Saved in:
Bibliographic Details
Main Authors: von Kügelgen, Julius, Ketterer, Jakob, Vollenweider, Michael, Scholkemper, Michael, Shen, Xinwei, Meinshausen, Nicolai, Peters, Jonas
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.18522
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910222806679552
author von Kügelgen, Julius
Ketterer, Jakob
Vollenweider, Michael
Scholkemper, Michael
Shen, Xinwei
Meinshausen, Nicolai
Peters, Jonas
author_facet von Kügelgen, Julius
Ketterer, Jakob
Vollenweider, Michael
Scholkemper, Michael
Shen, Xinwei
Meinshausen, Nicolai
Peters, Jonas
contents We consider the problem of modeling the effects of perturbations like gene knockouts on measurements such as single-cell RNA counts. Given data for some perturbations, we aim to predict the distribution of measurements for new combinations of perturbations. To address this challenging extrapolation task, we posit that perturbations act additively in a suitable, unknown embedding space. We formulate the data-generating process as a latent variable model, in which perturbations amount to mean shifts in latent space and can be combined additively. We then prove that, given sufficiently diverse training perturbations, the representation and perturbation effects are identifiable up to orthogonal transformation and use this to derive extrapolation guarantees for unseen perturbations that can be expressed as linear combinations of seen ones. To estimate the model from data, we propose the perturbation distribution autoencoder (PDAE), which is trained by maximizing the distributional similarity between true and simulated perturbation distributions. The trained model can then be used to predict previously unseen perturbation distributions. In support of our theoretical results, we demonstrate through simulations that PDAE can accurately predict the effects of unseen but identifiable perturbations, and showcase the method on combinatorial gene perturbation data.
format Preprint
id arxiv_https___arxiv_org_abs_2504_18522
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Extrapolation Guarantees for Perturbation Modeling Under the Additive Latent Shift Assumption
von Kügelgen, Julius
Ketterer, Jakob
Vollenweider, Michael
Scholkemper, Michael
Shen, Xinwei
Meinshausen, Nicolai
Peters, Jonas
Machine Learning
We consider the problem of modeling the effects of perturbations like gene knockouts on measurements such as single-cell RNA counts. Given data for some perturbations, we aim to predict the distribution of measurements for new combinations of perturbations. To address this challenging extrapolation task, we posit that perturbations act additively in a suitable, unknown embedding space. We formulate the data-generating process as a latent variable model, in which perturbations amount to mean shifts in latent space and can be combined additively. We then prove that, given sufficiently diverse training perturbations, the representation and perturbation effects are identifiable up to orthogonal transformation and use this to derive extrapolation guarantees for unseen perturbations that can be expressed as linear combinations of seen ones. To estimate the model from data, we propose the perturbation distribution autoencoder (PDAE), which is trained by maximizing the distributional similarity between true and simulated perturbation distributions. The trained model can then be used to predict previously unseen perturbation distributions. In support of our theoretical results, we demonstrate through simulations that PDAE can accurately predict the effects of unseen but identifiable perturbations, and showcase the method on combinatorial gene perturbation data.
title Extrapolation Guarantees for Perturbation Modeling Under the Additive Latent Shift Assumption
topic Machine Learning
url https://arxiv.org/abs/2504.18522