The p75 Neurotrophin Receptor Mediates Neuronal Apoptosis and Is Essential for Naturally Occurring Sympathetic Neuron Death

Abstract. To determine whether the p75 neurotrophin receptor (p75NTR) plays a role in naturally occurring neuronal death, we examined neonatal sympathetic neurons that express both the TrkA tyrosine kinase receptor and p75NTR. When sympathetic neuron survival is maintained with low quantities of NGF or KCl, the neurotrophin brain-derived neurotrophic factor (BDNF), which does not activate Trk receptors on sympathetic neurons, causes neuronal apoptosis and increased phosphorylation of c-jun. Function-blocking antibody studies indicate that this apoptosis is due to BDNF-mediated activation of p75NTR. To determine the physiological relevance of these culture findings, we examined sympathetic neurons in BDNF−/− and p75NTR−/− mice. In BDNF−/− mice, sympathetic neuron number is increased relative to BDNF+/+ littermates, and in p75NTR−/− mice, the normal period of sympathetic neuron death does not occur, with neuronal attrition occurring later in life. This deficit in apoptosis is intrinsic to sympathetic neurons, since cultured p75NTR−/− neurons die more slowly than do their wild-type counterparts. Together, these data indicate that p75NTR can signal to mediate apoptosis, and that this mechanism is essential for naturally occurring sympathetic neuron death.     

Expression of TrkB Receptors in Developing Visual Cortex Is Not Regulated by Light

1. Neurotrophins are very good candidates which relate electrical activity to molecular changes in activity-dependent phenomena. They exert their action through binding to specific tyrosine-kinase receptors: Trk receptors. It is important to consider Trk distribution in order to understand better the role of neurotrophins in the Central Nervous System (CNS). We focused our attention on brain-derived neurotrophic factor (BDNF) Trk receptors (TrkB) during development of the rat visual cortex, since this neurotrophin has been shown to play an important role in visual system development and plasticity.2. We investigated the full length form of TrkB receptors considering both its total amount and its cellular distribution. To address this issue we used an antibody that recognizes the full length form of TrkB and we used it both in Western blot and immunohistochemistry.3. We found that the expression of TrkB receptor increases during development, but that there is no effect on visual experience, since dark-reared animals show the same protein level and pattern of TrkB expression compared to age-matched, normally reared controls.     

The p75 neurotrophin receptor enhances TrkA signalling by binding to Shc and augmenting its phosphorylation

Nerve growth factor (NGF) is an important neuronal survival factor, especially during development. Optimal sensitivity of the survival response to NGF requires the presence of TrkA and the p75 neurotrophin receptor, p75(NTR). Signalling pathways used by TrkA are well established, but the mechanisms by which p75(NTR) enhances NGF signalling remain far from clear. A prevalent view is that p75(NTR) and TrkA combine to form a high-affinity receptor, but definitive evidence for this is still lacking. We therefore investigated the possibility that p75(NTR) and TrkA interact via their signal transduction pathways. Using antisense techniques to down-regulate p75(NTR) and TrkA, we found that p75(NTR) specifically enhanced phosphorylation of the 46- and 52-kDa isoforms of Shc during nerve growth factor-induced TrkA activation. p75(NTR) did not enhance tyrosine phosphorylation of other TrkA substrates. Serine phosphorylation of Akt, downstream of Shc activation, was also p75(NTR)-dependent. We consistently detected co-immunoprecipitation of p75(NTR) and Shc. These data indicate that p75(NTR) interacts with Shc physically, via a binding interaction, and functionally, by assisting its phosphorylation. Whilst providing evidence that p75(NTR) augments TrkA signal transduction, these results do not preclude the presence of a p75(NTR)-TrkA high-affinity NGF receptor.     

