The 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. Nogo is found on growing axons during development, suggesting possible functions for neuronal Nogo in axon guidance. Although Nogo, MAG and OMgp lack sequence homologies, they all bind to the Nogo receptor (NgR), a GPI-linked cell surface molecule which, in turn, binds p75 to activate RhoA. NgR is strongly expressed by cerebral cortical neurons but many other neurons express NgR weakly or not at all. Some neurons, such as DRG cells, respond to Nogo and CNS myelin in vitro although they express little or no NgR in vivo which, with other data, indicates that other receptors are available for NgR ligands. NgR expression is unaffected by injury to the nervous system, and there is no clear correlation between NgR expression by neurons and lack of regenerative ability. In the injured spinal cord, interactions between NgR and its ligands are most likely to be important for limiting regeneration of corticospinal and some other descending tracts; other receptors may be more important for ascending tracts. Antibodies to Nogo, mainly the poorly-characterised IN-1 or its derivatives, have been shown to enhance recovery from partial transections of the spinal cord. They induce considerable plasticity from the axons of corticospinal neurons, including sprouting across the midline and, to a limited extent, regeneration around the lesion. 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.     

Gangliosides and Nogo receptors independently mediate myelin-associated glycoprotein inhibition of neurite outgrowth in different nerve cells

In the injured nervous system, myelin-associated glycoprotein (MAG) on residual myelin binds to receptors on axons, inhibits axon outgrowth, and limits functional recovery. Conflicting reports identify gangliosides (GD1a and GT1b) and glycosylphosphatidylinositol-anchored Nogo receptors (NgRs) as exclusive axonal receptors for MAG. We used enzymes and pharmacological agents to distinguish the relative roles of gangliosides and NgRs in MAG-mediated inhibition of neurite outgrowth from three nerve cell types, dorsal root ganglion neurons (DRGNs), cerebellar granule neurons (CGNs), and hippocampal neurons. Primary rat neurons were cultured on control substrata and substrata adsorbed with full-length native MAG extracted from purified myelin. The receptors responsible for MAG inhibition of neurite outgrowth varied with nerve cell type. In DRGNs, most of the MAG inhibition was via NgRs, evidenced by reversal of inhibition by phosphatidylinositol-specific phospholipase C (PI-PLC), which cleaves glycosylphosphatidylinositol anchors, or by NEP1-40, a peptide inhibitor of NgR. A smaller percentage of MAG inhibition of DRGN outgrowth was via gangliosides, evidenced by partial reversal by addition of sialidase to cleave GD1a and GT1b or by P4, an inhibitor of ganglioside biosynthesis. Combining either PI-PLC and sialidase or NEP1-40 and P4 was additive. In contrast to DRGNs, in CGNs MAG inhibition was exclusively via gangliosides, whereas inhibition of hippocampal neuron outgrowth was mostly reversed by sialidase or P4 and only modestly reversed by PI-PLC or NEP1-40 in a non-additive fashion. A soluble proteolytic fragment of native MAG, dMAG, also inhibited neurite outgrowth. In DRGNs, dMAG inhibition was exclusively NgR-dependent, whereas in CGNs it was exclusively ganglioside-dependent. An inhibitor of Rho kinase reversed MAG-mediated inhibition in all nerve cells, whereas a peptide inhibitor of the transducer p75(NTR) had cell-specific effects quantitatively similar to NgR blockers. Our data indicate that MAG inhibits axon outgrowth via two independent receptors, gangliosides and NgRs.     

Myelin-associated glycoprotein interacts with the Nogo66 receptor to inhibit neurite outgrowth

Myelin inhibitors of axonal regeneration, like Nogo and MAG, block regrowth after injury to the adult CNS. While a GPI-linked receptor for Nogo (NgR) has been identified, MAG's receptor is unknown. We show that MAG inhibits regeneration by interaction with NgR. Binding of and inhibition by MAG are lost if neuronal GPI-linked proteins are cleaved. Binding of MAG to NgR-expressing cells is GPI dependent and sialic acid independent. Conversely, NgR binds to MAG-expressing cells. MAG, but not a truncated MAG that binds neurons but does not inhibit regeneration, precipitates NgR from NgR-expressing cells, DRG, and cerebellar neurons. Importantly, NgR antibody, soluble NgR, or dominant-negative NgR each prevent inhibition of neurite outgrowth by MAG. Also, MAG and Nogo66 compete for binding to NgR. These results suggest redundancy in myelin inhibitors and indicate therapies for CNS injuries.     

