Molecular Neuroprotection Group, Experimental Neurology Unit, Hospital Nacional de Parapléjicos (Servicio de Salud de Castilla-La Mancha) Toledo, Spain.
Departamento de Biología Experimental, Facultad de Ciencias Experimentales y de la Salud, Universidad de Jaén Jaén, Spain.
Front Cell Neurosci. 2014 Feb 25;8:53. doi: 10.3389/fncel.2014.00053. eCollection 2014.
Trauma to the spinal cord causes permanent disability to more than 180,000 people every year worldwide. The initial mechanical damage triggers a complex set of secondary events involving the neural, vascular, and immune systems that largely determine the functional outcome of the spinal cord injury (SCI). Cellular and biochemical mechanisms responsible for this secondary injury largely depend on activation and inactivation of specific gene programs. Recent studies indicate that microRNAs function as gene expression switches in key processes of the SCI. Microarray data from rodent contusion models reveal that SCI induces changes in the global microRNA expression patterns. Variations in microRNA abundance largely result from alterations in the expression of the cells at the damaged spinal cord. However, microRNA expression levels after SCI are also influenced by the infiltration of immune cells to the injury site and the death and migration of specific neural cells after injury. Evidences on the role of microRNAs in the SCI pathophysiology have come from different sources. Bioinformatic analysis of microarray data has been used to identify specific variations in microRNA expression underlying transcriptional changes in target genes, which are involved in key processes in the SCI. Direct evidences on the role of microRNAs in SCI are scarcer, although recent studies have identified several microRNAs (miR-21, miR-486, miR-20) involved in key mechanisms of the SCI such as cell death or astrogliosis, among others. From a clinical perspective, different evidences make clear that microRNAs can be potent therapeutic tools to manipulate cell state and molecular processes in order to enhance functional recovery. The present article reviews the actual knowledge on how injury affects microRNA expression and the meaning of these changes in the SCI pathophysiology, to finally explore the clinical potential of microRNAs in the SCI.
脊髓创伤每年导致全球超过 18 万人永久性残疾。初始的机械损伤引发了一系列涉及神经、血管和免疫系统的复杂二次事件,这些事件在很大程度上决定了脊髓损伤(SCI)的功能结果。负责这种二次损伤的细胞和生化机制在很大程度上取决于特定基因程序的激活和失活。最近的研究表明,microRNAs 在 SCI 的关键过程中作为基因表达开关发挥作用。来自啮齿动物挫伤模型的 microarray 数据表明,SCI 诱导了全局 microRNA 表达模式的变化。microRNA 丰度的变化主要归因于受损脊髓细胞表达的改变。然而,SCI 后 microRNA 的表达水平也受到免疫细胞浸润到损伤部位以及损伤后特定神经细胞死亡和迁移的影响。microRNAs 在 SCI 病理生理学中的作用的证据来自不同的来源。对 microarray 数据的生物信息学分析已被用于鉴定目标基因转录变化背后特定 microRNA 表达的变化,这些变化涉及 SCI 中的关键过程。尽管最近的研究已经确定了几种 microRNAs(miR-21、miR-486、miR-20)在 SCI 中的关键机制(如细胞死亡或星形胶质细胞增生等)中发挥作用,但关于 microRNAs 在 SCI 中作用的直接证据仍然较少。从临床角度来看,不同的证据表明,microRNAs 可以作为有效的治疗工具,用于操纵细胞状态和分子过程,以增强功能恢复。本文综述了损伤如何影响 microRNA 表达以及这些变化在 SCI 病理生理学中的意义的最新知识,最终探讨了 microRNAs 在 SCI 中的临床潜力。
