Imaging-Guided Metabolic Radiosensitization of Pediatric Rhabdoid Tumors

Abstract

Tumor hypoxia leads to increased resistance to radiation therapy (RT), resulting in markedly worse clinical outcomes in the treatment and management of pediatric malignant rhabdoid tumors (MRT). To alleviate hypoxia in MRT, we repurposed an FDA approved, mitochondrial oxidative phosphorylation (OXPHOS) inhibitor, Atovaquone (AVO), to inhibit oxygen consumption and thereby enhance the sensitivity of tumor cells to low dose RT in MRT by hypoxia alleviation. Additionally, to better understand the tumor response induced by AVO and optimize the combination with RT, we employed an emerging, noninvasive imaging modality, known as multispectral optoacoustic tomography (MSOT), to monitor and evaluate real-time dynamic changes in tumor hypoxia and vascular perfusion. Oxygen-Enhanced (OE)-MSOT could measure the change of tumor oxygenation in the MRT xenograft models after AVO and RT treatments, indicating its potential as a response biomarker. OE-MSOT showed that treating MRT mouse models with AVO resulted in a transient increase in oxygen saturation (ΔsO2) in tumors when the mice were subjected to oxygen challenge, while RT or saline treated groups produced no change. In AVO+RT combination groups, the tumors showed an increase in ΔsO2 after AVO administration followed by a significant decrease after RT, that correlated with a strong anti-tumor response, demarcated by complete regression of tumors, with no relapse on long-term monitoring. These observations were histologically validated. In MRT models of acquired AVO resistance, combination therapy failed to alleviate tumoral hypoxia and elicit any therapeutic benefit. Together, our data highlights the utility of repurposing anti-malarial AVO as an anticancer adjuvant for enabling low dose RT for pediatric patients.