Chronic excitotoxin-induced axon degeneration in a compartmented neuronal culture model

Glutamate excitotoxicity is a major pathogenic process implicated in many neurodegenerative conditions, including AD (Alzheimer''s disease) and following traumatic brain injury. Occurring predominantly from over-stimulation of ionotropic glutamate receptors located along dendrites, excitotoxic axonal degeneration may also occur in white matter tracts. Recent identification of axonal glutamate receptor subunits within axonal nanocomplexes raises the possibility of direct excitotoxic effects on axons. Individual neuronal responses to excitotoxicity are highly dependent on the complement of glutamate receptors expressed by the cell, and the localization of the functional receptors. To enable isolation of distal axons and targeted excitotoxicity, murine cortical neuron cultures were prepared in compartmented microfluidic devices, such that distal axons were isolated from neuronal cell bodies. Within the compartmented culture system, cortical neurons developed to relative maturity at 11 DIV (days in vitro) as demonstrated by the formation of dendritic spines and clustering of the presynaptic protein synaptophysin. The isolated distal axons retained growth cone structures in the absence of synaptic targets, and expressed glutamate receptor subunits. Glutamate treatment (100 μM) to the cell body chamber resulted in widespread degeneration within this chamber and degeneration of distal axons in the other chamber. Glutamate application to the distal axon chamber triggered a lesser degree of axonal degeneration without degenerative changes in the untreated somal chamber. These data indicate that in addition to current mechanisms of indirect axonal excitotoxicity, the distal axon may be a primary target for excitotoxicity in neurodegenerative conditions.     

Myelin-associated glycoprotein activation triggers glutamate uptake by oligodendrocytes in vitro and contributes to ameliorate glutamate-mediated toxicity in vivo

BackgroundMyelin-associated glycoprotein (MAG) is a key molecule involved in the nurturing effect of myelin on ensheathed axons. MAG also inhibits axon outgrowth after injury. In preclinical stroke models, administration of a function-blocking anti-MAG monoclonal antibody (mAb) aimed to improve axon regeneration demonstrated reduced lesion volumes and a rapid clinical improvement, suggesting a mechanism of immediate neuroprotection rather than enhanced axon regeneration. In addition, it has been reported that antibody-mediated crosslinking of MAG can protect oligodendrocytes (OLs) against glutamate (Glu) overload by unknown mechanisms.PurposeTo unravel the molecular mechanisms underlying the protective effect of anti-MAG therapy with a focus on neuroprotection against Glu toxicity.ResultsMAG activation (via antibody crosslinking) triggered the clearance of extracellular Glu by its uptake into OLs via high affinity excitatory amino acid transporters. This resulted not only in protection of OLs but also nearby neurons. MAG activation led to a PKC-dependent activation of factor Nrf2 (nuclear-erythroid related factor-2) leading to antioxidant responses including increased mRNA expression of metabolic enzymes from the glutathione biosynthetic pathway and the regulatory chain of cystine/Glu antiporter system xc^? increasing reduced glutathione (GSH), the main antioxidant in cells. The efficacy of early anti-MAG mAb administration was demonstrated in a preclinical model of excitotoxicity induced by intrastriatal Glu administration and extended to a model of Experimental Autoimmune Encephalitis showing axonal damage secondary to demyelination.ConclusionsMAG activation triggers Glu uptake into OLs under conditions of Glu overload and induces a robust protective antioxidant response.     

Microglial Toll-like receptor 2 contributes to kainic acid-induced glial activation and hippocampal neuronal cell death

Recent studies indicate that Toll-like receptors (TLRs), originally identified as infectious agent receptors, also mediate sterile inflammatory responses during tissue damage. In this study, we investigated the role of TLR2 in excitotoxic hippocampal cell death using TLR2 knock-out (KO) mice. TLR2 expression was up-regulated in microglia in the ipsilateral hippocampus of kainic acid (KA)-injected mice. KA-mediated hippocampal cell death was significantly reduced in TLR2 KO mice compared with wild-type (WT) mice. Similarly, KA-induced glial activation and proinflammatory gene expression in the hippocampus were compromised in TLR2 KO mice. In addition, neurons in organotypic hippocampal slice cultures (OHSCs) from TLR2 KO mouse brains were less susceptible to KA excitotoxicity than WT OHSCs. This protection is partly attributed to decreased expression of proinflammatory genes, such as TNF-α and IL-1β in TLR2 KO mice OHSCs. These data demonstrate conclusively that TLR2 signaling in microglia contributes to KA-mediated innate immune responses and hippocampal excitotoxicity.     

