IMATAC imputes single-cell ATAC-seq data by deep hierarchical network with denoising autoencoder

Abstract Single-cell ATAC-seq (scATAC-seq) technology allows the interrogation of chromatin accessibility of individual cells. Dropout events occur while the sequencing data signals at some bona fide chromatin sites of individuals are not captured, and the curse of these dropouts in scATAC-seq data...

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Vydané v:	Briefings in bioinformatics Ročník 26; číslo 5
Hlavní autori:	Li, Yao, Lyu, Hongqiang, Li, Kexin, Liu, Yuan, Zhang, Xinman, Liu, Ze, Jing, Pengcheng, Han, Peng
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	England Oxford University Press 01.09.2025 Oxford Publishing Limited (England)
Predmet:	Algorithms Autoencoder Chromatin Chromatin Immunoprecipitation Sequencing - methods Clustering Comparative analysis Computational Biology - methods Humans Interrogation Noise reduction Single-Cell Analysis - methods Software hierarchical network denoising autoencoder single-cell ATAC-seq imputation
ISSN:	1467-5463, 1477-4054, 1477-4054
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Shrnutí:	Abstract Single-cell ATAC-seq (scATAC-seq) technology allows the interrogation of chromatin accessibility of individual cells. Dropout events occur while the sequencing data signals at some bona fide chromatin sites of individuals are not captured, and the curse of these dropouts in scATAC-seq data inevitably hinders downstream analysis. It remains a challenge to impute scATAC-seq data due to its high dimensionality, sparsity, and near-binarization properties. Herein, we propose IMATAC, a deep hierarchical network with denoising autoencoder for imputing scATAC-seq data in the form of peak by cell. The network embeds scATAC-seq data into a latent space by a deep hierarchical architecture at two different levels, including bottom level for local details and top level for global information, that helps to characterize the high-dimensional sparse scATAC-seq data. Besides, it is encouraged to learn to reconstruct the original scATAC-seq data from an artificially corrupted version through a denoising autoencoder, so as to acquire an ability to recover the missing values primarily relying on the cells under the same population with the help of a parallel multi-classifier. Using simulated and experimental data, the performance of IMATAC is demonstrated by a comparative analysis with the other competing methods. The results suggest that our method can achieve lower imputation errors, and benefit the downstream analysis, including heterogeneous clustering, differential analysis, and regulatory element discovery. Besides, the contributions of several important network modules in our IMATAC are investigated, and how well it can separate the dropout zeros from biological zeros are discussed.
Bibliografia:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 content type line 23
ISSN:	1467-5463 1477-4054 1477-4054
DOI:	10.1093/bib/bbaf515