Xin Xudong, Zhou Haidong, Huang Song, Zhang Wenzhao, Xu Jiahou, Wang Wei, Wei Jihua, Li Liqing
Affiliated Hospital of Youjiang Medical University for Nationalities, Baise, Guangxi, China.
Guangxi Zhuang Autonomous Region Engineering Research Center for Biomaterials in Bone and Joint Degenerative Diseases, Baise, Guangxi, China.
Front Pharmacol. 2025 May 23;16:1561179. doi: 10.3389/fphar.2025.1561179. eCollection 2025.
This study aims to investigate the molecular mechanisms by which quercetin facilitates the treatment of diabetic foot ulcers (DFU).
Transcriptome sequencing datasets for DFU, specifically GSE80178, GSE134431, and GSE147890, along with single-cell dataset GSE165816, were retrieved from the Gene Expression Omnibus (GEO) online database (https://www.ncbi.nlm.nih.gov/geo/). The single-cell data were subjected to processing, annotation, differential gene expression analysis, and staining. The transcriptome sequencing data were analyzed using weighted gene co-expression network analysis (WGCNA), followed by assessment of immune infiltration. By integrating transcriptomic data and differentially expressed genes identified through WGCNA, co-expressed differentially expressed genes were obtained, and a protein-protein interaction (PPI) network was constructed followed by enrichment analysis. Core genes were screened using four machine learning models (Random Forest, Lasso, XGBoost, and SVM). Drug prediction was performed to identify potential therapeutic agents, and molecular docking simulations were conducted to assess the binding interactions between the macromolecular proteins encoded by the core genes and quercetin. A rat model of diabetic foot ulcer (DFU) was established and randomly divided into three groups: control, model, and treatment groups. Tissue samples were collected at 3, 7, and 14 days post-intervention for RT-qPCR, hematoxylin and eosin (H&E) staining, Masson's trichrome staining, and immunofluorescence staining to evaluate the therapeutic effects of quercetin via modulation of the core genes on DFU.
The analysis identified 275 differentially co-expressed genes that are extensively involved in the IL-17 signaling pathway, metabolic pathways, the PI3K/Akt signaling pathway, infection, complement and coagulation cascades, among others. From these, four core genes (CIB2, SAMHD1, DPYSL2, IFI44) were selected using machine learning techniques. Immune infiltration analysis demonstrated a strong correlation between SAMHD1, IFI44, DPYSL2, and macrophages. Molecular docking studies revealed that quercetin exhibits a lower binding energy with the target protein binding site, forming a stable structure. Single-cell analysis indicated that SAMHD1 is predominantly expressed in macrophages, whereas DPYSL2 is expressed not only in macrophages but also significantly in vascular endothelial cells and other cell types. This suggests that SAMHD1 and DPYSL2 may exert their effects by modulating these cells, as corroborated by basic experimental findings. The improvement in wound tissue morphology observed in the treatment group was more favorable compared to the model group. In comparison to the acute group, the gene expression profile in the model group aligned with bioinformatics predictions. Furthermore, the alterations in core gene expression following quercetin treatment were statistically significant.
Quercetin may enhance the healing of diabetic foot ulcers by modulating macrophage activity through the regulation of SAMHD1 and DPYSL2, thereby contributing to the recovery process.
本研究旨在探讨槲皮素促进糖尿病足溃疡(DFU)治疗的分子机制。
分析确定了275个差异共表达基因,这些基因广泛参与白细胞介素-17信号通路、代谢途径、磷脂酰肌醇-3激酶/蛋白激酶B(PI3K/Akt)信号通路、感染、补体和凝血级联反应等。从中使用机器学习技术选择了四个核心基因(CIB2、SAMHD1、DPYSL2、IFI44)。免疫浸润分析表明SAMHD1、IFI44、DPYSL2与巨噬细胞之间存在强相关性。分子对接研究表明,槲皮素与靶蛋白结合位点的结合能较低,形成稳定结构。单细胞分析表明,SAMHD1主要在巨噬细胞中表达,而DPYSL2不仅在巨噬细胞中表达,在血管内皮细胞和其他细胞类型中也有显著表达。这表明SAMHD1和DPYSL2可能通过调节这些细胞发挥作用,基础实验结果证实了这一点。与模型组相比,治疗组伤口组织形态的改善更明显。与急性组相比,模型组的基因表达谱与生物信息学预测一致。此外,槲皮素治疗后核心基因表达的变化具有统计学意义。
槲皮素可能通过调节SAMHD1和DPYSL2来调节巨噬细胞活性,从而促进糖尿病足溃疡的愈合,进而有助于恢复过程。
