TNF blockade uncouples toxicity from antitumor efficacy induced with CD40 chemoimmunotherapy
Meredith L. Stone, … , Kristen B. Long, Gregory L. Beatty
Meredith L. Stone, … , Kristen B. Long, Gregory L. Beatty
Published June 8, 2021
Citation Information: JCI Insight. 2021;6(14):e146314. https://doi.org/10.1172/jci.insight.146314.
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Research Article Immunology

TNF blockade uncouples toxicity from antitumor efficacy induced with CD40 chemoimmunotherapy

Abstract

Agonist CD40 antibodies are under clinical development in combination with chemotherapy as an approach to prime for antitumor T cell immunity. However, treatment with anti-CD40 is commonly accompanied by both systemic cytokine release and liver transaminase elevations, which together account for the most common dose-limiting toxicities. Moreover, anti-CD40 treatment increases the potential for chemotherapy-induced hepatotoxicity. Here, we report a mechanistic link between cytokine release and hepatotoxicity induced by anti-CD40 when combined with chemotherapy and show that toxicity can be suppressed without impairing therapeutic efficacy. We demonstrate in mice and humans that anti-CD40 triggers transient hepatotoxicity marked by increased serum transaminase levels. In doing so, anti-CD40 sensitizes the liver to drug-induced toxicity. Unexpectedly, this biology is not blocked by the depletion of multiple myeloid cell subsets, including macrophages, inflammatory monocytes, and granulocytes. Transcriptional profiling of the liver after anti-CD40 revealed activation of multiple cytokine pathways including TNF and IL-6. Neutralization of TNF, but not IL-6, prevented sensitization of the liver to hepatotoxicity induced with anti-CD40 in combination with chemotherapy without impacting antitumor efficacy. Our findings reveal a clinically feasible approach to mitigate toxicity without impairing efficacy in the use of agonist CD40 antibodies for cancer immunotherapy.

Authors

Meredith L. Stone, Jesse Lee, Veronica M. Herrera, Kathleen Graham, Jae W. Lee, Austin Huffman, Heather Coho, Evan Tooker, Max I. Myers, Michael Giannone, Yan Li, Thomas H. Buckingham, Kristen B. Long, Gregory L. Beatty

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Figure 3

TNF is necessary for hepatotoxicity produced with chemoimmunotherapy.

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TNF is necessary for hepatotoxicity produced with chemoimmunotherapy. (A...
(A) RNA was extracted from bulk liver tissue of control- (Ctrl) or αCD40-treated mice 2 days after treatment. Gene expression for Stat1, Stat2, Stat3, Il6, and Tnf displayed as FPKM detected using QuantSeq 3′ mRNA sequencing. n = 3–6 mice/group, 1 experimental replicate. (B) Quantification by IHC of phosphorylated (p-) STAT1, p-STAT3, and p–NF-κBp65 protein expression in liver tissues collected 2 days after treatment with αCD40 compared with control. (C) Representative images and (D) quantification of Tnf expression detected by RNA-ISH in the liver 2 days after αCD40 treatment compared with control. Positive and negative controls for RNA-ISH are shown. Scale bars: 50 μm. Insets wre generated by zooming in on indicated 50 x 50 μm regions. (AD) n = 8 mice/group, 1 experimental replicate. Mann-Whitney U tests were performed. (E) Study schema for F–H. n = 8 mice/group, 2 experimental replicates. (F) Mouse weight pretreatment and posttreatment on day 2. Paired 2-tailed t tests were performed. (G) Number of lesions/mm2 in the liver detected by H&E stain. (H) ALT serum levels on day 4. Red line indicates upper range of 95% CI for normal serum level of ALT derived from all experiments in the manuscript. (I) IFN-γ serum levels detected 24 hours after treatment with αCD40 in control, NSG, and Rag2–/– mice. (J) TNF serum levels detected 1 day after treatment with αCD40 (compared with control). Anti–IFN-γ and isotype control (IgG1) were given on days –1 and 0. αCD40 and isotype control (IgG2a) were given on day 0. (I and J) n = 6–8 mice per group, 2 experimental replicates. Significance was tested using (G and I) Kruskal-Wallis with Dunn’s multiple-comparison test and (H and J) ordinary 1-way ANOVA with Dunnett’s multiple-comparison test. In GJ, comparisons with control and αCD40→Gem (G and H) or αCD40 (I and J) are shown. Data shown are mean ± SD. Gem, gemcitabine; αCD40, clone FGK45; ALT, alanine aminotransferase; FPKM, fragments per kilobase of transcript per million mapped reads. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001.