Network medicine-based epistasis detection in complex diseases: Ready for quantum computing

Markus Hoffmann; Julian M. Poschenrieder; Massimiliano Incudini; Sylvie Baier; Amelie Fritz; Andreas Maier; Michael Hartung; Christian Hoffmann; Nico Trummer; Klaudia Adamowicz; Mario Picciani; Evelyn Scheibling; Maximilian V. Harl; Ingmar Lesch; Hunor Frey; Simon Kayser; Paul Wissenberg; Leon Schwartz; Leon Hafner; Aakriti Acharya; Lena Hackl; Gordon Grabert; Sung Gwon Lee; Gyuhyeok Cho; Matthew E. Cloward; Jakub Jankowski; Hye Kyung Lee; Olga Tsoy; Nina Wenke; Anders Gorm Pedersen; Klaus Bønnelykke; Antonio Mandarino; Federico Melograna; Laura Schulz; Héctor Climente-González; Mathias Wilhelm; Luigi Iapichino; Lars Wienbrandt; David Ellinghaus; Kristel Van Steen; Michele Grossi; Priscilla A. Furth; Lothar Hennighausen; Alessandra Di Pierro; Jan Baumbach; Tim Kacprowski; Markus List; David B. Blumenthal

doi:10.1093/nar/gkae697

Network medicine-based epistasis detection in complex diseases: Ready for quantum computing

Markus Hoffmann^*
, Julian M. Poschenrieder
, Massimiliano Incudini
, Sylvie Baier
, Amelie Fritz
, Andreas Maier
, Michael Hartung
, Christian Hoffmann
, Nico Trummer
, Klaudia Adamowicz
, Mario Picciani
, Evelyn Scheibling
, Maximilian V. Harl
, Ingmar Lesch
, Hunor Frey
, Simon Kayser
, Paul Wissenberg
, Leon Schwartz
, Leon Hafner
, Aakriti Acharya

Lena Hackl, Gordon Grabert, Sung Gwon Lee, Gyuhyeok Cho, Matthew E. Cloward, Jakub Jankowski, Hye Kyung Lee, Olga Tsoy, Nina Wenke, Anders Gorm Pedersen, Klaus Bønnelykke, Antonio Mandarino, Federico Melograna, Laura Schulz, Héctor Climente-González, Mathias Wilhelm, Luigi Iapichino, Lars Wienbrandt, David Ellinghaus, Kristel Van Steen, Michele Grossi, Priscilla A. Furth, Lothar Hennighausen, Alessandra Di Pierro, Jan Baumbach, Tim Kacprowski, Markus List, David B. Blumenthal

^*Kontaktforfatter

Technical University of Munich
National Institute of Diabetes and Digestive and Kidney Diseases
University of Hamburg
University of Verona
Danmarks Tekniske Universitet
Københavns Universitetshospital
Neuroscience Center Zurich
Hannover Medical School
Braunschweig University of Technology
Chonnam National University
Gwangju Institute of Science and Technology
Brigham Young University
Gdańsk University of Physical Education and Sport
University of Liège
KU Leuven
The Bavarian Academy of Sciences and Humanities (LRZ)
RIKEN Center for Advanced Intelligence Project
Christian-Albrechts-University of Kiel
CERN
Georgetown University
Friedrich-Alexander University Erlangen-Nürnberg

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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Abstract

Most heritable diseases are polygenic. To comprehend the underlying genetic architecture, it is crucial to discover the clinically relevant epistatic interactions (EIs) between genomic single nucleotide polymorphisms (SNPs) (1-3). Existing statistical computational methods for EI detection are mostly limited to pairs of SNPs due to the combinatorial explosion of higher-order EIs. With NeEDL (network-based epistasis detection via local search), we leverage network medicine to inform the selection of EIs that are an order of magnitude more statistically significant compared to existing tools and consist, on average, of five SNPs. We further show that this computationally demanding task can be substantially accelerated once quantum computing hardware becomes available. We apply NeEDL to eight different diseases and discover genes (affected by EIs of SNPs) that are partly known to affect the disease, additionally, these results are reproducible across independent cohorts. EIs for these eight diseases can be interactively explored in the Epistasis Disease Atlas (https://epistasis-disease-atlas.com). In summary, NeEDL demonstrates the potential of seamlessly integrated quantum computing techniques to accelerate biomedical research. Our network medicine approach detects higher-order EIs with unprecedented statistical and biological evidence, yielding unique insights into polygenic diseases and providing a basis for the development of improved risk scores and combination therapies.

