Functional Reprogramming of Neutrophils within the Brain Tumor Microenvironment by Hypoxia-Driven Histone Lactylation
Menée à l'aide de lignées cellulaires, de modèles murins de tumeurs cérébrales ainsi que d'échantillons sanguins et d'échantillons tumoraux prélevés sur des patients, cette étude met en évidence un mécanisme par lequel la lactylation des histones induite par l'hypoxie favorise l'acquisition, par les neutrophiles intratumoraux CD71+, de propriétés immunosuppressives
Despite functional heterogeneity, the high frequency of intratumoral neutrophils predicts poor clinical outcomes. The tumor microenvironment reprograms neutrophils into immunosuppressive subsets that hinder anticancer immunity, thereby contributing to tumor growth and resistance to immunotherapies. However, the mechanisms underlying neutrophil reprogramming remain elusive. In this study, we report that the immunosuppressive ability of brain tumor–infiltrating neutrophils was restricted to a highly glycolytic and long-lived subset expressing CD71, which acquired immunosuppressive properties in response to hypoxia. Mechanistically, hypoxia boosted glucose metabolism in CD71+ neutrophils, leading to high lactate production. Lactate caused histone lactylation, which subsequently regulated arginase-1 expression, required for T-cell suppression. Targeting histone lactylation with the antiepileptic drug isosafrole blocked CD71+ neutrophil immunosuppressive ability, delayed tumor progression, and sensitized brain tumors to immunotherapy. A distinctive gene signature characterizing immunosuppressive CD71+ neutrophils correlated with adverse clinical outcomes across diverse human malignancies. This study identifies histone lactylation as a potential therapeutic target to counteract neutrophil-induced immunosuppression within tumors.
Cancer Discovery , résumé 2025