Battisti W P, Shinar Y, Schwartz M, Levitt P, Murray M
Department of Anatomy and Neurobiology, Medical College of Pennsylvania, Philadelphia 19129.
J Neurocytol. 1992 Aug;21(8):557-73. doi: 10.1007/BF01187117.
Current views suggest that the extracellular environment is critically important for successful axonal regeneration in the CNS. The goldfish optic nerve readily regenerates, indicating the presence of an environment that supports regeneration. An analysis of changes that occur during regeneration in this model may help identify those molecules that contribute to a favourable environment for axonal regrowth. We examined the distribution and expression of two extracellular matrix molecules, laminin and chondroitin sulphate proteoglycan, and a carbohydrate epitope shared by a family of adhesion molecules (HNK-1), using immunocytochemical detection in sections from the normal adult goldfish optic nerve and in nerves from one hour to five months following optic nerve crush. We also used in vitro preparations to determine if neurites in retinal explants could express these same molecules. The linear distributions of laminin and chondroitin sulphate proteoglycan immunoreactivity in control optic nerves are co-extensive with the glia limitans, suggesting both are expressed by non-neuronal components surrounding the axon fascicles. Between one and three weeks postoperatively when axons elongate and reach their target, laminin and chondroitin sulphate proteoglycan immunoreactivity increases around the crush site and distally. At six weeks postoperatively the pattern of immunoreactivity has returned to normal. While the temporal pattern of changes in immunoreactivity is similar, the spatial pattern of these two extracellular proteins in the regenerating nerve differs. Chondroitin sulphate proteoglycan immunoreactivity is organized in discrete columns associated with regenerating axons while laminin immunoreactivity is more diffusely distributed. Examination of retinal explants reveals growing neurites express chondroitin sulphate proteoglycan but not laminin. Our results suggest that laminin is only associated with non-neuronal cells, while chondroitin sulphate proteoglycan is associated with axons as well as non-neuronal cells. HNK-1 immunoreactivity is co-extensive with both the glia limitans and axon fascicles and is more extensively distributed in the intact nerve than either laminin or chondroitin sulphate proteoglycan immunoreactivity. In contrast to laminin and chondroitin sulphate proteoglycan, HNK-1 immunoreactivity is substantially decreased at the crush site within one week following optic nerve crush. HNK-1 immunoreactivity reappears through the crush site during the next several weeks, although non-immunoreactive regions, co-extensive with areas predominantly containing non-neuronal cells, persist both proximal and distal to the crush, up to six weeks postoperatively. The pattern suggests that HNK-1 epitope expression by these non-neuronal cells is decreased during axonal regeneration.(ABSTRACT TRUNCATED AT 400 WORDS)
当前观点认为,细胞外环境对于中枢神经系统中轴突的成功再生至关重要。金鱼视神经能够轻易再生,这表明存在支持再生的环境。对该模型再生过程中发生的变化进行分析,可能有助于识别那些有助于为轴突生长营造有利环境的分子。我们利用免疫细胞化学检测方法,研究了正常成年金鱼视神经切片以及视神经挤压后1小时至5个月的神经切片中两种细胞外基质分子(层粘连蛋白和硫酸软骨素蛋白聚糖)以及一类粘附分子(HNK-1)共有的碳水化合物表位的分布和表达情况。我们还利用体外制备物来确定视网膜外植体中的神经突是否能够表达这些相同的分子。层粘连蛋白和硫酸软骨素蛋白聚糖免疫反应性在对照视神经中的线性分布与神经胶质界膜共同延伸,这表明二者均由轴突束周围的非神经元成分表达。术后1至3周,当轴突伸长并到达其靶标时,层粘连蛋白和硫酸软骨素蛋白聚糖免疫反应性在挤压部位及其远端增加。术后6周,免疫反应性模式恢复正常。虽然免疫反应性变化的时间模式相似,但这两种细胞外蛋白在再生神经中的空间模式有所不同。硫酸软骨素蛋白聚糖免疫反应性呈离散柱状分布,与再生轴突相关,而层粘连蛋白免疫反应性分布更为弥散。对视网膜外植体的检查显示,生长中的神经突表达硫酸软骨素蛋白聚糖,但不表达层粘连蛋白。我们的结果表明,层粘连蛋白仅与非神经元细胞相关,而硫酸软骨素蛋白聚糖与轴突以及非神经元细胞均相关。HNK-1免疫反应性与神经胶质界膜和轴突束共同延伸,并且在完整神经中的分布比层粘连蛋白或硫酸软骨素蛋白聚糖免疫反应性更为广泛。与层粘连蛋白和硫酸软骨素蛋白聚糖不同,视神经挤压后1周内,HNK-1免疫反应性在挤压部位大幅下降。在接下来的几周内,HNK-1免疫反应性重新出现在挤压部位,尽管与主要包含非神经元细胞的区域共同延伸的非免疫反应性区域在挤压部位近端和远端持续存在,直至术后6周。这种模式表明,在轴突再生过程中,这些非神经元细胞的HNK-1表位表达减少。(摘要截短于400字)
