Pediatric cancers often resemble trapped developmental intermediate states that fail to engage the normal differentiation program, typified by high-risk neuroblastoma arising from the developing sympathetic nervous system. Neuroblastoma cells resemble arrested neuroblasts trapped by a stable but aberrant epigenetic program controlled by sustained expression of a core transcriptional circuit of developmental regulators in conjunction with elevated MYCN or MYC (MYC). The transcription factor ASCL1 is a key master regulator in neuroblastoma and has oncogenic and tumor-suppressive activities in several other tumor types. Using functional mutational approaches, we find that preventing CDK-dependent phosphorylation of ASCL1 in neuroblastoma cells drives coordinated suppression of the MYC-driven core circuit supporting neuroblast identity and proliferation, while simultaneously activating an enduring gene program driving mitotic exit and neuronal differentiation. IMPLICATIONS: These findings indicate that targeting phosphorylation of ASCL1 may offer a new approach to development of differentiation therapies in neuroblastoma. VISUAL OVERVIEW: http://mcr.aacrjournals.org/content/molcanres/18/12/1759/F1.large.jpg.Work was supported by Cancer Research UK Programme Grant RG91505 (AP), Wellcome Trust Investigator Award 212253/Z/18/Z (AP), MRC Research Grant MR/L021129/1 (F.A, A.P); Neuroblastoma UK (D.M, T.P, A.P), CRUK Cambridge Centre Paediatric Programme (L.P), The Terry Fox Foundation (FA), MBRU College of Medicine Internal grant award
MBRU-CM-RG2019-14 (FA), MBRU-ALMAHMEED Collaborative Research Award ALM1909 (FA) and core support from the Wellcome Trust and the MRC Cambridge Stem Cell Institute (F.A, D.M, J.D., A.P.) and Cancer Research UK Cambridge Insititute (I.C, J.C)
