Niemann-Pick Type C1 deficiency in microglia does not cause neuron death in vitro.

Niemann-Pick Type C (NPC) disease is an autosomal recessive disorder that results in accumulation of cholesterol and other lipids in late endosomes/lysosomes and leads to progressive neurodegeneration and premature death. The mechanism by which lipid accumulation causes neurodegeneration remains unclear. Inappropriate activation of microglia, the resident immune cells of the central nervous system, has been implicated in several neurodegenerative disorders including NPC disease. Immunohistochemical analysis demonstrates that NPC1 deficiency in mouse brains alters microglial morphology and increases the number of microglia. In primary cultures of microglia from Npc1(-/-) mice cholesterol is sequestered intracellularly, as occurs in other NPC-deficient cells. Activated microglia secrete potentially neurotoxic molecules such as tumor necrosis factor-α (TNFα). However, NPC1 deficiency in isolated microglia did not increase TNFα mRNA or TNFα secretion in vitro. In addition, qPCR analysis shows that expression of pro-inflammatory and oxidative stress genes is the same in Npc1(+/+) and Npc1(-/-) microglia, whereas the mRNA encoding the anti-inflammatory cytokine, interleukin-10 in Npc1(-/-) microglia is ~60% lower than in Npc1(+/+) microglia. The survival of cultured neurons was not impaired by NPC1 deficiency, nor was death of Npc1(-/-) and Npc1(+/+) neurons in microglia-neuron co-cultures increased by NPC1 deficiency in microglia. However, a high concentration of Npc1(-/-) microglia appeared to promote neuron survival. Thus, although microglia exhibit an active morphology in NPC1-deficient brains, lack of NPC1 in microglia does not promote neuron death in vitro in microglia-neuron co-cultures, supporting the view that microglial NPC1 deficiency is not the primary cause of neuron death in NPC disease.

Involvement of CTP:phosphocholine cytidylyltransferase-ß2 in axonal phosphatidylcholine synthesis and branching of neurons.

In the brain, phosphatidylcholine (PC) is synthesized by the CDP-choline pathway in which the rate-limiting step is catalyzed by two isoforms of CTP:phosphocholine cytidylyltransferase (CT): CTα and CTß2. In mice, CTß2 mRNA is more highly expressed in the brain than in other tissues, and several observations suggest that CTß2 plays an important role in the nervous system. We, therefore, investigated the importance of CTß2 for PC synthesis as well as for axon formation, growth and branching of primary sympathetic neurons. We show that in cultured primary neurons nerve growth factor increases the amount of CTß2, but not CTα, mRNA and protein. The brains of mice lacking CTß2 had normal PC content despite having 35% lower CT activity than wild-type brains. CTß2 mRNA and protein are abundant in distal axons of mouse sympathetic neurons whereas CTα mRNA and protein were not detected. Moreover, CTß2 deficiency in distal axons reduced the incorporation of [(3)H]choline into PC by 95% whereas PC synthesis in cell bodies/proximal axons was unaltered. These data suggest that CTß2 is the major CT isoform involved in PC synthesis in axons. Axons of CTß2-deficient sympathetic neurons contained 32% fewer branch points than did wild-type neurons although the number of axons/neuron and the rate of axon extension were the same as in wild-type neurons. We conclude that in distal axons of primary sympathetic neurons CTß2 is a major contributor to PC synthesis and promotes axon branching, whereas CTα appears to be the major CT isoform involved in PC synthesis in cell bodies/proximal axons.

Involvement of low-density lipoprotein receptor-related protein and ABCG1 in stimulation of axonal extension by apoE-containing lipoproteins.

