LINGO-1 Protein Interacts with the p75 Neurotrophin Receptor in Intracellular Membrane Compartments

Axon outgrowth inhibition in response to trauma is thought to be mediated via the binding of myelin-associated inhibitory factors (e.g. Nogo-66, myelin-associated glycoprotein, oligodendrocyte myelin glycoprotein, and myelin basic protein) to a putative tripartite LINGO-1·p75^NTR·Nogo-66 receptor (NgR) complex at the cell surface. We found that endogenous LINGO-1 expression in neurons in the cortex and cerebellum is intracellular. Mutation or truncation of the highly conserved LINGO-1 C terminus altered this intracellular localization, causing poor intracellular retention and increased plasma membrane expression. p75^NTR associated predominantly with natively expressed LINGO-1 containing immature N-glycans, characteristic of protein that has not completed trans-Golgi-mediated processing, whereas mutant forms of LINGO-1 with enhanced plasma membrane expression did not associate with p75^NTR. Co-immunoprecipitation experiments demonstrated that LINGO-1 and NgR competed for binding to p75^NTR in a manner that is difficult to reconcile with the existence of a LINGO-1·p75^NTR·NgR ternary complex. These findings contradict models postulating functional LINGO-1·p75^NTR·NgR complexes in the plasma membrane.     

TAJ/TROY, an orphan TNF receptor family member, binds Nogo-66 receptor 1 and regulates axonal regeneration

Myelin-associated inhibitory factors (MAIFs) are inhibitors of CNS axonal regeneration following injury. The Nogo receptor complex, composed of the Nogo-66 receptor 1 (NgR1), neurotrophin p75 receptor (p75), and LINGO-1, represses axon regeneration upon binding to these myelin components. The limited expression of p75 to certain types of neurons and its temporal expression during development prompted speculation that other receptors are involved in the NgR1 complex. Here, we show that an orphan receptor in the TNF family called TAJ, broadly expressed in postnatal and adult neurons, binds to NgR1 and can replace p75 in the p75/NgR1/LINGO-1 complex to activate RhoA in the presence of myelin inhibitors. In vitro exogenously added TAJ reversed neurite outgrowth caused by MAIFs. Neurons from Taj-deficient mice were more resistant to the suppressive action of the myelin inhibitors. Given the limited expression of p75, the discovery of TAJ function is an important step for understanding the regulation of axonal regeneration.     

Troy/Taj and its role in CNS axon regeneration

Binding of myelin inhibitors to the NgR1/p75/LINGO-1 signaling complex activates RhoA to mediate the inhibition of axonal outgrowth. The nerve growth factor receptor p75, a TNF family receptor, is absent or poorly expressed in certain types of neurons that respond to myelin inhibitors, thereby prompting speculation that other TNF family receptors are involved in the NgR1 complex. Troy/Taj is an orphan TNF family receptor that is broadly expressed in postnatal and adult neurons. Troy binds to NgR1 and can functionally replace p75 in the p75/NgR1/LINGO-1 complex to activate RhoA and block neurite outgrowth in the presence of myelin inhibitors. Neurons from Troy-deficient mice are more resistant to the suppressive action of the myelin inhibitors. The discovery of TROY function in axon growth is an important step for understanding the complex regulation of axonal regeneration by diverse members of the TNF receptor family.     

LINGO-1-Fc蛋白对低钾诱导小脑颗粒神经元凋亡的保护作用

髓鞘抑制因子Nogo-A、MAG和OMgp通过共同的受体信号复合物NgR/p75NTR(或者TROY)发挥对中枢神经纤维再生的抑制作用.新近克隆的跨膜蛋白LINGO-1是该信号途径的另一个重要组成成分和调节分子.LINGO-1特异表达于中枢神经系统,神经元上的LINGO-1被证明参与调节中枢神经再生的抑制信号,而少突胶质细胞表达的LINGO-1分子参与负调节少突胶质细胞的髓鞘化过程.为探讨LINGO-1分子在神经元凋亡过程中的作用,利用包含LINGO-1分子胞外段LRR和IgC2结构域的Fc融合蛋白作为功能性拮抗剂,研究LINGO-1对低钾诱导的小脑颗粒神经元凋亡的保护作用.利用成熟的Hoechst标记凋亡细胞的方法,观察到经LINGO-1-Fc蛋白预处理2h能够显著阻止小脑颗粒神经元的凋亡.仅包括LRR结构域的GST-LINGO-1与LINGO-1-Fc蛋白,虽同样具有与颗粒神经元的结合活性,但是GST-LINGO-1不能有效地阻止低钾诱导的细胞凋亡.这些结果提示,LINGO-1-Fc蛋白能够阻止低钾诱导的小脑颗粒神经元凋亡,并且这种作用可能是IgC2结构域依赖的.     

