Identification of Disulfidptosis-Related Genes in Ischemic Stroke by Combining Single-Cell Sequencing, Machine Learning Algorithms, and In Vitro Experiments

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-09-15 DOI:10.1007/s12017-024-08804-2
Songyun Zhao, Hao Zhuang, Wei Ji, Chao Cheng, Yuankun Liu
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Abstract

Background

Ischemic stroke (IS) is a severe neurological disorder with a pathogenesis that remains incompletely understood. Recently, a novel form of cell death known as disulfidptosis has garnered significant attention in the field of ischemic stroke research. This study aims to investigate the mechanistic roles of disulfidptosis-related genes (DRGs) in the context of IS and to examine their correlation with immunopathological features.

Methods

To enhance our understanding of the mechanistic underpinnings of disulfidptosis in IS, we initially retrieved the expression profile of peripheral blood from human IS patients from the GEO database. We then utilized a suite of machine learning algorithms, including LASSO, random forest, and SVM-RFE, to identify and validate pivotal genes. Furthermore, we developed a predictive nomogram model, integrating multifactorial logistic regression analysis and calibration curves, to evaluate the risk of IS. For the analysis of single-cell sequencing data, we employed a range of analytical tools, such as "Monocle" and "CellChat," to assess the status of immune cell infiltration and to characterize intercellular communication networks. Additionally, we utilized an oxygen–glucose deprivation (OGD) model to investigate the effects of SLC7A11 overexpression on microglial polarization.

Results

This study successfully identified key genes associated with disulfidptosis and developed a reliable nomogram model using machine learning algorithms to predict the risk of ischemic stroke. Examination of single-cell sequencing data showed a robust correlation between disulfidptosis levels and the infiltration of immune cells. Furthermore, "CellChat" analysis elucidated the intricate characteristics of intercellular communication networks. Notably, the TNF signaling pathway was found to be intimately linked with the disulfidptosis signature in ischemic stroke. In an intriguing finding, the OGD model demonstrated that SLC7A11 expression suppresses M1 polarization while promoting M2 polarization in microglia.

Conclusion

The significance of our findings lies in their potential to shed light on the pathogenesis of ischemic stroke, particularly by underscoring the pivotal role of disulfidptosis-related genes (DRGs). These insights could pave the way for novel therapeutic strategies targeting DRGs to mitigate the impact of ischemic stroke.

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结合单细胞测序、机器学习算法和体外实验鉴定缺血性中风中的二硫化相关基因
背景缺血性中风(IS)是一种严重的神经系统疾病,其发病机制至今仍未完全明了。最近,一种被称为二硫化血症的新型细胞死亡形式引起了缺血性中风研究领域的极大关注。本研究旨在探讨二硫化相关基因(DRGs)在 IS 中的机理作用,并研究它们与免疫病理特征的相关性。方法为了加深对二硫化在 IS 中的机理基础的了解,我们首先从 GEO 数据库中检索了人类 IS 患者外周血的表达谱。然后,我们利用一套机器学习算法(包括 LASSO、随机森林和 SVM-RFE)来识别和验证关键基因。此外,我们还结合多因素逻辑回归分析和校准曲线建立了一个预测提名图模型,用于评估IS的风险。在分析单细胞测序数据时,我们采用了一系列分析工具,如 "Monocle "和 "CellChat",以评估免疫细胞浸润状况,并描述细胞间通讯网络的特征。此外,我们还利用氧-葡萄糖剥夺(OGD)模型研究了SLC7A11过表达对小胶质细胞极化的影响。结果这项研究成功鉴定了与二硫化相关的关键基因,并利用机器学习算法建立了一个可靠的提名图模型来预测缺血性中风的风险。对单细胞测序数据的研究表明,二硫化硫水平与免疫细胞的浸润之间存在密切的相关性。此外,"细胞聊天 "分析还阐明了细胞间通信网络错综复杂的特点。值得注意的是,研究发现 TNF 信号通路与缺血性中风的二硫化硫特征密切相关。一个有趣的发现是,OGD 模型显示 SLC7A11 的表达抑制了小胶质细胞的 M1 极化,同时促进了 M2 极化。这些见解可为针对 DRGs 的新型治疗策略铺平道路,从而减轻缺血性中风的影响。
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CiteScore
7.20
自引率
4.30%
发文量
567
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