Apolipoprotein E (apoE)-containing lipoproteins (LpE) are produced by glial cells in the central nervous system (CNS). When LpE are supplied to distal axons, but not cell bodies, of CNS neurons (retinal ganglion cells) the rate of axonal extension is increased. In this study we have investigated the molecular requirements underlying the stimulatory effect of LpE on axonal extension. We show that enhancement of axonal growth by LpE requires the presence of the low-density lipoprotein receptor-related protein-1 (LRP1) in neurons since RNA silencing of LRP1 in neurons, or antibodies directed against LRP, suppressed the LpE-induced axonal extension. In contrast, an alternative LRP1 ligand, α2-macroglobulin, failed to stimulate axonal extension, suggesting that LpE do not exert their growth-stimulatory effect solely by activation of a LRP1-mediated signaling pathway. In addition, although apoE3-containing LpE enhanced axonal extension, apoE4-containing LpE did not. Over-expression of ABCG1 in rat cortical glial cells resulted in production of LpE that increased the rate of axonal extension to a greater extent than did expression of an inactive, mutant form of ABGC1. Furthermore, reconstituted lipoprotein particles containing apoE3, phosphatidylcholine and sphingomyelin, but not cholesterol, stimulated axonal extension, suggesting that sphingomyelin, but not cholesterol, is involved in the stimulatory effect of LpE. These observations demonstrate that LpE and LRP1 promote axonal extension, and suggest that lipids exported to LpE by ABCG1 are important for the enhancement of axonal extension mediated by LpE.

Protection of neurons from apoptosis by apolipoprotein E-containing lipoproteins does not require lipoprotein uptake and involves activation of phospholipase Cgamma1 and inhibition of calcineurin.

Apolipoprotein E-containing lipoproteins (LpE) are generated in the central nervous system by glial cells, primarily astrocytes, and are recognized as key players in lipid metabolism and transport in the brain. We previously reported that LpE protect retinal ganglion neurons from apoptosis induced by withdrawal of trophic additives (Hayashi, H., Campenot, R. B., Vance, D. E., and Vance, J. E. (2007) J. Neurosci. 27, 1933-1941). LpE bind to low density lipoprotein receptor-related protein-1 and initiate a signaling pathway that involves activation of protein kinase Cdelta and inhibition of the pro-apoptotic glycogen synthase kinase-3beta. We now show that uptake of LpE is not required for the neuroprotection. Experiments with inhibitors of phospholipase Cgamma1 and RNAi knockdown studies demonstrate that activation of phospholipase Cgamma1 is required for the anti-apoptotic signaling pathway induced by LpE. In addition, the protein phosphatase-2B, calcineurin, is involved in a neuronal death pathway induced by removal of trophic additives, and LpE inhibit calcineurin activation. LpE also attenuate neuronal death caused by oxidative stress. Moreover, physiologically relevant apoE3-containing lipoproteins generated by apoE3 knock-in mouse astrocytes more effectively protect neurons from apoptosis than do apoE4-containing lipoproteins. Because inheritance of the apoE4 allele is the strongest known genetic risk factor for Alzheimer disease, the reduced neuroprotection afforded by apoE4-containing LpE might contribute to the neurodegeneration characteristic of this disease.

Apolipoprotein E-containing lipoproteins protect neurons from apoptosis via a signaling pathway involving low-density lipoprotein receptor-related protein-1.

Apolipoprotein E (apoE)-containing lipoproteins (LPs) are secreted by glia and play important roles in lipid homeostasis in the CNS. Glia-derived LPs also promote synaptogenesis and stimulate axon growth of CNS neurons. Here, we provide evidence that glia-derived LPs protect CNS neurons from apoptosis by a receptor-mediated signaling pathway. The protective effect was greater for apolipoprotein E3 than for apolipoprotein E4, the expression of which is a risk factor for Alzheimer's disease. The anti-apoptotic effect of LPs required the association of apolipoprotein E with lipids but did not require cholesterol. Apoptosis was not prevented by lipids alone or by apoA1- or apoJ-containing lipoproteins. The prevention of neuronal apoptosis was initiated after the binding of LPs to the low-density lipoprotein receptor-related protein (LRP), a multifunctional receptor of the low-density lipoprotein receptor family. We showed that inhibition of LRP activation, by treatment of neurons with receptor-associated protein or anti-LRP antibodies, or by LRP gene-silencing experiments, reduced the protective effect of LPs. Furthermore, another LRP ligand, alpha2-macroglobulin, also protected the neurons from apoptosis. After binding to LRP, LPs initiate a signaling pathway that involves activation of protein kinase Cdelta and inactivation of glycogen synthase kinase-3beta. These findings indicate the potential for using glial lipoproteins or an activator of the LRP signaling pathway for treatment for neurodegenerative disorders such as Alzheimer's disease.

