Journal of neurocytology
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Journal of neurocytology · Feb 2002
ReviewThe Nogo receptor, its ligands and axonal regeneration in the spinal cord; a review.
At least three proteins present in CNS myelin, Nogo, MAG and OMgp are capable of causing growth cone collapse and inhibiting neurite outgrowth in vitro. Surprisingly, Nogo and OMgp are also strongly expressed by many neurons (including neocortical projection cells). Nogo expression is increased by some cells at the borders of CNS lesion sites and by cells in injured peripheral nerves, but Nogo and CNS myelin are largely absent from spinal cord injury sites, which are none the less strongly inhibitory to axonal regeneration. ⋯ Regeneration of corticospinal axons induced by Nogo antibodies has not yet been demonstrated after complete transections or contusion injuries of the spinal cord. It is not clear whether antibodies against Nogo act on oligodendrocytes/myelin or by binding to neuronal Nogo, or whether they can stimulate regeneration of ascending axons in the spinal cord, most of which express little or no NgR. Despite these uncertainties, however, NgR and its ligands offer important new targets for enhancing plasticity and regeneration in the nervous system.
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Journal of neurocytology · Nov 2001
Neurofilamentous hypertrophy of intramedullary axonal arbors in intact spinal motoneurons undergoing peripheral sprouting.
An incomplete motor nerve injury or a partial loss of motoneurons leads to a partial denervation of skeletal muscle. As part of a compensatory response, the remaining intact motoneurons undergo peripheral sprouting and increase their motor unit size. Our knowledge about the responses in the more proximal parts of these sprouting motoneurons is sparse, however. ⋯ Electron microscopic studies of the hypertrophied collaterals demonstrated abnormal accumulations of disorganized neurofilaments arranged in bundles or whorls. The morphological changes were indistinguishable from the neurofilamentous hypertrophy that has previously been reported in Wallerian degeneration, in experimental and human motor neuron disease and in some regenerating axonal processes of spinal motoneurons. We conclude that, neurofilamentous hypertrophy of the intramedullary arbors of motor axons may also be part of a reactive and non-degenerative response in intact motoneurons undergoing compensatory peripheral sprouting.
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Journal of neurocytology · May 2001
Comparative StudyReelin in the extracellular matrix and dendritic spines of the cortex and hippocampus: a comparison between wild type and heterozygous reeler mice by immunoelectron microscopy.
Reelin is a glycoprotein ( approximately 400 kDa) secreted by GABAergic neurons into the extracellular matrix of the neocortex and hippocampus as well as other areas of adult rodent and nonhuman primate brains. Recent findings indicate that the heterozygote reeler mouse (haploinsufficient for the reeler gene) shares several neurochemical and behavioral abnormalities with schizophrenia and bipolar disorder with mania. These include (1) a downregulation of both reelin mRNA and the translated proteins, (2) a decrease in the number of dendritic spines in cortical and hippocampal neurons, (3) a concomitant increase in the packing density of cortical pyramidal neurons, and (4) an age-dependent decrease in prepulse inhibition of startle. ⋯ We suggest that in the heterozygous reeler mouse a downregulation of reelin biosynthesis results in a decreased rate of secretion into the extracellular space. This inhibits dendritic spine maturation and plasticity and leads to dissociation of dendritic postsynaptic density integrity and atrophy of spines. We speculate that the haploinsufficient reeler mouse may provide a model for future studies of the role of reelin, as it may be related to psychosis vulnerability.
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Journal of neurocytology · Feb 2001
Immunolocalization of occludin and claudin-1 to tight junctions in intact CNS vessels of mammalian retina.
The distributions of occludin and claudin-1, two tight junction-associated integral membrane proteins were investigated by immunohistochemical analysis of whole-mount preparations of the blood vessels in the myelinated streak of the rabbit retina. Light microscopy revealed that occludin and claudin-1 immunoreactivities were abundant along the interface of adjacent endothelial cells of all blood vessels. Electron microscopy revealed that both proteins were distributed in a regular pattern (at regular intervals of approximately 80 nm) along the length of tight junctions, probably in the regions of tight junction strands. ⋯ Occludin expression was evident at the leading edge of vessel formation and was found on all vessels in both the inner and outer vascular plexus. Numerous vascular segments at the early stage of vascular formation and regression lost occludin expression. The biological significance of this transient loss of occludin expression in terms of barrier function remains to be elucidated.
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Journal of neurocytology · Sep 2000
Fibroblast-like cells from rat plantar skin and neurotrophin-transfected 3T3 fibroblasts influence neurite growth from rat sensory neurons in vitro.
Our previous finding that skin-derived and muscle-derived molecules can be used to sort regenerating rat sciatic nerve axons evoked questions concerning neuron-target interactions at the level of single cells, which prompted the present study. The results show that dorsal root ganglion (DRG) neurons co-cultured with fibroblast-like skin-derived cells emit many neurites. These have a proximal linear segment and a distal network of beaded branches in direct relation to skin-derived cells. ⋯ In co-cultures with a membrane insert between skin-derived cells or 3T3 fibroblasts and DRG neurons few neurons survived and neurite growth was very sparse. We conclude that skin-derived cells stimulate neurite growth from sensory neurons in vitro, that these cells produce NGF, BDNF, NT-3 and NT-4 and that 3T3 fibroblasts producing NT-3 mimic the effect of skin-derived cells on sensory neurons in co-culture. Finally the results suggest that cell surface molecules are important for neuritogenesis.