Impact of isotype on the mechanism of action of agonist anti-OX40 antibodies in cancer: implications for therapeutic combinations
Impact of isotype on the mechanism of action of agonist anti-OX40 antibodies in cancer: implications for therapeutic combinations
Background OX40 has been widely studied as a target for immunotherapy with agonist antibodies taken forward into clinical trials for cancer where they are yet to show substantial efficacy. Here, we investigated potential mechanisms of action of anti-mouse (m) OX40 and anti-human (h) OX40 antibodies, including a clinically relevant monoclonal antibody (mAb) (GSK3174998) and evaluated how isotype can alter those mechanisms with the aim to develop improved antibodies for use in rational combination treatments for cancer. Methods Anti-mOX40 and anti-hOX40 mAbs were evaluated in a number of in vivo models, including an OT-I adoptive transfer immunization model in hOX40 knock-in (KI) mice and syngeneic tumor models. The impact of Fcγ3R engagement was evaluated in hOX40 KI mice deficient for Fc gamma receptors (Fcγ3R). Additionally, combination studies using anti-mouse programmed cell death protein-1 (mPD-1) were assessed. In vitro experiments using peripheral blood mononuclear cells (PBMCs) examining possible anti-hOX40 mAb mechanisms of action were also performed. Results Isotype variants of the clinically relevant mAb GSK3174998 showed immunomodulatory effects that differed in mechanism; mIgG1 mediated direct T-cell agonism while mIgG2a acted indirectly, likely through depletion of regulatory T cells (Tregs) via activating Fcγ3Rs. In both the OT-I and EG.7-OVA models, hIgG1 was the most effective human isotype, capable of acting both directly and through Treg depletion. The anti-hOX40 hIgG1 synergized with anti-mPD-1 to improve therapeutic outcomes in the EG.7-OVA model. Finally, in vitro assays with human peripheral blood mononuclear cells (hPBMCs), anti-hOX40 hIgG1 also showed the potential for T-cell stimulation and Treg depletion. Conclusions These findings underline the importance of understanding the role of isotype in the mechanism of action of therapeutic mAbs. As an hIgG1, the anti-hOX40 mAb can elicit multiple mechanisms of action that could aid or hinder therapeutic outcomes, dependent on the microenvironment. This should be considered when designing potential combinatorial partners and their Fcγ3R requirements to achieve maximal benefit and improvement of patient outcomes.
Immune modulatory, Monoclonal antibody, co-stimulatory molecules
Willoughby, Jane
aa6969bd-3830-4e1b-83ac-6369b5711e1f
Dou, Lang
1e311f9c-adea-44be-a14a-9c8196eff7b8
Bhattacharya, Sabyasachi
a1591dcf-6249-4fbd-a18b-3d9f44c1b19d
Cragg, Mark
ec97f80e-f3c8-49b7-a960-20dff648b78c
4 July 2024
Willoughby, Jane
aa6969bd-3830-4e1b-83ac-6369b5711e1f
Dou, Lang
1e311f9c-adea-44be-a14a-9c8196eff7b8
Bhattacharya, Sabyasachi
a1591dcf-6249-4fbd-a18b-3d9f44c1b19d
Cragg, Mark
ec97f80e-f3c8-49b7-a960-20dff648b78c
Willoughby, Jane, Dou, Lang and Bhattacharya, Sabyasachi
,
et al.
(2024)
Impact of isotype on the mechanism of action of agonist anti-OX40 antibodies in cancer: implications for therapeutic combinations.
Journal for Immunotherapy of Cancer, 12 (7), [e008677].
(doi:10.1136/jitc-2023-008677).
Abstract
Background OX40 has been widely studied as a target for immunotherapy with agonist antibodies taken forward into clinical trials for cancer where they are yet to show substantial efficacy. Here, we investigated potential mechanisms of action of anti-mouse (m) OX40 and anti-human (h) OX40 antibodies, including a clinically relevant monoclonal antibody (mAb) (GSK3174998) and evaluated how isotype can alter those mechanisms with the aim to develop improved antibodies for use in rational combination treatments for cancer. Methods Anti-mOX40 and anti-hOX40 mAbs were evaluated in a number of in vivo models, including an OT-I adoptive transfer immunization model in hOX40 knock-in (KI) mice and syngeneic tumor models. The impact of Fcγ3R engagement was evaluated in hOX40 KI mice deficient for Fc gamma receptors (Fcγ3R). Additionally, combination studies using anti-mouse programmed cell death protein-1 (mPD-1) were assessed. In vitro experiments using peripheral blood mononuclear cells (PBMCs) examining possible anti-hOX40 mAb mechanisms of action were also performed. Results Isotype variants of the clinically relevant mAb GSK3174998 showed immunomodulatory effects that differed in mechanism; mIgG1 mediated direct T-cell agonism while mIgG2a acted indirectly, likely through depletion of regulatory T cells (Tregs) via activating Fcγ3Rs. In both the OT-I and EG.7-OVA models, hIgG1 was the most effective human isotype, capable of acting both directly and through Treg depletion. The anti-hOX40 hIgG1 synergized with anti-mPD-1 to improve therapeutic outcomes in the EG.7-OVA model. Finally, in vitro assays with human peripheral blood mononuclear cells (hPBMCs), anti-hOX40 hIgG1 also showed the potential for T-cell stimulation and Treg depletion. Conclusions These findings underline the importance of understanding the role of isotype in the mechanism of action of therapeutic mAbs. As an hIgG1, the anti-hOX40 mAb can elicit multiple mechanisms of action that could aid or hinder therapeutic outcomes, dependent on the microenvironment. This should be considered when designing potential combinatorial partners and their Fcγ3R requirements to achieve maximal benefit and improvement of patient outcomes.
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Impact of isotype on the mechanism of action of agoinst OX40 antibodies in cancer Implications for therapeutic combinations
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e008677.full
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Accepted/In Press date: 16 May 2024
e-pub ahead of print date: 4 July 2024
Published date: 4 July 2024
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© Author(s) (or their employer(s)) 2024. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.
Keywords:
Immune modulatory, Monoclonal antibody, co-stimulatory molecules
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Local EPrints ID: 492403
URI: http://eprints.soton.ac.uk/id/eprint/492403
PURE UUID: b23dfd05-f3b5-4ce6-bc41-3377ff3e25fd
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Date deposited: 25 Jul 2024 17:06
Last modified: 14 Dec 2024 02:43
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Author:
Jane Willoughby
Author:
Lang Dou
Author:
Sabyasachi Bhattacharya
Corporate Author: et al.
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