Myelin-associated glycoprotein inhibits microtubule assembly by a Rho-kinase-dependent mechanism

Myelin-associated glycoprotein (MAG) and Nogo are potent inhibitors of neurite outgrowth from a variety of neurons, and they have been identified as possible components of the central nervous system myelin that prevents axonal regeneration in the adult vertebrate central nervous system. The activation of RhoA and Rho-kinase is reported to be an essential part of the signaling mechanism of these proteins. Here, we report that the collapsing response mediator protein-2 (CRMP-2) is phosphorylated by a Rho-kinase-dependent mechanism downstream of MAG or Nogo-66. The overexpression of the nonphosphorylated form of CRMP-2 at threonine 555, which is the phosphorylation site for Rho-kinase, counteracts the inhibitory effect of MAG on the postnatal cerebellar neurons. Additionally, the expression of the dominant negative form of CRMP-2 or knockdown of the gene using small interference RNA (siRNA) mimics the effect of MAG in vitro. Consistent with the function of CRMP-2, which promotes microtubule assembly, microtubule levels are down-regulated in the cerebellar neurons that are stimulated with MAG in vitro. Reduction in the density of microtubules is also observed in the injured axons following the spinal cord injury, and this effect depends on the Rho-kinase activity. Our data suggest the important roles of CRMP-2 and microtubules in the inhibition of the axon regeneration by the myelin-derived inhibitors.     

A role for Nogo receptor in macrophage clearance from injured peripheral nerve

We report a role for Nogo receptors (NgRs) in macrophage efflux from sites of inflammation in peripheral nerve. Increasing numbers of macrophages in crushed rat sciatic nerves express NgR1 and NgR2 on the cell surface in the first week after injury. These macrophages show reduced binding to myelin and MAG in vitro, which is reversed by NgR siRNA knockdown and by inhibiting Rho-associated kinase. Fourteen days after sciatic nerve crush, regenerating nerves with newly synthesized myelin have fewer macrophages than cut/ligated nerves that lack axons and myelin. Almost all macrophages in the cut/ligated nerves lie within the Schwann cell basal lamina, while in the crushed regenerating nerves the majority migrate out. Furthermore, crush-injured nerves of NgR1- and MAG-deficient mice and Y-27632-treated rats show impaired macrophage efflux from Schwann cell basal lamina containing myelinated axons. These data have implications for the resolution of inflammation in peripheral nerve and CNS pathologies.     

Nogo on the go

Growth inhibition in the central nervous system (CNS) is a major barrier to axon regeneration. Recent findings indicate that three distinct myelin proteins, myelin-associated glycoprotein (MAG), Nogo, and oligodendrocyte-myelin glycoprotein (OMgp), inhibit axon growth by binding a common receptor, the Nogo66 receptor (NgR), and likely converge on a common signaling cascade.     

Nogo受体相关研究进展

中枢神经系统损伤后其再生能力较弱已被人们所熟知,原因在于髓磷脂抑制物如Nogo、MAG、Omgp等抑制因子的作用,这些抑制因子通过与神经元上的Nogo受体(NgR)特异性结合,发挥对神经轴突再生的抑制作用。Nogo是一种存在于中枢神经系统少突胶质细胞上的髓磷脂蛋白,其作用主要在于神经细胞损伤后抑制其突触再生,这同时也是对损伤部位其他细胞免于进一步损伤的保护作用。存在于细胞表面的Nogo-66结构是与NgR特异性结合的功能域。NgR是一种存在于神经元表面,传递抑制轴突生长信号的复合共受体。近年来随着对NgR、Nogo及其下游信号通路其他相关蛋白研究的深入,提示多种神经系统疾病与之相关。我们简要综述近年来关于NgR的研究进展。     

中枢神经再生抑制因子及免疫治疗研究

成体哺乳动物中枢神经损伤后早期轴突再生失败的一个主要原因是由于髓磷脂抑制分子的存在。Nogo、髓磷脂相关糖蛋白以及少突胶质细胞髓磷脂糖蛋白等神经再生抑制因子的发现,大大促进了中枢神经再生分子机制的研究。它们均能独立通过Nogo-66受体产生对轴突再生的抑制效应,髓磷脂抑制分子及其信号转导机制的研究日益成为中枢神经再生的研究热点,髓磷脂及其信号转导分子特别是Nogo-66受体、p75神经营养素受体成为损伤后促进轴突再生、抑制生长锥塌陷的主要治疗靶点。抑制上述抑制因子及相关受体NgR或p75NTR可能有助于中枢神经损伤的修复,围绕这些抑制因子及其相关受体介导的信号转导途径,人们提出了多种治疗中枢神经损伤的新思路,其中免疫学方法尤其受到关注。     

