Ultrasound-targeted microbubble cavitation enhances anti–PD-L1 therapy in TNBC via eNOS-mediated reoxygenation
Zhiyu Zhao, Li Ba, Siwei Li, Jianxin Wang, Yuzhou Luo, Sihan Wang, Yan Jin, Changjun Wu
Zhiyu Zhao, Li Ba, Siwei Li, Jianxin Wang, Yuzhou Luo, Sihan Wang, Yan Jin, Changjun Wu
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Research Article Immunology Oncology Vascular biology

Ultrasound-targeted microbubble cavitation enhances anti–PD-L1 therapy in TNBC via eNOS-mediated reoxygenation

Abstract

Hypoxia critically restricts the effectiveness of immunotherapy in triple-negative breast cancer (TNBC). Comprehensive bioinformatics analyses have demonstrated that highly hypoxic TNBC tumors exhibited elevated T cell exhaustion, increased immune checkpoint molecule expression, and diminished responsiveness to immune checkpoint blockade (ICB). Consequently, strategies aimed at alleviating tumor hypoxia may effectively augment ICB therapy. Although ultrasound-targeted microbubble cavitation (UTMC) has been shown to reduce tumor hypoxia, the precise molecular mechanisms remain unclear. Here, we provide evidence that UTMC activated endothelial nitric oxide synthase (eNOS) through G protein–coupled signaling, resembling pathways induced by fluid shear stress. UTMC-induced eNOS activation was largely Ca2+ dependent and resulted in increased nitric oxide production. Enhanced nitric oxide generation was associated with improved tumor perfusion and reduced hypoxia. Combining UTMC with anti–PD-L1 therapy markedly improved the tumor immune microenvironment, characterized by increased CD8+ T cell infiltration, reduced T cell exhaustion, diminished regulatory T cell infiltration, increased macrophage polarization from an M2 to M1 phenotype, and elevated production of proinflammatory cytokines. Collectively, our findings identified UTMC as a promising adjunctive therapeutic approach to mitigate hypoxia and enhance the efficacy of anti–PD-L1 immunotherapy in TNBC. These results support further translational evaluation of UTMC-based combination strategies in hypoxic TNBC.

Authors

Zhiyu Zhao, Li Ba, Siwei Li, Jianxin Wang, Yuzhou Luo, Sihan Wang, Yan Jin, Changjun Wu

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Figure 5

Evaluation of antitumor effects of UTMC combined with immune checkpoint blockade.

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Evaluation of antitumor effects of UTMC combined with immune checkpoint ...
(A) Schematic illustration of the monitoring and treatment protocol for 4T1 tumor–bearing mice. MB, microbubbles-alone control; US, ultrasound-alone control. (B) Average tumor growth curves in mice subjected to different treatments (n = 5 per group). (C) Tumor weights and corresponding digital images of tumors harvested on day 18 after treatment (n = 5 per group). (D) Representative multiplex immunofluorescent staining images for CD31, α-SMA, and DAPI in tumor tissues collected on day 18 following the indicated treatments. Representative images from 5 independent tumors per group are shown, with 1 tissue section analyzed from each tumor. (E) Representative multiplex immunofluorescent staining images for CD31, NG2, VE-cadherin, and DAPI in tumor tissues collected on day 18 following the indicated treatments. Representative images from 5 independent tumors per group are shown, with 1 tissue section analyzed from each tumor. (F and G) Representative multiplex immunofluorescent staining images and corresponding quantitative analysis of RFU for PD-L1, HIF-1A, and DAPI in tumor tissues collected on day 18 following the indicated treatments (blue indicates DAPI nuclear staining). Scale bars: 50 μm (DF). Representative images from 5 independent tumors per group are shown, with 2 tissue sections analyzed from each tumor. Statistical analyses were conducted using 2-way ANOVA followed by Šidák’s post hoc test (B) or 1-way ANOVA followed by Tukey’s post hoc test (C and G). NS, no significance. *P < 0.05; **P < 0.01; ***P < 0.001.