In situ vaccination via tissue-targeted cDC1 expansion enhances the immunogenicity of chemoradiation and immunotherapy
Brandon Lam, … , Chien-Fu Hung, T.-C. Wu
Brandon Lam, … , Chien-Fu Hung, T.-C. Wu
Published November 2, 2023
Citation Information: J Clin Invest. 2024;134(1):e171621. https://doi.org/10.1172/JCI171621.
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Research Article Immunology

In situ vaccination via tissue-targeted cDC1 expansion enhances the immunogenicity of chemoradiation and immunotherapy

Abstract

Even with the prolific clinical use of next-generation cancer therapeutics, many tumors remain unresponsive or become refractory to therapy, creating a medical need. In cancer, DCs are indispensable for T cell activation, so there is a restriction on cytotoxic T cell immunity if DCs are not present in sufficient numbers in the tumor and draining lymph nodes to take up and present relevant cancer antigens. To address this bottleneck, we developed a therapeutic based on albumin fused with FMS-related tyrosine kinase 3 ligand (Alb-Flt3L) that demonstrated superior pharmacokinetic properties compared with Flt3L, including significantly longer half-life, accumulation in tumors and lymph nodes, and cross-presenting-DC expansion following a single injection. We demonstrated that Alb-Flt3L, in combination with standard-of-care chemotherapy and radiation therapy, serves as an in situ vaccination strategy capable of engendering polyclonal tumor neoantigen–specific immunity spontaneously. In addition, Alb-Flt3L–mediated tumor control synergized with immune checkpoint blockade delivered as anti–PD-L1. The mechanism of action of Alb-Flt3L treatment revealed a dependency on Batf3, type I IFNs, and plasmacytoid DCs. Finally, the ability of Alb-Flt3L to expand human DCs was explored in humanized mice. We observed significant expansion of human cross-presenting-DC subsets, supporting the notion that Alb-Flt3L could be used clinically to modulate human DC populations in future cancer therapeutic regimens.

Authors

Brandon Lam, Yu Jui Kung, John Lin, Ssu-Hsueh Tseng, Hsin-Fang Tu, Claire Huang, Brandon Lee, Esteban Velarde, Ya Chea Tsai, Rafael Villasmil, Sung Taek Park, Deyin Xing, Chien-Fu Hung, T.-C. Wu

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Figure 2

Treatment with Alb-Flt3L drives cross-presenting-DC expansion, T cell activation, and ultimately tumor control.

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Treatment with Alb-Flt3L drives cross-presenting-DC expansion, T cell ac...
C57BL/6 mice were inoculated with 2 × 105 B16-OVA tumor cells subcutaneously. Sixteen days after implantation, mice were administered Alb-Flt3L (100 μg), Flt3L (20 μg) (equimolar amounts), or vehicle control on days 19, 21, 24, and 30 for a total of 4 doses. (A) Tumor growth and (B) survival curves following the described treatment protocol (n = 5). For immunologic analysis, the experiment was repeated, and mice were sacrificed following 3 treatments (day 24) with Alb-Flt3L, Flt3L (equimolar amounts), or vehicle control, and assayed for DC expansion and T cell activation. The frequencies and counts of (C) total DCs (D) pDCs, (E) cDC1s, and (F) cDC2s in the tumor-draining lymph nodes and the frequencies and counts of (G) total DCs, (H) pDCs, (I) cDC1s, and (J) cCD2s in the tumor for the indicated treatment groups are shown (n = 7). The frequencies and counts of (K) CD8+IFN-γ+, (L) CD8+Ki-67+, (M) CD4+IFN-γ+, and (N) CD4+Ki-67+ cells in the tumor-draining lymph nodes and the frequencies and counts of (O) CD8+IFN-γ+, (P) CD8+Ki-67+, (Q) CD4+IFN-γ+, and (R) CD4+Ki-67+ cells in the tumors for the indicated treatment groups are shown (n = 5). *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001 by 1-way ANOVA (bar graphs) or 2-way ANOVA (tumor growth curves), except tumor survival curves in B, which were assessed using the log-rank test.