Cure of syngeneic carcinomas with targeted IL-12 through obligate reprogramming of lymphoid and myeloid immunity
Youji Hong, Yvette Robbins, Xinping Yang, Wojciech K. Mydlarz, Anastasia Sowers, James B. Mitchell, James L. Gulley, Jeffrey Schlom, Sofia R. Gameiro, Cem Sievers, Clint T. Allen
Youji Hong, Yvette Robbins, Xinping Yang, Wojciech K. Mydlarz, Anastasia Sowers, James B. Mitchell, James L. Gulley, Jeffrey Schlom, Sofia R. Gameiro, Cem Sievers, Clint T. Allen
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Research Article Immunology Oncology

Cure of syngeneic carcinomas with targeted IL-12 through obligate reprogramming of lymphoid and myeloid immunity

Abstract

Therapeutic IL-12 has demonstrated the ability to reduce local immune suppression in preclinical models, but clinical development has been limited by severe inflammation-related adverse events with systemic administration. Here, we show that potent immunologic tumor control of established syngeneic carcinomas can be achieved by i.t. administration of a tumor-targeted IL-12 antibody fusion protein (NHS–rmIL-12) using sufficiently low doses to avoid systemic toxicity. Single-cell transcriptomic analysis and ex vivo functional assays of NHS–rmIL-12–treated tumors revealed reinvigoration and enhanced proliferation of exhausted CD8+ T lymphocytes, induction of Th1 immunity, and a decrease in Treg number and suppressive capacity. Similarly, myeloid cells transitioned toward inflammatory phenotypes and displayed reduced suppressive capacity. Cell type–specific IL-12 receptor–KO BM chimera studies revealed that therapeutic modulation of both lymphoid and myeloid cells is required for maximum treatment effect and tumor cure. Study of single-cell data sets from human head and neck carcinomas revealed IL-12 receptor expression patterns similar to those observed in murine tumors. These results describing the diverse mechanisms underlying tumor-directed IL-12–induced antitumor immunity provide the preclinical rationale for the clinical study of i.t. NHS–IL-12.

Authors

Youji Hong, Yvette Robbins, Xinping Yang, Wojciech K. Mydlarz, Anastasia Sowers, James B. Mitchell, James L. Gulley, Jeffrey Schlom, Sofia R. Gameiro, Cem Sievers, Clint T. Allen

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Figure 6

NHS–rmIL-12 reduces immunosuppressive capacity of macrophages.

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NHS–rmIL-12 reduces immunosuppressive capacity of macrophages. (A) UMAP ...
(A) UMAP embedding of mononuclear myeloid cells colored by cluster identity. (B) UMAP embedding of mononuclear myeloid cells; clusters were colored by log2 fold change in relative cell abundance in NHS–rmIL-12– and PBS control–treated tumors. Red represents a relative increase, and blue a relative decrease in cell frequency following treatment with NHS–rmIL-12. (C) Dot plot shows module scores related to myeloid cell subsets (top) and myeloid-related genes (bottom) across myeloid cell clusters sorted by fold change in relative cell abundance comparing cells from NHS–rmIL-12– to control-treated tumors (lower bar graph). Circle color corresponds to scaled average expression; circle size denotes fraction of cells with nonzero gene expression of corresponding gene. Top bar graph represents total cell number. (D) Dot plot showing Reactome terms enriched in genes upregulated in cells from NHS–rmIL-12–treated tumors within cells of clusters 9 and 13 compared with control-treated cells. (E) Quantification of CD206 high (M2) and low (M1) CD11b, F4/80+ (CD11c) myeloid cells from tumors 48 hours after treatment, with NHS–rmIL-12 or PBS control measured by flow cytometry. The log10-transformed ratio of M1/M2 cells is shown on the right. P value determined by Student’s t test. (F) CD11b+ and F4/80+ cells were isolated from tumors treated with NHS–rmIL-12 or PBS control via magnetic selection and cocultured with CFSE-labeled WT T lymphocytes stimulated with CD3/CD28 antibodies. Representative CFSE histograms are shown, T lymphocyte proliferation was measured by flow cytometry, and IFN-γ production was measured by ELISA. P value determined by Student’s t test.