Dissecting NGF interactions with TrkA and p75 receptors by structural and functional studies of an anti-NGF neutralizing antibody

The anti-nerve growth factor (NGF) monoclonal antibody αD11 is a potent antagonist that neutralizes the biological functions of its antigen in vivo. NGF antagonism is expected to be a highly effective and safe therapeutic approach in many pain states. A comprehensive functional and structural analysis of αD11 monoclonal antibody was carried out, showing its ability to neutralize NGF binding to either tropomyosine receptor kinase A (TrkA) or p75 receptors. The 3-D structure of the αD11 Fab fragment was solved at 1.7 Å resolution. A computational docking model of the αD11 Fab-NGF complex, based on epitope mapping using a pool of 44 NGF mutants and experimentally validated by small-angle X-ray scattering, provided the structural basis for identifying the residues involved in αD11 Fab binding. The present study pinpoints loop II of NGF to be an important structural determinant for NGF biological activity mediated by TrkA receptor.     

Sympathetic neurons synthesize and secrete pro‐nerve growth factor protein

Postmitotic sympathetic neuronal survival is dependent upon nerve growth factor (NGF) provided by peripheral targets, and this dependency serves as a central tenet of the neurotrophic hypothesis. In some other systems, NGF has been shown to play an autocrine role, although the pervasiveness and significance of this phenomenon within the nervous system remain unclear. We show here that rat sympathetic neurons synthesize and secrete NGF. NGF mRNA is expressed in nearly half of superior cervical ganglion sympathetic neurons at embryonic day 17, rising to over 90% in the early postnatal period, and declining in the adult. Neuronal immunoreactivity is reduced when retrograde transport is interrupted by axotomy, but persists in a subpopulation of neurons despite diminished mRNA expression, suggesting that intrinsic protein synthesis occurs. Cultured neonatal neurons express NGF mRNA, which is maintained even when they are undergoing apoptosis. To determine which NGF isoforms are secreted, we performed metabolic labeling and immunoprecipitation of NGF‐immunoreactive proteins synthesized by cultured NGF‐dependent and ‐independent neurons. Conditioned medium contained high molecular weight NGF precursor proteins, which varied depending upon the state of NGF dependence. Mature NGF was undetectable by these methods. High molecular weight NGF isoforms were also detected in ganglion homogenates, and persisted at diminished levels following axotomy. We conclude that sympathetic neurons express NGF mRNA, and synthesize and secrete pro‐NGF protein. These findings suggest that a potential NGF‐sympathetic neuron autocrine loop may exist in this prototypic target‐dependent system, but that the secreted forms of this neurotrophin apparently do not support neuronal survival. © 2003 Wiley Periodicals, Inc. J Neurobiol 38–53, 2003     

Human ProNGF: biological effects and binding profiles at TrkA, P75NTR and sortilin

Nerve growth factor (NGF) promotes cell survival via binding to the tyrosine kinase receptor A (TrkA). Its precursor, proNGF, binds to p75(NTR) and sortilin receptors to initiate apoptosis. Current disagreement exists over whether proNGF acts neurotrophically following binding to TrkA. As in Alzheimer's disease the levels of proNGF increase and TrkA decrease, it is important to clarify the properties of proNGF. Here, wild-type and cleavage-resistant mutated forms (M) of proNGF were engineered and their binding characteristics determined. M-proNGF and NGF bound to p75(NTR) with similar affinities, whilst M-proNGF had a lower affinity than NGF for TrkA. M-proNGF behaved neurotrophically, albeit less effectively than NGF. M-proNGF addition resulted in phosphorylation of TrkA and ERK1/2, and in PC12 cells elicited neurite outgrowth and supported cell survival. Conversely, M-proNGF addition to cultured cortical neurons initiated caspase 3 cleavage. Importantly, these biological effects were shown to be mediated by unprocessed M-proNGF. Surprisingly, binding of the pro region alone to TrkA, at a site other than that of NGF, caused TrkA and ERK1/2 phosphorylation. Our data show that M-proNGF stimulates TrkA to a lesser degree than NGF, suggesting that in Alzheimer brain the increased proNGF : NGF and p75(NTR) : TrkA ratios may permit apoptotic effects to predominate over neurotrophic effects.     

