Bartsch U, Kirchhoff F, Schachner M
Department of Neurobiology, University of Heidelberg, Federal Republic of Germany.
J Comp Neurol. 1989 Jun 15;284(3):451-62. doi: 10.1002/cne.902840310.
The localization of the cell adhesion molecules L1, neural cell adhesion molecule (N-CAM), and myelin-associated glycoprotein (MAG) was studied immunohistologically at the light and electron microscopic levels and immunochemically in the developing and adult mouse optic nerve and retina. The neural adhesion molecule L1 is strongly expressed on the shafts of fasciculating unmyelinated axons at all ages studied from embryonic day 15 through adulthood. Growth cones of retinal ganglion cell axons were weakly L1-positive or L1-negative when contacting glial cells. Unmyelinated axons were not only L1-positive when contacting each other but also when contacting glia, whereas contacts between glial cells were L1-negative at all developmental unmyelinated retinal nerve fiber layer or in the unmyelinated optic nerve head became L1-negative when enwrapped by myelin in the optic nerve proper. At all stages of development N-CAM showed profuse labeling on fasciculating axons, growth cones, and their contact sites with glial cells as well as contacts between glial cells. In contrast to L1, axons remained N-CAM-positive when becoming myelinated. Sometimes, N-CAM was found in compact myelin. However, N-CAM was absent from glial surfaces contacting basement membranes at the interface to meninges, blood vessels, and the vitreous body of the eye. MAG was first detectable intracellularly in oligodendrocytes associated with the endoplasmic reticulum and Golgi apparatus before it became apparent at the cell surface. There it was present on oligodendrocytes prior and during the first stages of ensheathment of axons, both on cell body and processes. After formation of compact myelin MAG remained strongly expressed periaxonally and was only weakly detectable in noncompacted myelin including inner mesaxon and paranodal loops. None of the adhesion molecules was detectable on extracellular matrix, in the meninges, or on endothelial cells. Immunochemical analysis of antigen expression at different developmental stages was in agreement with the immunohistological data. We infer from these observations that L1 is involved in stabilization not only of axon-axon, but also axon-glia contacts, while the more dynamic structure of the growth cone generally expresses less L1. A differential expression of L1 along the course of an axon--being present on its unmyelinated, but absent on its myelinated part--further supports the notion that L1 may be involved in the stabilization of axonal fascicles but not of axon-myelin contacts.(ABSTRACT TRUNCATED AT 400 WORDS)
运用免疫组织化学方法,在光学显微镜和电子显微镜水平,以及免疫化学方法,对发育中和成年小鼠的视神经和视网膜中细胞粘附分子L1、神经细胞粘附分子(N-CAM)和髓鞘相关糖蛋白(MAG)进行了定位研究。从胚胎第15天到成年期的所有研究年龄段中,神经粘附分子L1在成束的无髓轴突干上均有强烈表达。视网膜神经节细胞轴突的生长锥在与胶质细胞接触时L1呈弱阳性或阴性。无髓轴突不仅在相互接触时L1呈阳性,与胶质细胞接触时也呈阳性,而胶质细胞之间的接触在所有发育阶段L1均为阴性。在视网膜无髓神经纤维层或视神经乳头的无髓部分,当被视神经中适当的髓鞘包裹时,L1变为阴性。在发育的各个阶段,N-CAM在成束的轴突、生长锥及其与胶质细胞的接触部位以及胶质细胞之间的接触部位均有大量标记。与L1不同,轴突在髓鞘形成时仍保持N-CAM阳性。有时,在致密髓鞘中可发现N-CAM。然而,在与脑膜、血管和眼玻璃体界面的基底膜接触的胶质细胞表面未发现N-CAM。MAG最初在内质网和高尔基体相关的少突胶质细胞内可检测到,之后才在细胞表面显现。在轴突被包裹的前期和第一阶段,它存在于少突胶质细胞的细胞体和突起上。致密髓鞘形成后,MAG在轴突周围仍强烈表达,而在包括内轴系膜和结旁环在内的非致密髓鞘中仅微弱可检测到。在细胞外基质、脑膜或内皮细胞上均未检测到任何一种粘附分子。对不同发育阶段抗原表达的免疫化学分析与免疫组织学数据一致。从这些观察结果我们推断,L1不仅参与轴突-轴突接触的稳定,还参与轴突-胶质细胞接触的稳定,而生长锥更具动态的结构通常表达较少的L1。沿着轴突的不同部位L1表达存在差异——在其无髓部分存在,而在有髓部分不存在——这进一步支持了L1可能参与轴突束稳定而非轴突-髓鞘接触稳定这一观点。(摘要截选至400字)
