Microbiome-derived inosine modulates response to checkpoint inhibitor immunotherapy

Lukas F. Mager; Regula Burkhard; Nicola Pett; Noah C.A. Cooke; Kirsty Brown; Hena R. Ramay; Seungil Paik; John Stagg; Ryan A. Groves; Marco Gallo; Ian A. Lewis; Markus B. Geuking; Kathy D. McCoy

doi:10.1126/science.abc3421

Microbiome-derived inosine modulates response to checkpoint inhibitor immunotherapy

Lukas F. Mager(University of Calgary), Regula Burkhard(University of Calgary), Nicola Pett(University of Calgary), Noah C.A. Cooke(University of Calgary), Kirsty Brown(University of Calgary), Hena R. Ramay(University of Calgary), Seungil Paik(Alberta Children's Hospital), John Stagg(Centre Hospitalier de l’Université de Montréal), Ryan A. Groves(University of Calgary), Marco Gallo(Alberta Children's Hospital), Ian A. Lewis(University of Calgary), Markus B. Geuking(University of Calgary), Kathy D. McCoy(University of Calgary)

Science

August 13, 2020

10.1126/science.abc3421

Cited by 1,320

Abstract

Inosine modulates antitumor immunity Checkpoint blockade immunotherapy harnesses the immune system to kill cancer cells and has been used with great success to treat certain tumors, but not all cancer patients respond. The efficacy of checkpoint blockade immunotherapy has been shown to depend on the presence of distinct, beneficial bacteria residing in the gut of patients, but how the microbiome mediates such beneficial effects is unclear. Mager et al. found that specific bacteria produce a metabolite called inosine that enhances the effect of checkpoint blockade immunotherapy (see the Perspective by Shaikh and Sears). In mouse models, inosine, together with proinflammatory stimuli and immunotherapy, strongly enhanced the antitumor capacities of T cells in multiple tumor types, including colorectal cancer, bladder cancer, and melanoma. Science , this issue p. 1481 ; see also p. 1427

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