Abstract BACKGROUND H3K27-altered diffuse midline glioma (DMG) is a devastating pediatric brainstem tumor that affects 200-300 individuals in the US per year. Median survival is 9-11 months, and there are virtually no long-term survivors. Despite decades of clinical trials, radiation therapy remains standard of care, extending survival by 2-3 months. Elucidating the mechanisms that drive H3K27-altered DMG pathogenesis in order to uncover therapeutic vulnerabilities is of critical importance. Recent studies implicate MALT1 as a potential therapeutic target in gliomas. MALT1 is the effector molecule of the CARMA-BCL10-MALT1 (CBM) signalosome, a cytoplasmic protein complex that drives downstream pro-survival transcriptional activity. MALT1, which possesses scaffolding and protease functions, promotes cell viability, proliferation, and migration/invasion in multiple cancer types. We aim to evaluate the hypotheses that MALT1 promotes DMG cancer cell proliferation and migration and that MALT1 inhibition will abrogate tumor progression. METHODS/RESULTS We screened a panel of cells including astrocytes, neural stem cells, and DMG cell lines by Western blot and found that CBM complex members BCL10 and MALT1 are present in all cells tested. We next demonstrated that MALT1 is proteolytically active in DMG cell lines SF8628 and HSJD-DIPG-007. Specifically, we showed cleavage of the MALT1 protease substrate HOIL, which was abrogated by treatment with the MALT1 protease inhibitor MLT-748. We next generated multiple dox-inducible MALT1 shRNA DMG cell lines to assess the impact of MALT1 deficiency on DMG biology. Thus far, we find that shRNA knockdown of MALT1 does not impact SF8628 cell proliferation. CONCLUSIONS MALT1 is expressed and proteolytically active in DMG cells. Initial studies show that MALT1 knockdown does not affect proliferation of SF8628 cells. We will next evaluate the effect of MALT1 knockdown on proliferation of additional DMG cell lines, as well as the impact on other malignant features of DMG cells including migration/invasion.