AEP-cleaved DDX3X induces alternative RNA splicing events to mediate cancer cell adaptation in harsh microenvironments
Wenrui Zhang, … , Jiayi Chen, Yingying Lin
Wenrui Zhang, … , Jiayi Chen, Yingying Lin
Published November 21, 2023
Citation Information: J Clin Invest. 2024;134(3):e173299. https://doi.org/10.1172/JCI173299.
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Research Article Oncology

AEP-cleaved DDX3X induces alternative RNA splicing events to mediate cancer cell adaptation in harsh microenvironments

Abstract

Oxygen and nutrient deprivation are common features of solid tumors. Although abnormal alternative splicing (AS) has been found to be an important driving force in tumor pathogenesis and progression, the regulatory mechanisms of AS that underly the adaptation of cancer cells to harsh microenvironments remain unclear. Here, we found that hypoxia- and nutrient deprivation–induced asparagine endopeptidase (AEP) specifically cleaved DDX3X in a HIF1A-dependent manner. This cleavage yields truncated carboxyl-terminal DDX3X (tDDX3X-C), which translocates and aggregates in the nucleus. Unlike intact DDX3X, nuclear tDDX3X-C complexes with an array of splicing factors and induces AS events of many pre-mRNAs; for example, enhanced exon skipping (ES) in exon 2 of the classic tumor suppressor PRDM2 leads to a frameshift mutation of PRDM2. Intriguingly, the isoform ARRB1-Δexon 13 binds to glycolytic enzymes and regulates glycolysis. By utilizing in vitro assays, glioblastoma organoids, and animal models, we revealed that AEP/tDDX3X-C promoted tumor malignancy via these isoforms. More importantly, high AEP/tDDX3X-C/ARRB1-Δexon 13 in cancerous tissues was tightly associated with poor patient prognosis. Overall, our discovery of the effect of AEP-cleaved DDX3X switching on alternative RNA splicing events identifies a mechanism in which cancer cells adapt to oxygen and nutrient shortages and provides potential diagnostic and/or therapeutic targets.

Authors

Wenrui Zhang, Lu Cao, Jian Yang, Shuai Zhang, Jianyi Zhao, Zhonggang Shi, Keman Liao, Haiwei Wang, Binghong Chen, Zhongrun Qian, Haoping Xu, Linshi Wu, Hua Liu, Hongxiang Wang, Chunhui Ma, Yongming Qiu, Jianwei Ge, Jiayi Chen, Yingying Lin

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Figure 1

Hypoxia and starvation trigger AEP-specific cleavage of DDX3X in a HIF1A-dependent manner.

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Hypoxia and starvation trigger AEP-specific cleavage of DDX3X in a HIF1A...
(A) Left panel: silver-stained gel showing immunoprecipitated AEP or IgG and their bound proteins; right panel: immunoblot showing DDX3X in AEP immunoprecipitates. The arrowhead indicates that DDX3X may be a substrate of AEP. (B) MS analysis of proteins interacting with AEP. The detected MS/MS peptide spectrum of DDX3X is shown. (C) Endogenous co-IP assays detected the AEP/DDX3X interaction in U87-MG, U251-MG, and MDA-MB-231 cells underwent hypoxia and nutrient deprivation. (D) Immunoblots of DDX3X, AEP and β-actin in U87-MG, U251-MG and MDA-MB-231 cells with or without AEP overexpression (OE). Blots run contemporaneously are presented together. (E) Co-IP assays detected the ability of different DDX3X domains to interact with AEP. (F) Immunoblots of DDX3X, AEP and β-actin in hypoxia-and-starvation–stressed cancer cells (U87-MG) with or without KD of HIF1A. (G) Quantitation of the DDX3X cleavage ratio (tDDX3X/DDX3X) and AEP activity in the indicated U87-MG cells. (H) Immunoblots of DDX3X, AEP and β-actin in hypoxia-and-starvation–stressed cancer cells (MDA-MB-231) with or without KD of HIF1A. Blots run contemporaneously are presented together. (I) Quantitation of the DDX3X cleavage ratio (tDDX3X/DDX3X) and AEP activity in the indicated MDA-MB-231 cells. (J) Immunoblots of Flag, HIF1A, DDX3X, AEP and β-actin in U8 7-MG and MDA-MB-231 cells with WT or stable HIF1A mutant OE. (K) Representative Gd-enhanced T1-weighted and FLAIR MRI images of regional biopsy derived from tumor and adjacent normal parts of GBM. Scale bar: 10 cm. (L) Immunoblots of DDX3X, AEP, and β-actin of tumor and adjacent normal tissues of GBM. Data were plotted as the mean ± SEM. Statistical analysis was performed using 1-way ANOVA followed by Šidák’s multiple comparisons test (G and I). ***P < 0.001, ****P < 0.0001.