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慢性气道炎症性疾病中的转录后基因调控网络:气道上皮中RNA结合蛋白表达图谱

Posttranscriptional Gene Regulatory Networks in Chronic Airway Inflammatory Diseases: Mapping of RNA-Binding Protein Expression in Airway Epithelium.

作者信息

Ricciardi Luca, Giurato Giorgio, Memoli Domenico, Pietrafesa Mariagrazia, Dal Col Jessica, Salvato Ilaria, Nigro Annunziata, Vatrella Alessandro, Caramori Gaetano, Casolaro Vincenzo, Stellato Cristiana

机构信息

Department of Medicine, Surgery and Dentistry Scuola Medica Salernitana, University of Salerno, Salerno, Italy.

Pulmonology, Department of Biomedical Sciences, Dentistry and Morphological and Functional Imaging (BIOMORF), University of Messina, Messina, Italy.

出版信息

Front Immunol. 2020 Oct 16;11:579889. doi: 10.3389/fimmu.2020.579889. eCollection 2020.

DOI:10.3389/fimmu.2020.579889
PMID:33178205
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7596416/
Abstract

Posttranscriptional gene regulation (PTGR) contributes to inflammation through alterations in messenger RNA (mRNA) turnover and translation rates. RNA-binding proteins (RBPs) coordinate these processes but their role in lung inflammatory diseases is ill-defined. We evaluated the expression of a curated list of mRNA-binding RBPs (mRBPs) in selected Gene Expression Omnibus (GEO) transcriptomic databases of airway epithelium isolated from chronic obstructive pulmonary disease (COPD), severe asthma (SA) and matched control subjects, hypothesizing that global changes in mRBPs expression could be used to infer their pathogenetic roles and identify novel disease-related regulatory networks. A published list of 692 mRBPs [Nat Rev Genet 2014] was searched in GEO datasets originated from bronchial brushings of stable COPD patients (C), smokers (S), non-smokers (NS) controls with normal lung function ( = 6/12/12) (GEO ID: GSE5058) and of (SA) and healthy control (HC) ( = 6/12) (GSE63142). Fluorescence intensity data were extracted and normalized on the medians for fold change (FC) comparisons. FCs were set at ≥ |1.5| with a false discovery rate (FDR) of ≤ 0.05. Pearson correlation maps and heatmaps were generated using tMEV tools v4_9_0.45. DNA sequence motifs were searched using PScan-ChIP. Gene Ontology (GO) was performed with Ingenuity Pathway Analysis (IPA) tool. Significant mRBP expression changes were detected for S/NS, COPD/NS and COPD/S ( = 41, 391, 382, respectively). Of those, 32% of genes changed by FC ≥ |1.5| in S/NS but more than 60% in COPD/NS and COPD/S ( = 13, 267, 257, respectively). Genes were predominantly downregulated in COPD/NS ( = 194, 73%) and COPD/S ( = 202, 79%), less so in S/NS ( = 4, 31%). Unsupervised cluster analysis identified in 4 out of 12 S the same mRBP pattern seen in C, postulating subclinical COPD. Significant DNA motifs enrichment for transcriptional regulation was found for downregulated RBPs. Correlation analysis identified five clusters of co-expressed mRBPs. GO analysis revealed significant enrichments in canonical pathways both specific and shared among comparisons. Unexpectedly, no significant mRBPs modulation was found in SA compared to controls. Airway epithelial mRBPs profiling reveals a COPD-specific global downregulation of RBPs shared by a subset of control smokers, the potential of functional cooperation by coexpressed RBPs and significant impact on relevant pathogenetic pathways in COPD. Elucidation of PTGR in COPD could identify disease biomarkers or pathways for therapeutic targeting.

摘要

转录后基因调控(PTGR)通过信使核糖核酸(mRNA)周转和翻译速率的改变促进炎症反应。RNA结合蛋白(RBP)协调这些过程,但其在肺部炎症性疾病中的作用尚不明确。我们在从慢性阻塞性肺疾病(COPD)、重度哮喘(SA)患者及匹配的对照受试者中分离出的气道上皮的选定基因表达综合数据库(GEO)中评估了一组经过整理的mRNA结合RBP(mRBP)的表达情况,假设mRBP表达的整体变化可用于推断其致病作用并识别新的疾病相关调控网络。在源自稳定期COPD患者(C)、吸烟者(S)、肺功能正常的非吸烟者(NS)对照(每组n = 6/12/12)(GEO编号:GSE5058)以及SA患者和健康对照(HC)(每组n = 6/12)(GSE63142)的支气管刷检样本的GEO数据集中搜索了一份已发表的692个mRBP列表[《自然综述:遗传学》2014年]。提取荧光强度数据并以中位数进行标准化以进行倍数变化(FC)比较。FC设定为≥|1.5|,错误发现率(FDR)≤0.05。使用tMEV工具v4_9_0.45生成Pearson相关图和热图。使用PScan - ChIP搜索DNA序列基序。使用Ingenuity通路分析(IPA)工具进行基因本体(GO)分析。在S/NS、COPD/NS和COPD/S组中分别检测到41、391和382个mRBP表达有显著变化。其中,在S/NS组中FC≥|1.5|时基因变化的比例为32%,而在COPD/NS和COPD/S组中超过60%(分别为13、267和257个)。基因在COPD/NS组(194个,73%)和COPD/S组(202个,79%)中主要下调,在S/NS组中较少(4个,31%)。无监督聚类分析在12名吸烟者中有4名呈现出与对照组相同的mRBP模式,推测为亚临床COPD。发现下调的RBP在转录调控方面有显著的DNA基序富集。相关分析确定了五个共表达mRBP的聚类。GO分析揭示了在比较中特定和共有的经典通路均有显著富集。出乎意料的是,与对照组相比,SA组中未发现mRBP有显著调节。气道上皮mRBP谱分析揭示了一部分对照吸烟者所共有的RBP在COPD中存在特异性的整体下调,共表达RBP存在功能合作的潜力以及对COPD相关致病途径有显著影响。阐明COPD中的PTGR可能会识别出疾病生物标志物或治疗靶点的途径。

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2
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3
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4
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5
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Int J Mol Sci. 2021 Nov 4;22(21):11963. doi: 10.3390/ijms222111963.
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4
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5
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