Shrinkage estimation of gene interaction networks in single-cell RNA sequencing data.

IF 2.9 3区 生物学 Q2 BIOCHEMICAL RESEARCH METHODS
Duong H T Vo, Thomas Thorne
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引用次数: 0

Abstract

Background: Gene interaction networks are graphs in which nodes represent genes and edges represent functional interactions between them. These interactions can be at multiple levels, for instance, gene regulation, protein-protein interaction, or metabolic pathways. To analyse gene interaction networks at a large scale, gene co-expression network analysis is often applied on high-throughput gene expression data such as RNA sequencing data. With the advance in sequencing technology, expression of genes can be measured in individual cells. Single-cell RNA sequencing (scRNAseq) provides insights of cellular development, differentiation and characteristics at the transcriptomic level. High sparsity and high-dimensional data structures pose challenges in scRNAseq data analysis.

Results: In this study, a sparse inverse covariance matrix estimation framework for scRNAseq data is developed to capture direct functional interactions between genes. Comparative analyses highlight high performance and fast computation of Stein-type shrinkage in high-dimensional data using simulated scRNAseq data. Data transformation approaches also show improvement in performance of shrinkage methods in non-Gaussian distributed data. Zero-inflated modelling of scRNAseq data based on a negative binomial distribution enhances shrinkage performance in zero-inflated data without interference on non zero-inflated count data.

Conclusion: The proposed framework broadens application of graphical model in scRNAseq analysis with flexibility in sparsity of count data resulting from dropout events, high performance, and fast computational time. Implementation of the framework is in a reproducible Snakemake workflow https://github.com/calathea24/ZINBGraphicalModel and R package ZINBStein https://github.com/calathea24/ZINBStein .

单细胞 RNA 测序数据中基因相互作用网络的收缩估计
背景基因相互作用网络是一种图,其中节点代表基因,边缘代表基因之间的功能相互作用。这些相互作用可以是多层次的,例如基因调控、蛋白-蛋白相互作用或代谢途径。为了大规模分析基因相互作用网络,基因共表达网络分析通常应用于高通量基因表达数据,如 RNA 测序数据。随着测序技术的进步,基因的表达可以在单个细胞中测量。单细胞 RNA 测序(scRNAseq)可从转录组水平深入了解细胞的发育、分化和特征。高稀疏性和高维数据结构给 scRNAseq 数据分析带来了挑战:本研究为 scRNAseq 数据开发了一个稀疏逆协方差矩阵估计框架,以捕捉基因之间的直接功能相互作用。使用模拟 scRNAseq 数据进行的比较分析突出表明,在高维数据中,Stein 型收缩的计算性能高且速度快。数据转换方法也显示了收缩方法在非高斯分布数据中性能的提高。基于负二项分布的 scRNAseq 数据零膨胀建模提高了零膨胀数据的收缩性能,而不会干扰非零膨胀计数数据:结论:所提出的框架扩大了图形模型在 scRNAseq 分析中的应用范围,可灵活处理因辍学事件导致的计数数据稀疏性、高性能和快速计算时间。该框架在可重现的 Snakemake 工作流 https://github.com/calathea24/ZINBGraphicalModel 和 R 软件包 ZINBStein https://github.com/calathea24/ZINBStein 中实现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
BMC Bioinformatics
BMC Bioinformatics 生物-生化研究方法
CiteScore
5.70
自引率
3.30%
发文量
506
审稿时长
4.3 months
期刊介绍: BMC Bioinformatics is an open access, peer-reviewed journal that considers articles on all aspects of the development, testing and novel application of computational and statistical methods for the modeling and analysis of all kinds of biological data, as well as other areas of computational biology. BMC Bioinformatics is part of the BMC series which publishes subject-specific journals focused on the needs of individual research communities across all areas of biology and medicine. We offer an efficient, fair and friendly peer review service, and are committed to publishing all sound science, provided that there is some advance in knowledge presented by the work.
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