Originalsprog	Engelsk
Tidsskrift	Nucleic Acids Research
Vol/bind	52
Udgave nummer	17
Sider (fra-til)	10144-10160
ISSN	0305-1048
DOI	https://doi.org/10.1093/nar/gkae697
Status	Udgivet - 23. sep. 2024

Dokumenter og links

10.1093/nar/gkae697Licens: CC BY-NC-ND

Open Access VersionForlagets udgivne version, 3,21 MBLicens: CC BY-NC-ND

SDU link

Tjek adgangen til materialet i Syddansk Universitetsbiblioteks søgemaskine

Citationsformater

Hoffmann, M., Poschenrieder, J. M., Incudini, M., Baier, S., Fritz, A., Maier, A., Hartung, M., Hoffmann, C., Trummer, N., Adamowicz, K., Picciani, M., Scheibling, E., Harl, M. V., Lesch, I., Frey, H., Kayser, S., Wissenberg, P., Schwartz, L., Hafner, L., ... Blumenthal, D. B. (2024). Network medicine-based epistasis detection in complex diseases: Ready for quantum computing. Nucleic Acids Research, 52(17), 10144-10160. https://doi.org/10.1093/nar/gkae697

@article{f7e5e61971234e2bab9f62466e246bfc,

title = "Network medicine-based epistasis detection in complex diseases: Ready for quantum computing",

abstract = "Most heritable diseases are polygenic. To comprehend the underlying genetic architecture, it is crucial to discover the clinically relevant epistatic interactions (EIs) between genomic single nucleotide polymorphisms (SNPs) (1-3). Existing statistical computational methods for EI detection are mostly limited to pairs of SNPs due to the combinatorial explosion of higher-order EIs. With NeEDL (network-based epistasis detection via local search), we leverage network medicine to inform the selection of EIs that are an order of magnitude more statistically significant compared to existing tools and consist, on average, of five SNPs. We further show that this computationally demanding task can be substantially accelerated once quantum computing hardware becomes available. We apply NeEDL to eight different diseases and discover genes (affected by EIs of SNPs) that are partly known to affect the disease, additionally, these results are reproducible across independent cohorts. EIs for these eight diseases can be interactively explored in the Epistasis Disease Atlas (https://epistasis-disease-atlas.com). In summary, NeEDL demonstrates the potential of seamlessly integrated quantum computing techniques to accelerate biomedical research. Our network medicine approach detects higher-order EIs with unprecedented statistical and biological evidence, yielding unique insights into polygenic diseases and providing a basis for the development of improved risk scores and combination therapies.",

author = "Markus Hoffmann and Poschenrieder, \{Julian M.\} and Massimiliano Incudini and Sylvie Baier and Amelie Fritz and Andreas Maier and Michael Hartung and Christian Hoffmann and Nico Trummer and Klaudia Adamowicz and Mario Picciani and Evelyn Scheibling and Harl, \{Maximilian V.\} and Ingmar Lesch and Hunor Frey and Simon Kayser and Paul Wissenberg and Leon Schwartz and Leon Hafner and Aakriti Acharya and Lena Hackl and Gordon Grabert and Lee, \{Sung Gwon\} and Gyuhyeok Cho and Cloward, \{Matthew E.\} and Jakub Jankowski and Lee, \{Hye Kyung\} and Olga Tsoy and Nina Wenke and Pedersen, \{Anders Gorm\} and Klaus B{\o}nnelykke and Antonio Mandarino and Federico Melograna and Laura Schulz and H{\'e}ctor Climente-Gonz{\'a}lez and Mathias Wilhelm and Luigi Iapichino and Lars Wienbrandt and David Ellinghaus and \{Van Steen\}, Kristel and Michele Grossi and Furth, \{Priscilla A.\} and Lothar Hennighausen and \{Di Pierro\}, Alessandra and Jan Baumbach and Tim Kacprowski and Markus List and Blumenthal, \{David B.\}",

year = "2024",

month = sep,

day = "23",

doi = "10.1093/nar/gkae697",

language = "English",

volume = "52",

pages = "10144--10160",

journal = "Nucleic Acids Research",

issn = "0305-1048",

publisher = "Oxford University Press",

number = "17",

}

Hoffmann, M, Poschenrieder, JM, Incudini, M, Baier, S, Fritz, A, Maier, A, Hartung, M, Hoffmann, C, Trummer, N, Adamowicz, K, Picciani, M, Scheibling, E, Harl, MV, Lesch, I, Frey, H, Kayser, S, Wissenberg, P, Schwartz, L, Hafner, L, Acharya, A, Hackl, L, Grabert, G, Lee, SG, Cho, G, Cloward, ME, Jankowski, J, Lee, HK, Tsoy, O, Wenke, N, Pedersen, AG, Bønnelykke, K, Mandarino, A, Melograna, F, Schulz, L, Climente-González, H, Wilhelm, M, Iapichino, L, Wienbrandt, L, Ellinghaus, D, Van Steen, K, Grossi, M, Furth, PA, Hennighausen, L, Di Pierro, A, Baumbach, J, Kacprowski, T, List, M & Blumenthal, DB 2024, 'Network medicine-based epistasis detection in complex diseases: Ready for quantum computing', Nucleic Acids Research, bind 52, nr. 17, s. 10144-10160. https://doi.org/10.1093/nar/gkae697

TY - JOUR

T1 - Network medicine-based epistasis detection in complex diseases

T2 - Ready for quantum computing

AU - Hoffmann, Markus

AU - Poschenrieder, Julian M.

