Abstract BACKGROUND Medulloblastoma (MB) is one of the most common malignant childhood brain tumors. The sonic hedgehog (SHH) subgroup represents 30% of MBs and can arise from granule neuron progenitors (GNPs). SHH-MB is a diverse subgroup of tumors which often exhibit loss-of function mutations in PTCH1 or SUFU, activating mutations in the receptor SMO and amplification of the transcription factor GLI2. Of note, SHH-MBs harboring GLI2-amplification and associated with P53 mutations have extremely poor prognosis with a 5-year survival rate less than 30%. These tumors are non-responsive to SMO inhibitors, which are the only targeted treatment currently available for SHH-MB. Therefore, the development of novel effective therapies for this disease is urgent. Although GLI2 amplification is detected in SHH-MBs, it is not yet known if GLI2 can drive oncogenic activity in this disease. METHOD To elucidate the mechanisms underlying tumorigenesis, our group has developed a novel transgenic model of GLI2-driven MB by expressing a constitutively active form of GLI2 (GLI2A) in Atoh1+ cells in the developing mouse cerebellum to form tumors. To accomplish this, we crossed R26;Gli2A mice with Atoh1-Cre. RESULTS The resulting tumors faithfully recapitulate human GLI2-amplified MB at the cellular and molecular levels. Inactivation of GLI2A resulted in tumor regression, indicating that GLI2 is not only critical for tumorigenesis, but also required for tumor maintenance, suggesting that targeting GLI2 itself or its downstream targets may be effective to inhibit growth of GLI2-driven MB. Interestingly, activation of GLI2A expression in the neonatal cerebellum was not sufficient to drive tumorigenesis, indicating that GLI2-driven MB arises from more primitive cells in the developing cerebellum. CONCLUSION Taken together, our studies demonstrate for the first time the role of GLI2 as an oncogenic driver of MB and introduce a novel mouse model which can be used to develop targeted therapies for this disease.