A role for CXCR4 signaling in survival and migration of neural and oligodendrocyte precursors

Oligodendrocyte development is controlled by a number of survival and migratory factors. The present study shows that signaling of CXCR4 receptor by the chemokine CXCL12 regulates survival and migration of neural precursors (NP) as well as oligodendrocyte progenitors (OP). CXCR4 is expressed by E14 striatal NP and OP generated by neurospheres. In CXCR4-defective mice, the number of NP in neurosphere outgrowth was twofold less than in wild-type (WT) mice; NP radial cell migration was also decreased. In contrast, the addition of CXCL12 to WT NP increased radial migration from the sphere in a dose-dependent manner with a maximal response at 200 nM. When oligodendrocytes differentiated in neurosphere outgrowth, CXCR4 was downregulated. OP isolated from newborn brain coexpressed CXCR4 with platelet-derived growth factor receptor-alpha (PDGFR alpha) or chondroitin sulfate proteoglycan; receptor expression also decreased during differentiation in vitro. Neonatal OP showed a peak migratory response to 20 nM of CXCL12 in chemotactic chambers, a migration inhibited by a CXCR4 antagonist and anti-CXCL12 antibody. In the embryonic spinal cord, the number of OP-expressing PDGFR alpha was reduced more than twofold in CXCR4-defective mice compared with WT and the ratio of ventral to dorsal OP was significantly increased. This indicates a defect in OP survival and their dorsal migration from the ventral cord region, probably because CXCR4(-/-) OP are unable to respond to CXCL12 made by vascular endothelia and the pia mater. We propose that CXCR4 signaling regulate survival and outward chemotactic migration of OP during embryonic and postnatal CNS development.

Migration and multipotentiality of PSA-NCAM+ neural precursors transplanted in the developing brain

By optimizing the previously described strategy for obtention of spheres enriched in PSA-NCAM+ precursors, we prepared PSA-NCAM-immunoselected cell populations from cerebral hemispheres of neonatal MBP-LacZ transgenic mice. These cells expressed Nestin, exhibited clonal expansion potential and formed spheres, which were initially enriched in PSA-NCAM+ cells but became enriched in GD3+ oligodendrocyte progenitors after 1 week in B104 contionned medium. One month after their periventricular transplantation into the brain of wild-type and/or shiverer newborn mice, cells from PSA-NCAM+ spheres exhibited a higher rostral migration potential than cells from GD3+ spheres, and clearly contributed to myelination in the olfactory bulb. In shiverer hosts, both sphere populations generated oligodendrocytes with similar myelination potential. In addition PSA-NCAM+ sphere cells generated GFAP+ astrocytes and NeuN+ neurons, depending on their site of insertion. These results evidence the high plasticity of newborn PSA-NCAM+ neural precursors and suggest that they are promising tools for cell therapy of CNS diseases, including myelin disorders.

Mouse oligospheres: from pre-progenitors to functional oligodendrocytes

To study the biology and repair capacities of mouse oligodendroglial cells, we established cultures of cells purified from neonatal wild-type and 9.6-kb MBP-LacZ transgenic newborn mice cerebral hemispheres as free-floating aggregates in the continuous presence of neuroblastoma conditioned medium (N1-B104). In vitro analysis indicated that the initial cell preparations were enriched in oligodendrocyte pre-progenitors that expressed PSA-NCAM and GAP-43 but not GD3, O4, NF68 or glial fibrillary acidic protein (GFAP) markers. These pre-progenitors required increased concentrations of insulin and progesterone to allow their survival in vitro. With time in culture, spheres composed of oligodendrocyte pre-progenitors became oligospheres enriched in oligodendrocyte progenitors expressing GAP-43 and GD3. As well as conserving bipotentiality in vitro, these spheres were able to form myelin in vivo after transplantation into the neonatal shiverer mouse brain. Thus, the oligosphere strategy is a powerful method for generating large populations of mouse oligodendrocyte pre-progenitors and progenitors. The ability to generate oligospheres from transgenic mice will be instrumental in the further dissection of the molecular and cellular mechanisms of myelination and remyelination of the central nervous system.