AU - Incudini, Massimiliano

AU - Baier, Sylvie

AU - Fritz, Amelie

AU - Maier, Andreas

AU - Hartung, Michael

AU - Hoffmann, Christian

AU - Trummer, Nico

AU - Adamowicz, Klaudia

AU - Picciani, Mario

AU - Scheibling, Evelyn

AU - Harl, Maximilian V.

AU - Lesch, Ingmar

AU - Frey, Hunor

AU - Kayser, Simon

AU - Wissenberg, Paul

AU - Schwartz, Leon

AU - Hafner, Leon

AU - Acharya, Aakriti

AU - Hackl, Lena

AU - Grabert, Gordon

AU - Lee, Sung Gwon

AU - Cho, Gyuhyeok

AU - Cloward, Matthew E.

AU - Jankowski, Jakub

AU - Lee, Hye Kyung

AU - Tsoy, Olga

AU - Wenke, Nina

AU - Pedersen, Anders Gorm

AU - Bønnelykke, Klaus

AU - Mandarino, Antonio

AU - Melograna, Federico

AU - Schulz, Laura

AU - Climente-González, Héctor

AU - Wilhelm, Mathias

AU - Iapichino, Luigi

AU - Wienbrandt, Lars

AU - Ellinghaus, David

AU - Van Steen, Kristel

AU - Grossi, Michele

AU - Furth, Priscilla A.

AU - Hennighausen, Lothar

AU - Di Pierro, Alessandra

AU - Baumbach, Jan

AU - Kacprowski, Tim

AU - List, Markus

AU - Blumenthal, David B.

PY - 2024/9/23

Y1 - 2024/9/23

N2 - Most heritable diseases are polygenic. To comprehend the underlying genetic architecture, it is crucial to discover the clinically relevant epistatic interactions (EIs) between genomic single nucleotide polymorphisms (SNPs) (1-3). Existing statistical computational methods for EI detection are mostly limited to pairs of SNPs due to the combinatorial explosion of higher-order EIs. With NeEDL (network-based epistasis detection via local search), we leverage network medicine to inform the selection of EIs that are an order of magnitude more statistically significant compared to existing tools and consist, on average, of five SNPs. We further show that this computationally demanding task can be substantially accelerated once quantum computing hardware becomes available. We apply NeEDL to eight different diseases and discover genes (affected by EIs of SNPs) that are partly known to affect the disease, additionally, these results are reproducible across independent cohorts. EIs for these eight diseases can be interactively explored in the Epistasis Disease Atlas (https://epistasis-disease-atlas.com). In summary, NeEDL demonstrates the potential of seamlessly integrated quantum computing techniques to accelerate biomedical research. Our network medicine approach detects higher-order EIs with unprecedented statistical and biological evidence, yielding unique insights into polygenic diseases and providing a basis for the development of improved risk scores and combination therapies.

AB - Most heritable diseases are polygenic. To comprehend the underlying genetic architecture, it is crucial to discover the clinically relevant epistatic interactions (EIs) between genomic single nucleotide polymorphisms (SNPs) (1-3). Existing statistical computational methods for EI detection are mostly limited to pairs of SNPs due to the combinatorial explosion of higher-order EIs. With NeEDL (network-based epistasis detection via local search), we leverage network medicine to inform the selection of EIs that are an order of magnitude more statistically significant compared to existing tools and consist, on average, of five SNPs. We further show that this computationally demanding task can be substantially accelerated once quantum computing hardware becomes available. We apply NeEDL to eight different diseases and discover genes (affected by EIs of SNPs) that are partly known to affect the disease, additionally, these results are reproducible across independent cohorts. EIs for these eight diseases can be interactively explored in the Epistasis Disease Atlas (https://epistasis-disease-atlas.com). In summary, NeEDL demonstrates the potential of seamlessly integrated quantum computing techniques to accelerate biomedical research. Our network medicine approach detects higher-order EIs with unprecedented statistical and biological evidence, yielding unique insights into polygenic diseases and providing a basis for the development of improved risk scores and combination therapies.

U2 - 10.1093/nar/gkae697

DO - 10.1093/nar/gkae697

M3 - Journal article

C2 - 39175109

AN - SCOPUS:85204819837

SN - 0305-1048

VL - 52

SP - 10144

EP - 10160

JO - Nucleic Acids Research

JF - Nucleic Acids Research

IS - 17

ER -

Network medicine-based epistasis detection in complex diseases: Ready for quantum computing

Abstract

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SDU link

Fingeraftryk

Citationsformater