Combination of locoregional radiotherapy with a TIM-3 aptamer improves survival in diffuse midline glioma models
Iker Ausejo-Mauleon, Naiara Martinez-Velez, Andrea Lacalle, Daniel de la Nava, Javier Cebollero, Helena Villanueva, Noelia Casares, Javier Marco-Sanz, Virginia Laspidea, Oren Becher, Ana Patiño-García, Sara Labiano, Fernando Pastor, Marta M. Alonso
Iker Ausejo-Mauleon, Naiara Martinez-Velez, Andrea Lacalle, Daniel de la Nava, Javier Cebollero, Helena Villanueva, Noelia Casares, Javier Marco-Sanz, Virginia Laspidea, Oren Becher, Ana Patiño-García, Sara Labiano, Fernando Pastor, Marta M. Alonso
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Research Article Oncology Therapeutics

Combination of locoregional radiotherapy with a TIM-3 aptamer improves survival in diffuse midline glioma models

Abstract

Pediatric diffuse midline gliomas (DMG) with altered H3-K27M are aggressive brain tumors that arise during childhood. Despite advances in genomic knowledge and the significant number of clinical trials testing new targeted therapies, patient outcomes are still poor. Immune checkpoint blockades with small molecules, such as aptamers, are opening new therapeutic options that represent hope for this orphan disease. Here, we demonstrated that a TIM-3 aptamer (TIM-3 Apt) as monotherapy increased the immune infiltration and elicited a strong specific immune response with a tendency to improve the overall survival of treated DMG-bearing mice. Importantly, combining TIM-3 Apt with radiotherapy increased the overall median survival and led to long-term survivor mice in 2 pediatric DMG orthotopic murine models. Interestingly, TIM-3 Apt administration increased the number of myeloid populations and the proinflammatory CD8-to-Tregs ratios in the tumor microenvironment as compared with nontreated groups after radiotherapy. Importantly, the depletion of T cells led to a major loss of the therapeutic effect achieved by the combination. This work uncovers TIM-3 targeting as an immunotherapy approach to improve the radiotherapy outcome in DMGs and offers a strong foundation for propelling a phase I clinical trial using radiotherapy and TIM-3 blockade combination as a treatment for these tumors.

Authors

Iker Ausejo-Mauleon, Naiara Martinez-Velez, Andrea Lacalle, Daniel de la Nava, Javier Cebollero, Helena Villanueva, Noelia Casares, Javier Marco-Sanz, Virginia Laspidea, Oren Becher, Ana Patiño-García, Sara Labiano, Fernando Pastor, Marta M. Alonso

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Figure 3

Assessment of TIM-3 expression after RT treatment.

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Assessment of TIM-3 expression after RT treatment. (A) Real-time PCR ana...
(A) Real-time PCR analysis of TIM-3 expression in NP53 tumors cells 48 hours after RT (n = 3). (B) Flow cytometry analysis of TIM-3 expression in NP53 tumor cells 48 hours after 3, 6, and 12 Gy of RT (n = 3). (C) Left, a representative image of TIM-3 expression analysis in mice bearing NP53 tumor cells comparing saline and RT by IF. Right, analysis of TIM-3+ cells per mm2 (n = 3). Scale bars: 50μm. (D) Left, flow cytometry analysis of the percentage of microglia cells that expressed TIM-3. Right, MFI of TIM-3 on microglia cells after RT (6 Gy) in a DMG orthotopic model (n = 7–12). (EG) Flow cytometry analysis of TIM-3 expression MFI on (E) macrophages, dendritic cells, (F) NK cells, (G) conventional CD4, Tregs, and CD8 T cells after RT (6 Gy) in a DMG orthotopic model (n = 7–12). Data were analyzed with 1-way ANOVA (A, B, DG) and student t test (C). Bar graphs indicate the mean ± SEM (*P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001).