Targeting STING-induced immune evasion with nanoparticulate binary pharmacology improves tumor control in mice
Fanchao Meng, Hengyan Zhu, Shuo Wu, Bohan Li, Xiaona Chen, Hangxiang Wang
Fanchao Meng, Hengyan Zhu, Shuo Wu, Bohan Li, Xiaona Chen, Hangxiang Wang
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Research Article Immunology Oncology

Targeting STING-induced immune evasion with nanoparticulate binary pharmacology improves tumor control in mice

Abstract

Harnessing the stimulator of IFN genes (STING) signaling pathway to trigger innate immune responses has shown remarkable promise in cancer immunotherapy; however, overwhelming resistance to intratumoral STING monotherapy has been witnessed in clinical trials, and the underlying mechanisms remain to be fully explored. Herein, we show that pharmacological STING activation following the intratumoral injection of a nonnucleotide STING agonist (i.e., MSA-2) resulted in apoptosis of the cytolytic T cells, IFN-mediated overexpression of indoleamine 2,3-dioxygenase 1 (IDO1), and evasion from immune surveillance. We leveraged a noncovalent chemical strategy for developing immunomodulatory binary nanoparticles (iBINP) that include both the STING agonist and an IDO1 inhibitor for treating immune-evasive tumors. This iBINP platform, developed by dual prodrug engineering and subsequent nanoparticle assembly, enabled tumor-restricted STING activation and IDO1 inhibition, achieving immune activation while mitigating immune tolerance. A systemic treatment of preclinical models of colorectal cancer with iBINP resulted in robust antitumor immune responses, reduced infiltration of Tregs, and enhanced activity of CD8+ T cells. Importantly, this platform exhibits great therapeutic efficacy by overcoming STING-induced immune evasion and controlling the progression of multiple tumor models. This study unveils the mechanisms by which STING monotherapy induces immunosuppression in the tumor microenvironment and provides a combinatorial strategy for advancing cancer immunotherapies.

Authors

Fanchao Meng, Hengyan Zhu, Shuo Wu, Bohan Li, Xiaona Chen, Hangxiang Wang

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Figure 2

STING pathway activation upregulates the expression of Ido1.

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STING pathway activation upregulates the expression of Ido1. (A) Venn di...
(A) Venn diagram showing the intersection of DEGs from the 3 GEO databases (GSE204825, GSE159825, and GSE134129). (B) Volcano plot illustrating changes in gene expression after the administration of STING agonist, with the Ido1 gene marked by an arrow. (C) Heatmap of DEGs, excluding some genes with unclear functions. The DEGs were divided into 2 clusters of antitumor and protumor genes. (D) GSEA analysis demonstrating the enrichment of DEGs in various pathways. (E and F) Analysis of the correlation between the expression of IDO1 and that of the genes (IFNG or FOXP3 in patients with colon adenocarcinoma [COAD]) using the TCGA database. (G) Expression of Ifng across all types of immune cells. (H) Feature plot of Ido1 showing inducible patterns of expression upon MSA-2 administration. Red indicates Ido1hi cells. (I) Expression of signature genes of the IDO pathway (Ido1, Ido2, and Tdo2) in various immune cells. (J) Alterations in Ido1 gene expression following stimulation with IFN-α and IFN-γ. (K) Quantitative real-time PCR analysis of Ido1 and Western blot analysis of the protein IDO1 in IFN-γ–treated MC38 tumor cells (n = 3). β-Actin was used as internal control. (L) IHC staining of Ido1 at the tumor site with or without MSA-2 administration. Early-stage and advanced tumors represent tumor volumes of approximately 500 and 1,500 mm3, respectively. Scale bar: 50 μm. (M) IFN-γ secretion was assessed using ELISA (n = 3). (N) Western blot analysis of IDO1 protein expression in MSA-2–treated or untreated BMDCs. Data are depicted as the mean ± SD. *P < 0.05, **P < 0.01, as determined by Student’s t test.