FLASH radiation reprograms lipid metabolism and macrophage immunity and sensitizes medulloblastoma to CAR-T cell therapy.

in Nature cancer by Haiwei Ni, Zachary J Reitman, Wei Zou, Md Naushad Akhtar, Ritama Paul, Menggui Huang, Duo Zhang, Hao Zheng, Ruitao Zhang, Ruiying Ma, Gina Ngo, Lin Zhang, Eric S Diffenderfer, S Azar Oliaei Motlagh, Michele M Kim, Andy J Minn, Jay F Dorsey, Jessica B Foster, James Metz, Constantinos Koumenis, David G Kirsch, Yanqing Gong, Yi Fan

TLDR

  • FLASH radiotherapy stimulates proinflammatory polarization in tumor macrophages, increasing T cell infiltration and improving CAR T cell therapy.
  • The study suggests that FLASH radiotherapy may offer exciting opportunities for solid tumor treatment, particularly in combination with CAR T cell therapy.
  • Future research will aim to optimize FLASH radiotherapy treatment and explore its mechanisms of action.

Abstract

FLASH radiotherapy holds promise for treating solid tumors given the potential lower toxicity in normal tissues but its therapeutic effects on tumor immunity remain largely unknown. Using a genetically engineered mouse model of medulloblastoma, we show that FLASH radiation stimulates proinflammatory polarization in tumor macrophages. Single-cell transcriptome analysis shows that FLASH proton beam radiation skews macrophages toward proinflammatory phenotypes and increases T cell infiltration. Furthermore, FLASH radiation reduces peroxisome proliferator-activated receptor-γ (PPARγ) and arginase 1 expression and inhibits immunosuppressive macrophage polarization under stimulus-inducible conditions. Mechanistically, FLASH radiation abrogates lipid oxidase expression and oxidized low-density lipid generation to reduce PPARγ activity, while standard radiation induces reactive oxygen species-dependent PPARγ activation in macrophages. Notably, FLASH radiotherapy improves infiltration and activation of chimeric antigen receptor (CAR) T cells and sensitizes medulloblastoma to GD2 CAR-T cell therapy. Thus, FLASH radiotherapy reprograms macrophage lipid metabolism to reverse tumor immunosuppression. Combination FLASH-CAR radioimmunotherapy may offer exciting opportunities for solid tumor treatment.

Overview

  • The study investigates the effects of FLASH radiotherapy on tumor immunity in a genetically engineered mouse model of medulloblastoma.
  • FLASH radiotherapy was found to stimulate proinflammatory polarization in tumor macrophages, increasing T cell infiltration and improving CAR T cell therapy.
  • The study aims to explore the therapeutic potential of FLASH radiotherapy in solid tumors and its potential combination with CAR T cell therapy.

Comparative Analysis & Findings

  • FLASH radiation was compared to standard radiation, showing that it stimulates proinflammatory polarization in tumor macrophages and reduces immunosuppressive macrophage polarization.
  • Single-cell transcriptome analysis revealed that FLASH proton beam radiation skews macrophages toward proinflammatory phenotypes and increases T cell infiltration.
  • FLASH radiation was found to abrogate lipid oxidase expression and oxidized low-density lipid generation to reduce PPARγ activity, whereas standard radiation induces ROS-dependent PPARγ activation in macrophages.

Implications and Future Directions

  • The study's findings suggest that FLASH radiotherapy may have potential in treating solid tumors, particularly when combined with CAR T cell therapy.
  • Future research should explore the optimal dosing and fractionation of FLASH radiation for maximized therapeutic effects.
  • Further studies should investigate the mechanistic underpinnings of FLASH radiotherapy's effects on tumor immunity and macrophage polarization.
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