A nerve growth factor-induced retrograde survival signal mediated by mechanisms downstream of TrkA.

Considerable evidence suggests that mammalian neurons are always poised to destroy themselves by apoptosis but are blocked by retrograde survival signals triggered in their axon terminals by neurotrophic factors secreted by the target cells they innervate. Studies with nerve growth factor (NGF) and its receptor, TrkA, form the basis of the prevalent theory of retrograde signaling. According to this theory, retrograde survival signals travel to the cell bodies in the form of endosomes produced at the axon terminals with internalized NGF in their lumens bound to phosphorylated TrkA in their membranes. The inhibition of TrkA phosphorylation in the cell bodies of sympathetic neurons in compartmented cultures by K252a blocked retrograde NGF signaling in some studies in accord with this theory, but other studies do not show a block. We report that local block of TrkA phosphorylation in the cell bodies and proximal axons with another kinase inhibitor, Gö6976 (25nM), did not block the survival signal from NGF at distal axons, while Gö6976 at the distal axons completely blocked the retrograde survival signal. These results suggest that downstream signals activated by phosphorylated TrkA in the distal axons carry the retrograde survival signals to the cell bodies, possibly via a downstream type of signaling endosome not necessarily transporting NGF or phosphorylated TrkA. Unlike Gö6976, K252a exerted a survival effect on its own when applied to cell bodies/proximal axons or distal axons of completely NGF-deprived neurons. The latter effect suggests that downstream retrograde survival signals can arise from alterations in one or more kinase activities in the distal axons without activation of TrkA by NGF.

Application of Rho antagonist to neuronal cell bodies promotes neurite growth in compartmented cultures and regeneration of retinal ganglion cell axons in the optic nerve of adult rats.

Inactivation of Rho promotes neurite growth on inhibitory substrates and axon regeneration in vivo. Here, we compared axon growth when neuronal cell bodies or injured axons were treated with a cell-permeable Rho antagonist (C3-07) in vitro and in vivo. In neurons plated in compartmented cultures, application of C3-07 to either cell bodies or distal axons promoted axonal growth on myelin-associated glycoprotein substrates. In vivo, an injection of C3-07 into the eye promoted regeneration of retinal ganglion cell (RGC) axons in the optic nerve after microcrush lesion. Delayed application of C3-07 promoted RGC growth across the lesion scar. Application of C3-07 completely prevented RGC cell death for 1 week after axotomy. To investigate the mechanism by which Rho inactivation promotes RGC growth, we studied slow axonal transport. Reduction in slow transport of cytoskeletal proteins was observed after axotomy, but inactivation of Rho did not increase slow axonal transport rates. Together, our results indicate that application of a Rho antagonist at the cell body is neuroprotective and overcomes growth inhibition but does not fully prime RGCs for active growth.

Generation and function of astroglial lipoproteins from Niemann-Pick type C1-deficient mice.

NPC (Niemann-Pick type C) disease is a progressive neurological disorder characterized by defects in intracellular cholesterol trafficking, accumulation of cholesterol in the endosomal system and impaired cholesterol homoeostasis. Although these alterations appear to occur in all NPC1-deficient cell types, the consequences are most profound in the nervous system. Since glial cells are important mediators of brain cholesterol homoeostasis, we proposed that defective generation and/or function of lipoproteins released by glia might contribute to the neurological abnormalities associated with NPC disease. We found that, as in other cell types, Npc1-/- glia accumulate cholesterol intracellularly. We hypothesized that this sequestration of cholesterol in glia might restrict the availability of cholesterol for lipoprotein production. Cerebellar astroglia were cultured from a murine model of NPC disease to compare the lipoproteins generated by these cells and wild-type glia. The experiments demonstrate that the amount of cholesterol in glia-conditioned medium is not reduced by NPC1 deficiency. Similarly, cholesterol efflux to apo (apolipoprotein) A1 or glial expression of the transporter ATP-binding-cassette transporter A1 was not decreased by NPC1 deficiency. In addition, the ratio of apo E:cholesterol and the density distribution of lipoproteins in Npc1-/- and Npc1+/+ glia-conditioned medium are indistinguishable. Importantly, in a functional assay, apo E-containing lipoproteins generated by Npc1-/- and Npc1+/+ glia each stimulate axonal elongation of neurons by approx. 35%. On the basis of these observations, we speculate that the neuropathology characteristic of NPC disease can quite probably be ascribed to impaired processes within neurons in the brain rather than defective lipoprotein production by astroglia.

