Morrey Mark E, Abdel Matthew P, Riester Scott M, Dudakovic Amel, van Wijnen Andre J, Morrey Bernard F, Sanchez-Sotelo Joaquin
Department of Orthopedic Surgery and Orthopedic Biomechanics Laboratory, Mayo Clinic, Rochester, United States.
Department of Orthopedic Surgery and Orthopedic Biomechanics Laboratory, Mayo Clinic, Rochester, United States.
Gene. 2017 Apr 30;610:15-23. doi: 10.1016/j.gene.2017.01.025. Epub 2017 Feb 3.
Inflammatory changes are suspected in the pathophysiology of arthrofibrosis formation and require early molecular examination. Here, we assessed the hypothesis that early inflammatory genes are related to arthrofibrosis by ascertaining gene expression during the early stages of contracture genesis in an animal model.
Joint trauma was incited surgically in a cohort of rabbits (n=36) knees followed by immobilization in a model of contracture. Six groups of 6 rabbits were sacrificed at multiple time points (0, 6, 12, 24, 72h and 2weeks). Microarray expression and RT-qPCR profiling were performed to determine genes that are significantly up or downregulated. Bioinformatic analysis was carried out to understand which biological programs and functional groups of genes are modulated in arthrofibrosis.
Gene expression profiling revealed a large number biologically relevant genes (>100) that are either upregulated or downregulated by at least a 1.5 fold (log2) during the first two weeks after joint injury during contracture development. Gene ontology analysis identified molecular pathways and programs that act during the course of fibrosis and joint contracture. Our main finding is that the development of contractures occur concomitant with modulation of genes mediating inflammatory responses, ECM remodeling and the epithelial-to-mesenchymal transition.
The genesis of joint contracture reflects an imbalance between pro- and anti-fibrotic expression. Our study indicates that inflammatory genes may be involved in the process of contracture genesis and initiated at relatively early stages. Our findings also may inform clinical practice in the future by suggesting potential therapeutic targets in preventing the long-term development of arthrofibrosis.
关节纤维化形成的病理生理学中怀疑存在炎症变化,需要进行早期分子检查。在此,我们通过确定动物模型中挛缩发生早期阶段的基因表达,评估早期炎症基因与关节纤维化相关的假设。
对一组兔子(n = 36)的膝关节进行手术创伤,随后在挛缩模型中固定。在多个时间点(0、6、12、24、72小时和2周)处死6组每组6只兔子。进行微阵列表达和RT-qPCR分析以确定显著上调或下调的基因。进行生物信息学分析以了解在关节纤维化中哪些生物学程序和基因功能组受到调节。
基因表达谱显示大量生物学相关基因(>100个)在关节损伤后的前两周挛缩发展过程中上调或下调至少1.5倍(log2)。基因本体分析确定了在纤维化和关节挛缩过程中起作用的分子途径和程序。我们的主要发现是挛缩的发展与介导炎症反应、细胞外基质重塑和上皮-间质转化的基因调节同时发生。
关节挛缩的发生反映了促纤维化和抗纤维化表达之间的失衡。我们的研究表明炎症基因可能参与挛缩发生过程并在相对早期启动。我们的发现还可能通过提示预防关节纤维化长期发展的潜在治疗靶点,为未来的临床实践提供参考。
