The bioactive phospholipid lysophosphatidic acid (LPA) causes growth cone collapse and neurite retraction in neuronal cells. These changes are brought about by the action of a cell surface receptor coupled to specific G proteins that control morphology and motility through the action of a group of small GTPases, the Rho family of proteins. Many studies have focused on actin reorganization modulated by Rho-GTPases, but almost no information has been obtained concerning microtubular network reorganization after LPA-induced neurite retraction. In the present study, we demonstrate an increase in site-specific Alzheimer's disease-like Tau phosphorylation during LPA-induced neurite retraction in differentiated SY-SH5Y human neuroblastoma cells. The phosphorylation state of Tau was inferred from its immunoreactivity with antibodies that recognize phosphorylation-sensitive epitopes. The effects of specific kinase inhibitors indicate that this phosphorylation is mediated by glycogen synthase kinase-3 (GSK-3). In support of this idea, we observed an increase of GSK-3 activity upon growth cone collapse. Our results are consistent with the hypothesis that activation of GSK-3 occurs in the Rho pathway and may represent an important link between microtubules and microfilaments dynamics during neuritogenesis and in pathological situations such as Alzheimer's disease.
Activation and proliferation of microglia are common cellular hallmarks in many different pathological processes of the central nervous system. Although a number of colony-stimulating factors enhance microglial proliferation in vitro, little is known about the endogenous mitogens. In the present study we show a strong and selective inhibition of microglial proliferation in the facial nucleus of osteopetrotic (op/op) mice, with a genetic deficiency in biologically active macrophage colony-stimulating factor (MCSF). Posttraumatic activation of adjacent axotomized neurons and reactive astrocytes was not affected, emphasizing the specificity of MCSF as a microglial growth factor.
The molecular mechanisms used by olfactory ensheathing cells (OECs) to promote repair in the damaged adult mammalian CNS remain unknown. Thus, we used microarrays to analyze three OEC populations with different capacities to promote axonal regeneration in cultured rat retinal neurons. Gene expression in "long-term cultured OECs" that do not stimulate adult axonal outgrowth was compared with that of "primary olfactory ensheathing cells" and the immortalized OEC cell line TEG3. In this way, we identified a number of candidate genes that might play a role in promoting adult axonal regeneration. Among these genes, it was striking that both the matrix metalloproteinase 2 (MMP2) and an inhibitor of this protease were represented. The disruption of MMP2 activity in TEG3 cells impaired their capacity to trigger axon regeneration in cultured adult retinal neurons. Furthermore, the MMP2 protein was detected in grafts of OECs that elicited robust axonal regeneration in the injured spinal cord of adult rats in vivo. These data suggest that MMP2 does indeed participate in adult axonal regeneration induced by OECs.
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