Myelin-associated glycoprotein (Siglec-4) expression is progressively and selectively decreased in the brains of mice lacking complex gangliosides

Myelin-associated glycoprotein (MAG, Siglec-4) is a quantitatively minor membrane component expressed preferentially on the innermost myelin wrap, adjacent to the axon. It stabilizes myelin-axon interactions by binding to complementary ligands on the axolemma. MAG, a member of the Siglec family of sialic acid-binding lectins, binds specifically to gangliosides GD1a and GT1b, which are the major sialoglycoconjugates on mammalian axons. Mice with a disrupted Galgt1 gene lack UDP-GalNAc:GM3/GD3 N-acetylgalactosaminyltransferase (GM2/GD2 synthase) and fail to express complex brain gangliosides, including GD1a and GT1b, instead expressing a comparable amount of the simpler gangliosides GM3, GD3, and O-acetyl-GD3. Galgt1-null mice produce similar amounts of total myelin compared to wild-type mice, but as the mice age, they exhibit axon degeneration and dysmyelination with accompanying motor behavioral deficits. Here we report that Galgt1-null mice display progressive and selective loss of MAG from the brain. At 1.5 months of age, MAG expression was similar in Galgt1-null and wild-type mice. However, by 6 months of age MAG was decreased approximately 60% and at 12 months of age approximately 70% in Galgt1-null mice compared to wild-type littermates. Expression of the major myelin proteins (myelin basic protein and proteolipid protein) was not reduced in Galgt1-null mice compared to wild type. MAG mRNA expression was the same in 12-month-old Galgt1-null compared to wild-type mice, an age at which MAG protein expression was markedly reduced. We conclude that the maintenance of MAG protein levels depends on the presence of complex gangliosides, perhaps due to enhanced stability when MAG on myelin binds to its complementary ligands, GD1a and GT1b, on the apposing axon surface.     

Rap1 is involved in the signal transduction of myelin-associated glycoprotein

Myelin-associated glycoprotein (MAG) is a well-characterized axon growth inhibitor in the adult vertebrate nervous system. Several signals that play roles in inhibiting axon growth have been identified. Here, we report that soluble MAG induces activation of Rap1 in postnatal cerebellar granule neurons (CGNs) and dorsal root ganglion (DRG) neurons. The p75 receptor associates with activated Rap1 and is internalized in response to MAG. After MAG is applied to the distal axons of the sciatic nerves, the activated Rap1, internalized p75 receptor, and MAG are retrogradely trafficked via axons to the cell bodies of the DRG neurons. Rap1 activity is required for survival of the DRG neurons as well as CGNs when treated with MAG. The transport of the signaling complex containing the p75 receptor and Rap1 may play a role in the effect of MAG.     

Myelin suppresses axon regeneration by PIR-B/SHP-mediated inhibition of Trk activity

Paired immunoglobulin-like receptor B (PIR-B) partially mediates the regeneration-inhibiting effects of the myelin-derived protein Nogo, myelin-associated glycoprotein (MAG), and oligodendrocyte-myelin glycoprotein (OMgp). In this study, we report that inhibition of the PIR-B signaling cascades in neurons enhances axon regeneration in the central nervous system (CNS). Binding of MAG to PIR-B led to the association of PIR-B with tropomyosin receptor kinase (Trk) neurotrophin receptors. Src homology 2-containing protein tyrosine phosphatase (SHP)-1 and SHP-2, which were recruited to PIR-B upon MAG binding, functioned as Trk tyrosine phosphatases. Further, SHP-1 and SHP-2 inhibition reduced MAG-induced dephosphorylation of Trk receptors and abolished the inhibitory effect of MAG on neurite growth. Thus, PIR-B associated with Trk to downregulate basal and neurotrophin-regulated Trk activity through SHP-1/2 in neurons. Moreover, in vivo transfection of small interfering RNA (siRNA) for SHP-1 or SHP-2 induced axonal regeneration after optic nerve injury in mice. Our results thus identify a new molecular target to enhance regeneration of the injured CNS.     