A TNF receptor family member, TROY, is a coreceptor with Nogo receptor in mediating the inhibitory activity of myelin inhibitors

A major obstacle for successful axon regeneration in the adult central nervous system (CNS) arises from inhibitory molecules in CNS myelin, which signal through a common receptor complex on neurons consisting of the ligand-binding Nogo-66 receptor (NgR) and two transmembrane coreceptors, p75 and LINGO-1. However, p75 expression is only detectable in subpopulations of mature neurons, raising the question of how these inhibitory signals are transduced in neurons lacking p75. In this study, we demonstrate that TROY (also known as TAJ), a TNF receptor family member selectively expressed in the adult nervous system, can form a functional receptor complex with NgR and LINGO-1 to mediate cellular responses to myelin inhibitors. Also, both overexpressing a dominant-negative TROY or presence of a soluble TROY protein can efficiently block neuronal response to myelin inhibitors. Our results implicate TROY in mediating myelin inhibition, offering new insights into the molecular mechanisms of regeneration failure in the adult nervous system.     

AMIGO3 Is an NgR1/p75 Co-Receptor Signalling Axon Growth Inhibition in the Acute Phase of Adult Central Nervous System Injury

Axon regeneration in the injured adult CNS is reportedly inhibited by myelin-derived inhibitory molecules, after binding to a receptor complex comprised of the Nogo-66 receptor (NgR1) and two transmembrane co-receptors p75/TROY and LINGO-1. However, the post-injury expression pattern for LINGO-1 is inconsistent with its proposed function. We demonstrated that AMIGO3 levels were significantly higher acutely than those of LINGO-1 in dorsal column lesions and reduced in models of dorsal root ganglion neuron (DRGN) axon regeneration. Similarly, AMIGO3 levels were raised in the retina immediately after optic nerve crush, whilst levels were suppressed in regenerating optic nerves, induced by intravitreal peripheral nerve implantation. AMIGO3 interacted functionally with NgR1-p75/TROY in non-neuronal cells and in brain lysates, mediating RhoA activation in response to CNS myelin. Knockdown of AMIGO3 in myelin-inhibited adult primary DRG and retinal cultures promoted disinhibited neurite growth when cells were stimulated with appropriate neurotrophic factors. These findings demonstrate that AMIGO3 substitutes for LINGO-1 in the NgR1-p75/TROY inhibitory signalling complex and suggests that the NgR1-p75/TROY-AMIGO3 receptor complex mediates myelin-induced inhibition of axon growth acutely in the CNS. Thus, antagonizing AMIGO3 rather than LINGO-1 immediately after CNS injury is likely to be a more effective therapeutic strategy for promoting CNS axon regeneration when combined with neurotrophic factor administration.     

p75NTR and TROY: Uncharted Roles of Nogo Receptor Complex in Experimental Autoimmune Encephalomyelitis

Multiple sclerosis (MS) and its animal model, experimental autoimmune encephalomyelitis (EAE), have been on the forefront of drug discovery for most of the myelin inhibitory molecules implicated in axonal regenerative process. Nogo-A along with its putative receptor NgR and co-receptor LINGO-1 has paved the way for the production of pharmaceutical agents such as monoclonal antibodies, which are already put into handful of clinical trials. On the other side, little progress has been made towards clarifying the role of neurotrophin receptor p75 (p75NTR) and TROY in disease progression, other key players of the Nogo receptor complex. Previous work of our lab has shown that their exact location and type of expression is harmonized in a phase-dependent manner. Here, in this review, we outline their façade in normal and diseased central nervous system (CNS) and suggest a role for p75NTR in chronic axonal regeneration whereas TROY in acute inflammation of EAE intercourse.     

