Targeting the tumor mutanome for personalized vaccination in a TMB low non-small cell lung cancer
Targeting the tumor mutanome for personalized vaccination in a TMB low non-small cell lung cancer
Background: cancer is characterized by an accumulation of somatic mutations, of which a significant subset can generate cancer-specific neoepitopes that are recognized by autologous T cells. Such neoepitopes are emerging as important targets for cancer immunotherapy, including personalized cancer vaccination strategies.
Methods: we used whole-exome and RNA sequencing analysis to identify potential neoantigens for a patient with non-small cell lung cancer. Thereafter, we assessed the autologous T-cell reactivity to the candidate neoantigens using a long peptide approach in a cultured interferon gamma ELISpot and tracked the neoantigen-specific T-cells in the tumor by T-cell receptor (TCR) sequencing. In parallel, identified gene variants were incorporated into a Modified Vaccinia Ankara-based vaccine, which was evaluated in the human leucocyte antigen A*0201 transgenic mouse model (HHD).
Results: sequencing revealed a tumor with a low mutational burden: 2219 sequence variants were identified from the primary tumor, of which 23 were expressed in the transcriptome, involving 18 gene products. We could demonstrate spontaneous T-cell responses to 5/18 (28%) mutated gene variants, and further analysis of the TCR repertoire of neoantigen-specific CD4+ and CD8+ T cells revealed TCR clonotypes that were expanded in both blood and tumor tissue. Following vaccination of HHD mice, de novo T-cell responses were generated to 4/18 (22%) mutated gene variants; T cells reactive against two variants were also evident in the autologous setting. Subsequently, we determined the major histocompatibility complex restriction of the T-cell responses and used in silico prediction tools to determine the likely neoepitopes.
Conclusions: our study demonstrates the feasibility of efficiently identifying tumor-specific neoantigens that can be targeted by vaccination in tumors with a low mutational burden, promising successful clinical exploitation, with trials currently underway.
McCann, Katy
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Witzleben, Adrian von
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Jaya, Thomas
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Wang, Chuan
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Wood, Oliver
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Singh, Divya
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Boukas, Konstantinos
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Bendjama, Kaidre
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Silvestre, Nathalie
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Nielsen, Finn Cilius
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Thomas, Gareth
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Sanchez-Elsner, Tilman
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Greenbaum, Jason
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Schoenberger, Stephen
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Peters, Bjoern
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Vijayanand, Pandurangan
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Savelyeva, Natalia
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Ottensmeier, Christian
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18 October 2023
McCann, Katy
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Witzleben, Adrian von
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Jaya, Thomas
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Wang, Chuan
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Wood, Oliver
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Singh, Divya
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Boukas, Konstantinos
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Bendjama, Kaidre
396f6b75-c857-4bcf-a0fc-37ef2d525118
Silvestre, Nathalie
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Nielsen, Finn Cilius
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Thomas, Gareth
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Sanchez-Elsner, Tilman
b8799f8d-e2b4-4b37-b77c-f2f0e8e2070d
Greenbaum, Jason
195ede5f-25ce-4306-b653-d0ee3be7d47a
Schoenberger, Stephen
62140e85-c833-46d9-8728-c1106c2b801e
Peters, Bjoern
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Vijayanand, Pandurangan
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Savelyeva, Natalia
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Ottensmeier, Christian
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McCann, Katy, Witzleben, Adrian von, Jaya, Thomas, Wang, Chuan, Wood, Oliver, Singh, Divya, Boukas, Konstantinos, Bendjama, Kaidre, Silvestre, Nathalie, Nielsen, Finn Cilius, Thomas, Gareth, Sanchez-Elsner, Tilman, Greenbaum, Jason, Schoenberger, Stephen, Peters, Bjoern, Vijayanand, Pandurangan, Savelyeva, Natalia and Ottensmeier, Christian
(2023)
Targeting the tumor mutanome for personalized vaccination in a TMB low non-small cell lung cancer.
Journal for Immunotherapy of Cancer, 10 (3).
(doi:10.1136/jitc-2021-003821).
Abstract
Background: cancer is characterized by an accumulation of somatic mutations, of which a significant subset can generate cancer-specific neoepitopes that are recognized by autologous T cells. Such neoepitopes are emerging as important targets for cancer immunotherapy, including personalized cancer vaccination strategies.
Methods: we used whole-exome and RNA sequencing analysis to identify potential neoantigens for a patient with non-small cell lung cancer. Thereafter, we assessed the autologous T-cell reactivity to the candidate neoantigens using a long peptide approach in a cultured interferon gamma ELISpot and tracked the neoantigen-specific T-cells in the tumor by T-cell receptor (TCR) sequencing. In parallel, identified gene variants were incorporated into a Modified Vaccinia Ankara-based vaccine, which was evaluated in the human leucocyte antigen A*0201 transgenic mouse model (HHD).
Results: sequencing revealed a tumor with a low mutational burden: 2219 sequence variants were identified from the primary tumor, of which 23 were expressed in the transcriptome, involving 18 gene products. We could demonstrate spontaneous T-cell responses to 5/18 (28%) mutated gene variants, and further analysis of the TCR repertoire of neoantigen-specific CD4+ and CD8+ T cells revealed TCR clonotypes that were expanded in both blood and tumor tissue. Following vaccination of HHD mice, de novo T-cell responses were generated to 4/18 (22%) mutated gene variants; T cells reactive against two variants were also evident in the autologous setting. Subsequently, we determined the major histocompatibility complex restriction of the T-cell responses and used in silico prediction tools to determine the likely neoepitopes.
Conclusions: our study demonstrates the feasibility of efficiently identifying tumor-specific neoantigens that can be targeted by vaccination in tumors with a low mutational burden, promising successful clinical exploitation, with trials currently underway.
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Accepted/In Press date: 14 March 2022
e-pub ahead of print date: 31 March 2022
Published date: 18 October 2023
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Local EPrints ID: 491865
URI: http://eprints.soton.ac.uk/id/eprint/491865
PURE UUID: 6f3fbfee-7858-483b-833c-62ec1de82585
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Date deposited: 04 Jul 2024 17:34
Last modified: 12 Jul 2024 01:45
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Contributors
Author:
Katy McCann
Author:
Adrian von Witzleben
Author:
Thomas Jaya
Author:
Chuan Wang
Author:
Oliver Wood
Author:
Divya Singh
Author:
Konstantinos Boukas
Author:
Kaidre Bendjama
Author:
Nathalie Silvestre
Author:
Finn Cilius Nielsen
Author:
Gareth Thomas
Author:
Jason Greenbaum
Author:
Stephen Schoenberger
Author:
Bjoern Peters
Author:
Pandurangan Vijayanand
Author:
Natalia Savelyeva
Author:
Christian Ottensmeier
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