects and poor CNS penetration of clinically available drugs. METHODS: We investigated the genetic and chemical dependencies of HDAC isoforms in DMG cell lines using CRISPR/Cas9 screening and an HDAC inhibitor toolbox. We identified an HDAC inhibitor termed “Compound 26” with class I isoform selectivity and excellent CNS penetration (brain/plasma AUC of >7). Effects of Compound 26 on DMG cells was evaluated in-vitro through assessment of cytotoxicity, proliferation and apoptosis. Mechanistic studies were undertaken using bulk RNAseq and HiChIP (H3K27ac, H3K27me3). Efficacy of Compound 26 in-vivo was determined using an aggressive orthotopic xenograft model. RESULTS: We confirmed that HDAC class I isoforms are dependencies in DMG cell lines, with HDAC2 representing a selective dependency that is highly expressed in patient tumors. Compound 26 is cytotoxic in DMG cells, reducing proliferation through cell cycle arrest. Differential expression analysis confirmed profound effects on cycling programs with Compound 26 treatment. Furthermore, analysis of genome structure using HiChIP revealed global increases in H3K27ac contacts, with notable spreading along key cell cycle gene bodies such as p16 (CDKN2A). Interestingly, treatment with Compound 26 also significantly increased global H3K27me3 contacts, which is canonically decreased in H3K27-altered DMG. Most importantly, Compound 26 was well tolerated, effectively crossed the blood-brain barrier, and significantly extended survival in an aggressive DMG-orthotopic xenograft model. CONCLUSIONS: This study comprehensively outlines the reliance of DMG cells on HDAC class I isoforms, elucidates novel mechanisms for this dependency, and highlights a compelling new agent to bypass prior translational pitfalls