The role of neurotrophins in the developing nervous system

Neurotrophins were originally identified by their ability to promote the survival of developing neurons. However, recent work on these proteins indicates that they may also influence the proliferation and differentiation of neuron progenitor cells and regular several differentiated traits of neurons throughout life. Moreover, the effects of neurotrophins on survival have turned out to be more complex than originally thought. Some neurons switch their survival requirements from one set of neurotrophins to another during development, and several neurotrophins may be involved in regulating the survival of a population of neurons at any one time. Much of our understanding of the developmental physiology of neurotrophins has come from studying neurons of the peripheral nervous system. Because these neurons and their progenitors are segregated into anatomically discrete sites, it has been possible to obtain these cell for in vitro experimental studies from the earliest stage of their development. The recent generation of mice having null mutations in the neurotrophin and neurotrophin receptor genes has opened up an unparalleled opportunity to assess the physiological relevance of the wealth of data obtained from these in vitro studies. Here I provide a chronological account of the effects of members of the NGF family of neurotrophins on cells of the neural lineage with special reference to the peripheral nervous system. 1994 John Wiley & Sons, Inc.     

The p75 neurotrophin receptor: effects on neuron survival in vitro and interaction with death domain-containing adaptor proteins

The p75 neurotrophin receptor (p75NTR) is a death domain (DD) containing receptor of the TNF/FAS(APO-1) family. p75NTR has recently been shown to mediate apoptosis in certain types of neurons as well as in oligodendrocytes. The molecular mechanisms by which p75NTR stimulates apoptosis are still unknown. Here, we have tested whether overexpression of p75NTR could modulate survival of sympathetic neurons cultured in the presence or absence of NGF. Moreover, using the yeast two-hybrid system, we tested whether p75NTR intracellular domain was able to dimerize or interact with known DD-containing proteins including FADD, RIP, RAIDD and TRADD. We found that over-expression of p75NTR had no effect on the survival of sympathetic neurons cultured in the presence of NGF but instead delayed neuronal death following NGF deprivation. These results strongly support the finding that p75NTR is not involved in the apoptosis process induced by NGF deprivation in sympathetic neurons. We also foun d that the intracellular domain of p75NTR failed to associate either with itself or with other known DD-containing proteins. This suggests that the mechanisms by which p75NTR triggers apoptosis in certain cell types are different from those used by other receptors of the TNF/FAS family.     

High-affinity TrkA and p75 neurotrophin receptor complexes: A twisted affair

Neurotrophin signaling is essential for normal nervous system development and adult function. Neurotrophins are secreted proteins that signal via interacting with two neurotrophin receptor types: the multifaceted p75 neurotrophin receptor and the tropomyosin receptor kinase receptors. In vivo, neurons compete for the limited quantities of neurotrophins, a process that underpins neural plasticity, axonal targeting, and ultimately survival of the neuron. Thirty years ago, it was discovered that p75 neurotrophin receptor and tropomyosin receptor kinase A form a complex and mediate high-affinity ligand binding and survival signaling; however, despite decades of functional and structural research, the mechanism of modulation that yields this high-affinity complex remains unclear. Understanding the structure and mechanism of high-affinity receptor generation will allow development of pharmaceuticals to modulate this function for treatment of the many nervous system disorders in which altered neurotrophin expression or signaling plays a causative or contributory role. Here we re-examine the key older literature and integrate it with more recent studies on the topic of how these two receptors interact. We also identify key outstanding questions and propose a model of inside-out allosteric modulation to assist in resolving the elusive high-affinity mechanism and complex.     