Myelin associated glycoprotein cross-linking triggers its partitioning into lipid rafts, specific signaling events and cytoskeletal rearrangements in oligodendrocytes

Myelin-associated glycoprotein (MAG) has been implicated in inhibition of nerve regeneration in the CNS. This results from interactions between MAG and the Nogo receptor and gangliosides on the apposing axon, which generates intracellular inhibitory signals in the neuron. However, because myelin-axon signaling is bidirectional, we undertook an analysis of potential MAG-activated signaling in oligodendrocytes (OLs). In this study, we show that antibody cross-linking of MAG on the surface of OLs (to mimic axonal binding) leads to the redistribution of MAG into detergent (TX-100)-insoluble complexes, hyperphosphorylation of Fyn, dephosphorylation of serine and threonine residues in specific proteins, including lactate dehydrogenase and the beta subunit of the trimeric G-protein-complex, and cleavage of alpha-fodrin followed by a transient depolymerization of actin. We propose that these changes are part of a signaling cascade in OLs associated with MAG function as a mediator of axon-glial communication which might have implications for the mutual regulation of the formation and stability of axons and myelin.     

Binding of soluble myelin-associated glycoprotein to specific gangliosides induces the association of p75NTR to lipid rafts and signal transduction

Myelin-associated glycoprotein (MAG) is a potent inhibitor of neurite outgrowth from a variety of neurons. Here we show that gangliosides, GT1b and GD1a, as well as the Nogo receptor, are functional binding partners for soluble MAG-Fc. Postnatal cerebellar neurons from mice deficient in the GalNAcT gene are insensitive to MAG with regard to neurite outgrowth and lack in the activation of RhoA. MAG-Fc or the antibody to GT1b and GD1a elicits recruitment of p75(NTR.) to lipid rafts, specialized microdomain for signal transduction. Disruption of lipid rafts results in abolishment of inhibitory effects of MAG-Fc and the Nogo peptide. These findings establish gangliosides as functional binding partners for soluble MAG. Gangliosides may play a role in translocation of p75(NTR.) to lipid rafts for initiation of the signal transduction.     

Spinal axon regeneration induced by elevation of cyclic AMP

Myelin inhibitors, including MAG, are major impediments to CNS regeneration. However, CNS axons of DRGs regenerate if the peripheral branch of these neurons is lesioned first. We show that 1 day post-peripheral-lesion, DRG-cAMP levels triple and MAG/myelin no longer inhibit growth, an effect that is PKA dependent. By 1 week post-lesion, DRG-cAMP returns to control, but growth on MAG/myelin improves and is now PKA independent. Inhibiting PKA in vivo blocks the post-lesion growth on MAG/myelin at 1 day and attenuates it at 1 week. Alone, injection of db-cAMP into the DRG mimics completely a conditioning lesion as DRGs grow on MAG/myelin, initially, in a PKA-dependent manner that becomes PKA independent. Importantly, DRG injection of db-cAMP results in extensive regeneration of dorsal column axons lesioned 1 week later. These results may be relevant to developing therapies for spinal cord injury.     

A Hypothesis About the Relationship of Myelin-Associated Glycoprotein’s Function in Myelinated Axons to its Capacity to Inhibit Neurite Outgrowth

The myelin-associated glycoprotein (MAG) is selectively localized in periaxonal Schwann cell and oligodendroglial membranes of myelin sheaths suggesting that it functions in glia–axon interactions in the PNS and CNS, and this is supported by much experimental evidence. In addition, MAG is now well known as one of several white matter inhibitors of neurite outgrowth in vitro and axonal regeneration in vivo, and this latter area of research has provided a substantial amount of information about neuronal receptors or receptor complexes for MAG. This article makes the hypothesis that the capacity of MAG to inhibit outgrowth of immature developing or regenerating neurites is an aberration of its normal physiological function to promote the maturation, maintenance, and survival of myelinated axons. The overview summarizes the literature on the function of MAG in PNS and CNS myelin sheaths and its role as an inhibitor of neurite outgrowth to put this hypothesis into perspective. Additional research is needed to determine if receptors and signaling systems similar to those responsible for MAG inhibition of neurite outgrowth also promote the maturation, maintenance, and survival of myelinated axons as hypothesized here, or if substantially different MAG-mediated signaling mechanisms are operative at the glia–axon junction. Special issue article in honor of Dr. George DeVries.