Modelling cell type-specific lncRNA regulatory network in autism with Cycle.

IF 2.9 3区 生物学 Q2 BIOCHEMICAL RESEARCH METHODS
Chenchen Xiong, Mingfang Zhang, Haolin Yang, Xuemei Wei, Chunwen Zhao, Junpeng Zhang
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引用次数: 0

Abstract

Background: Autism spectrum disorder (ASD) is a class of complex neurodevelopment disorders with high genetic heterogeneity. Long non-coding RNAs (lncRNAs) are vital regulators that perform specific functions within diverse cell types and play pivotal roles in neurological diseases including ASD. Therefore, exploring lncRNA regulation would contribute to deciphering ASD molecular mechanisms. Existing computational methods utilize bulk transcriptomics data to identify lncRNA regulation in all of samples, which could reveal the commonalities of lncRNA regulation in ASD, but ignore the specificity of lncRNA regulation across various cell types.

Results: Here, we present Cycle (Cell type-specific lncRNA regulatory network) to construct the landscape of cell type-specific lncRNA regulation in ASD. We have found that each ASD cell type is unique in lncRNA regulation, and more than one-third and all cell type-specific lncRNA regulatory networks are characterized as scale-free and small-world, respectively. Across 17 ASD cell types, we have discovered 19 rewired and 11 stable modules, along with eight rewired and three stable hubs within the constructed cell type-specific lncRNA regulatory networks. Enrichment analysis reveals that the discovered rewired and stable modules and hubs are closely related to ASD. Furthermore, more similar ASD cell types tend to be connected with higher strength in the constructed cell similarity network. Finally, the comparison results demonstrate that Cycle is a potential method for uncovering cell type-specific lncRNA regulation.

Conclusion: Overall, these results illustrate that Cycle is a promising method to model the landscape of cell type-specific lncRNA regulation, and provides insights into understanding the heterogeneity of lncRNA regulation between various ASD cell types.

自闭症细胞类型特异性 lncRNA 调控网络建模。
背景:自闭症谱系障碍(ASD)是一类具有高度遗传异质性的复杂神经发育障碍。长非编码 RNA(lncRNA)是在不同细胞类型中发挥特定功能的重要调控因子,在包括 ASD 在内的神经系统疾病中发挥着关键作用。因此,探索 lncRNA 的调控有助于破译 ASD 的分子机制。现有的计算方法利用大容量转录组学数据来识别所有样本中的lncRNA调控,可以揭示ASD中lncRNA调控的共性,但忽略了lncRNA在不同细胞类型中调控的特异性:在此,我们提出了Cycle(细胞类型特异性lncRNA调控网络)来构建ASD中细胞类型特异性lncRNA调控的格局。我们发现,每种ASD细胞类型在lncRNA调控方面都是独特的,超过三分之一的细胞类型特异性lncRNA调控网络和所有细胞类型特异性lncRNA调控网络分别具有无标度和小世界的特征。在17种ASD细胞类型中,我们在构建的细胞类型特异性lncRNA调控网络中发现了19个重联模块和11个稳定模块,以及8个重联枢纽和3个稳定枢纽。富集分析表明,所发现的重配和稳定模块及中枢与ASD密切相关。此外,在构建的细胞相似性网络中,更多相似的ASD细胞类型往往以更高的强度连接在一起。最后,比较结果表明,Cycle 是一种揭示细胞类型特异性 lncRNA 调控的潜在方法:总之,这些结果表明,Cycle是一种很有前途的方法,可用于模拟细胞类型特异性lncRNA调控的景观,并为理解不同ASD细胞类型之间lncRNA调控的异质性提供了见解。
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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