Molecular and Structural Insight into proNGF Engagement of p75NTR and Sortilin

Nerve growth factor (NGF) is initially synthesized as a precursor, proNGF, that is cleaved to release its C-terminal mature form. Recent studies suggested that proNGF is not an inactive precursor but acts as a signaling ligand distinct from its mature counterpart. proNGF and mature NGF initiate opposing biological responses by utilizing both distinct and shared receptor components. In this study, we carried out structural and biochemical characterization of proNGF interactions with p75NTR and sortilin. We crystallized proNGF complexed to p75NTR and present the structure at 3.75-Å resolution. The structure reveals a 2:2 symmetric binding mode, as compared with the asymmetric structure of a previously reported crystal structure of mature NGF complexed to p75NTR and the 2:2 symmetric complex of neurotrophin-3 (NT-3) and p75NTR. Here, we discuss the possible origins and implications of the different stoichiometries. In the proNGF-p75NTR complex, the pro regions of proNGF are mostly disordered and two hairpin loops (loop 2) at the top of the NGF dimer have undergone conformational changes in comparison with mature NT structures, suggesting possible interactions with the propeptide. We further explored the binding characteristics of proNGF to sortilin using surface plasmon resonance and cell-based assays and determined that calcium ions promote the formation of a stable ternary complex of proNGF-sortilin-p75NTR. These results, together with those of previous structural and mechanistic studies of NT-receptor interactions, suggest the potential for distinct signaling activities through p75NTR mediated by different NT-induced conformational changes.     

p75 and TrkA Receptor Signaling Independently Regulate Amyloid Precursor Protein mRNA Expression, Isoform Composition, and Protein Secretion in PC12 Cells

Abstract: The pheochromocytoma PC12 cell line was used as a model system to characterize the role of the p75 neurotrophin receptor (p75^NTR) and tyrosine kinase (Trk) A nerve growth factor (NGF) receptors on amyloid precursor protein (APP) expression and processing. NGF increased in a dose-dependent fashion neurite outgrowth, APP mRNA expression, and APP secretion with maximal effects at concentrations known to saturate TrkA receptor binding. Displacement of NGF binding to p75^NTR by addition of an excess of brain-derived neurotrophic factor abolished NGF's effects on neurite outgrowth and APP metabolism, whereas addition of brain-derived neurotrophic factor alone did not induce neurite outgrowth or affect APP mRNA or protein processing. However, treatment of PC12 cells with C2-ceramide, an analogue of ceramide, the endogenous product produced by the activity of p75^NTR-activated sphingomyelinase, mimicked the effects of NGF on cell morphology and stimulation of both APP mRNA levels and APP secretion. Specific stimulation of TrkA receptors by receptor cross-linking, on the other hand, selectively stimulated neurite outgrowth and APP secretion but not APP mRNA levels, which were decreased. These findings demonstrate that in PC12 cells expressing p75^NTR and TrkA receptors, binding of NGF to the p75^NTR is required to mediate NGF effects on cell morphology and APP metabolism. Furthermore, our data are consistent with NGF having specific effects on p75^NTR not shared with other neurotrophins. Lastly, we have shown that specific activation of TrkA receptors—in contrast to p75^NTR-associated signaling—stimulates neurite outgrowth and increases nonamyloidogenic secretory APP processing without increases in APP mRNA levels.     

Nerve growth factor-stimulated neuronal differentiation induces changes in P2 receptor expression and nucleotide-stimulated catecholamine release

