A convolutional neural network-based regression model to infer the epigenetic crosstalk responsible for CG methylation patterns

Epigenetic modifications, including CG methylation (a major form of DNA methylation) and histone modifications, interact with each other to shape their genomic distribution patterns. However, the entire picture of the epigenetic crosstalk regulating the CG methylation pattern is unknown especially i...

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Bibliographic Details
Published in:BMC bioinformatics 2021-06, Vol.22 (1), p.1-341, Article 341
Main Authors: Au Yeung, Wan Kin, Maruyama, Osamu, Sasaki, Hiroyuki
Format: Article
Language:English
Subjects:
Analysis
Artificial neural networks
Chromosomes
Convolutional neural network
Crosstalk
Datasets
Deoxyribonucleic acid
Distribution patterns
DNA
DNA methylation
DNA sequencing
Epigenetic crosstalk
Epigenetics
Gametocytes
Gene sequencing
Health aspects
Histone modification
Histones
Learning algorithms
Machine learning
Mammals
Methylation
Neural networks
Nucleotide sequence
Nucleotide sequencing
Oocyte
Oocytes
Regression models
Stem cell
Stem cells
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Summary:Epigenetic modifications, including CG methylation (a major form of DNA methylation) and histone modifications, interact with each other to shape their genomic distribution patterns. However, the entire picture of the epigenetic crosstalk regulating the CG methylation pattern is unknown especially in cells that are available only in a limited number, such as mammalian oocytes. Most machine learning approaches developed so far aim at finding DNA sequences responsible for the CG methylation patterns and were not tailored for studying the epigenetic crosstalk. We built a machine learning model named epiNet to predict CG methylation patterns based on other epigenetic features, such as histone modifications, but not DNA sequence. Using epiNet, we identified biologically relevant epigenetic crosstalk between histone H3K36me3, H3K4me3, and CG methylation in mouse oocytes. This model also predicted the altered CG methylation pattern of mutant oocytes having perturbed histone modification, was applicable to cross-species prediction of the CG methylation pattern of human oocytes, and identified the epigenetic crosstalk potentially important in other cell types. Our findings provide insight into the epigenetic crosstalk regulating the CG methylation pattern in mammalian oocytes and other cells. The use of epiNet should help to design or complement biological experiments in epigenetics studies.
ISSN:1471-2105
1471-2105
DOI:10.1186/s12859-021-04272-8