Brevican distinctively assembles extracellular components at the large diameter nodes of Ranvier in the CNS

Brevican is known to be an abundant extracellular matrix component in the adult brain and a structural constituent of perineuronal nets. We herein show that brevican, tenascin-R (TN-R) and phosphacan are present at the nodes of Ranvier on myelinated axons with a particularly large diameter in the central nervous system. A brevican deficiency resulted in a reorganization of the nodal matrices, which was characterized by the shift of TN-R, and concomitantly phosphacan, from an axonal diameter-dependent association with nodes to an axonal diameter independent association. Supported by the co-immunoprecipitation results, these observations indicate that the presence of TN-R and phosphacan at nodes is normally brevican-dependent, while in the absence of brevican these molecules can also be recruited by versican V2. The versican V2 and Bral1 distribution was not affected, thus indicating a brevican-independent role of these two molecules for establishing hyaluronan-binding matrices at the nodes. Our results revealed that brevican plays a crucial role in determining the specialization of the hyaluronan-binding nodal matrix assemblies in large diameter nodes.     

NF-κB Mediates αvβ3 Integrin-induced Endothelial Cell Survival

The α_vβ₃ integrin plays a fundamental role during the angiogenesis process by inhibiting endothelial cell apoptosis. However, the mechanism of inhibition is unknown. In this report, we show that integrin-mediated cell survival involves regulation of nuclear factor-kappa B (NF-κB) activity. Different extracellular matrix molecules were able to protect rat aorta- derived endothelial cells from apoptosis induced by serum withdrawal. Osteopontin and β₃ integrin ligation rapidly increased NF-κB activity as measured by gel shift and reporter activity. The p65 and p50 subunits were present in the shifted complex. In contrast, collagen type I (a β₁-integrin ligand) did not induce NF-κB activity. The α_vβ₃ integrin was most important for osteopontin-mediated NF-κB induction and survival, since adding a neutralizing anti-β₃ integrin antibody blocked NF-κB activity and induced endothelial cell death when cells were plated on osteopontin. NF-κB was required for osteopontin- and vitronectin-induced survival since inhibition of NF-κB activity with nonphosphorylatable IκB completely blocked the protective effect of osteopontin and vitronectin. In contrast, NF-κB was not required for fibronectin, laminin, and collagen type I–induced survival. Activation of NF-κB by osteopontin depended on the small GTP-binding protein Ras and the tyrosine kinase Src, since NF-κB reporter activity was inhibited by Ras and Src dominant-negative mutants. In contrast, inhibition of MEK and PI3-kinase did not affect osteopontin-induced NF-κB activation. These studies identify NF-κB as an important signaling molecule in α_vβ₃ integrin-mediated endothelial cell survival.     

Regulated binding of the fibrinogen-like domains of tenascin-R and tenascin-C to the neural EGF family member CALEB

The neural transmembrane protein CALEB was discovered in a screen for novel molecules implicated in neuronal differentiation processes and was found to bind to two proteins of the extracellular matrix, tenascin-C and tenascin-R. The expression of different isoforms of CALEB in axon- and synapse-rich areas in the nervous system is regulated during development. Here we show that an unusual acidic peptide segment of CALEB is sufficient to mediate the binding of CALEB to the fibrinogen-like globes of both tenascin family members as well as to native tenascin-C. We identify a small sequence element within the acidic peptide segment of CALEB as important for this binding. Interestingly, the interactions of CALEB and tenascin-C and -R seem to be regulated during development. We demonstrate that only CALEB-80, the expression of which is up-regulated in the chicken retina during synaptogenesis, but not CALEB-140, expressed later on in development, can bind to the fibrinogen-like domains of tenascin-R or tenascin-C and to native tenascin-C. While both CALEB-80 and CALEB-140 are expressed in the plexiform layers and the optic fiber layer of embryonic chicken retina, CALEB-140 labeling is more intense in the optic fiber layer in comparison to the inner plexiform layer.     

Severe cognitive and motor coordination deficits in tenascin-R-deficient mice

The extracellular matrix molecule tenascin-R (TN-R), predominantly expressed in the central nervous system, has been implied in a variety of functions, e.g. during myelination, cerebellar neurite fasciculation and hippocampal long-term potentiation. In this study, we investigated in detail the impact of TN-R deficiency on the living animal by analyzing the behavior of TN-R-deficient mice. The general state, gross sensory functions, reflexes and motoric capabilities appeared normal. In contrast, motor coordination on the rota-rod was compromised in these mice, indicating a deficit in cerebellar functions. In the open field and the hole board, the mutants interact differently with their environment, probably due to differences in their exploratory behavior. TN-R-deficient mice were able to learn a reference memory task in the Morris water maze. In contrast to wild-type mice, the mutants displayed an alternative strategy; swimming around the pool using a stereotypical circling pattern, crossing all possible platform positions after relocation of the escape platform (reversal). These results, confirmed by relocating the platform in the center of the pool, suggest that TN-R-deficient mice may be impaired in constructing a goal-independent representation of space. In addition, a two-way active avoidance test (shuttle box) revealed a severe deficit in associative learning in TN-R-deficient mice. Our results support important functions of TN-R in vivo in the central nervous system, in particular in the cerebellum and the hippocampus.     

肌腱蛋白R(Tenascin-R)研究进展

肌腱蛋白R(tenascin-R, TN-R)是一种重要的细胞外基质糖蛋白(extracellular matrix,ECM).分布于中枢神经系统, 主要在髓鞘形成早期的少突胶质细胞中表达,成熟的胶质细胞及某些神经元(如脊髓,视网膜, 小脑和海马的中间神经元)也有表达.TN-R具有复杂的结构,由三种不同的结构域组成,从氨基端到羧基端依次为:类似于表皮生长因子的重复片段, 类似于Ⅲ型纤连蛋白重复片段,类似(血)纤维蛋白原片段组成.TN-R具有多种复杂的功能, 对神经元具有排斥作用,促进或抑制神经元突起的生长, 诱导神经元形态的极性化, 并和髓鞘的形成有关,TN-R结构的复杂性和功能的多样性提示,TN-R有多个受体存在,已经发现的受体有F3/F11,MAG,XL1,Xprocan等.