Abstract
RATIONALE: Low grade gliomas (LGGs) are defined by isocitrate dehydrogenase (IDH)-mutations that mediate broad epigenetic changes. However, additional determinants of low-grade gliomagenesis remain unknown, including factors necessary for the activation of LGG gene programs. Here, we aim at identifying epigenetic prerequisites of IDH-dependent gliomagenesis by modulating key chromatin modifiers in a conditionally IDH(R132H)-expressing immortalized human astrocyte (IHA) model system. METHODS: Using chemical compounds, we targeted key histone modifications and DNA methylation in an inducibly IDH(R132H) expressing IHA cell line. Flow cytometry for the LGG-associated marker L1CAM served as a primary read-out. Compound candidates were further assessed with RNA-Seq and mass spectrometry. Phenotypic evaluation included sphere formation, clonogenicity, cell viability and invasion assays. Relevant findings were additionally assessed in established LGG cell lines TS603, NCH612 and NCH1681. RESULTS: L1CAM was significantly altered by DOT1L inhibitor EPZ00477, MLL1 inhibitor MM-102, and EZH2 inhibitor GSK-126. MM-102 treatment was associated with broad transcriptional downregulation. Intersecting data from MM-102 and GSK126 treated cells, we identified potential bivalent genes directly affected by inhibitor treatment that were enriched for Wnt signaling and developmental transcription factors implicated in gliomagenesis. Overlapping transcriptional and proteomics data, MM-102-treated cells exhibited a signature of predominantly downregulated genes associated with invasion/migration, extracellular matrix (ECM) and cholesterol metabolism. Fittingly, cells showed impaired invasion, clonal proliferation and sphere forming capacity. The negative effect on sphere formation tracked inversely with aggressiveness of established LGG cell lines. CONCLUSION: Interfering with histone H3K4 methylation through MLL1 inhibition is associated with broad downregulation of gene sets related to cell identity and ECM/migration, reflected by disruption of clonal proliferation in IDH(R132H) astrocytes and LGG cell lines. This points to deposition of H3K4 methylation as a prerequisite of cell fate change in LGG development. Persisting effects on established LGG cell lines warrant its investigation as a potential therapeutic target.