通过机器学习方法识别人类卵母细胞衰老的诊断基因和 miRNA-mRNA-TF 调控网络。

IF 3.2 3区 医学 Q2 GENETICS & HEREDITY
Xi Luo, Mingming Liang, Dandan Zhang, Ben Huang
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引用次数: 0

摘要

目的:卵母细胞老化是导致老年妇女生育不良后果的一个重要因素。然而,卵母细胞衰老的发病机制仍不清楚。本研究旨在通过生物信息学方法确定参与卵母细胞衰老的枢纽基因:方法:从 GEO 数据库中获得卵母细胞衰老数据集 GSE155179 和 GSE158802,并将其作为训练集进行分析。然后将 GSE164371 数据集定义为验证集。差异表达基因通过 limma 软件包和加权基因共表达网络分析进行分析,并与细胞衰老数据库中的细胞衰老相关基因进行交叉。通过支持向量机递归特征消除、随机森林、最小绝对收缩和选择算子逻辑等三种机器学习算法确定了中心基因,并通过验证集进行了确认。最后,通过微RNA-mRNA-转录因子调控网络和单基因基因组富集分析,阐明了卵母细胞衰老的发病机制:结果:在 GSE155179 和 GSE158802 中构建了一个包含 124 个 mRNA、31 个长非编码 RNA 和 31 个 miRNA 的竞争性内源 RNA 网络。其中有两个包含 814 个基因的模块被认为是卵母细胞衰老的关键模块。随后,PDIK1L、SIRT1和MCU被确定为枢纽基因;在这些枢纽基因的基础上,最终构建了一个包含8个miRNA、3个mRNA和227个TF的卵母细胞衰老调控网络:这项研究有助于加深对卵母细胞衰老的理解,并有助于开发治疗方法,改善老年妇女的生殖结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Identification of diagnostic genes and the miRNA‒mRNA‒TF regulatory network in human oocyte aging via machine learning methods.

Purpose: Oocyte aging is a significant factor in the negative reproductive outcomes of older women. However, the pathogenesis of oocyte aging remains unclear. This study aimed to identify the hub genes involved in oocyte aging via bioinformatics methods.

Methods: The oocyte aging datasets GSE155179 and GSE158802 were obtained from the GEO database and analyzed as the training set. The GSE164371 dataset was then defined as the validation set. Differentially expressed genes were analyzed via the limma package and weighted gene coexpression network analysis, and intersected with cellular senescence-associated genes from the Cell Senescence database. The hub genes were identified via three machine learning algorithms, namely, support vector machine recursive feature elimination, random forest, and least absolute shrinkage and selection operator logistic, which were also confirmed via the validation set. Finally, a microRNA-mRNA‒transcription factor regulatory network and single-gene gene set enrichment analysis were performed to clarify the pathogenesis of oocyte aging.

Results: A competing endogenous RNA network of GSE155179 and GSE158802 with 124 mRNAs, 31 long noncoding RNAs, and 31 miRNAs was constructed. Two modules with 814 genes were considered the key modules of oocyte aging. PDIK1L, SIRT1, and MCU were subsequently identified as hub genes; on the basis of these hub genes, a regulatory network of oocyte aging with 8 miRNAs, 3 mRNAs, and 227 TFs was ultimately constructed.

Conclusions: This study contributes to a deeper understanding of oocyte aging and may aid in the development of therapeutic approaches to improve reproductive outcomes in older women.

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来源期刊
CiteScore
5.70
自引率
9.70%
发文量
286
审稿时长
1 months
期刊介绍: The Journal of Assisted Reproduction and Genetics publishes cellular, molecular, genetic, and epigenetic discoveries advancing our understanding of the biology and underlying mechanisms from gametogenesis to offspring health. Special emphasis is placed on the practice and evolution of assisted reproduction technologies (ARTs) with reference to the diagnosis and management of diseases affecting fertility. Our goal is to educate our readership in the translation of basic and clinical discoveries made from human or relevant animal models to the safe and efficacious practice of human ARTs. The scientific rigor and ethical standards embraced by the JARG editorial team ensures a broad international base of expertise guiding the marriage of contemporary clinical research paradigms with basic science discovery. JARG publishes original papers, minireviews, case reports, and opinion pieces often combined into special topic issues that will educate clinicians and scientists with interests in the mechanisms of human development that bear on the treatment of infertility and emerging innovations in human ARTs. The guiding principles of male and female reproductive health impacting pre- and post-conceptional viability and developmental potential are emphasized within the purview of human reproductive health in current and future generations of our species. The journal is published in cooperation with the American Society for Reproductive Medicine, an organization of more than 8,000 physicians, researchers, nurses, technicians and other professionals dedicated to advancing knowledge and expertise in reproductive biology.
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