Protein co-expression network analysis (ProCoNA).

David L Gibbs, Arie Baratt, Ralph S Baric, Yoshihiro Kawaoka, Richard D Smith, Eric S Orwoll, Michael G Katze, Shannon K McWeeney
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引用次数: 31

Abstract

Background: Biological networks are important for elucidating disease etiology due to their ability to model complex high dimensional data and biological systems. Proteomics provides a critical data source for such models, but currently lacks robust de novo methods for network construction, which could bring important insights in systems biology.

Results: We have evaluated the construction of network models using methods derived from weighted gene co-expression network analysis (WGCNA). We show that approximately scale-free peptide networks, composed of statistically significant modules, are feasible and biologically meaningful using two mouse lung experiments and one human plasma experiment. Within each network, peptides derived from the same protein are shown to have a statistically higher topological overlap and concordance in abundance, which is potentially important for inferring protein abundance. The module representatives, called eigenpeptides, correlate significantly with biological phenotypes. Furthermore, within modules, we find significant enrichment for biological function and known interactions (gene ontology and protein-protein interactions).

Conclusions: Biological networks are important tools in the analysis of complex systems. In this paper we evaluate the application of weighted co-expression network analysis to quantitative proteomics data. Protein co-expression networks allow novel approaches for biological interpretation, quality control, inference of protein abundance, a framework for potentially resolving degenerate peptide-protein mappings, and a biomarker signature discovery.

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蛋白共表达网络分析(ProCoNA)
背景:由于生物网络能够模拟复杂的高维数据和生物系统,因此对阐明疾病病因学非常重要。蛋白质组学为这些模型提供了一个重要的数据源,但目前缺乏强大的从头构建网络的方法,这可能会给系统生物学带来重要的见解。结果:我们使用加权基因共表达网络分析(WGCNA)衍生的方法评估了网络模型的构建。我们通过两个小鼠肺实验和一个人体血浆实验证明,由统计显著模块组成的近似无标度肽网络是可行的,并且具有生物学意义。在每个网络中,来自相同蛋白质的肽在统计上具有更高的拓扑重叠和一致性,这对于推断蛋白质丰度具有潜在的重要意义。模块代表,称为特征肽,与生物表型显著相关。此外,在模块内,我们发现生物功能和已知相互作用(基因本体和蛋白质-蛋白质相互作用)显著丰富。结论:生物网络是分析复杂系统的重要工具。本文评估了加权共表达网络分析在定量蛋白质组学数据中的应用。蛋白质共表达网络为生物学解释、质量控制、蛋白质丰度推断、潜在解决退化肽-蛋白质映射的框架和生物标志物签名发现提供了新的方法。
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