将量化离散化和贝叶斯网络分析应用于公开的囊性纤维化数据集。

Q2 Computer Science
Kiyoshi Ferreira Fukutani, Thomas H Hampton, Carly A Bobak, Todd A MacKenzie, Bruce A Stanton
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引用次数: 0

摘要

研究同一现象的多个公开数据集的可用性有望加速科学发现。荟萃分析可以解决可重复性问题,通常还能提高研究效率。荟萃分析的前景对于囊性纤维化(CF)等罕见疾病尤为重要,全世界约有 10 万人患有囊性纤维化。最近对美国国立卫生研究院基因表达总库的搜索显示,与癌症有关的数据集有130万个,而与囊性纤维化有关的数据集只有约2000个。这些研究非常多样化,涉及不同的组织、动物模型、治疗方法和临床协变量。在搜索原代人类气道上皮细胞的基因表达研究时,我们发现了三项方法兼容、元数据充分的研究:GSE139078、Sala Study 和 PRJEB9292。尽管如此,实验设计并不完全相同,而且我们还发现了显著的批次效应,这将使功能分析变得更加复杂。在这里,我们介绍了使用希尔爬坡法进行量化离散化和贝叶斯网络构建的方法,它是克服实验差异并揭示 CF 基因型本身、暴露于病毒、细菌和用于治疗 CF 的药物的生物相关反应的有力工具。集群剖析器揭示的功能模式包括干扰素信号传导、γ干扰素信号传导、白细胞介素4和13信号传导、白细胞介素6信号传导、白细胞介素21信号传导,以及CSF3/G-CSF信号传导通路的失活,显示出显著的变化。与非CF细胞相比,这些通路始终与CF上皮细胞中较高的基因表达相关,这表明以这些通路为靶点可改善临床疗效。量子离散化和贝叶斯网络分析在CF方面的成功表明,这些方法可能适用于其他难以找到完全可比数据集的情况。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
APPLICATION OF QUANTILE DISCRETIZATION AND BAYESIAN NETWORK ANALYSIS TO PUBLICLY AVAILABLE CYSTIC FIBROSIS DATA SETS.

The availability of multiple publicly-available datasets studying the same phenomenon has the promise of accelerating scientific discovery. Meta-analysis can address issues of reproducibility and often increase power. The promise of meta-analysis is especially germane to rarer diseases like cystic fibrosis (CF), which affects roughly 100,000 people worldwide. A recent search of the National Institute of Health's Gene Expression Omnibus revealed 1.3 million data sets related to cancer compared to about 2,000 related to CF. These studies are highly diverse, involving different tissues, animal models, treatments, and clinical covariates. In our search for gene expression studies of primary human airway epithelial cells, we identified three studies with compatible methodologies and sufficient metadata: GSE139078, Sala Study, and PRJEB9292. Even so, experimental designs were not identical, and we identified significant batch effects that would have complicated functional analysis. Here we present quantile discretization and Bayesian network construction using the Hill climb method as a powerful tool to overcome experimental differences and reveal biologically relevant responses to the CF genotype itself, exposure to virus, bacteria, and drugs used to treat CF. Functional patterns revealed by cluster Profiler included interferon signaling, interferon gamma signaling, interleukins 4 and 13 signaling, interleukin 6 signaling, interleukin 21 signaling, and inactivation of CSF3/G-CSF signaling pathways showing significant alterations. These pathways were consistently associated with higher gene expression in CF epithelial cells compared to non-CF cells, suggesting that targeting these pathways could improve clinical outcomes. The success of quantile discretization and Bayesian network analysis in the context of CF suggests that these approaches might be applicable to other contexts where exactly comparable data sets are hard to find.

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CiteScore
4.50
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