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Main Authors: Bodinier, Barbara, Dissez, Gaetan, Ter-Minassian, Lucile, Bleistein, Linus, Codato, Roberta, Klein, John, Durand, Eric, Dauvin, Antonin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.15646
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author Bodinier, Barbara
Dissez, Gaetan
Ter-Minassian, Lucile
Bleistein, Linus
Codato, Roberta
Klein, John
Durand, Eric
Dauvin, Antonin
author_facet Bodinier, Barbara
Dissez, Gaetan
Ter-Minassian, Lucile
Bleistein, Linus
Codato, Roberta
Klein, John
Durand, Eric
Dauvin, Antonin
contents High-throughput preclinical perturbation screens, where the effects of genetic, chemical, or environmental perturbations are systematically tested on disease models, hold significant promise for machine learning-enhanced drug discovery due to their scale and causal nature. Predictive models trained on such datasets can be used to (i) infer perturbation response for previously untested disease models, and (ii) characterise the biological context that affects perturbation response. Existing predictive models suffer from limited reproducibility, generalisability and interpretability. To address these issues, we introduce a framework of Layered Ensemble of Autoencoders and Predictors (LEAP), a general and flexible ensemble strategy to aggregate predictions from multiple regressors trained using diverse gene expression representation models. LEAP consistently improves prediction performances in unscreened cell lines across modelling strategies. In particular, LEAP applied to perturbation-specific LASSO regressors (PS-LASSO) provides a favorable balance between near state-of-the-art performance and low computation time. We also propose an interpretability approach combining model distillation and stability selection to identify important biological pathways for perturbation response prediction in LEAP. Our models have the potential to accelerate the drug discovery pipeline by guiding the prioritisation of preclinical experiments and providing insights into the biological mechanisms involved in perturbation response. The code and datasets used in this work are publicly available.
format Preprint
id arxiv_https___arxiv_org_abs_2502_15646
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Predicting gene essentiality and drug response from perturbation screens in preclinical cancer models with LEAP: Layered Ensemble of Autoencoders and Predictors
Bodinier, Barbara
Dissez, Gaetan
Ter-Minassian, Lucile
Bleistein, Linus
Codato, Roberta
Klein, John
Durand, Eric
Dauvin, Antonin
Machine Learning
High-throughput preclinical perturbation screens, where the effects of genetic, chemical, or environmental perturbations are systematically tested on disease models, hold significant promise for machine learning-enhanced drug discovery due to their scale and causal nature. Predictive models trained on such datasets can be used to (i) infer perturbation response for previously untested disease models, and (ii) characterise the biological context that affects perturbation response. Existing predictive models suffer from limited reproducibility, generalisability and interpretability. To address these issues, we introduce a framework of Layered Ensemble of Autoencoders and Predictors (LEAP), a general and flexible ensemble strategy to aggregate predictions from multiple regressors trained using diverse gene expression representation models. LEAP consistently improves prediction performances in unscreened cell lines across modelling strategies. In particular, LEAP applied to perturbation-specific LASSO regressors (PS-LASSO) provides a favorable balance between near state-of-the-art performance and low computation time. We also propose an interpretability approach combining model distillation and stability selection to identify important biological pathways for perturbation response prediction in LEAP. Our models have the potential to accelerate the drug discovery pipeline by guiding the prioritisation of preclinical experiments and providing insights into the biological mechanisms involved in perturbation response. The code and datasets used in this work are publicly available.
title Predicting gene essentiality and drug response from perturbation screens in preclinical cancer models with LEAP: Layered Ensemble of Autoencoders and Predictors
topic Machine Learning
url https://arxiv.org/abs/2502.15646