Identification of Renal Transplantation Rejection Biomarkers in Blood Using the Systems Biology Approach.

Q2 Biochemistry, Genetics and Molecular Biology
Fatemeh Saberi, Zeinab Dehghan, Effat Noori, Hakimeh Zali
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Abstract

Background: Renal transplantation plays an essential role in the quality of life of patients with end-stage renal disease. At least 12% of the renal patients receiving transplantations show graft rejection. One of the methods used to diagnose renal transplantation rejection is renal allograft biopsy. This procedure is associated with some risks such as bleeding and arteriovenous fistula formation. In this study, we applied a bioinformatics approach to identify serum markers for graft rejection in patients receiving a renal transplantation.

Methods: Transcriptomic data were first retrieved from the blood of renal transplantation rejection patients using the GEO database. The data were then used to construct the protein-protein interaction and gene regulatory networks using Cytoscape software. Next, network analysis was performed to identify hub-bottlenecks, and key blood markers involved in renal graft rejection. Lastly, the gene ontology and functional pathways related to hub-bottlenecks were detected using PANTHER and DAVID servers.

Results: In PPIN and GRN, SYNCRIP, SQSTM1, GRAMD1A, FAM104A, ND2, TPGS2, ZNF652, RORA, and MALAT1 were the identified critical genes. In GRN, miR-155, miR17, miR146b, miR-200 family, and GATA2 were the factors that regulated critical genes. The MAPK, neurotrophin, and TNF signaling pathways, IL-17, and human cytomegalovirus infection, human papillomavirus infection, and shigellosis were identified as significant pathways involved in graft rejection.

Concusion: The above-mentioned genes can be used as diagnostic and therapeutic serum markers of transplantation rejection in renal patients. The newly predicted biomarkers and pathways require further studies.

利用系统生物学方法鉴定血液中的肾移植排斥反应生物标志物
背景:肾移植对提高终末期肾病患者的生活质量至关重要。接受移植的肾病患者中至少有 12% 出现移植排斥反应。肾移植活检是诊断肾移植排斥反应的方法之一。这种方法存在一些风险,如出血和动静脉瘘形成。在这项研究中,我们采用生物信息学方法来确定肾移植患者血清中的移植物排斥标记物:方法:首先利用 GEO 数据库从肾移植排斥反应患者的血液中检索转录组数据。然后使用 Cytoscape 软件构建蛋白质-蛋白质相互作用和基因调控网络。接着,进行网络分析,以确定肾移植排斥反应所涉及的枢纽-瓶颈和关键血液标记物。最后,利用PANTHER和DAVID服务器检测了与枢纽瓶颈相关的基因本体和功能通路:结果:在 PPIN 和 GRN 中,SYNCRIP、SQSTM1、GRAMD1A、FAM104A、ND2、TPGS2、ZNF652、RORA 和 MALAT1 是已确定的关键基因。在 GRN 中,miR-155、miR17、miR146b、miR-200 家族和 GATA2 是调控关键基因的因子。MAPK、神经营养素和 TNF 信号通路、IL-17 以及人类巨细胞病毒感染、人类乳头瘤病毒感染和志贺氏杆菌病被确定为参与移植物排斥反应的重要通路:上述基因可作为肾病患者移植排斥反应的诊断和治疗血清标志物。新预测的生物标志物和途径需要进一步研究。
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来源期刊
Iranian Biomedical Journal
Iranian Biomedical Journal Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)
CiteScore
3.20
自引率
0.00%
发文量
42
审稿时长
8 weeks
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