Machine learning in Alzheimer’s disease genetics

EADB

doi:10.1038/s41467-025-61650-z

Machine learning in Alzheimer’s disease genetics

EADB

Glenn Biggs Institute for Alzheimer’s & Neurodegenerative Diseases

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

Abstract

Traditional statistical approaches have advanced our understanding of the genetics of complex diseases, yet are limited to linear additive models. Here we applied machine learning (ML) to genome-wide data from 41,686 individuals in the largest European consortium on Alzheimer’s disease (AD) to investigate the effectiveness of various ML algorithms in replicating known findings, discovering novel loci, and predicting individuals at risk. We utilised Gradient Boosting Machines (GBMs), biological pathway-informed Neural Networks (NNs), and Model-based Multifactor Dimensionality Reduction (MB-MDR) models. ML approaches successfully captured all genome-wide significant genetic variants identified in the training set and 22% of associations from larger meta-analyses. They highlight 6 novel loci which replicate in an external dataset, including variants which map to ARHGAP25, LY6H, COG7, SOD1 and ZNF597. They further identify novel association in AP4E1, refining the genetic landscape of the known SPPL2A locus. Our results demonstrate that machine learning methods can achieve predictive performance comparable to classical approaches in genetic epidemiology and have the potential to uncover novel loci that remain undetected by traditional GWAS. These insights provide a complementary avenue for advancing the understanding of AD genetics.

Original language	English (US)
Article number	6726
Journal	Nature communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-61650-z
State	Published - Dec 2025

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General
General Physics and Astronomy

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10.1038/s41467-025-61650-z

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@article{421f14e933b544d695440f5c18899b5a,

title = "Machine learning in Alzheimer{\textquoteright}s disease genetics",

abstract = "Traditional statistical approaches have advanced our understanding of the genetics of complex diseases, yet are limited to linear additive models. Here we applied machine learning (ML) to genome-wide data from 41,686 individuals in the largest European consortium on Alzheimer{\textquoteright}s disease (AD) to investigate the effectiveness of various ML algorithms in replicating known findings, discovering novel loci, and predicting individuals at risk. We utilised Gradient Boosting Machines (GBMs), biological pathway-informed Neural Networks (NNs), and Model-based Multifactor Dimensionality Reduction (MB-MDR) models. ML approaches successfully captured all genome-wide significant genetic variants identified in the training set and 22\% of associations from larger meta-analyses. They highlight 6 novel loci which replicate in an external dataset, including variants which map to ARHGAP25, LY6H, COG7, SOD1 and ZNF597. They further identify novel association in AP4E1, refining the genetic landscape of the known SPPL2A locus. Our results demonstrate that machine learning methods can achieve predictive performance comparable to classical approaches in genetic epidemiology and have the potential to uncover novel loci that remain undetected by traditional GWAS. These insights provide a complementary avenue for advancing the understanding of AD genetics.",

author = "EADB and Matthew Bracher-Smith and Federico Melograna and Brittany Ulm and C{\'e}line Bellenguez and Benjamin Grenier-Boley and Diane Duroux and Nevado, \{Alejo J.\} and Peter Holmans and Tijms, \{Betty M.\} and Marc Hulsman and \{de Rojas\}, Itziar and Rafael Campos-Martin and \{der Lee\}, \{Sven van\} and Atahualpa Castillo and Fahri K{\"u}{\c c}{\"u}kali and Oliver Peters and Anja Schneider and Martin Dichgans and Dan Rujescu and Norbert Scherbaum and J{\"u}rgen Deckert and Steffi Riedel-Heller and Lucrezia Hausner and Laura Molina-Porcel and Emrah D{\"u}zel and Timo Grimmer and Jens Wiltfang and Stefanie Heilmann-Heimbach and Susanne Moebus and Thomas Tegos and Nikolaos Scarmeas and Oriol Dols-Icardo and Fermin Moreno and Jordi P{\'e}rez-Tur and Bullido, \{Mar{\'i}a J.\} and Pau Pastor and Raquel S{\'a}nchez-Valle and Victoria {\'A}lvarez and Merc{\`e} Boada and Pablo Garc{\'i}a-Gonz{\'a}lez and Raquel Puerta and Pablo Mir and Real, \{Luis M.\} and Gerard Pi{\~n}ol-Ripoll and Garc{\'i}a-Alberca, \{Jose Mar{\'i}a\} and Eloy Rodriguez-Rodriguez and Hilkka Soininen and Sami Heikkinen and \{de Mendon{\c c}a\}, Alexandre and Agust{\'i}n Ruiz",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1038/s41467-025-61650-z",

language = "English (US)",

volume = "16",

journal = "Nature communications",

issn = "2041-1723",

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AU - EADB

AU - Bracher-Smith, Matthew

AU - Melograna, Federico

AU - Ulm, Brittany

AU - Bellenguez, Céline

AU - Grenier-Boley, Benjamin

AU - Duroux, Diane

AU - Nevado, Alejo J.