New Insights on Neuronal Alterations in Jimpy Mutant Brain

In spite of abundant data on oligodendrocyte abnormalities in dysmyelinated jimpy brain, little is known about the axonal damage and the expression of neuronal genes. Recent findings indicate that Nogo-A, oligodendrocyte-myelin glycoprotein (OMgp), and myelin-associated glycoprotein (MAG) inhibit axonal growth by binding a common receptor, the Nogo-A receptor (NgR)-p75 complex. In order to evaluate neuronal modifications in the absence of myelin and in the presence of abnormal oligodendrocytes at different developmental stages, the expression of these inhibitory proteins and their receptors was investigated in jimpy mutant brain. Despite the decrease in oligodendrocyte number at P15 and P25 in jimpy, Nogo-A and OMgp mRNA levels are not significantly different compared with control, suggesting an overexpression of neuronal Nogo-A and OMgp in mutant. Double immunolabeling for Nogo-A and neurofilaments shows strong axonal staining of Nogo-A in jimpy and its down-regulation in oligodendrocytes. The current data raise questions about functions of Nogo-A other than neurite growth inhibition in the CNS. No significant changes in NgR mRNA levels were observed in jimpy, where the increase in p75 level can be correlated with the cell death of oligodendrocytes. In the paranodal region, the cell adhesion molecule neurofascin glial isoform NFN155 mRNA level is reduced by 40% whereas neuronal form NFN186 is up-regulated. These results may explain the failure of paranodal region organization, even with normal level of CASPR (paranodin) mRNA detected in jimpy brain.     

Nogo在中枢神经损伤再生中的作用机制

Nogo是中枢神经系统（CNS）少突胶质细胞分泌的一种髓磷脂蛋白,它的主要功能是抑制损伤后轴突的再生,它含有两个完全独立的具有抑制活性的结构域：位于细胞内的amino—Nogo和位于细胞表面的Nogo-66。Nogo-66是通过与受体复合体NgR／p75／Lingo—1结合,触发Rho信号通路来发挥作用。Nogo及其信号转导机制日益成为CNS损伤再生的研究热点,就Nogo在CNS损伤再生中的作用机制作一综述。     

Nogo receptor 3, a paralog of Nogo-66 receptor 1 （NgR1）, may function as a NgR1 co-receptor for Nogo-66

Nogo-A is a major myelin associated inhibitor that blocks regeneration of injured axons in the central nervous system (CNS).Nogo-66 (a 66-residue domain of Nogo-A) expressed on the surface of oligodendrocytes has been shown to directly interact with Nogo-66 receptor 1 (NgR1).A number of additional components of NgR1 receptor complex essential for its signaling have been uncovered.However,detailed composition of the complex and its signaling mechanisms remain to be fully elucidated.In this study,we show that Nogo receptor 3 (NgR3),a paralog of NgR1,is a binding protein for NgR1.The interaction is highly specific because other members of the reticulin family,to which Nogo-A belongs,do not bind to NgR3.Neither does NgR3 show any binding activity with Nogo receptor 2 (NgR2),another NgR1 paralog.Majority of NgR3 domains are required for its binding to NgR1.Moreover,a truncated NgR3 with the membrane anchoring domain deleted can function as a decoy receptor to reverse neurite outgrowth inhibition caused by Nogo-66 in culture.These in vitro results,together with previously reported overlapping expression profile between NgR1 and NgR3,suggest that NgR3 may be associated with NgR1 in vivo and that their binding interface may be targeted for treating neuronal injuries.     

Epitope mapping of the neuronal growth inhibitor Nogo-A for the Nogo receptor and the cognate monoclonal antibody IN-1 by means of the SPOT technique

Nogo-A is a potent inhibitor of axonal outgrowth in the central nervous system of adult mammals, where it is expressed as a membrane protein on oligodendrocytes and in myelin. Here we describe an attempt to identify linear peptide epitopes in its sequence that are responsible for the interaction either with the Nogo receptor (NgR) or with the neutralizing monoclonal antibody IN-1. Analysis of an array of immobilized overlapping 15 mer peptides covering the entire amino acid sequence of human Nogo-A (1192 residues) revealed a single epitope with prominent binding activity both towards the recombinant NgR and the IN-1 F(ab) fragment. Further truncation and substitution analysis yielded the minimal epitope sequence 'IKxLRRL' (x not equal to P), which occurs within the so-called Nogo66 region (residues 1054-1120) of Nogo-A. The bacterially produced Nogo66 fragment exhibited binding activity both for the recombinant NgR and for the IN-1 F(ab) fragment on the Western blot as well as in ELISA. Unexpectedly, the synthetic epitope peptide and the recombinant Nogo66 showed cross-reactivity with the 8-18C5 F(ab) fragment, which is directed against myelin oligodendrocyte glycoprotein (MOG) as a structurally unrelated target. On the other hand, the recombinant N-terminal domain of Nogo-A (residues 334-966) was shown to specifically interact on the Western blot and in an ELISA with the IN-1 F(ab) fragment but not with the recombinant NgR, which is in agreement with previous results. Hence, our data suggest that there is a distinct binding site for the Nogo receptor in the Nogo66 region of Nogo-A, whereas its interaction with NgR is less specific than anticipated before. Although there probably exists a non-linear epitope for the neutralizing antibody IN-1 in the N-terminal region of Nogo-A, which is likely to be accessible from outside the cell, a previously postulated second binding site for NgR in this region (called Nogo-A-24) remains elusive.     

