A transfer-learning approach to predict antigen immunogenicity and T-cell receptor specificity

Barbara Bravi; Andrea Di Gioacchino; Jorge Fernandez-de-Cossio-Diaz; Aleksandra M. Walczak; Thierry Mora; Simona Cocco; Rémi Monasson

doi:10.7554/eLife.85126

A transfer-learning approach to predict antigen immunogenicity and T-cell receptor specificity

Barbara Bravi
, Andrea Di Gioacchino
, Jorge Fernandez-de-Cossio-Diaz
, Aleksandra M. Walczak
, Thierry Mora
, Simona Cocco
, Rémi Monasson

École Polytechnique

Research output: Contribution to journal › Article › peer-review

Abstract

Antigen immunogenicity and the specificity of binding of T-cell receptors to antigens are key properties underlying effective immune responses. Here we propose diffRBM, an approach based on transfer learning and Restricted Boltzmann Machines, to build sequence-based predictive models of these properties. DiffRBM is designed to learn the distinctive patterns in amino-acid composition that, on the one hand, underlie the antigen's probability of triggering a response, and on the other hand the T-cell receptor's ability to bind to a given antigen. We show that the patterns learnt by diffRBM allow us to predict putative contact sites of the antigen-receptor complex. We also discriminate immunogenic and non-immunogenic antigens, antigen-specific and generic receptors, reaching performances that compare favorably to existing sequence-based predictors of antigen immunogenicity and T-cell receptor specificity.

Original language	English
Journal	eLife
Volume	12
DOIs	https://doi.org/10.7554/eLife.85126
Publication status	Published - 8 Sept 2023

Keywords

computational biology
human
immune response
immunogenicity
machine learning
systems biology

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10.7554/eLife.85126

Cite this

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title = "A transfer-learning approach to predict antigen immunogenicity and T-cell receptor specificity",

abstract = "Antigen immunogenicity and the specificity of binding of T-cell receptors to antigens are key properties underlying effective immune responses. Here we propose diffRBM, an approach based on transfer learning and Restricted Boltzmann Machines, to build sequence-based predictive models of these properties. DiffRBM is designed to learn the distinctive patterns in amino-acid composition that, on the one hand, underlie the antigen's probability of triggering a response, and on the other hand the T-cell receptor's ability to bind to a given antigen. We show that the patterns learnt by diffRBM allow us to predict putative contact sites of the antigen-receptor complex. We also discriminate immunogenic and non-immunogenic antigens, antigen-specific and generic receptors, reaching performances that compare favorably to existing sequence-based predictors of antigen immunogenicity and T-cell receptor specificity.",

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T1 - A transfer-learning approach to predict antigen immunogenicity and T-cell receptor specificity

AU - Bravi, Barbara

AU - Di Gioacchino, Andrea

AU - Fernandez-de-Cossio-Diaz, Jorge

AU - Walczak, Aleksandra M.

AU - Mora, Thierry

AU - Cocco, Simona

AU - Monasson, Rémi

PY - 2023/9/8

Y1 - 2023/9/8

N2 - Antigen immunogenicity and the specificity of binding of T-cell receptors to antigens are key properties underlying effective immune responses. Here we propose diffRBM, an approach based on transfer learning and Restricted Boltzmann Machines, to build sequence-based predictive models of these properties. DiffRBM is designed to learn the distinctive patterns in amino-acid composition that, on the one hand, underlie the antigen's probability of triggering a response, and on the other hand the T-cell receptor's ability to bind to a given antigen. We show that the patterns learnt by diffRBM allow us to predict putative contact sites of the antigen-receptor complex. We also discriminate immunogenic and non-immunogenic antigens, antigen-specific and generic receptors, reaching performances that compare favorably to existing sequence-based predictors of antigen immunogenicity and T-cell receptor specificity.

AB - Antigen immunogenicity and the specificity of binding of T-cell receptors to antigens are key properties underlying effective immune responses. Here we propose diffRBM, an approach based on transfer learning and Restricted Boltzmann Machines, to build sequence-based predictive models of these properties. DiffRBM is designed to learn the distinctive patterns in amino-acid composition that, on the one hand, underlie the antigen's probability of triggering a response, and on the other hand the T-cell receptor's ability to bind to a given antigen. We show that the patterns learnt by diffRBM allow us to predict putative contact sites of the antigen-receptor complex. We also discriminate immunogenic and non-immunogenic antigens, antigen-specific and generic receptors, reaching performances that compare favorably to existing sequence-based predictors of antigen immunogenicity and T-cell receptor specificity.

KW - computational biology

KW - human

KW - immune response

KW - immunogenicity

KW - machine learning

KW - systems biology

U2 - 10.7554/eLife.85126

DO - 10.7554/eLife.85126

M3 - Article

C2 - 37681658

AN - SCOPUS:85171690905

SN - 2050-084X

VL - 12

JO - eLife

JF - eLife

ER -

A transfer-learning approach to predict antigen immunogenicity and T-cell receptor specificity

Abstract

Keywords

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