Spatial requirements for TrkA kinase activity in the support of neuronal survival and axon growth in rat sympathetic neurons.

Nerve growth factor (NGF) interacts with its receptor tyrosine kinase, TrkA, at axon terminals to produce local signals within axon terminals and retrograde signals to the neuronal cell body. According to prevalent theory, retrograde signaling requires the retrograde transport to the cell bodies of signaling endosomes containing activated TrkA complexed with NGF. Alternative mechanisms in which retrograde signals reach the cell bodies unaccompanied by NGF may or may not require activated TrkA in the cell body. To help distinguish this possibility, we investigated the spatial requirements of TrkA kinase activity for neuronal survival and axon growth in rat sympathetic neurons supported by NGF provided only to distal axons. Inhibition of local TrkA kinase activity in the distal axons by K252a blocked local axon growth and induced apoptosis. Although local application of K252a to cell bodies/proximal axons resulted in a sustained loss of phosphorylated TrkA from the cell bodies/proximal axons, the neurons survived, and growth of the distal axons was not inhibited. These results suggest that TrkA kinase activity in distal axons, but not in the cell bodies, is required for both local growth and retrograde survival signaling. These results support the hypothesis that retrograde signals can be carried by mechanisms downstream of TrkA activity.

A HaloTag® method for assessing the retrograde axonal transport of the p75 neurotrophin receptor and other proteins in compartmented cultures of rat sympathetic neurons.

We have adapted HaloTag® (HT) technology for use in compartmented cultures of rat sympathetic neurons in order to provide a technique that can be broadly applied to studies of the retrograde transport of molecules that play roles in neurotrophin signaling. Transfected neurons expressing HT protein alone, HT protein fused to the p75 neurotrophin receptor (p75NTR) or HT protein fused to tubulin α-1B were maintained in compartmented cultures in which cell bodies and proximal axons of rat sympathetic neurons reside in proximal compartments and their distal axons extend into distal compartments. HT ligand containing a fluorescent tetramethylrhodamine (TMR) label was applied either in the distal compartments or the proximal compartments, and the transport of labeled proteins was assayed by gel fluorescence imaging and TMR immunoblot. HT protein expressed alone displayed little or no retrograde transport. HT protein fused to either the intracellular C-terminus or the extracellular N-terminus of p75NTR was retrogradely transported. The retrograde transport of p75NTR was augmented when the distal axons were provided with nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF) or antibodies to BDNF. The anterograde transport of HT protein fused to the N-terminus of tubulin α-1B was also demonstrated. We conclude that retrograde transport of HT fusion proteins provides a powerful and novel approach in studies of axonal transport.

NGF uptake and retrograde signaling mechanisms in sympathetic neurons in compartmented cultures.

Many neurons depend for their survival on retrograde signals to their cell bodies generated by nerve growth factor (NGF) or other neurotrophins at their axon terminals. Apoptosis resulting from the loss of retrograde NGF signaling contributes to the elimination of excess and misconnected neurons during development and to the death of neurons during the course of neurodegenerative diseases. Possible mechanisms of retrograde signaling include (1) retrograde transport of signaling endosomes, carrying NGF bound to activated TrkA, (2) retrograde transport of signaling molecules downstream of TrkA, and (3) retrograde propagation of a phosphorylation signal without transport of signaling molecules. Evidence is also described, which indicates that two or more retrograde signaling mechanisms exist to regulate neuronal survival, including recent evidence that withdrawal of NGF from distal axons produces a retrograde apoptotic signal, which is transported to the cell bodies, where it initiates the apoptotic program, leading to the death of the neuron.

