Liu Hong, Ji Ming, Yang Tao, Zou Shihua, Qiu Xingan, Zhan Fangbiao, Chen Jian, Yan Fei, Ding Fan, Li Ping
Department of Orthopedics, Chongqing University Three Gorges Hospital, Chongqing, People's Republic of China.
Chongqing Municipality Clinical Research Center for Geriatric Diseases, Chongqing, People's Republic of China.
Am J Physiol Cell Physiol. 2025 Feb 1;328(2):C679-C698. doi: 10.1152/ajpcell.00573.2024. Epub 2025 Jan 16.
This study aimed to investigate the regulation of fibroblast phenotypes by mesenchymal stem cells (MSCs) delivering copper sulfide (CuS) nanoparticles (NPs) loaded with CDKN1A plasmids and their role in cartilage repair during osteoarthritis (OA). Single-cell RNA sequencing data from the GEO database were analyzed to identify subpopulations within the OA immune microenvironment. Quality control, filtering, principal component analysis (PCA) dimensionality reduction, and tSNE clustering were performed to obtain detailed cell subtypes. Pseudotime analysis was used to understand the developmental trajectory of fibroblasts, and GO/KEGG enrichment analyses highlighted biological processes related to fibroblast function. Transcriptomic data and WGCNA identified CDKN1A as a key regulatory gene. A biomimetic CuS@CDKN1A nanosystem was constructed and loaded into MSCs to create MSCs@CuS@CDKN1A. The characterization of this system confirmed its efficient cellular uptake by fibroblasts. In vitro experiments demonstrated that MSCs@CuS@CDKN1A significantly modulated fibroblast phenotypes and improved the structure, proliferation, reduced apoptosis, and enhanced migration of IL-1β-stimulated chondrocytes. In vivo, an OA mouse model was treated with intra-articular injections of MSCs@CuS@CDKN1A. Micro-CT scans revealed a significant reduction in osteophyte formation and improved joint space compared with control groups. Histological analysis, including H&E, Safranin O-Fast Green, and toluidine blue staining, confirmed improved cartilage integrity, whereas the International Osteoarthritis Research Society (OARSI) scoring indicated reduced disease severity. Immunofluorescence showed upregulated CDKN1A expression, decreased MMP13, and reduced α-SMA expression in fibroblast subtypes. Major organs exhibited no signs of toxicity, confirming the biocompatibility and safety of the treatment. These findings suggest that MSCs@CuS@CDKN1A can effectively regulate fibroblast activity and promote cartilage repair, providing a promising therapeutic strategy for OA treatment. This study introduces MSCs@CuS@CDKN1A, a nanoengineered MSC platform that targets fibroblast phenotypes in osteoarthritis (OA). By modulating CDKN1A expression, this innovative approach not only enhances cartilage repair but also effectively mitigates fibroblast-driven inflammation, marking a significant advancement in OA therapeutics with demonstrated efficacy and biocompatibility.
本研究旨在探讨间充质干细胞(MSCs)递送负载CDKN1A质粒的硫化铜(CuS)纳米颗粒(NPs)对成纤维细胞表型的调控及其在骨关节炎(OA)软骨修复中的作用。分析来自GEO数据库的单细胞RNA测序数据,以鉴定OA免疫微环境中的亚群。进行质量控制、过滤、主成分分析(PCA)降维和tSNE聚类,以获得详细的细胞亚型。使用伪时间分析来了解成纤维细胞的发育轨迹,GO/KEGG富集分析突出了与成纤维细胞功能相关的生物学过程。转录组数据和WGCNA将CDKN1A鉴定为关键调控基因。构建了一种仿生CuS@CDKN1A纳米系统,并将其加载到MSCs中以创建MSCs@CuS@CDKN1A。该系统的表征证实了其能被成纤维细胞有效摄取。体外实验表明,MSCs@CuS@CDKN1A显著调节成纤维细胞表型,并改善了白细胞介素-1β刺激的软骨细胞的结构、增殖、减少凋亡和增强迁移。在体内,用关节内注射MSCs@CuS@CDKN1A治疗OA小鼠模型。与对照组相比,显微CT扫描显示骨赘形成显著减少,关节间隙改善。组织学分析,包括苏木精-伊红(H&E)、番红O-固绿和甲苯胺蓝染色,证实软骨完整性得到改善,而国际骨关节炎研究学会(OARSI)评分表明疾病严重程度降低。免疫荧光显示成纤维细胞亚型中CDKN1A表达上调、基质金属蛋白酶13(MMP13)减少和α-平滑肌肌动蛋白(α-SMA)表达降低。主要器官未表现出毒性迹象,证实了该治疗方法的生物相容性和安全性。这些发现表明,MSCs@CuS@CDKN1A可以有效调节成纤维细胞活性并促进软骨修复,为OA治疗提供了一种有前景的治疗策略。本研究介绍了MSCs@CuS@CDKN1A,这是一种针对骨关节炎(OA)中成纤维细胞表型的纳米工程化MSC平台。通过调节CDKN1A表达,这种创新方法不仅增强了软骨修复,还有效减轻了成纤维细胞驱动的炎症,标志着OA治疗学的重大进展,具有已证实的疗效和生物相容性。
