Identification of hub genes and key pathways in arsenic-treated rice (Oryza sativa L.) based on 9 topological analysis methods of CytoHubba.

IF 4 3区医学 Q1 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH

Environmental Health and Preventive Medicine Pub Date : 2024-01-01 DOI:10.1265/ehpm.24-00095

Zhen Yu, Rongxuan Wang, Tian Dai, Yuan Guo, Zanxuan Tian, Yuanyuan Zhu, Juan Chen, Yongjian Yu

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引用次数: 0

Abstract

Background: Arsenic is a toxic metalloid that can cause acute and chronic adverse health problems. Unfortunately, rice, the primary staple food for more than half of the world's population, is generally regarded as a typical arsenic-accumulating crop plant. Evidence indicates that arsenic stress can influence the growth and development of the rice plant, and lead to high concentrations of arsenic in rice grain. But the underlying mechanisms remain unclear.

Methods: In the present research, the possible molecules and pathways involved in rice roots in response to arsenic stress were explored using bioinformatics methods. Datasets that involving arsenic-treated rice root and the "study type" that was restricted to "Expression profiling by array" were selected and downloaded from Gene Expression Omnibus (GEO) database. Differentially expressed genes (DEGs) between the arsenic-treated group and the control group were obtained using the online web tool GEO2R. Gene Ontology (GO) function and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis were performed to investigate the functions of DEGs. The protein-protein interactions (PPI) network and the molecular complex detection algorithm (MCODE) of DEGs were analyzed using STRING and Cystoscope, respectively. Important nodes and hub genes in the PPI network were predicted and explored using the Cytoscape-cytoHubba plug-in.

Results: Two datasets, GSE25206 and GSE71492, were downloaded from Gene Expression Omnibus (GEO) database. Eighty common DEGs from the two datasets, including sixty-three up-regulated and seventeen down-regulated genes, were then selected. After functional enrichment analysis, these common DEGs were enriched mainly in 10 GO items, including glutathione transferase activity, glutathione metabolic process, toxin catabolic process, and 7 KEGG pathways related to metabolism. After PPI network and MCODE analysis, 49 nodes from the DEGs PPI network were identified, filtering two significant modules. Next, the Cytoscape-cytoHubba plug-in was used to predict important nodes and hub genes. Finally, five genes [Os01g0644000, PRDX6 (Os07g0638400), PRX112 (Os07g0677300), ENO1(Os06g0136600), LOGL9 (Os09g0547500)] were verified and could serve as the best candidates associated with rice root in response to arsenic stress.

Conclusions: In summary, we elucidated the potential pathways and genes in rice root in response to arsenic stress through a comprehensive bioinformatics analysis.

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基于CytoHubba的9种拓扑分析方法鉴定砷处理水稻（Oryza sativa L.）的枢纽基因和关键通路。

背景：砷是一种有毒的类金属，可导致急性和慢性的不良健康问题。遗憾的是，作为世界上一半以上人口的主要主食，水稻被普遍认为是一种典型的砷累积作物。有证据表明，砷胁迫会影响水稻植株的生长和发育，并导致水稻籽粒中砷浓度升高。但其潜在机制仍不清楚：本研究利用生物信息学方法探讨了水稻根系对砷胁迫反应可能涉及的分子和途径。从基因表达总库（Gene Expression Omnibus，GEO）数据库中选择并下载了涉及砷处理水稻根的数据集，且 "研究类型 "仅限于 "阵列表达谱分析"。利用在线网络工具 GEO2R 获得砷处理组与对照组之间的差异表达基因（DEGs）。通过基因本体（GO）功能和京都基因组百科全书（KEGG）通路富集分析来研究 DEGs 的功能。利用 STRING 和 Cystoscope 分别分析了 DEGs 的蛋白-蛋白相互作用（PPI）网络和分子复合物检测算法（MCODE）。使用Cytoscape-cytoHubba插件预测和探索了PPI网络中的重要节点和枢纽基因：从基因表达总库（GEO）数据库下载了两个数据集：GSE25206和GSE71492。然后从这两个数据集中筛选出80个常见的DEGs，包括63个上调基因和17个下调基因。经过功能富集分析，这些常见的 DEGs 主要富集在 10 个 GO 项目中，包括谷胱甘肽转移酶活性、谷胱甘肽代谢过程、毒素分解过程以及与代谢相关的 7 个 KEGG 通路。经过PPI网络和MCODE分析，从DEGs PPI网络中确定了49个节点，筛选出两个重要模块。接下来，Cytoscape-cytoHubba插件被用来预测重要节点和枢纽基因。最后，5个基因[Os01g0644000、PRDX6（Os07g0638400）、PRX112（Os07g0677300）、ENO1（Os06g0136600）、LOGL9（Os09g0547500）]得到验证，可作为与水稻根应对砷胁迫相关的最佳候选基因：综上所述，我们通过全面的生物信息学分析，阐明了水稻根应对砷胁迫的潜在通路和基因。

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

Environmental Health and Preventive Medicine PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH -

CiteScore

7.90

自引率

2.10%

发文量

审稿时长

10 weeks

期刊介绍： The official journal of the Japanese Society for Hygiene, Environmental Health and Preventive Medicine (EHPM) brings a comprehensive approach to prevention and environmental health related to medical, biological, molecular biological, genetic, physical, psychosocial, chemical, and other environmental factors. Environmental Health and Preventive Medicine features definitive studies on human health sciences and provides comprehensive and unique information to a worldwide readership.