Extracellular nucleotides modulate synaptic transmission and neuronal communication by activating purinergic 2 (P2) (nucleotide) receptors. Here, we assessed changes in the regulation by nucleotides and their receptors of an important physiological response - release and uptake of catecholamines - that accompanies sympathoadrenal neuronal differentiation. Nerve growth factor (NGF)-promoted differentiation of pheochromocytoma 12 (PC12) cells enhanced the ability of the non-hydrolyzable ATP analog, ATPgammaS, to stimulate catecholamine (norepinephrine, NE) release and this enhancement occurred without a significant alteration in NE uptake. In addition to ATPgammaS, 2-MeSATP and alphabetaMeATP, P2X receptor-selective agonists, caused greater NE release from NGF-differentiated than from undifferentiated PC12 cells. NGF-differentiated PC12 cells had altered mRNA expression of several P2Y and P2X receptors but protein expression was only increased for P2X, in particular P2X(1-4,) receptors and P2X, but not P2Y, receptor inhibitors blunted the NGF-promoted enhancement in nucleotide-regulated catecholamine release. Surprisingly, siRNA directed against P2X(2), the receptor with the highest expression, failed to alter NE release by ATPgammaS. These findings indicate that sympathetic neuronal differentiation by NGF increases both the expression of P2X receptor sub-types and their regulation of catecholamine release. NGF-promoted increased expression of P2X receptors thus appears to be a physiologically important response that characterizes sympathetic neuronal differentiation.     

NGF activates the phosphorylation of MAP1B by GSK3beta through the TrkA receptor and not the p75(NTR) receptor

We have recently shown that nerve growth factor (NGF) induces the phosphorylation of the microtubule-associated protein 1B (MAP1B) by activating the serine/threonine kinase glycogen synthase kinase 3beta (GSK3beta) in a spatio-temporal pattern in PC12 cells that correlates tightly with neurite growth. PC12 cells express two types of membrane receptor for NGF: TrkA receptors and p75NTR receptors, and it was not clear from our studies which receptor was responsible. We show here that brain-derived neurotrophic factor, which activates p75NTR but not TrkA receptors, does not stimulate GSK3beta phosphorylation of MAP1B in PC12 cells. Similarly, NGF fails to activate GSK3beta phosphorylation of MAP1B in PC12 cells that lack TrkA receptors but express p75NTR receptors (PC12 nnr). Chick ciliary ganglion neurons in culture lack TrkA receptors but express p75NTR and also fail to show NGF-dependent GSK3beta phosphorylation of MAP1B, whereas in rat superior cervical ganglion neurons in culture, NGF activation of TrkA receptors elicits GSK3beta phosphorylation of MAP1B. Finally, inhibition of TrkA receptor tyrosine kinase activity in PC12 cells and superior cervical ganglion neurons with K252a potently and dose-dependently inhibits neurite elongation while concomitantly blocking GSK3beta phosphorylation of MAP1B. These results suggest that the activation of GSK3beta by NGF is mediated through the TrkA tyrosine kinase receptor and not through p75NTR receptors.     

Regulated release of BDNF by cortical oligodendrocytes is mediated through metabotropic glutamate receptors and the PLC pathway

A number of studies suggest that OLGs (oligodendrocytes), the myelinating cells of the central nervous system, are also a source of trophic molecules, such as neurotrophins that may influence survival of proximate neurons. What is less clear is how the release of these molecules may be regulated. The present study investigated the effects of BDNF (brain-derived neurotrophic factor) derived from cortical OLGs on proximate neurons, as well as regulatory mechanisms mediating BDNF release. Initial work determined that BDNF derived from cortical OLGs increased the numbers of VGLUT1 (vesicular glutamate transporter 1)-positive glutamatergic cortical neurons. Furthermore, glutamate acting through metabotropic, and not AMPA/kainate or NMDA (N-methyl-d-aspartate), receptors increased BDNF release. The PLC (phospholipase C) pathway is a key mediator of metabotropic actions to release BDNF in astrocytes and neurons. Treatment of OLGs with the PLC activator m-3M3FBS [N-(3-trifluoromethylphenyl)-2,4,6-trimethylbenzenesulfonamide] induced robust release of BDNF. Moreover, release elicited by the metabotropic receptor agonist ACPD [trans-(1S,3R)-1-aminocyclopentane-1,3-dicarboxylic acid] was inhibited by the PLC antagonist {"type":"entrez-nucleotide","attrs":{"text":"U73122","term_id":"4098075","term_text":"U73122"}}U73122, the IP₃ (inositol triphosphate 3) receptor inhibitor 2-APB (2-aminoethoxydiphenylborane) and the intracellular calcium chelator BAPTA/AM [1,2-bis-(o-aminophenoxy)ethane-N,N,N′,N′-tetra-acetic acid tetrakis(acetoxymethyl ester)]. Taken together, these results suggest that OLG lineage cells release BDNF, a molecule trophic for proximate neurons. BDNF release is regulated by glutamate acting through mGluRs (metabotropic glutamate receptors) and the PLC pathway. Thus glutamate and BDNF may be molecules that support neuron–OLG interactions in the cortex.     

