Asparagine drives immune evasion in bladder cancer via RIG-I stability and type I IFN signaling
Wenjie Wei, … , Xu Zhang, Yan Huang
Wenjie Wei, … , Xu Zhang, Yan Huang
Published February 18, 2025
Citation Information: J Clin Invest. 2025;135(8):e186648. https://doi.org/10.1172/JCI186648.
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Research Article Cell biology Immunology

Asparagine drives immune evasion in bladder cancer via RIG-I stability and type I IFN signaling

Abstract

Tumor cells often employ many ways to restrain type I IFN signaling to evade immune surveillance. However, whether cellular amino acid metabolism regulates this process remains unclear, and its effects on antitumor immunity are relatively unexplored. Here, we found that asparagine inhibited IFN-I signaling and promoted immune escape in bladder cancer. Depletion of asparagine synthetase (ASNS) strongly limited in vivo tumor growth in a CD8+ T cell–dependent manner and boosted immunotherapy efficacy. Moreover, clinically approved L-asparaginase (ASNase),synergized with anti–PD-1 therapy in suppressing tumor growth. Mechanistically, asparagine can directly bind to RIG-I and facilitate CBL-mediated RIG-I degradation, thereby suppressing IFN signaling and antitumor immune responses. Clinically, tumors with higher ASNS expression show decreased responsiveness to immune checkpoint inhibitor therapy. Together, our findings uncover asparagine as a natural metabolite to modulate RIG-I–mediated IFN-I signaling, providing the basis for developing the combinatorial use of ASNase and anti–PD-1 for bladder cancer.

Authors

Wenjie Wei, Hongzhao Li, Shuo Tian, Chi Zhang, Junxiao Liu, Wen Tao, Tianwei Cai, Yuhao Dong, Chuang Wang, Dingyi Lu, Yakun Ai, Wanlin Zhang, Hanfeng Wang, Kan Liu, Yang Fan, Yu Gao, Qingbo Huang, Xin Ma, Baojun Wang, Xu Zhang, Yan Huang

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Figure 3

Silencing of ASNS activates RIG-I–induced IFN-I signaling.

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Silencing of ASNS activates RIG-I–induced IFN-I signaling. (A) Heat map ...
(A) Heat map depicted the differentially expressed mRNA in the indicated MBT2 cells. (B) Enrichment analysis for representative GO pathways in shAsns-mediated target genes. (C) GSEA plots of individual pathways enriched in shAsns-deficient MBT2 cells. (D) qRT-PCR showed the relative expression levels of ISGs genes in the indicated MBT2 cells. (E) Heatmap of multiple cytokines and chemokines detected by Luminex protein biochip testing system between Asns knockdown and the control groups in MBT2 cell culture supernatants. (F) ELISA experiment revealed the expression levels of Ifn-β and Ccl5 in culture supernatants of the indicated MBT2 cells. (G) qRT-PCR (left) and ELISA (right) assays showed the expression levels of Ifn-β in the indicated MBT2 cells. Western blot analysis of cell lysates from the indicated MBT2 cells. (H and I) Scramble or shAsns MBT2 cells were transfected with poly (I:C) (2 μg/mL) for 8 hours and the protein levels of Ifn-β (H) and Ccl5 (I) were determined by ELISA. (J) ELISA assay showed the expression levels of Ifn-β protein in the indicated MBT2 cells. (K) ELISA assay showed the expression levels of Ifn-β and Ccl5 in MBT2 cells treated with ASNase for 48 hours. (L) Western blot analysis of cell lysates from the MBT2 cells stably transfected with scramble and shAsns. (M) Western blot analysis of cell lysates from the indicated MBT2 cells. (N) Western blot analysis of cell lysates from the indicated MBT2 cells. (O and P) Tumor image and tumor weight of immunocompetent C57BL/6 mice (n = 5) injected subcutaneously with indicated MB49 cells. Data were mean ± SD. Statistical significance was calculated by 2 tailed unpaired Student’s t tests for J; 1-way ANOVA for D, F, H, I, and K; 2-way ANOVA for G and P. *P < 0.05, **P < 0.01, ***P < 0.001.