Indyk J A, Chen Z L, Tsirka S E, Strickland S
Department of Pharmacology, University at Stony Brook, Stony Brook, NY 11794-8651, USA.
Neuroscience. 2003;116(2):359-71. doi: 10.1016/s0306-4522(02)00704-2.
Laminins are important components of the extracellular matrix, and participate in neuronal development, survival and regeneration. The tissue plasminogen activator/plasmin extracellular protease cascade and downstream laminin degradation are implicated in excitotoxin-induced neuronal degeneration. To determine which specific laminin chains are involved, we investigated the expression of laminins in the hippocampus, and the cell types expressing them. Reverse transcription-PCR demonstrated that the messenger RNAs for all laminin chains could be detected in the hippocampus. To determine the localization of laminin chain expression, immunostaining was used. This method showed that alpha5, beta1 and gamma1 are most highly expressed in the neuronal cell layers. Immunoblotting confirmed the hippocampal expression of the chains alpha5, beta1 and gamma1, and RNA in situ hybridization showed a neuronal expression pattern of alpha5, beta1 and gamma1. At early time points following intrahippocampal injection of kainate, alpha5, beta1 and gamma1 chain immunoreactivities were lost. In addition, tissue plasminogen activator-deficient mice, which are resistant to kainate-induced neuronal death, show no significant change in laminins alpha5, beta1 and gamma1 after intrahippocampal kainate injection. Taken together, these results suggest that laminin-10 (alpha5-beta1-gamma1) comprises a major neuronal laminin in the mouse hippocampus, and is degraded before neuronal death during excitotoxic injury by the tissue plasminogen activator/plasmin protease cascade. By identifying a neuronal laminin (laminin-10) that participates in neuronal degeneration after excitotoxic injury, this study clarifies the molecular definition of the extracellular matrix in the hippocampus and further defines a pathway for mechanisms of neuronal death.
层粘连蛋白是细胞外基质的重要组成部分,参与神经元的发育、存活和再生。组织纤溶酶原激活物/纤溶酶细胞外蛋白酶级联反应以及下游层粘连蛋白的降解与兴奋性毒素诱导的神经元变性有关。为了确定哪些特定的层粘连蛋白链参与其中,我们研究了海马体中层粘连蛋白的表达情况以及表达它们的细胞类型。逆转录聚合酶链反应表明,海马体中可以检测到所有层粘连蛋白链的信使核糖核酸。为了确定层粘连蛋白链表达的定位,采用了免疫染色法。该方法显示,α5、β1和γ1在神经元细胞层中表达最高。免疫印迹证实了α5、β1和γ1链在海马体中的表达,而RNA原位杂交显示α5、β1和γ1呈现神经元表达模式。在海马体内注射海藻酸后的早期时间点,α5、β1和γ1链的免疫反应性消失。此外,对海藻酸诱导的神经元死亡具有抗性的组织纤溶酶原激活物缺陷型小鼠,在海马体内注射海藻酸后,层粘连蛋白α5、β1和γ1没有显著变化。综上所述,这些结果表明,层粘连蛋白-10(α5-β1-γ1)是小鼠海马体中主要的神经元层粘连蛋白,并且在兴奋性毒性损伤导致神经元死亡之前,被组织纤溶酶原激活物/纤溶酶蛋白酶级联反应降解。通过鉴定一种参与兴奋性毒性损伤后神经元变性的神经元层粘连蛋白(层粘连蛋白-10),本研究阐明了海马体中细胞外基质的分子定义,并进一步明确了神经元死亡机制的途径。
