HO-1 impairs the efficacy of radiotherapy by redistributing cGAS and STING in tumors
Chuqing Zhang, … , Cheng Xu, Xiaoyu Liang
Chuqing Zhang, … , Cheng Xu, Xiaoyu Liang
Published December 2, 2024
Citation Information: J Clin Invest. 2024;134(23):e181044. https://doi.org/10.1172/JCI181044.
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Research Article Immunology Oncology

HO-1 impairs the efficacy of radiotherapy by redistributing cGAS and STING in tumors

Abstract

Type I IFNs (IFN-Is) induced by radiotherapy (RT) are critical for its efficacy, while the mechanism by which tumor cells inhibit IFN-I production remains largely unsolved. By an unbiased CRISPR screen, we identified hemeoxygenase 1 (HO-1) as an RT-related regulator of IFN-I production. Mechanistically, the ER-anchored, full-length HO-1 disrupted stimulator of IFN genes (STING) polymerization and subsequent coat protein complex II–mediated (COPII-mediated) ER-Golgi transportation, leading to hampered activation of downstream signaling. This process was exacerbated by the upregulation of HO-1 expression under RT. Importantly, RT also induced HO-1 cleavage. Cleaved HO-1 underwent nuclear translocation, interacted with cyclic GMP-AMP synthase (cGAS), and inhibited its nuclear export upon irradiation, leading to suppressed 2′3′-cyclic GMP-AMP (cGAMP) production. Furthermore, we revealed that HO-1 inhibitors could enhance local and distant tumor control of RT in vivo. Clinically, higher HO-1 expression was associated with a poorer prognosis and earlier tumor relapse after RT in multiple types of patient tumors. Collectively, through comprehensive inhibition of the cGAS/STING pathway, HO-1 strongly inhibited RT-induced IFN-I production, and targeting HO-1 was shown to be a promising RT-sensitizing therapeutic strategy.

Authors

Chuqing Zhang, Zhenji Deng, Jiawei Wu, Cong Ding, Zhe Li, Zhimin Xu, Weipeng Chen, Kaibin Yang, Hanmiao Wei, Tingxiang He, Liufen Long, Jun Ma, Cheng Xu, Xiaoyu Liang

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Figure 4

RT induces HO-1 and promotes its cleavage.

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RT induces HO-1 and promotes its cleavage. (A) Immunoblot analysis of HO...
(A) Immunoblot analysis of HO-1 expression and truncation in the indicated cells before and after RT. (B and C) Immunoblot analysis of HO-1 expression and truncation in HK1 cells after RT (B) or IFN-β treatment (C) combined with or without NAC treatment. (D and E) Immunoblot analysis of Flag–HO-1 expression in HK1 cells before and after RT. (D) Flag tag was fused to N-terminus or C-terminus of HO-1, respectively. (E) Mutating S272-F276 of HO-1 individually or mutating all 5 amino acids between S272 and F276. (F) Subcellular distribution (ER and nucleus) of full-length HO-1, uncleavable HO-1 mutant, cleaved HO-1 (HO-1ΔTMS) in HK1 cells with or without RT. Calreticulin staining for the ER; DAPI staining for the nucleus (scale bars: 10 μm). FL, full-length. (G and H) Nuclear and cytoplasmic protein extraction experiment was performed to determine the cellular localization of exogenous HO-1 or its mutants before (G) and after (H) RT in HK1 cells. (I) Subcellular distribution of endogenous HO-1 was determined with immunofluorescence staining in HK1 cells stimulated with RT (scale bars: 10 μm). (J) Nuclear and cytoplasmic protein extraction experiment was performed to determine the cellular localization of endogenous HO-1 at the indicated time point of RT in HK1 cells. (K and L) HMOX1-KO HK1 cells were stably transfected with the indicated HO-1 mutants. With or without RT, cGAMP (K) and IFN-β (L) production was determined with ELISA. (M and N) HMOX1-KO HK1 cells were stably transfected with indicated HO-1 mutants. With or without cGAMP, STING activation was determined with immunoblot analysis (M), and IFN-β production was determined by ELISA (N). Representative data from 1 experiment are shown (n = 3 biologically independent experiments). *P < 0.05, **P < 0.01, ***P < 0.001, and ****P < 0.0001, by 1-way ANOVA (K, L, and N). Data are shown as the mean ± SD.