Abstract
BackgroundDespite outstanding responses to anti-PD-1 agents in a subset of non-small cell lung cancer (NSCLC) patients, approximately 80% of patients fail to have prolonged favorable response. Recent studies show that tumor cell oxidative metabolism is a barrier to PD-1 immunotherapy and radiotherapy could overcome PD-1 resistance, so it is urgent to determine if combination treatment with radiotherapy and a novel oxidative phosphorylation (OXPHOS) inhibitor (IACS-010759) is an effective strategy against PD-1 resistance in NSCLC.MethodsThe antitumor effect of this combinational treatment was evaluated in vitro and in vivo. For in vivo experiments, we treated 129Sv/Ev mice with anti-PD1-sensitive and anti-PD1-resistant 344SQ NSCLC adenocarcinoma xenografts with oral IACS-010759 combined with radiotherapy (XRT). In vitro experiments included PCR, seahorse bioenergetic profiling, flow cytometry phenotyping, and clonogenic survival assay.ResultsIn the current study, we found that our PD-1-resistant model utilized OXPHOS to a significantly greater extent than the PD-1-sensitive model and XRT increased OXPHOS in vitro and in vivo. Thus, we explored the effect of the novel OXPHOS inhibitor IACS-010759 on PD-1-resistant NSCLC in an effort to overcome XRT-induced immunosuppression and maximize response to PD-1. Additionally, combined XRT and IACS-010759 promoted antitumor effects in the PD-1-resistant model, but not in the sensitive model. After elucidation of the most optimal dose/fractionation scheme of XRT with IACS-010759, the combinatorial therapy with this regimen did not increase the abscopal antitumor effect, although IACS-010549 did not decrease CD45+, CD4+, and CD8+ immune cells. Finally, triple therapy with IACS-010759, XRT, and anti-PD-1 promoted abscopal responses and prolonged survival time.ConclusionOXPHOS inhibition as part of a combinatorial regimen with XRT is a promising strategy to address PD-1-resistant NSCLC, and this combination is being tested clinically.
Highlights
It is well known that cancer cells have upregulated glycolysis compared with non-cancer cells, which may lead to the downregulation of oxidative phosphorylation (OXPHOS)
It has been reported that mitochondrial inhibition via IACS-010759 overcame MAPK inhibitor-r esistance in melanoma,[4] and metformin plus tyrosine kinase inhibitors (TKIs) significantly increased treatment efficacy compared with TKIs alone in epidermal growth factor receptor-mutated non-small cell lung cancer (NSCLC),[5] indicating that combining metabolic therapy with biologic targeted therapy is an effective way to control cancer growth
The current study demonstrated that our PD-1-resistant 344-S Q model was characterized by increased OXPHOS at baseline and after XRT
Summary
It is well known that cancer cells have upregulated glycolysis compared with non-cancer cells, which may lead to the downregulation of oxidative phosphorylation (OXPHOS). It has been reported that mitochondrial inhibition via IACS-010759 overcame MAPK inhibitor-r esistance in melanoma,[4] and metformin plus tyrosine kinase inhibitors (TKIs) significantly increased treatment efficacy compared with TKIs alone in epidermal growth factor receptor-mutated NSCLC,[5] indicating that combining metabolic therapy with biologic targeted therapy is an effective way to control cancer growth. Recent studies show that tumor cell oxidative metabolism is a barrier to PD-1 immunotherapy and radiotherapy could overcome PD-1 resistance, so it is urgent to determine if combination treatment with radiotherapy and a novel oxidative phosphorylation (OXPHOS) inhibitor (IACS-010759) is an effective strategy against PD-1 resistance in NSCLC.
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