Mutations in the RNA Splicing Factor SF3B1 Promote Tumorigenesis through MYC Stabilization.
Zhaoqi LiuAkihide YoshimiJi-Guang WangHana ChoStanley Chun-Wei LeeMichelle KiLillian BitnerTimothy ChuHarshal ShahBo LiuAnthony R MatoPeter RuvoloGiulia FabbriLaura PasqualucciOmar Abdel-WahabRaul RabadanPublished in: Cancer discovery (2020)
Although mutations in the gene encoding the RNA splicing factor SF3B1 are frequent in multiple cancers, their functional effects and therapeutic dependencies are poorly understood. Here, we characterize 98 tumors and 12 isogenic cell lines harboring SF3B1 hotspot mutations, identifying hundreds of cryptic 3' splice sites common and specific to different cancer types. Regulatory network analysis revealed that the most common SF3B1 mutation activates MYC via effects conserved across human and mouse cells. SF3B1 mutations promote decay of transcripts encoding the protein phosphatase 2A (PP2A) subunit PPP2R5A, increasing MYC S62 and BCL2 S70 phosphorylation which, in turn, promotes MYC protein stability and impair apoptosis, respectively. Genetic PPP2R5A restoration or pharmacologic PP2A activation impaired SF3B1-mutant tumorigenesis, elucidating a therapeutic approach to aberrant splicing by mutant SF3B1. SIGNIFICANCE: Here, we identify that mutations in SF3B1, the most commonly mutated splicing factor gene across cancers, alter splicing of a specific subunit of the PP2A serine/threonine phosphatase complex to confer post-translational MYC and BCL2 activation, which is therapeutically intervenable using an FDA-approved drug.See related commentary by O'Connor and Narla, p. 765.This article is highlighted in the In This Issue feature, p. 747.
Keyphrases
- transcription factor
- protein kinase
- network analysis
- genome wide
- cell cycle arrest
- oxidative stress
- machine learning
- induced apoptosis
- cell death
- dna methylation
- squamous cell carcinoma
- endoplasmic reticulum stress
- papillary thyroid
- signaling pathway
- wild type
- cell proliferation
- quantum dots
- induced pluripotent stem cells