Irina Alimova, Dong Wang, John DeSisto, Etienne Danis, Senthilnath Lakshmanachetty, Eric Prince, Gillian Murdock, Angela Pierce, Andrew Donson, Ilango Balakrishnan, Natalie Serkova, Hening Lin, Nicholas K Foreman, Nathan Dahl, Sujatha Venkataraman, Rajeev Vibhakar
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引用次数: 0
Abstract
An atypical teratoid rhabdoid tumor (ATRT) is a highly aggressive pediatric brain tumor driven by the loss of SMARCB1, which results in epigenetic dysregulation of the genome. SMARCB1 loss affects lineage commitment and differentiation by controlling gene expression. We hypothesized that additional epigenetic factors cooperate with SMARCB1 loss to control cell self-renewal and drive ATRT. We performed an unbiased epigenome-targeted screen to identify genes that cooperate with SMARCB1 and identified SIRT2 as a key regulator. Using in vitro pluripotency assays combined with in vivo single-cell RNA transcriptomics, we examined the impact of SIRT2 on differentiation of ATRT cells. We used a series of orthotopic murine models treated with SIRT2 inhibitors to examine the impact on survival and clinical applicability. We found that ATRT cells are highly dependent on SIRT2 for survival. Genetic or chemical inhibition led to decreased cell self-renewal and induction of differentiation in tumor spheres and in vivo models. We found that SIRT2 inhibition can restore gene expression programs lost because of SMARCB1 loss and reverse the differentiation block in ATRT in vivo. Finally, we showed the in vivo efficacy of a clinically relevant inhibitor demonstrating SIRT2 inhibition as a potential therapeutic strategy. We concluded that SIRT2 is a critical dependency in SMARCB1-deficient ATRT cells and acts by controlling the pluripotency-differentiation switch. Thus, SIRT2 inhibition is a promising therapeutic approach that warrants further investigation and clinical development.
Implications: SIRT2 inhibition is a molecular vulnerability in SMARCB1-deleted tumors.
期刊介绍:
Molecular Cancer Research publishes articles describing novel basic cancer research discoveries of broad interest to the field. Studies must be of demonstrated significance, and the journal prioritizes analyses performed at the molecular and cellular level that reveal novel mechanistic insight into pathways and processes linked to cancer risk, development, and/or progression. Areas of emphasis include all cancer-associated pathways (including cell-cycle regulation; cell death; chromatin regulation; DNA damage and repair; gene and RNA regulation; genomics; oncogenes and tumor suppressors; signal transduction; and tumor microenvironment), in addition to studies describing new molecular mechanisms and interactions that support cancer phenotypes. For full consideration, primary research submissions must provide significant novel insight into existing pathway functions or address new hypotheses associated with cancer-relevant biologic questions.
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