Author
Listed:
- Laura Codarri Deak
(Roche Innovation Center Zurich)
- Valeria Nicolini
(Roche Innovation Center Zurich)
- Masao Hashimoto
(Emory University School of Medicine)
- Maria Karagianni
(Roche Innovation Center Zurich)
- Petra C. Schwalie
(Roche Innovation Center Basel)
- Laura Lauener
(Roche Innovation Center Zurich)
- Eleni Maria Varypataki
(Roche Innovation Center Zurich)
- Marine Richard
(Roche Innovation Center Zurich)
- Esther Bommer
(Roche Innovation Center Zurich)
- Johannes Sam
(Roche Innovation Center Zurich)
- Stefanie Joller
(Roche Innovation Center Zurich)
- Mario Perro
(Roche Innovation Center Zurich)
- Floriana Cremasco
(Roche Innovation Center Zurich)
- Leo Kunz
(Roche Innovation Center Zurich)
- Emilio Yanguez
(Roche Innovation Center Zurich)
- Tamara Hüsser
(Roche Innovation Center Zurich)
- Ramona Schlenker
(Roche Innovation Center Munich)
- Marisa Mariani
(Roche Innovation Center Zurich)
- Vinko Tosevski
(Roche Innovation Center Zurich)
- Sylvia Herter
(Roche Innovation Center Zurich)
- Marina Bacac
(Roche Innovation Center Zurich)
- Inja Waldhauer
(Roche Innovation Center Zurich)
- Sara Colombetti
(Roche Innovation Center Zurich)
- Xavier Gueripel
(Roche Innovation Center Zurich)
- Stephan Wullschleger
(School of Life Sciences, EPFL
Swiss Cancer Center Leman (SCCL))
- Melanie Tichet
(School of Life Sciences, EPFL
Swiss Cancer Center Leman (SCCL)
Ludwig Institute for Cancer Research, Lausanne Branch
Agora Translational Cancer Research Center)
- Douglas Hanahan
(School of Life Sciences, EPFL
Swiss Cancer Center Leman (SCCL)
Ludwig Institute for Cancer Research, Lausanne Branch
Agora Translational Cancer Research Center)
- Haydn T. Kissick
(Emory University School of Medicine
Emory University School of Medicine
Winship Cancer Institute of Emory University)
- Stephane Leclair
(Roche Innovation Center Munich)
- Anne Freimoser-Grundschober
(Roche Innovation Center Zurich)
- Stefan Seeber
(Roche Innovation Center Munich)
- Volker Teichgräber
(Roche Innovation Center Basel)
- Rafi Ahmed
(Emory University School of Medicine
Winship Cancer Institute of Emory University)
- Christian Klein
(Roche Innovation Center Zurich)
- Pablo Umaña
(Roche Innovation Center Zurich)
Abstract
Expansion and differentiation of antigen-experienced PD-1+TCF-1+ stem-like CD8+ T cells into effector cells is critical for the success of immunotherapies based on PD-1 blockade1–4. Hashimoto et al. have shown that, in chronic infections, administration of the cytokine interleukin (IL)-2 triggers an alternative differentiation path of stem-like T cells towards a distinct population of ‘better effector’ CD8+ T cells similar to those generated in an acute infection5. IL-2 binding to the IL-2 receptor α-chain (CD25) was essential in triggering this alternative differentiation path and expanding better effectors with distinct transcriptional and epigenetic profiles. However, constitutive expression of CD25 on regulatory T cells and some endothelial cells also contributes to unwanted systemic effects from IL-2 therapy. Therefore, engineered IL-2 receptor β- and γ-chain (IL-2Rβγ)-biased agonists are currently being developed6–10. Here we show that IL-2Rβγ-biased agonists are unable to preferentially expand better effector T cells in cancer models and describe PD1-IL2v, a new immunocytokine that overcomes the need for CD25 binding by docking in cis to PD-1. Cis binding of PD1-IL2v to PD-1 and IL-2Rβγ on the same cell recovers the ability to differentiate stem-like CD8+ T cells into better effectors in the absence of CD25 binding in both chronic infection and cancer models and provides superior efficacy. By contrast, PD-1- or PD-L1-blocking antibodies alone, or their combination with clinically relevant doses of non-PD-1-targeted IL2v, cannot expand this unique subset of better effector T cells and instead lead to the accumulation of terminally differentiated, exhausted T cells. These findings provide the basis for the development of a new generation of PD-1 cis-targeted IL-2R agonists with enhanced therapeutic potential for the treatment of cancer and chronic infections.
Suggested Citation
Laura Codarri Deak & Valeria Nicolini & Masao Hashimoto & Maria Karagianni & Petra C. Schwalie & Laura Lauener & Eleni Maria Varypataki & Marine Richard & Esther Bommer & Johannes Sam & Stefanie Jolle, 2022.
"PD-1-cis IL-2R agonism yields better effectors from stem-like CD8+ T cells,"
Nature, Nature, vol. 610(7930), pages 161-172, October.
Handle:
RePEc:nat:nature:v:610:y:2022:i:7930:d:10.1038_s41586-022-05192-0
DOI: 10.1038/s41586-022-05192-0
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Cited by:
- Joseph R. Palmeri & Brianna M. Lax & Joshua M. Peters & Lauren Duhamel & Jordan A. Stinson & Luciano Santollani & Emi A. Lutz & William Pinney & Bryan D. Bryson & K. Dane Wittrup, 2024.
"CD8+ T cell priming that is required for curative intratumorally anchored anti-4-1BB immunotherapy is constrained by Tregs,"
Nature Communications, Nature, vol. 15(1), pages 1-19, December.
- Kateryna Onyshchenko & Ren Luo & Elena Guffart & Simone Gaedicke & Anca-Ligia Grosu & Elke Firat & Gabriele Niedermann, 2023.
"Expansion of circulating stem-like CD8+ T cells by adding CD122-directed IL-2 complexes to radiation and anti-PD1 therapies in mice,"
Nature Communications, Nature, vol. 14(1), pages 1-17, December.
- Chenxi Tian & Yu Wang & Miya Su & Yuanyuan Huang & Yuwei Zhang & Jiaxiang Dou & Changfeng Zhao & Yuting Cai & Jun Pan & Shiyu Bai & Qielan Wu & Sanwei Chen & Shuhang Li & Di Xie & Rong Lv & Yusheng Ch, 2024.
"Motility and tumor infiltration are key aspects of invariant natural killer T cell anti-tumor function,"
Nature Communications, Nature, vol. 15(1), pages 1-16, December.
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