[Single-cell transcriptomic sequencing coupled with Mendelian randomization analysis elucidates the pivotal role of CTSC in chronic rhinosinusitis].

S C Zhou, J Lai, K Fan, J W Li, X Y Xu, C Y Yao, B J Long, C L Zhao, N Che, Y Y Gao, S Q Yu
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引用次数: 0

Abstract

Objective: To investigate the molecular mechanisms of chronic rhinosinusitis (CRS), to identify key cell subgroups and genes, to construct effective diagnostic models, and to screen for potential therapeutic drugs. Methods: Key cell subgroups in CRS were identified through single-cell transcriptomic sequencing data. Essential genes associated with CRS were selected and diagnostic models were constructed by hdWGCNA (high dimensional weighted gene co-expression network analysis) and various machine learning algorithms. Causal inference analysis was performed using Mendelian randomization and colocalization analysis. Potential therapeutic drugs were identified using molecular docking technology, and the results of bioinformatics analysis were validated by immunofluorescence staining. Graphpad Prism, R, Python, and Adobe Illustrator software were used for data and image processing. Results: An increased proportion of basal and suprabasal cells was observed in CRS, especially in eosinophilic CRS with nasal polyps (ECRSwNP), with P=0.001. hdWGCNA revealed that the "yellow module" was closely related to basal and suprabasal cells in CRS. Univariate logistic regression and LASSO algorithm selected 13 key genes (CTSC, LAMB3, CYP2S1, TRPV4, ARHGAP21, PTHLH, CDH26, MRPS6, TENM4, FAM110C, NCKAP5, SAMD3, and PTCHD4). Based on these 13 genes, an effective CRS diagnostic model was developed using various machine learning algorithms (AUC=0.958). Mendelian randomization analysis indicated a causal relationship between CTSC and CRS (inverse variance weighted: OR=1.06, P=0.006), and colocalization analysis confirmed shared genetic variants between CTSC and CRS (PPH4/PPH3>2). Molecular docking results showed that acetaminophen binded well with CTSC (binding energy:-5.638 kcal/mol). Immunofluorescence staining experiments indicated an increase in CTSC+cells in CRS. Conclusion: This study integrates various bioinformatics methods to identify key cell types and genes in CRS, constructs an effective diagnostic model, underscores the critical role of the CTSC gene in CRS pathogenesis, and provides new targets for the treatment of CRS.

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[单细胞转录组测序与孟德尔随机分析相结合,阐明了 CTSC 在慢性鼻炎中的关键作用】。]
研究目的研究慢性鼻炎(CRS)的分子机制,确定关键细胞亚群和基因,构建有效的诊断模型,筛选潜在的治疗药物。研究方法通过单细胞转录组测序数据确定 CRS 的关键细胞亚群。通过高维加权基因共表达网络分析(hdWGCNA)和各种机器学习算法,筛选出与CRS相关的重要基因并构建诊断模型。利用孟德尔随机化和共聚焦分析进行了因果推理分析。利用分子对接技术确定了潜在的治疗药物,并通过免疫荧光染色验证了生物信息学分析的结果。数据和图像处理使用了 Graphpad Prism、R、Python 和 Adobe Illustrator 软件。结果hdWGCNA显示,"黄色模块 "与CRS中的基底细胞和基底上细胞密切相关。单变量逻辑回归和 LASSO 算法选择了 13 个关键基因(CTSC、LAMB3、CYP2S1、TRPV4、ARHGAP21、PTHLH、CDH26、MRPS6、TENM4、FAM110C、NCKAP5、SAMD3 和 PTCHD4)。基于这 13 个基因,利用各种机器学习算法建立了有效的 CRS 诊断模型(AUC=0.958)。孟德尔随机化分析表明,CTSC 和 CRS 之间存在因果关系(逆方差加权:OR=1.06,P=0.006),共定位分析证实了 CTSC 和 CRS 之间存在共同的遗传变异(PPH4/PPH3>2)。分子对接结果显示,对乙酰氨基酚与CTSC结合良好(结合能:-5.638 kcal/mol)。免疫荧光染色实验表明,CRS 中的 CTSC+ 细胞有所增加。结论该研究整合了多种生物信息学方法,确定了CRS中的关键细胞类型和基因,构建了有效的诊断模型,强调了CTSC基因在CRS发病机制中的关键作用,并为CRS的治疗提供了新的靶点。
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