A retrograde apoptotic signal originating in NGF-deprived distal axons of rat sympathetic neurons in compartmented cultures.

Previous investigations of retrograde survival signaling by nerve growth factor (NGF) and other neurotrophins have supported diverse mechanisms, but all proposed mechanisms have in common the generation of survival signals retrogradely transmitted to the neuronal cell bodies. We report the finding of a retrograde apoptotic signal in axons that is suppressed by local NGF signaling. NGF withdrawal from distal axons alone was sufficient to activate the pro-apoptotic transcription factor, c-jun, in the cell bodies. Providing NGF directly to cell bodies, thereby restoring a source of NGF-induced survival signals, could not prevent c-jun activation caused by NGF withdrawal from the distal axons. This is evidence that c-jun is not activated due to loss of survival signals at the cell bodies. Moreover, blocking axonal transport with colchicine inhibited c-jun activation caused by NGF deprivation suggesting that a retrogradely transported pro-apoptotic signal, rather than loss of a retrogradely transported survival signal, caused c-jun activation. Additional experiments showed that activation of c-jun, pro-caspase-3 cleavage, and apoptosis were blocked by the protein kinase C inhibitors, rottlerin and chelerythrine, only when applied to distal axons suggesting that they block the axon-specific pro-apoptotic signal. The rottlerin-sensitive mechanism was found to regulate glycogen synthase kinase 3 (GSK3) activity. The effect of siRNA knockdown, and pharmacological inhibition of GSK3 suggests that GSK3 is required for apoptosis caused by NGF deprivation and may function as a retrograde carrier of the axon apoptotic signal. The existence of a retrograde death signaling system in axons that is suppressed by neurotrophins has broad implications for neurodevelopment and for discovering treatments for neurodegenerative diseases and neurotrauma.

Production of compartmented cultures of rat sympathetic neurons.

The compartmented culture, in which primary neurons plated in a proximal compartment send their axons under silicone grease barriers and into left and right distal compartments, has enhanced the experimental capabilities of neuronal cultures. Treatments can be applied separately to cell bodies/proximal axons or distal axons, and cell bodies/proximal axons and distal axons can be separately harvested and analyzed. Distal axons can be axotomized, and the neurons can be studied while their axons regenerate. Construction of the culture dishes requires 3 h for 48 cultures, and preparing the neurons also requires 3 h. Compartmented cultures provide enough cellular material for biochemical analyses such as immunoblotting. The uses of compartmented cultures have included studies of neurotrophic factor retrograde signaling, axonal transport, and axonal protein and lipid biosynthesis. Here we focus on sympathetic neurons cultured from neonatal rats and provide protocols for the production and some of the uses of compartmented cultures.

Phosphatidylcholine biosynthesis via CTP:phosphocholine cytidylyltransferase 2 facilitates neurite outgrowth and branching.

Hallmarks of neuronal differentiation are neurite sprouting, extension, and branching. We previously showed that increased expression of CTP:phosphocholine cytidylyltransferase beta2 (CTbeta2), an isoform of a key phosphatidylcholine (PC) biosynthetic enzyme, accompanies neurite outgrowth (Carter, J. M., Waite, K. A., Campenot, R. B., Vance, J. E., and Vance, D. E. (2003) J. Biol. Chem. 278, 44988-44994). CTbeta2 mRNA is highly expressed in the brain. We show that CTbeta2 is abundant in axons of rat sympathetic neurons and retinal ganglion cells. We used RNA silencing to decrease CTbeta2 expression in PC12 cells differentiated by nerve growth factor. In CTbeta2-silenced cells, numbers of primary and secondary neurites were markedly reduced, suggesting that CTbeta2 facilitates neurite outgrowth and branching. However, the length of individual neurites was significantly increased, and the total amount of neuronal membrane was unchanged. Neurite branching of PC12 cells is known to be inhibited by activation of Akt and promoted by the Akt inhibitor LY294002. Our experiments showed that LY294002 increases neurite sprouting and branching in control PC12 cells but not in CTbeta2-deficient cells. CTbeta2 was not phosphorylated in vitro by Akt. However, inhibition of Cdk5 by roscovitine blocked CTbeta2 phosphorylation and reduced neurite outgrowth and branching. These results highlight the importance of CTbeta2 in neurons for promoting neurite outgrowth and branching and represent the first identification of a lipid biosynthetic enzyme that facilitates these functions.