Generation of mice with a conditional allele for the p75(NTR) neurotrophin receptor gene

The p75(NTR) neurotrophin receptor has been implicated in multiple biological and pathological processes. While significant advances have recently been made in understanding the physiologic role of p75(NTR) , many details and aspects remain to be determined. This is in part because the two existing knockout mouse models (Exons 3 or 4 deleted, respectively), both display features that defy definitive conclusions. Here we describe the generation of mice that carry a conditional p75(NTR) (p75(NTR-FX) ) allele made by flanking Exons 4-6, which encode the transmembrane and all cytoplasmic domains, by loxP sites. To validate this novel conditional allele, both neural crest-specific p75(NTR) /Wnt1-Cre mutants and conventional p75(NTR) null mutants were generated. Both mutants displayed abnormal hind limb reflexes, implying that loss of p75(NTR) in neural crest-derived cells causes a peripheral neuropathy similar to that seen in conventional p75(NTR) mutants. This novel conditional p75(NTR) allele will offer new opportunities to investigate the role of p75(NTR) in specific tissues and cells.     

The p53 family in nervous system development and disease

The p53 family, consisting of the tumor suppressors p53, p63 and p73, play a vital role as regulators of survival and apoptosis in the developing, adult and injured nervous system. These proteins function as key survival and apoptosis checkpoints in neurons, acting as either rheostats or sensors responsible for integrating multiple pro-apoptotic and survival cues. A dramatic example of this checkpoint function is observed in developing sympathetic neurons, where a pro-survival and truncated form of p73 antagonizes the apoptotic functions of p53 and p63. Thus the levels and activities of the different p53 family members may ultimately determine whether neurons either live or die during nervous system development and disease.     

Cyclin-dependent Kinase 5 (Cdk5)-dependent Phosphorylation of p70 Ribosomal S6 Kinase 1 (S6K) Is Required for Dendritic Spine Morphogenesis

The maturation and maintenance of dendritic spines depends on neuronal activity and protein synthesis. One potential mechanism involves mammalian target of rapamycin, which promotes protein synthesis through phosphorylation of eIF4E-binding protein and p70 ribosomal S6 kinase 1 (S6K). Upon extracellular stimulation, mammalian target of rapamycin phosphorylates S6K at Thr-389. S6K also undergoes phosphorylation at other sites, including four serine residues in the autoinhibitory domain. Despite extensive biochemical studies, the importance of phosphorylation in the autoinhibitory domain in S6K function remains unresolved, and its role has not been explored in the cellular context. Here we demonstrated that S6K in neuron was phosphorylated at Ser-411 within the autoinhibitory domain by cyclin-dependent kinase 5. Ser-411 phosphorylation was regulated by neuronal activity and brain-derived neurotrophic factor (BDNF). Knockdown of S6K in hippocampal neurons by RNAi led to loss of dendritic spines, an effect that mimics neuronal activity blockade by tetrodotoxin. Notably, coexpression of wild type S6K, but not the phospho-deficient S411A mutant, could rescue the spine defects. These findings reveal the importance of cyclin-dependent kinase 5-mediated phosphorylation of S6K at Ser-411 in spine morphogenesis driven by BDNF and neuronal activity.