The Nogo-66 receptor family in the intact and diseased CNS

The Nogo-66 receptor family (NgR) consists in three glycophosphatidylinositol (GPI)-anchored receptors (NgR1, NgR2 and NgR3), which are primarily expressed by neurons in the central and peripheral mammalian nervous system. NgR1 was identified as serving as a high affinity binding protein for the three classical myelin-associated inhibitors (MAIs) Nogo-A, myelin-associated glycoprotein (MAG) and oligodendrocyte myelin glycoprotein (OMgp), which limit axon regeneration and sprouting in the injured brain. Recent studies suggest that NgR signaling may also play an essential role in the intact adult CNS in restricting axonal and synaptic plasticity and are involved in neurodegenerative diseases, particularly in Alzheimer's disease pathology through modulation of β-secretase cleavage. Here, we outline the biochemical properties of NgRs and their functional roles in the intact and diseased CNS.     

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。     

Nogo-A and Nogo-66 receptor in amyotrophic lateral sclerosis

Nogo/reticulon (RTN)-4 has been strongly implicated as a disease marker for the motor neuron disease amyotrophic lateral sclerosis (ALS). Nogo isoforms, including Nogo-A, are ectopically expressed in the skeletal muscle of ALS mouse models and patients and their levels correlate with the disease severity. The notion of a direct involvement of Nogo-A in ALS aetiology is supported by the findings that Nogo-A deletion in mice reduces muscle denervation and prolongs survival, whereas overexpression of Nogo-A destabilizes motor nerve terminals and promotes denervation. Another intriguing, and somewhat paradoxical, recent finding revealed that binding of the Nogo-66 receptor (NgR) by either agonistic or antagonistic Nogo-66-derived peptides protects against p75 neurotrophin receptor (p75(NTR))-dependent motor neuron death. Ligand binding by NgR could result in subsequent engagement of p75(NTR), and this association could preclude pro-apoptotic signalling by the latter. Understanding the intricate interplay among Nogo isoforms, NgR and p75(NTR) in ALS disease progression may provide important, therapeutically exploitable information.     

Getting RIP'd Stunts Your Growth

The p75 neurotrophin receptor (p75NTR) collaborates with the Nogo receptor (NgR) and LINGO-1 to activate RhoA in response to myelin-based growth inhibitors such as myelin-associated glycoprotein (MAG). In this issue of Neuron, Domeniconi et al., in a surprising turn, show that MAG induces intramembrane proteolysis (RIP) of p75NTR and find that p75NTR cleavage is required for MAG-induced RhoA activation and growth inhibition.     

中枢神经系统轴突再生抑制蛋白

中枢神经系统 (CNS)轴突再生的主要障碍之一是存在抑制再生的蛋白 ,迄今 ,已在少突胶质细胞 /髓鞘中相继发现至少三个重要的轴突再生抑制蛋白 ,即髓鞘相关糖蛋白 (MAG)、Nogo A和少突胶质细胞 /髓鞘糖蛋白 (OMgp)。最近的研究又证实 ,这三个不同的抑制成分可能主要通过与一个共同的受体Nogo6 6受体 (NgR)结合而发挥作用。这些研究成果扩充了对CNS损伤后轴突再生障碍的理解 ,也为探讨CNS损伤的治疗新策略提供了新的思路。     

Olfactomedin 1 Interacts with the Nogo A Receptor Complex to Regulate Axon Growth

