Engineered cytokine/antibody fusion proteins improve IL-2 delivery to pro-inflammatory cells and promote antitumor activity
Elissa K. Leonard, … , Warren J. Leonard, Jamie B. Spangler
Elissa K. Leonard, … , Warren J. Leonard, Jamie B. Spangler
Published August 8, 2024
Citation Information: JCI Insight. 2024;9(18):e173469. https://doi.org/10.1172/jci.insight.173469.
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Research Article Immunology Therapeutics

Engineered cytokine/antibody fusion proteins improve IL-2 delivery to pro-inflammatory cells and promote antitumor activity

Abstract

Progress in cytokine engineering is driving therapeutic translation by overcoming these proteins’ limitations as drugs. The IL-2 cytokine is a promising immune stimulant for cancer treatment but is limited by its concurrent activation of both pro-inflammatory immune effector cells and antiinflammatory regulatory T cells, toxicity at high doses, and short serum half-life. One approach to improve the selectivity, safety, and longevity of IL-2 is complexing with anti–IL-2 antibodies that bias the cytokine toward immune effector cell activation. Although this strategy shows potential in preclinical models, clinical translation of a cytokine/antibody complex is complicated by challenges in formulating a multiprotein drug and concerns regarding complex stability. Here, we introduced a versatile approach to designing intramolecularly assembled single-agent fusion proteins (immunocytokines, ICs) comprising IL-2 and a biasing anti–IL-2 antibody that directs the cytokine toward immune effector cells. We optimized IC construction and engineered the cytokine/antibody affinity to improve immune bias. We demonstrated that our IC preferentially activates and expands immune effector cells, leading to superior antitumor activity compared with natural IL-2, both alone and combined with immune checkpoint inhibitors. Moreover, therapeutic efficacy was observed without inducing toxicity. This work presents a roadmap for the design and translation of cytokine/antibody fusion proteins.

Authors

Elissa K. Leonard, Jakub Tomala, Joseph R. Gould, Michael I. Leff, Jian-Xin Lin, Peng Li, Mitchell J. Porter, Eric R. Johansen, Ladaisha Thompson, Shanelle D. Cao, Shenda Hou, Tereza Henclova, Maros Huliciak, Paul R. Sargunas, Charina S. Fabilane, Ondřej Vaněk, Marek Kovar, Bohdan Schneider, Giorgio Raimondi, Warren J. Leonard, Jamie B. Spangler

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Figure 7

F10 IC promotes biased expansion of Effs and improves the therapeutic efficacy of IL-2.

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F10 IC promotes biased expansion of Effs and improves the therapeutic ef...
(AC) C57BL/6 mice (n = 4) were injected intraperitoneally daily for 4 days with the molar equivalent of 0.075 mg/kg IL-2/dose of control IC, IL-2/602 Cx (2:1 molar ratio), 602 IC, or F10 IC. Spleens were harvested on day 5. Total counts of CD4+ Tconvs, CD8+ T cells, NK cells, and Tregs were determined by flow cytometry. Ratios of CD4+ Tconvs to Tregs (A), CD8+ T cells to Tregs (B), and NK cells to Tregs (C) were calculated. (DG) C57BL/6 mice (n = 7–9) were injected subcutaneously with B16F10 tumor cells (D and F), and BALB/c mice (n = 8) were injected subcutaneously with CT26 tumor cells (E and G). Mice were treated on days indicated with dashed lines with either PBS or the molar equivalent of 0.125 mg/kg IL-2 of control IC or F10 IC. Tumor volume (D and E) and percentage body weight changes relative to weight at the time of tumor implantation (F and G) are shown. (H) C57BL/6 mice (n = 5) were injected daily for 4 days with PBS, 0.075 mg/kg IL-2, or the molar equivalent of 0.075 mg/kg IL-2 of control IC, IL-2/602 Cx, 602 IC, or F10 IC. Day 5 lung water content was measured. Data are shown as mean ± SEM. *P < 0.05, **P < 0.01, ****P < 0.0001 by 2-way ANOVA with Tukey’s test. For tumor growth and mouse weight curves, significance is indicated for overall curves.