Causal machine learning for single-cell genomics

Alejandro Tejada-Lapuerta; Paul Bertin; Stefan Bauer; Hananeh Aliee; Yoshua Bengio; Fabian J. Theis

doi:10.1038/s41588-025-02124-2

Causal machine learning for single-cell genomics

Alejandro Tejada-Lapuerta
, Paul Bertin
, Stefan Bauer
, Hananeh Aliee
, Yoshua Bengio
, Fabian J. Theis

Chair of Mathematical Modelling of Biological Systems

Institute of Computational Biology
Technical University of Munich
Quebec Artificial Intelligence Institute
Université de Montréal
Helmholtz Munich
Munich Center for Machine Learning
Wellcome Sanger Institute
Canadian Institute for Advanced Research

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

20 Scopus citations

Abstract

Advances in single-cell '-omics' allow unprecedented insights into the transcriptional profiles of individual cells and, when combined with large-scale perturbation screens, enable measuring of the effect of targeted perturbations on the whole transcriptome. These advances provide an opportunity to better understand the causative role of genes in complex biological processes. In this Perspective, we delineate the application of causal machine learning to single-cell genomics and its associated challenges. We first present the causal model that is most commonly applied to single-cell biology and then identify and discuss potential approaches to three open problems: the lack of generalization of models to novel experimental conditions, the complexity of interpreting learned models, and the difficulty of learning cell dynamics.

Original language	English
Article number	12
Pages (from-to)	797-808
Number of pages	12
Journal	Nature Genetics
Volume	57
Issue number	4
DOIs	https://doi.org/10.1038/s41588-025-02124-2
State	Published - Apr 2025

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AU - Bauer, Stefan

AU - Aliee, Hananeh

AU - Bengio, Yoshua

AU - Theis, Fabian J.

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AB - Advances in single-cell '-omics' allow unprecedented insights into the transcriptional profiles of individual cells and, when combined with large-scale perturbation screens, enable measuring of the effect of targeted perturbations on the whole transcriptome. These advances provide an opportunity to better understand the causative role of genes in complex biological processes. In this Perspective, we delineate the application of causal machine learning to single-cell genomics and its associated challenges. We first present the causal model that is most commonly applied to single-cell biology and then identify and discuss potential approaches to three open problems: the lack of generalization of models to novel experimental conditions, the complexity of interpreting learned models, and the difficulty of learning cell dynamics.

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Causal machine learning for single-cell genomics

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