Go to The Journal of Clinical Investigation
  • About
  • Editors
  • Consulting Editors
  • For authors
  • Publication ethics
  • Publication alerts by email
  • Transfers
  • Advertising
  • Job board
  • Contact
  • Physician-Scientist Development
  • Current issue
  • Past issues
  • By specialty
    • COVID-19
    • Cardiology
    • Immunology
    • Metabolism
    • Nephrology
    • Oncology
    • Pulmonology
    • All ...
  • Videos
  • Collections
    • In-Press Preview
    • Resource and Technical Advances
    • Clinical Research and Public Health
    • Research Letters
    • Editorials
    • Perspectives
    • Physician-Scientist Development
    • Reviews
    • Top read articles

  • Current issue
  • Past issues
  • Specialties
  • In-Press Preview
  • Resource and Technical Advances
  • Clinical Research and Public Health
  • Research Letters
  • Editorials
  • Perspectives
  • Physician-Scientist Development
  • Reviews
  • Top read articles
  • About
  • Editors
  • Consulting Editors
  • For authors
  • Publication ethics
  • Publication alerts by email
  • Transfers
  • Advertising
  • Job board
  • Contact
SETD2 regulates chromatin accessibility and transcription to suppress lung tumorigenesis
Yuchen Xie, Merve Sahin, Toru Wakamatsu, Akane Inoue-Yamauchi, Wanming Zhao, Song Han, Amrita M. Nargund, Shaoyuan Yang, Yang Lyu, James J. Hsieh, Christina S. Leslie, Emily H. Cheng
Yuchen Xie, Merve Sahin, Toru Wakamatsu, Akane Inoue-Yamauchi, Wanming Zhao, Song Han, Amrita M. Nargund, Shaoyuan Yang, Yang Lyu, James J. Hsieh, Christina S. Leslie, Emily H. Cheng
View: Text | PDF
Research Article Oncology

SETD2 regulates chromatin accessibility and transcription to suppress lung tumorigenesis

  • Text
  • PDF
Abstract

SETD2, a H3K36 trimethyltransferase, is the most frequently mutated epigenetic modifier in lung adenocarcinoma, with a mutation frequency of approximately 9%. However, how SETD2 loss of function promotes tumorigenesis remains unclear. Using conditional Setd2-KO mice, we demonstrated that Setd2 deficiency accelerated the initiation of KrasG12D-driven lung tumorigenesis, increased tumor burden, and significantly reduced mouse survival. An integrated chromatin accessibility and transcriptome analysis revealed a potentially novel tumor suppressor model of SETD2 in which SETD2 loss activates intronic enhancers to drive oncogenic transcriptional output, including the KRAS transcriptional signature and PRC2-repressed targets, through regulation of chromatin accessibility and histone chaperone recruitment. Importantly, SETD2 loss sensitized KRAS-mutant lung cancer to inhibition of histone chaperones, the FACT complex, or transcriptional elongation both in vitro and in vivo. Overall, our studies not only provide insight into how SETD2 loss shapes the epigenetic and transcriptional landscape to promote tumorigenesis, but they also identify potential therapeutic strategies for SETD2 mutant cancers.

Authors

Yuchen Xie, Merve Sahin, Toru Wakamatsu, Akane Inoue-Yamauchi, Wanming Zhao, Song Han, Amrita M. Nargund, Shaoyuan Yang, Yang Lyu, James J. Hsieh, Christina S. Leslie, Emily H. Cheng

×

Figure 3

Setd2 deficiency induces Etv1 through activation of an intronic enhancer to promote transformation.

Options: View larger image (or click on image) Download as PowerPoint

Setd2 deficiency induces Etv1 through activation of an intronic enhance...
(A) Venn diagram showing overlap of differentially expressed genes (FDR < 0.05) comparing KrasG12DSetd2–/– with KrasG12D mouse lung tumors and comparing SETD2MT (n = 20) with SETD2WT (n = 210) human lung adenocarcinomas from TCGA. Heatmap showing these genes in mouse lung tumors. (B) Left, qPCR analysis of Etv1 in mouse lung tumors (mean ± SD, n = 4). Right, the normalized ETV1 expression comparing SETD2MT with SETD2WT human lung adenocarcinomas was obtained from cBioPortal. (C) Immunoblot analyses of the indicated mouse lung tumors. The number denotes the ETV1 expression normalized against β-actin (P = 0.0301, KrasG12D versus KrasG12DSetd2–/–). (D) A schematic of the domain structure of SETD2 and SETD2ΔN. Whole cell lysates (WCL) and histone fractions from primary KrasG12DSetd2–/– (KS) mouse lung tumor cells ± SETD2ΔN transduction or KrasG12Dp53–/– mouse lung tumor cells were analyzed by immunoblots. The Etv1 mRNA levels were assessed by qPCR (mean ± SD, n = 3). (E) Primary KS cells transduced with the indicated sgRNAs were analyzed by soft agar colony formation assays and immunoblots. (F) Representative ATAC-Seq tracks at the Etv1 locus in mouse lung tumors. (G) Primary mouse lung tumor cells were assessed by ChIP-qPCR at the indicated genomic regions (mean ± SD, n = 3). (H and I) KS cells transduced the indicated sgRNAs were analyzed by qPCR (mean ± SD, n = 3), immunoblots, or soft agar colony formation assays. (J) A549 cells were transiently transfected with pGL2-pro vector or pGL2-pro containing the putative intron 4 enhancer of Etv1 ± deletion of the FOS binding motif, together with the pRL-SV40 plasmid (Promega) as a normalization control (mean ± SD, n = 3). *P < 0.05; **P < 0.01; ***P < 0.001 by Student’s t test.

Copyright © 2026 American Society for Clinical Investigation
ISSN 2379-3708

Sign up for email alerts