Lenvatinib or anti-VEGF in combination with anti–PD-1 differentially augments antitumor activity in melanoma
Thuy T. Tran, Jasmine Caulfield, Lin Zhang, David Schoenfeld, Dijana Djureinovic, Veronica L. Chiang, Victor Oria, Sarah A. Weiss, Kelly Olino, Lucia B. Jilaveanu, Harriet M. Kluger
Thuy T. Tran, Jasmine Caulfield, Lin Zhang, David Schoenfeld, Dijana Djureinovic, Veronica L. Chiang, Victor Oria, Sarah A. Weiss, Kelly Olino, Lucia B. Jilaveanu, Harriet M. Kluger
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Research Article Oncology

Lenvatinib or anti-VEGF in combination with anti–PD-1 differentially augments antitumor activity in melanoma

Abstract

Targeting tumor-associated blood vessels to increase immune infiltration may enhance treatment effectiveness, yet limited data exist regarding anti-angiogenesis effects on the tumor microenvironment (TME). We hypothesized that dual targeting of angiogenesis with immune checkpoints would improve both intracranial and extracranial disease. We used subcutaneous and left ventricle melanoma models to evaluate anti–PD-1/anti-VEGF and anti–PD-1/lenvatinib (pan-VEGFR inhibitor) combinations. Cytokine/chemokine profiling and flow cytometry were performed to assess signaling and immune-infiltrating populations. An in vitro blood-brain barrier (BBB) model was utilized to study intracranial treatment effects on endothelial integrity and leukocyte transmigration. Anti–PD-1 with either anti-VEGF or lenvatinib improved survival and decreased tumor growth in systemic melanoma murine models; treatment increased Th1 cytokine/chemokine signaling. Lenvatinib decreased tumor-associated macrophages but increased plasmacytoid DCs early in treatment; this effect was not evident with anti-VEGF. Both lenvatinib and anti-VEGF resulted in decreased intratumoral blood vessels. Although anti-VEGF promoted endothelial stabilization in an in vitro BBB model, while lenvatinib did not, both regimens enabled leukocyte transmigration. The combined targeting of PD-1 and VEGF or its receptors promotes enhanced melanoma antitumor activity, yet their effects on the TME are quite different. These studies provide insights into dual anti–PD-1 and anti-angiogenesis combinations.

Authors

Thuy T. Tran, Jasmine Caulfield, Lin Zhang, David Schoenfeld, Dijana Djureinovic, Veronica L. Chiang, Victor Oria, Sarah A. Weiss, Kelly Olino, Lucia B. Jilaveanu, Harriet M. Kluger

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Figure 3

Anti–PD-1 combined with lenvatinib or anti-VEGF enhanced intracranial antitumor responses in a metastatic animal model of melanoma.

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Anti–PD-1 combined with lenvatinib or anti-VEGF enhanced intracranial an...
(A) Experimental timeline for YUMMER1.7 melanoma injected into the LV to model metastatic disease, including BrMs. Mice were injected on day 0 and treatment initiated on day 3. (B) Survival was lower in the LV model due to increased aggressiveness of metastatic disease compared with the SQ model. Treatment with lenvatinib alone and especially with anti–PD-1/lenvatinib or anti–PD-1/anti-VEGF resulted in improved survival of animals compared with control. There was no significant difference between the groups receiving anti–PD-1/lenvatinib or anti–PD-1/anti-VEGF. As monotherapy, lenvatinib was superior to anti-VEGF. Curves compared by log-rank testing. (C) The decrease in intracranial luminescence was significant between control and anti–PD-1 alone, anti–PD-1/lenvatinib, and anti–PD-1/anti-VEGF at day 16 by 2-way ANOVA with correction for multiple comparisons. (D) Individual animal luminescence in each treatment arm graphed over time. Dark colored lines represent whole body ventral luminescence. Gray lines represent dorsal cranial luminescence. n = 9 in the control, anti-VEGF, and anti–PD-1/lenvatinib cohorts. n = 10 in the anti–PD-1 and lenvatinib cohorts. n = 11 in the anti–PD-1/anti-VEGF cohorts. *P < 0.05, **P < 0.01, and ***P < 0.001.