A connect consortium preclinical study identifies mek inhibition and radiation as potential combination partners for the alk2 inhibitor tp-0184 in acvr1-mutant dmg

Abstract Somatic mutations in ACVR1, which encodes the serine/threonine kinase ALK2, are found in 20-25% of DMG-H3K27 patients. Treatment of ACVR1-mutant orthotopic xenografts with multiple chemotypes of ALK2 inhibitors (ALK2i) results in extended survival in vivo but, as single agents, these inhibitors are unable to achieve a complete anti-tumour response. To identify novel combination strategies alongside ALK2 inhibition, five international laboratories pooled resources to evaluate the ALK2i TP-0184 across 26 patient-derived DMG-H3K27 models in vitro, demonstrating GI50 values of ~0.5-10uM, although with no significant difference between ACVR1-mutant and wild-type. Genome-scale CRISPR screens of ALK2i-treated ACVR1-mutant models revealed specific genetic dependencies in critical nodes of several signalling pathways including MTOR, as well as PPP2R1A, known to play a role in MAPK pathway activation. Biomarker analysis showed inhibition of phospho-SMAD1/5/9 by western blot, with RNAseq and proteomic analysis indicating downstream signalling consequences in BMP/SMAD signalling following TP-0184 treatment. We observed synergistic pharmacological interactions between TP-0184 and both everolimus (mTORi) and trametinib (MEKi) in 7 to 8 ACVR1-mutant DMG models, respectively, with the latter validated across laboratories using orthogonal assays. Importantly, combining TP-0184 with radiation in vitro showed a profound radiosensitisation effect of the ALK2i in three ACVR1-mutant models using both clonogenic and cell viability assays in multiple laboratories, in part due to an observed activation of phospho-SMAD1/5/9 by radiation. Finally, in vivo tolerability and pharmacokinetic assays in multiple immuno-compromised and immune-competent mouse strains suggested a dose of 150mg/kg TP-0184 and 0.4mg/kg trametinib for use in in vivo efficacy studies, with good CNS penetrance of both drugs in excess of in vitro GI50 values. Such studies have been initiated in six DMG-H3K27 models across our laboratories to robustly assess the combination of TP-0184 and trametinib/radiation to support rapid potential translation to clinical trial.