Geometric deep learning improves generalizability of MHC-bound peptide predictions

Dario F. Marzella; Giulia Crocioni; Tadija Radusinović; Daniil Lepikhov; Heleen Severin; Dani L. Bodor; Daniel T. Rademaker; Chia Yu Lin; Sonja Georgievska; Nicolas Renaud; Amy L. Kessler; Pablo Lopez-Tarifa; Sonja I. Buschow; Erik Bekkers; Li C. Xue

doi:10.1038/s42003-024-07292-1

Geometric deep learning improves generalizability of MHC-bound peptide predictions

Dario F. Marzella
, Giulia Crocioni
, Tadija Radusinović
, Daniil Lepikhov
, Heleen Severin
, Dani L. Bodor
, Daniel T. Rademaker
, Chia Yu Lin
, Sonja Georgievska
, Nicolas Renaud
, Amy L. Kessler
, Pablo Lopez-Tarifa
, Sonja I. Buschow
, Erik Bekkers
, Li C. Xue^*

^*Corresponding author for this work

Gastroenterology & Hepatology

Radboud University Medical Center
Netherlands eScience Center
University of Amsterdam

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

10 Citations (Scopus)

56 Downloads (Pure)

Abstract

The interaction between peptides and major histocompatibility complex (MHC) molecules is pivotal in autoimmunity, pathogen recognition and tumor immunity. Recent advances in cancer immunotherapies demand for more accurate computational prediction of MHC-bound peptides. We address the generalizability challenge of MHC-bound peptide predictions, revealing limitations in current sequence-based approaches. Our structure-based methods leveraging geometric deep learning (GDL) demonstrate promising improvement in generalizability across unseen MHC alleles. Further, we tackle data efficiency by introducing a self-supervised learning approach on structures (3D-SSL). Without being exposed to any binding affinity data, our 3D-SSL outperforms sequence-based methods trained on ~90 times more data points. Finally, we demonstrate the resilience of structure-based GDL methods to biases in binding data on an Hepatitis B virus vaccine immunopeptidomics case study. This proof-of-concept study highlights structure-based methods’ potential to enhance generalizability and data efficiency, with possible implications for data-intensive fields like T-cell receptor specificity predictions.

Original language	English
Article number	1661
Journal	Communications Biology
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s42003-024-07292-1
Publication status	Published - 19 Dec 2024

Bibliographical note

Publisher Copyright:
© The Author(s) 2024.

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Marzella, D. F., Crocioni, G., Radusinović, T., Lepikhov, D., Severin, H., Bodor, D. L., Rademaker, D. T., Lin, C. Y., Georgievska, S., Renaud, N., Kessler, A. L., Lopez-Tarifa, P., Buschow, S. I., Bekkers, E., & Xue, L. C. (2024). Geometric deep learning improves generalizability of MHC-bound peptide predictions. Communications Biology, 7(1), Article 1661. https://doi.org/10.1038/s42003-024-07292-1

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title = "Geometric deep learning improves generalizability of MHC-bound peptide predictions",

abstract = "The interaction between peptides and major histocompatibility complex (MHC) molecules is pivotal in autoimmunity, pathogen recognition and tumor immunity. Recent advances in cancer immunotherapies demand for more accurate computational prediction of MHC-bound peptides. We address the generalizability challenge of MHC-bound peptide predictions, revealing limitations in current sequence-based approaches. Our structure-based methods leveraging geometric deep learning (GDL) demonstrate promising improvement in generalizability across unseen MHC alleles. Further, we tackle data efficiency by introducing a self-supervised learning approach on structures (3D-SSL). Without being exposed to any binding affinity data, our 3D-SSL outperforms sequence-based methods trained on \textasciitilde{}90 times more data points. Finally, we demonstrate the resilience of structure-based GDL methods to biases in binding data on an Hepatitis B virus vaccine immunopeptidomics case study. This proof-of-concept study highlights structure-based methods{\textquoteright} potential to enhance generalizability and data efficiency, with possible implications for data-intensive fields like T-cell receptor specificity predictions.",

author = "Marzella, \{Dario F.\} and Giulia Crocioni and Tadija Radusinovi{\'c} and Daniil Lepikhov and Heleen Severin and Bodor, \{Dani L.\} and Rademaker, \{Daniel T.\} and Lin, \{Chia Yu\} and Sonja Georgievska and Nicolas Renaud and Kessler, \{Amy L.\} and Pablo Lopez-Tarifa and Buschow, \{Sonja I.\} and Erik Bekkers and Xue, \{Li C.\}",

