A nanoparticle-incorporated STING activator enhances antitumor immunity in PD-L1–insensitive models of triple-negative breast cancer
Ning Cheng, Rebekah Watkins-Schulz, Robert D. Junkins, Clément N. David, Brandon M. Johnson, Stephanie A. Montgomery, Kevin J. Peine, David B. Darr, Hong Yuan, Karen P. McKinnon, Qi Liu, Lei Miao, Leaf Huang, Eric M. Bachelder, Kristy M. Ainslie, Jenny P-Y Ting
Ning Cheng, Rebekah Watkins-Schulz, Robert D. Junkins, Clément N. David, Brandon M. Johnson, Stephanie A. Montgomery, Kevin J. Peine, David B. Darr, Hong Yuan, Karen P. McKinnon, Qi Liu, Lei Miao, Leaf Huang, Eric M. Bachelder, Kristy M. Ainslie, Jenny P-Y Ting
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Research Article Immunology Therapeutics

A nanoparticle-incorporated STING activator enhances antitumor immunity in PD-L1–insensitive models of triple-negative breast cancer

Abstract

Triple-negative breast cancer (TNBC) has few therapeutic options, and alternative approaches are urgently needed. Stimulator of IFN genes (STING) is becoming an exciting target for therapeutic adjuvants. However, STING resides inside the cell, and the intracellular delivery of CDNs, such as cGAMP, is required for the optimal activation of STING. We show that liposomal nanoparticle-delivered cGAMP (cGAMP-NP) activates STING more effectively than soluble cGAMP. These particles induce innate and adaptive host immune responses to preexisting tumors in both orthotopic and genetically engineered models of basal-like TNBC. cGAMP-NPs also reduce melanoma tumor load, with limited responsivity to anti–PD-L1. Within the tumor microenvironment, cGAMP-NPs direct both mouse and human macrophages (M), reprograming from protumorigenic M2-like phenotype toward M1-like phenotype; enhance MHC and costimulatory molecule expression; reduce M2 biomarkers; increase IFN-γ–producing T cells; augment tumor apoptosis; and increase CD4+ and CD8+ T cell infiltration. Activated T cells are required for tumor suppression, as their depletion reduces antitumor activity. Importantly, cGAMP-NPs prevent the formation of secondary tumors, and a single dose is sufficient to inhibit TNBC. These data suggest that a minimal system comprised of cGAMP-NP alone is sufficient to modulate the tumor microenvironment to effectively control PD-L1–insensitive TNBC.

Authors

Ning Cheng, Rebekah Watkins-Schulz, Robert D. Junkins, Clément N. David, Brandon M. Johnson, Stephanie A. Montgomery, Kevin J. Peine, David B. Darr, Hong Yuan, Karen P. McKinnon, Qi Liu, Lei Miao, Leaf Huang, Eric M. Bachelder, Kristy M. Ainslie, Jenny P-Y Ting

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Figure 7

Liposomal cGAMP-NPs increase CD8+ cytotoxic T cells and apoptosis.

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Liposomal cGAMP-NPs increase CD8+ cytotoxic T cells and apoptosis. (A) I...
(A) In vitro stimulation of T cells was evaluated by directly coculturing splenic isolated CD3+ T cells with cGAMP-NP–treated B16F10 tumor antigen–pulsed macrophages (using blank-NP, TF, or soluble form as control treatments). IFN-γ secretion was determined by ELISA assay after 3 days of coculture. (BD) C3(1)Tag orthotopic tumors were harvested on day 21. (B) The percentages of tumor-infiltrating leukocytes (CD45+ cells), CD3+ lymphocytes, and CD8+ T cells were detected by flow cytometry. (C) Representative H&E staining (top, scale bar: 500 μm; bottom: scale bar: 100 μm), IHC staining (red, CD8; brown, IFN-γ; scale bar: 100 μm), and IF staining (caspase-3+, red; nucleus, blue; scale bar: 100 μm) in tumors harvested on day 21. (D) Quantitative analysis of CD8+ T cells and caspase-3+ cells as shown in C. Data in A, B, and D were pooled from 2 experiments (A, n = 8/group; B, n = 10 mice/group; D, n = 5–10/group). Images in C are representative of 2 experiments (n = 10 mice/group). Statistical significance was determined by 1-way ANOVA (A and B) or 2-tailed Student’s t test (D). *P < 0.05; ***P < 0.001; ****P < 0.0001.