AU - Holmans, Peter

AU - Tijms, Betty M.

AU - Hulsman, Marc

AU - de Rojas, Itziar

AU - Campos-Martin, Rafael

AU - der Lee, Sven van

AU - Castillo, Atahualpa

AU - Küçükali, Fahri

AU - Peters, Oliver

AU - Schneider, Anja

AU - Dichgans, Martin

AU - Rujescu, Dan

AU - Scherbaum, Norbert

AU - Deckert, Jürgen

AU - Riedel-Heller, Steffi

AU - Hausner, Lucrezia

AU - Molina-Porcel, Laura

AU - Düzel, Emrah

AU - Grimmer, Timo

AU - Wiltfang, Jens

AU - Heilmann-Heimbach, Stefanie

AU - Moebus, Susanne

AU - Tegos, Thomas

AU - Scarmeas, Nikolaos

AU - Dols-Icardo, Oriol

AU - Moreno, Fermin

AU - Pérez-Tur, Jordi

AU - Bullido, María J.

AU - Pastor, Pau

AU - Sánchez-Valle, Raquel

AU - Álvarez, Victoria

AU - Boada, Mercè

AU - García-González, Pablo

AU - Puerta, Raquel

AU - Mir, Pablo

AU - Real, Luis M.

AU - Piñol-Ripoll, Gerard

AU - García-Alberca, Jose María

AU - Rodriguez-Rodriguez, Eloy

AU - Soininen, Hilkka

AU - Heikkinen, Sami

AU - de Mendonça, Alexandre

AU - Ruiz, Agustín

PY - 2025/12

Y1 - 2025/12

N2 - Traditional statistical approaches have advanced our understanding of the genetics of complex diseases, yet are limited to linear additive models. Here we applied machine learning (ML) to genome-wide data from 41,686 individuals in the largest European consortium on Alzheimer’s disease (AD) to investigate the effectiveness of various ML algorithms in replicating known findings, discovering novel loci, and predicting individuals at risk. We utilised Gradient Boosting Machines (GBMs), biological pathway-informed Neural Networks (NNs), and Model-based Multifactor Dimensionality Reduction (MB-MDR) models. ML approaches successfully captured all genome-wide significant genetic variants identified in the training set and 22% of associations from larger meta-analyses. They highlight 6 novel loci which replicate in an external dataset, including variants which map to ARHGAP25, LY6H, COG7, SOD1 and ZNF597. They further identify novel association in AP4E1, refining the genetic landscape of the known SPPL2A locus. Our results demonstrate that machine learning methods can achieve predictive performance comparable to classical approaches in genetic epidemiology and have the potential to uncover novel loci that remain undetected by traditional GWAS. These insights provide a complementary avenue for advancing the understanding of AD genetics.

AB - Traditional statistical approaches have advanced our understanding of the genetics of complex diseases, yet are limited to linear additive models. Here we applied machine learning (ML) to genome-wide data from 41,686 individuals in the largest European consortium on Alzheimer’s disease (AD) to investigate the effectiveness of various ML algorithms in replicating known findings, discovering novel loci, and predicting individuals at risk. We utilised Gradient Boosting Machines (GBMs), biological pathway-informed Neural Networks (NNs), and Model-based Multifactor Dimensionality Reduction (MB-MDR) models. ML approaches successfully captured all genome-wide significant genetic variants identified in the training set and 22% of associations from larger meta-analyses. They highlight 6 novel loci which replicate in an external dataset, including variants which map to ARHGAP25, LY6H, COG7, SOD1 and ZNF597. They further identify novel association in AP4E1, refining the genetic landscape of the known SPPL2A locus. Our results demonstrate that machine learning methods can achieve predictive performance comparable to classical approaches in genetic epidemiology and have the potential to uncover novel loci that remain undetected by traditional GWAS. These insights provide a complementary avenue for advancing the understanding of AD genetics.

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VL - 16

JO - Nature communications

JF - Nature communications

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ER -

Machine learning in Alzheimer’s disease genetics

Abstract

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