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year = "2024",

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doi = "10.1038/s42003-024-07292-1",

language = "English",

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Marzella, DF, Crocioni, G, Radusinović, T, Lepikhov, D, Severin, H, Bodor, DL, Rademaker, DT, Lin, CY, Georgievska, S, Renaud, N, Kessler, AL, Lopez-Tarifa, P, Buschow, SI, Bekkers, E & Xue, LC 2024, 'Geometric deep learning improves generalizability of MHC-bound peptide predictions', Communications Biology, vol. 7, no. 1, 1661. https://doi.org/10.1038/s42003-024-07292-1

TY - JOUR

T1 - Geometric deep learning improves generalizability of MHC-bound peptide predictions

AU - Marzella, Dario F.

AU - Crocioni, Giulia

AU - Radusinović, Tadija

AU - Lepikhov, Daniil

AU - Severin, Heleen

AU - Bodor, Dani L.

AU - Rademaker, Daniel T.

AU - Lin, Chia Yu

AU - Georgievska, Sonja

AU - Renaud, Nicolas

AU - Kessler, Amy L.

AU - Lopez-Tarifa, Pablo

AU - Buschow, Sonja I.

AU - Bekkers, Erik

AU - Xue, Li C.

PY - 2024/12/19

Y1 - 2024/12/19

N2 - The interaction between peptides and major histocompatibility complex (MHC) molecules is pivotal in autoimmunity, pathogen recognition and tumor immunity. Recent advances in cancer immunotherapies demand for more accurate computational prediction of MHC-bound peptides. We address the generalizability challenge of MHC-bound peptide predictions, revealing limitations in current sequence-based approaches. Our structure-based methods leveraging geometric deep learning (GDL) demonstrate promising improvement in generalizability across unseen MHC alleles. Further, we tackle data efficiency by introducing a self-supervised learning approach on structures (3D-SSL). Without being exposed to any binding affinity data, our 3D-SSL outperforms sequence-based methods trained on ~90 times more data points. Finally, we demonstrate the resilience of structure-based GDL methods to biases in binding data on an Hepatitis B virus vaccine immunopeptidomics case study. This proof-of-concept study highlights structure-based methods’ potential to enhance generalizability and data efficiency, with possible implications for data-intensive fields like T-cell receptor specificity predictions.

AB - The interaction between peptides and major histocompatibility complex (MHC) molecules is pivotal in autoimmunity, pathogen recognition and tumor immunity. Recent advances in cancer immunotherapies demand for more accurate computational prediction of MHC-bound peptides. We address the generalizability challenge of MHC-bound peptide predictions, revealing limitations in current sequence-based approaches. Our structure-based methods leveraging geometric deep learning (GDL) demonstrate promising improvement in generalizability across unseen MHC alleles. Further, we tackle data efficiency by introducing a self-supervised learning approach on structures (3D-SSL). Without being exposed to any binding affinity data, our 3D-SSL outperforms sequence-based methods trained on ~90 times more data points. Finally, we demonstrate the resilience of structure-based GDL methods to biases in binding data on an Hepatitis B virus vaccine immunopeptidomics case study. This proof-of-concept study highlights structure-based methods’ potential to enhance generalizability and data efficiency, with possible implications for data-intensive fields like T-cell receptor specificity predictions.

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DO - 10.1038/s42003-024-07292-1

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AN - SCOPUS:85212685753

SN - 2399-3642

VL - 7

JO - Communications Biology

JF - Communications Biology

IS - 1

M1 - 1661

ER -

Geometric deep learning improves generalizability of MHC-bound peptide predictions

Abstract

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