23ME-00610, a genetically informed, first-in-class antibody targeting CD200R1 to enhance antitumor T cell function

Jill Fenaux; Xin Fang; Yao-ming Huang; Cristina Melero; Caroline Bonnans; Earth Light Lowe; Tiziana Palumbo; Cecilia Lay; Zuoan Yi; Aileen Zhou; Mauro Poggio; Wei-Jen Chung; Sophia R. Majeed; Dylan Glatt; Alice Chen; Maike Schmidt; Clarissa C. Lee

doi:10.1080/2162402X.2023.2217737

OncoImmunology (Dec 2023)

23ME-00610, a genetically informed, first-in-class antibody targeting CD200R1 to enhance antitumor T cell function

Jill Fenaux,
Xin Fang,
Yao-ming Huang,
Cristina Melero,
Caroline Bonnans,
Earth Light Lowe,
Tiziana Palumbo,
Cecilia Lay,
Zuoan Yi,
Aileen Zhou,
Mauro Poggio,
Wei-Jen Chung,
Sophia R. Majeed,
Dylan Glatt,
Alice Chen,
Maike Schmidt,
Clarissa C. Lee

Affiliations

Jill Fenaux: Immuno-Oncology, 23andMe, South San Francisco, CA, USA
Xin Fang: Computational Biology, 23andMe, South San Francisco, CA, USA
Yao-ming Huang: Antibody and Protein Engineering, 23andMe, South San Francisco, CA, USA
Cristina Melero: Antibody and Protein Engineering, 23andMe, South San Francisco, CA, USA
Caroline Bonnans: In Vivo Pharmacology, 23andMe, South San Francisco, CA, USA
Earth Light Lowe: In Vivo Pharmacology, 23andMe, South San Francisco, CA, USA
Tiziana Palumbo: In Vivo Pharmacology, 23andMe, South San Francisco, CA, USA
Cecilia Lay: Immuno-Oncology, 23andMe, South San Francisco, CA, USA
Zuoan Yi: Immuno-Oncology, 23andMe, South San Francisco, CA, USA
Aileen Zhou: Immuno-Oncology, 23andMe, South San Francisco, CA, USA
Mauro Poggio: Immuno-Oncology, 23andMe, South San Francisco, CA, USA
Wei-Jen Chung: Computational Biology, 23andMe, South San Francisco, CA, USA
Sophia R. Majeed: Clinical Science, 23andMe, South San Francisco, CA, USA
Dylan Glatt: Clinical Pharmacology, 23andMe, South San Francisco, CA, USA
Alice Chen: Immuno-Oncology, 23andMe, South San Francisco, CA, USA
Maike Schmidt: Biomarker Translation, 23andMe, South San Francisco, CA, USA
Clarissa C. Lee: Immuno-Oncology, 23andMe, South San Francisco, CA, USA

DOI: https://doi.org/10.1080/2162402X.2023.2217737
Journal volume & issue: Vol. 12, no. 1

Abstract

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ABSTRACTImmune checkpoint inhibition (ICI) has revolutionized cancer treatment; however, only a subset of patients benefit long term. Therefore, methods for identification of novel checkpoint targets and development of therapeutic interventions against them remain a critical challenge. Analysis of human genetics has the potential to inform more successful drug target discovery. We used genome-wide association studies of the 23andMe genetic and health survey database to identify an immuno-oncology signature in which genetic variants are associated with opposing effects on risk for cancer and immune diseases. This signature identified multiple pathway genes mapping to the immune checkpoint comprising CD200, its receptor CD200R1, and the downstream adapter protein DOK2. We confirmed that CD200R1 is elevated on tumor-infiltrating immune cells isolated from cancer patients compared to the matching peripheral blood mononuclear cells. We developed a humanized, effectorless IgG1 antibody (23ME-00610) that bound human CD200R1 with high affinity (KD <0.1 nM), blocked CD200 binding, and inhibited recruitment of DOK2. 23ME-00610 induced T-cell cytokine production and enhanced T cell-mediated tumor cell killing in vitro. Blockade of the CD200:CD200R1 immune checkpoint inhibited tumor growth and engaged immune activation pathways in an S91 tumor cell model of melanoma in mice.

Published in OncoImmunology

ISSN: 2162-402X (Online)
Publisher: Taylor & Francis Group
Country of publisher: United Kingdom
LCC subjects: Medicine: Internal medicine: Specialties of internal medicine: Immunologic diseases. Allergy; Medicine: Internal medicine: Neoplasms. Tumors. Oncology. Including cancer and carcinogens
Website: https://www.tandfonline.com/journals/koni

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