Oligodendrocyte differentiation and myelination defects in OMgp null mice.

OMgp is selectively expressed in CNS by oligodendrocyte. However, its potential role(s) in oligodendrocyte development and myelination remain unclear. We show that OMgp null mice are hypomyelinated in their spinal cords, resulting in slower ascending and descending conduction velocities compared to wild-type mice. Consistent with the hypomyelination, in the MOG induced EAE model, OMgp null mice show a more severe EAE clinical disease and slower nerve conduction velocity compared to WT animals. The contribution of OMgp to oligodendrocyte differentiation and myelination was verified using cultured oligodendrocytes from null mice. Oligodendrocytes isolated from OMgp null mice show a significant decrease in the number of MBP(+) cells and in myelination compared to wild-type mice. The dramatic effects of the OMgp KO in oligodendrocyte maturation in vivo and in vitro reveal a new and important function for OMgp in regulating CNS myelination.

Assessment of functional recovery and axonal sprouting in oligodendrocyte-myelin glycoprotein (OMgp) null mice after spinal cord injury.

Oligodendrocyte-myelin glycoprotein (OMgp) is a myelin component that has been shown in vitro to inhibit neurite outgrowth by binding to the Nogo-66 receptor (NgR1)/Lingo-1/Taj (TROY)/p75 receptor complex to activate the RhoA pathway. To investigate the effects of OMgp on axon regeneration in vivo, OMgp(-/-) mice on a mixed 129/Sv/C57BL/6 (129BL6) or a C57BL/6 (BL6) genetic background were tested in two spinal cord injury (SCI) models - a severe complete transection or a milder dorsal hemisection. OMgp(-/-) mice on the mixed 129BL6 genetic background showed greater functional improvement compared to OMgp(+/+) littermates, with increased numbers of cholera toxin B-labeled ascending sensory axons and 5-HT(+) descending axons and less RhoA activation after spinal cord injury. Myelin isolated from OMgp(-/-) mice (129BL6) was significantly less inhibitory to neurite outgrowth than wild-type (wt) myelin in vitro. However, OMgp(-/-) mice on a BL/6 genetic background showed neither statistically significant functional recovery nor axonal sprouting following dorsal hemisection.

NGF regulates the expression of axonal LINGO-1 to inhibit oligodendrocyte differentiation and myelination.

Neurons and glia share a mutual dependence in establishing a functional relationship, and none is more evident than the process by which axons control myelination. Here, we identify LRR and Ig domain-containing, Nogo receptor-interacting protein (LINGO-1) as a potent axonal inhibitor of oligodendrocyte differentiation and myelination that is regulated by nerve growth factor and its cognate receptor TrkA in a dose-dependent manner. Whereas LINGO-1 expressed by oligodendrocyte progenitor cells was previously identified as an inhibitor of differentiation, we demonstrate that axonal expression of LINGO-1 inhibits differentiation with equal potency. Disruption of LINGO-1 on either cell type is sufficient to overcome the inhibitory action and promote differentiation and myelination, independent of axon diameter. Furthermore, these results were recapitulated in transgenic mice overexpressing the full length LINGO-1 under the neuronal promoter synapsin. Myelination was greatly inhibited in the presence of enforced axonal LINGO-1. The implications of these results relate specifically to the development of potential therapeutics targeting extrinsic growth factors that may regulate the axonal expression of modulators of oligodendrocyte development.

NG2 glial cells provide a favorable substrate for growing axons.

NG2 cells (polydendrocytes) comprise an abundant glial population that is widely and uniformly distributed throughout the developing and mature CNS and are identified by the expression of the NG2 proteoglycan at the cell surface. Although recent electrophysiological studies suggest that they are capable of receiving signals from axon terminals, other studies, based on the finding that the NG2 molecule itself induces growth cone collapse, have led to a widely held speculation that NG2 cells themselves also repel and inhibit growing axons. In this study, we have examined the effects of rat NG2 cells on growing hippocampal and neocortical axons in vitro and in vivo. NG2 cells did not repel growing axons but promoted their growth in vitro, and axonal growth cones formed extensive contacts with NG2 cells both in vitro and in the developing corpus callosum. Punctate immunoreactivity for fibronectin and laminin was found to be colocalized with NG2 on the surface of NG2 cells. Altering the level of cell surface NG2 expression had no effect on the growth-promoting effects of NG2 cells on growing axons. Thus, our study indicates that NG2 cells are not inhibitory to growing axons but provide an adhesive substrate for axonal growth cones and promote their growth even in the presence of elevated levels of the NG2 proteoglycan. These findings suggest a novel role for NG2 cells in facilitating axonal growth during development and regeneration.

