Supervised and unsupervised deep learning-based approaches for studying DNA replication spatiotemporal dynamics

Julian Ng-Kee-Kwong; Ben Philps; Fiona N.C. Smith; Aleksandra Sobieska; Naiming Chen; Constance Alabert; Hakan Bilen; Sara C.B. Buonomo

doi:10.1038/s42003-025-07744-2

Supervised and unsupervised deep learning-based approaches for studying DNA replication spatiotemporal dynamics

Julian Ng-Kee-Kwong, Ben Philps, Fiona N.C. Smith, Aleksandra Sobieska, Naiming Chen, Constance Alabert, Hakan Bilen, Sara C.B. Buonomo (Lead / Corresponding author)

Molecular Cell and Developmental Biology

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Abstract

In eukaryotic cells, DNA replication is organised both spatially and temporally, as evidenced by the stage-specific spatial distribution of replication foci in the nucleus. Despite the genetic association of aberrant DNA replication with numerous human diseases, the labour-intensive methods employed to study DNA replication have hindered large-scale analyses of its roles in pathological processes. In this study, we employ two distinct methodologies. We first apply supervised machine learning, successfully classifying S-phase patterns in wild-type mouse embryonic stem cells (mESCs), while additionally identifying altered replication dynamics in Rif1-deficient mESCs. Given the constraints imposed by a classification-based approach, we then develop an unsupervised method for large-scale detection of aberrant S-phase cells. Such a method, which does not aim to classify patterns based on pre-defined categories but rather detects differences autonomously, closely recapitulates expected differences across genotypes. We therefore extend our approach to a well-characterised cellular model of inducible deregulated origin firing, involving cyclin E overexpression. Through parallel EdU- and PCNA-based analyses, we demonstrate the potential applicability of our method to patient samples, offering a means to identify the contribution of deregulated DNA replication to a plethora of pathogenic processes.

Original language	English
Article number	311
Number of pages	12
Journal	Communications Biology
Volume	8
Issue number	1
Early online date	26 Feb 2025
DOIs	https://doi.org/10.1038/s42003-025-07744-2
Publication status	E-pub ahead of print - 26 Feb 2025

ASJC Scopus subject areas

Medicine (miscellaneous)
General Biochemistry,Genetics and Molecular Biology
General Agricultural and Biological Sciences

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Final published version, 3.14 MBLicence: CC BY

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title = "Supervised and unsupervised deep learning-based approaches for studying DNA replication spatiotemporal dynamics",

abstract = "In eukaryotic cells, DNA replication is organised both spatially and temporally, as evidenced by the stage-specific spatial distribution of replication foci in the nucleus. Despite the genetic association of aberrant DNA replication with numerous human diseases, the labour-intensive methods employed to study DNA replication have hindered large-scale analyses of its roles in pathological processes. In this study, we employ two distinct methodologies. We first apply supervised machine learning, successfully classifying S-phase patterns in wild-type mouse embryonic stem cells (mESCs), while additionally identifying altered replication dynamics in Rif1-deficient mESCs. Given the constraints imposed by a classification-based approach, we then develop an unsupervised method for large-scale detection of aberrant S-phase cells. Such a method, which does not aim to classify patterns based on pre-defined categories but rather detects differences autonomously, closely recapitulates expected differences across genotypes. We therefore extend our approach to a well-characterised cellular model of inducible deregulated origin firing, involving cyclin E overexpression. Through parallel EdU- and PCNA-based analyses, we demonstrate the potential applicability of our method to patient samples, offering a means to identify the contribution of deregulated DNA replication to a plethora of pathogenic processes.",

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AU - Chen, Naiming

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AU - Buonomo, Sara C.B.

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AB - In eukaryotic cells, DNA replication is organised both spatially and temporally, as evidenced by the stage-specific spatial distribution of replication foci in the nucleus. Despite the genetic association of aberrant DNA replication with numerous human diseases, the labour-intensive methods employed to study DNA replication have hindered large-scale analyses of its roles in pathological processes. In this study, we employ two distinct methodologies. We first apply supervised machine learning, successfully classifying S-phase patterns in wild-type mouse embryonic stem cells (mESCs), while additionally identifying altered replication dynamics in Rif1-deficient mESCs. Given the constraints imposed by a classification-based approach, we then develop an unsupervised method for large-scale detection of aberrant S-phase cells. Such a method, which does not aim to classify patterns based on pre-defined categories but rather detects differences autonomously, closely recapitulates expected differences across genotypes. We therefore extend our approach to a well-characterised cellular model of inducible deregulated origin firing, involving cyclin E overexpression. Through parallel EdU- and PCNA-based analyses, we demonstrate the potential applicability of our method to patient samples, offering a means to identify the contribution of deregulated DNA replication to a plethora of pathogenic processes.

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Supervised and unsupervised deep learning-based approaches for studying DNA replication spatiotemporal dynamics

Abstract

ASJC Scopus subject areas

UN SDGs

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