SETD2 loss-of-function uniquely sensitizes cells to epigenetic targeting of NSD1-directed H3K36 methylation

SETD2 loss-of-function uniquely sensitizes cells to epigenetic targeting of NSD1-directed H3K36 methylation

Abstract Background SETD2 is the sole epigenetic factor responsible for catalyzing histone 3, lysine 36, tri-methylation (H3K36me3) in mammals. Its role in regulating cellular processes such as RNA splicing, DNA repair, and spurious transcription initiation underlies its broader tumor suppressor fun...

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Main Authors: Ryan T. Wagner, Ryan A. Hlady, Xiaoyu Pan, Liguo Wang, Sungho Kim, Xia Zhao, Louis Y. El Khoury, Shafiq Shaikh, Jian Zhong, Jeong-Heon Lee, Jolanta Grembecka, Tomasz Cierpicki, Thai H. Ho, Keith D. Robertson
Format: Article
Language:English
Published: BMC 2025-02-01
Series:Genome Biology
Subjects:
Clear cell renal cell carcinoma (ccRCC)
SETD2
Histone 3, lysine 36, tri-methylation (H3K36me3)
NSD1
Synthetic lethality (SL)
CRISPRi
Online Access:https://doi.org/10.1186/s13059-025-03483-z
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Summary:Abstract Background SETD2 is the sole epigenetic factor responsible for catalyzing histone 3, lysine 36, tri-methylation (H3K36me3) in mammals. Its role in regulating cellular processes such as RNA splicing, DNA repair, and spurious transcription initiation underlies its broader tumor suppressor function. SETD2 mutation promotes the epithelial-mesenchymal transition and is clinically associated with adverse outcomes highlighting a therapeutic need to develop targeted therapies against this dangerous mutation. Results We employ an unbiased genome-wide synthetic lethal screen, which identifies another H3K36me writer, NSD1, as a synthetic lethal modifier in SETD2-mutant cells. Confirmation of this synthetic lethal interaction is performed in isogenic clear cell renal cell carcinoma and immortalized renal epithelial cell lines, in mouse and human backgrounds. Depletion of NSD1 using a CRISPRi targeting approach promotes the loss of SETD2-mutant cells coincident with elevated levels of DNA damage and apoptosis. Surprisingly, only suppression of NSD1, but not related H3K36-methyltransferases, promotes synthetic lethality in these models. Mapping of genomic H3K36me2 targeting by NSD1 and NSD2 individually highlights the independent functions of these epigenetic writers. Furthermore, as a proof-of-principle, we demonstrate the therapeutic feasibility of targeting this synthetic lethal interaction by recapitulating the phenotype using BT5, a first-in-class pharmacologic inhibitor against NSD1. Conclusions These findings unify genome-wide screening approaches with the latest genetic and pharmacologic modeling methodologies to reveal an entirely novel epigenetic approach to individualize therapies against a challenging loss-of-function SETD2 mutation in cancer.
ISSN:1474-760X

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