Astrocytes and NG2-glia: what's in a name?

Classic studies recognize two functionally segregated macroglial cell types in the central nervous system (CNS), namely astrocytes and oligodendrocytes. A third macroglial cell type has now been identified by its specific expression of the NG2 chondroitin sulphate proteoglycan (NG2-glia). These NG2-glia exist abundantly in both grey and white matter of the mature CNS and are almost as numerous as astrocytes. It is well established that NG2-glia give rise to oligodendrocytes. However, the majority of NG2-glia in the adult CNS proliferate very slowly and are non-motile. Both astrocytes and NG2-glia display a stellate morphology and express ion channels and receptors to neurotransmitters used by neurons. Both types of glia make intimate contacts with neurons in grey and white matter, and their functional differences and similarities are only beginning to be unravelled. Recent observations emphasize the need to examine the relationship between astrocytes and NG2-glia, and address the question of whether they represent overlapping or two distinct glial cell populations. To be of any relevance, this classification must relate to specific functions in the neural network. At present, the balance of evidence is that NG2-glia and astrocytes are functionally segregated populations.

Optimization of oligodendrocyte progenitor cell culture method for enhanced survival.

Oligodendrocyte progenitor cells (OPCs, NG2 glia) play an important role not only as progenitor cells that give rise to myelinating cells in the central nervous system (CNS), but also as an active participant in the neural network. It is necessary to develop a simplified method for generating large quantities of highly purified OPCs for biochemical studies and to establish a neuron-OPC coculture method for functional studies on the mechanism of neuron-OPC signaling. In this study, we have compared the effects of plating density and culture medium on purity, survival, and differentiation of cells collected from primary rat mixed glial cultures by differential adhesion. Comparison of two chemically-defined culture media, Dulbecco's modified Eagle's medium with N1 supplements (N1/DMEM) and Neurobasal medium with B27 supplements (B27/NBM) revealed that while both media successfully maintained greater than 90% pure OPCs after 3 days, B27/NBM was significantly more effective in maintaining viable cells and in supporting oligodendrocyte differentiation than N1/DMEM, and this effect was more pronounced in low density cultures. Furthermore, B27/NBM supported neuron-OPC coculture in which OPCs remained as NG2-positive progenitors and neurons differentiated to form synapses over a period of 3 weeks.

Identity, distribution, and development of polydendrocytes: NG2-expressing glial cells.

Cells that express the NG2 proteoglycan (NG2+ cells) comprise a unique population of glial cells in the central nervous system. While there is no question that some NG2+ cells differentiate into oligodendrocytes during development, the persistence of numerous NG2+ cells in the mature CNS has raised questions about their identity, relation to other CNS cell types, and functions besides their progenitor role. NG2+ cells also express the alpha receptor for platelet-derived growth factor (PDGF alphaR), a receptor that mediates oligodendrocyte progenitor proliferation during development. Antigenically, NG2+ cells are distinct from fibrous and protoplasmic astrocytes, resting microglia, and mature oligodendrocytes. Therefore, we propose the term polydendrocytes to refer to all NG2-expressing glial cells in the CNS parenchyma. This distinguishes them from the classical glial cell types and identifies them as the fourth major glial population in the CNS. Recent observations suggest that polydendrocytes are complex cells that physically and functionally interact with other cell types in the CNS. Committed oligodendrocyte progenitor cells arise from restricted foci in the ventral ventricular zone in both spinal cord and brain. It remains to be clarified whether there are multiple sources of oligodendrocytes, and if so whether polydendrocytes (NG2+ cells) represent progenitor cells of all oligodendrocyte lineages. Proliferation of NG2+ cells during early development appears to be dependent on PDGF, but the regulatory mechanisms that govern NG2+ cell proliferation in the mature CNS remain unknown. Pulse-chase labeling with bromodeoxyuridine indicates that polydendrocytes that proliferate in the postnatal spinal cord differentiate into oligodendrocytes. Novel experimental approaches are being developed to further elucidate the functional properties and differentiation potential of polydendrocytes.