Structural and functional characterization of C0021158, a high-affinity monoclonal antibody that inhibits Arginase 2 function via a novel non-competitive mechanism of action
Mark Austin,
Daniel Burschowsky,
Denice T.Y. Chan,
Lesley Jenkinson,
Stuart Haynes,
Agata Diamandakis,
Chitra Seewooruthun,
Alexandra Addyman,
Sebastian Fiedler,
Stephanie Ryman,
Jessica Whitehouse,
Louise H. Slater,
Andreas V. Hadjinicolaou,
Uzi Gileadi,
Ellen Gowans,
Yoko Shibata,
Michelle Barnard,
Teresa Kaserer,
Pooja Sharma,
Nadia M. Luheshi,
Robert W. Wilkinson,
Tristan J. Vaughan,
Sarah V. Holt,
Vincenzo Cerundolo,
Mark D. Carr,
Maria A. T. Groves
Affiliations
Mark Austin
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Daniel Burschowsky
Leicester Institute of Structural and Chemical Biology and the Department of Molecular and Cell Biology, University of Leicester, Leicester, UK
Denice T.Y. Chan
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Lesley Jenkinson
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Stuart Haynes
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Agata Diamandakis
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Chitra Seewooruthun
Leicester Institute of Structural and Chemical Biology and the Department of Molecular and Cell Biology, University of Leicester, Leicester, UK
Alexandra Addyman
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Sebastian Fiedler
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Stephanie Ryman
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Jessica Whitehouse
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Louise H. Slater
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Andreas V. Hadjinicolaou
MRC Human Immunology Unit, Weatherall Institute of Molecular Medicine, University of Oxford, Oxford, UK
Uzi Gileadi
MRC Human Immunology Unit, Weatherall Institute of Molecular Medicine, University of Oxford, Oxford, UK
Ellen Gowans
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Yoko Shibata
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Michelle Barnard
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Teresa Kaserer
Cancer Research UK, Cancer Therapeutics Unit, The Institute of Cancer Research, London, UK
Pooja Sharma
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Nadia M. Luheshi
Early Oncology Discovery, Oncology R&D, AstraZeneca, Cambridge, UK
Robert W. Wilkinson
Early Oncology Discovery, Oncology R&D, AstraZeneca, Cambridge, UK
Tristan J. Vaughan
Antibody Discovery & Protein Engineering, BioPharmaceuticals R&D, AstraZeneca, Cambridge, UK
Sarah V. Holt
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Vincenzo Cerundolo
MRC Human Immunology Unit, Weatherall Institute of Molecular Medicine, University of Oxford, Oxford, UK
Mark D. Carr
Leicester Institute of Structural and Chemical Biology and the Department of Molecular and Cell Biology, University of Leicester, Leicester, UK
Maria A. T. Groves
Cancer Research UK AstraZeneca Antibody Alliance Laboratory, Cambridge, UK
Arginase 2 (ARG2) is a binuclear manganese metalloenzyme that catalyzes the hydrolysis of L-arginine. The dysregulated expression of ARG2 within specific tumor microenvironments generates an immunosuppressive niche that effectively renders the tumor ‘invisible’ to the host’s immune system. Increased ARG2 expression leads to a concomitant depletion of local L-arginine levels, which in turn leads to suppression of anti-tumor T-cell-mediated immune responses. Here we describe the isolation and characterization of a high affinity antibody (C0021158) that inhibits ARG2 enzymatic function completely, effectively restoring T-cell proliferation in vitro. Enzyme kinetic studies confirmed that C0021158 exhibits a noncompetitive mechanism of action, inhibiting ARG2 independently of L-arginine concentrations. To elucidate C0021158’s inhibitory mechanism at a structural level, the co-crystal structure of the Fab in complex with trimeric ARG2 was solved. C0021158’s epitope was consequently mapped to an area some distance from the enzyme’s substrate binding cleft, indicating an allosteric mechanism was being employed. Following C0021158 binding, distinct regions of ARG2 undergo major conformational changes. Notably, the backbone structure of a surface-exposed loop is completely rearranged, leading to the formation of a new short helix structure at the Fab-ARG2 interface. Moreover, this large-scale structural remodeling at ARG2’s epitope translates into more subtle changes within the enzyme’s active site. An arginine residue at position 39 is reoriented inwards, sterically impeding the binding of L-arginine. Arg39 is also predicted to alter the pKA of a key catalytic histidine residue at position 160, further attenuating ARG2’s enzymatic function. In silico molecular docking simulations predict that L-arginine is unable to bind effectively when antibody is bound, a prediction supported by isothermal calorimetry experiments using an L-arginine mimetic. Specifically, targeting ARG2 in the tumor microenvironment through the application of C0021158, potentially in combination with standard chemotherapy regimens or alternate immunotherapies, represents a potential new strategy to target immune cold tumors.