Olfm1, a secreted highly conserved glycoprotein, is detected in peripheral and central nervous tissues and participates in neural progenitor maintenance, cell death in brain, and optic nerve arborization. In this study, we identified Olfm1 as a molecule promoting axon growth through interaction with the Nogo A receptor (NgR1) complex. Olfm1 is coexpressed with NgR1 in dorsal root ganglia and retinal ganglion cells in embryonic and postnatal mice. Olfm1 specifically binds to NgR1, as judged by alkaline phosphatase assay and coimmunoprecipitation. The addition of Olfm1 inhibited the growth cone collapse of dorsal root ganglia neurons induced by myelin-associated inhibitors, indicating that Olfm1 attenuates the NgR1 receptor functions. Olfm1 caused the inhibition of NgR1 signaling by interfering with interaction between NgR1 and its coreceptors p75NTR or LINGO-1. In zebrafish, inhibition of optic nerve extension by olfm1 morpholino oligonucleotides was partially rescued by dominant negative ngr1 or lingo-1. These data introduce Olfm1 as a novel NgR1 ligand that may modulate the functions of the NgR1 complex in axonal growth.     

Characterization of myelin ligand complexes with neuronal Nogo-66 receptor family members

Nogo, MAG, and OMgp are myelin-associated proteins that bind to a neuronal Nogo-66 receptor (NgR/NgR1) to limit axonal regeneration after central nervous system injury. Within Nogo-A, two separate domains are known interact with NgR1. NgR1 is the founding member of the three-member NgR family, whereas Nogo-A (RTN4A) belongs to a four-member reticulon family. Here, we systematically mapped the interactions between these superfamilies, demonstrating novel nanomolar interactions of RTN2 and RTN3 with NgR1. Because RTN3 is expressed in spinal cord white matter, it may have a role in myelin inhibition of axonal growth. Further analysis of the Nogo-A and NgR1 interactions revealed a novel third interaction site between the proteins, suggesting a trivalent Nogo-A interaction with NgR1. We also confirmed here that MAG binds to NgR2, but not to NgR3. Unexpectedly, we found that OMgp interacts with MAG with a higher affinity compared with NgR1. To better define how these multiple structurally distinct ligands bind to NgR1, we examined a series of Ala-substituted NgR1 mutants for ligand binding activity. We found that the core of the binding domain is centered in the middle of the concave surface of the NgR1 leucine-rich repeat domain and surrounded by differentially utilized residues. This detailed knowledge of the molecular interactions between NgR1 and its ligands is imperative when assessing options for development of NgR1-based therapeutics for central nervous system injuries.     

Molecular dissection of the myelin-associated glycoprotein receptor complex reveals cell type-specific mechanisms for neurite outgrowth inhibition

Neuronal Nogo66 receptor-1 (NgR1) binds the myelin inhibitors NogoA, OMgp, and myelin-associated glycoprotein (MAG) and has been proposed to function as the ligand-binding component of a receptor complex that also includes Lingo-1, p75(NTR), or TROY. In this study, we use Vibrio cholerae neuraminidase (VCN) and mouse genetics to probe the molecular composition of the MAG receptor complex in postnatal retinal ganglion cells (RGCs). We find that VCN treatment is not sufficient to release MAG inhibition of RGCs; however, it does attenuate MAG inhibition of cerebellar granule neurons. Furthermore, the loss of p75(NTR) is not sufficient to release MAG inhibition of RGCs, but p75(NTR-/-) dorsal root ganglion neurons show enhanced growth on MAG compared to wild-type controls. Interestingly, TROY is not a functional substitute for p75(NTR) in RGCs. Finally, NgR1(-/-) RGCs are strongly inhibited by MAG. In the presence of VCN, however, NgR1(-/-) RGCs exhibit enhanced neurite growth. Collectively, our experiments reveal distinct and cell type-specific mechanisms for MAG-elicited growth inhibition.     

Segregation of Nogo66 receptors into lipid rafts in rat brain and inhibition of Nogo66 signaling by cholesterol depletion

NogoA, a myelin-associated component, inhibits neurite outgrowth. Nogo66, a portion of NogoA, binds to Nogo66 receptor (NgR) and induces the inhibitory signaling. LINGO-1 and p75 neurotrophin receptor (p75), the low-affinity nerve growth factor receptor, are also required for NogoA signaling. However, signaling mechanisms downstream to Nogo receptor remain poorly understood. Here, we observed that NgR and p75 were colocalized in low-density membrane raft fractions derived from forebrains and cerebella as well as from cerebellar granule cells. NgR interacted with p75 in lipid rafts. In addition, disruption of lipid rafts by beta-methylcyclodextrin, a cholesterol-binding reagent, reduced the Nogo66 signaling. Our results suggest an important role of lipid rafts in facilitating the interaction between NgRs and provide insight into mechanisms underlying the inhibition of neurite outgrowth by NogoA.