Neural-cell adhesion molecules (N-CAMs) are members of the immunoglobulin superfamily mediating homo- and heterophilic cell-cell interactions. N-CAM exists in various isoforms which are generated by alternative splicing. During embryonic development, N-CAMs are expressed in derivatives of all three germ layers, whereas in the adult animal they are predominantly present in neural tissue. Processes like neurulation, axonal outgrowth, histogenesis of the retina and development of the olfactory system are correlated with the regulated expression of N-CAMs. We show here that N-CAM-deficient mice generated by gene targeting appear healthy and fertile, but adult mutants show a 10% reduction in overall brain weight and a 36% decline in size of the olfactory bulb. N-CAM deficiency coincides with almost total loss of protein-bound alpha-(2,8)-linked polysialic acid, a carbohydrate structure thought to be correlated with neural development and plasticity. The animals showed deficits in spatial learning when tested in the Morris water maze, whereas activity and motor abilities appeared normal.
Fibroblasts are subjected to changes of the mechanical force balance during physiological as well as pathological situations, such as wound healing, development of hypertrophic scars, and fibrogenesis. However, the molecular response and the changes in fibroblast gene expression upon mechanical stimulation remain poorly understood. As an in vitro model, human dermal fibroblasts were cultured within a three-dimensional network of fibrillar collagen either under high (stressed) or low tension (relaxed). cDNA microarray technology in combination with Northern blot analysis led to identification of mechano-responsive genes coding for extracellular matrix proteins, fibrogenic growth factors, protease inhibitors, components of focal adhesions, and the cytoskeleton. Application of biaxial strain to fibroblasts cultured on flexible silicone membranes revealed that the type of strain as well as the properties of the substrate induced different patterns of gene regulation. The transcriptional profile of mechanically induced genes in collagen lattices suggests that mechanical stimuli lead to a "synthetic" fibroblast phenotype characterized by induction of connective tissue synthesis while simultaneously inhibiting matrix degradation.Regulation of genes by mechanical forces has been studied extensively relating to the biology of vascular endothelial and smooth muscle cells or chondrocytes that are obviously subjected to high fluid shear or pressure load (1). In contrast, dermal fibroblasts are less well characterized in their response to mechanical load, despite the fact that skin in its physiological state is constantly exposed to stretching and bending forces. Moreover, healing of skin wounds represents a special situation in which fibroblasts develop tensile forces against the granulation tissue matrix in order to bring the wound margins together and to obtain fast wound closure. It has been postulated that during wound contraction mechanically stressed fibroblasts differentiate into the specialized myofibroblast phenotype, characterized by expression of ␣-smooth muscle actin and formation of prominent stress fibers and of fibronexus junctions (2-4). The scar that finally develops is itself a tissue under increased mechanical forces, at least as long as scar resolution is not complete. The specialized cases of abnormal scarring, e.g. keloids, represent a further situation to which mechanical forces are of relevance; such lesions have long been known to develop in regions of the body that are subjected to relatively higher mechanical forces than others. Furthermore, fibroblasts in fibrotic skin lesions are thought to be subject to considerable mechanical tension.Thus, there are examples of physiological and disease conditions that strongly argue for the presence of mechanical forces acting upon skin fibroblasts. To analyze the effects of such forces, several experimental models have been designed that clearly demonstrated that fibroblasts respond to mechanical stress. In a classical experiment, it has been shown that fibr...
A key step in glutamatergic synapse maturation is the replacement of developmentally expressed N-methyl-D-aspartate receptors (NMDARs) with mature forms that differ in subunit composition, electrophysiological properties and propensity to elicit synaptic plasticity. However, the mechanisms underlying the removal and replacement of synaptic NMDARs are poorly understood. Here we demonstrate that NMDARs containing the developmentally regulated NR3A subunit undergo rapid endocytosis from the dendritic plasma membrane in cultured rat hippocampal neurons. This endocytic removal is regulated by PACSIN1/syndapin1, which directly and selectively binds the carboxy-terminal domain of NR3A through its NPF motifs and assembles a complex of proteins including dynamin and clathrin. Endocytosis of NR3A by PACSIN1 is activity dependent, and disruption of PACSIN1 function causes NR3A accumulation at synaptic sites. Our results reveal a new activity-dependent mechanism involved in the regulation of NMDAR expression at synapses during development, and identify a brain-specific endocytic adaptor that confers spatiotemporal and subunit specificity to NMDAR endocytosis.Stabilization and maturation of synapses is central to neural circuit formation. During development, excitatory synapses in the central nervous system are remodeled in response to
Nicotinic acetylcholine receptors play important roles in numerous cognitive processes as well as in several debilitating central nervous system (CNS) disorders. In order to fully elucidate the diverse roles of nicotinic acetylcholine receptors in CNS function and dysfunction, a detailed knowledge of their cellular and subcellular localizations is essential. To date, methods to precisely localize nicotinic acetylcholine receptors in the CNS have predominantly relied on the use of antireceptor subunit antibodies. Although data obtained by immunohistology and immunoblotting are generally in accordance with ligand binding studies, some discrepancies remain, in particular with electrophysiological findings. In this context, nicotinic acetylcholine receptor subunit-deficient mice should be ideal tools for testing the specificity of subunitdirected antibodies. Here, we used standard protocols for immunohistochemistry and western blotting to examine the antibodies raised against the a3-, a4-, a7-, b2-, and b4-nicotinic acetylcholine receptor subunits on brain tissues of the respective knock-out mice. Unexpectedly, for each of the antibodies tested, immunoreactivity was the same in wild-type and knock-out mice. These data imply that, under commonly
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