The Niemann-Pick C1 protein in recycling endosomes of presynaptic nerve terminals.

Niemann-Pick type C (NPC) disease is a fatal, neurodegenerative disorder caused in 95% of cases by loss of function of NPC1, a ubiquitous endosomal transmembrane protein. A biochemical hallmark of NPC deficiency is cholesterol accumulation in the endocytic pathway. Although cholesterol trafficking defects are observed in all cell types, neurons are the most vulnerable to NPC1 deficiency, suggesting a specialized function for NPC1 in neurons. We investigated the subcellular localization of NPC1 in neurons to gain insight into the mechanism of action of NPC1 in neuronal metabolism. We show that NPC1 is abundant in axons of sympathetic neurons and is present in recycling endosomes in presynaptic nerve terminals. NPC1 deficiency causes morphological and biochemical changes in the presynaptic nerve terminal. Synaptic vesicles from Npc1(-/-) mice have normal cholesterol content but altered protein composition. We propose that NPC1 plays a previously unrecognized role in the presynaptic nerve terminal and that NPC1 deficiency at this site might contribute to the progressive neurological impairment in NPC disease.

Expression of ABCG1, but not ABCA1, correlates with cholesterol release by cerebellar astroglia.

Central nervous system lipoproteins mediate the exchange of cholesterol between cells and support synaptogenesis and neuronal growth. The primary source of lipoproteins in the brain is astroglia cells that synthesize and secrete apolipoprotein (apo) E in high density lipoprotein-like particles. Small quantities of apoA1, derived from the peripheral circulation, are also present in the brain. In addition to the direct secretion of apoE-containing lipoproteins from astroglia, glia-derived lipoproteins are thought to be formed by cholesterol efflux to extracellular apolipoproteins via ATP-binding cassette (ABC) transporters. We used cultured cerebellar murine astroglia to investigate the relationship among cholesterol availability, apoE secretion, expression of ABCA1 and ABCG1, and cholesterol efflux. In many cell types, cholesterol content, ABCA1 expression, and cholesterol efflux are closely correlated. In contrast, cholesterol enrichment of glia failed to increase ABCA1 expression, although ABCG1 expression and cholesterol efflux to apoA1 were increased. Moreover, the liver X receptor (LXR) agonist TO901317 up-regulated ABCA1 and ABCG1 expression in glia without stimulating cholesterol efflux. Larger lipoproteins were generated when glia were enriched with cholesterol, whereas treatment with the LXR agonist produced smaller particles that were eliminated when the glia were loaded with cholesterol. We also used glia from ApoE(-/-) mice to distinguish between direct lipoprotein secretion and the extracellular generation of lipoproteins. Our observations indicate that partially lipidated apoE, secreted directly by glia, is likely to be the major extracellular acceptor of cholesterol released from glia in a process mediated by ABCG1.

Regulation of Wallerian degeneration and nerve growth factor withdrawal-induced pruning of axons of sympathetic neurons by the proteasome and the MEK/Erk pathway.

Treatment of transected distal axons of rat sympathetic neurons in compartmented cultures with MG132 (5 microM) and other inhibitors of proteasome activity, preserved axonal mitochondrial function, assessed by Mitotracker-Orange and MTT staining, for at least 24 h. MG132 similarly protected axons from undergoing branch elimination (pruning) in response to local NGF deprivation. Axons protected by MG132 displayed persistent phosphorylation of Erk1/2, and pharmacological inhibition of MEK activity with U0126 (50 microM) restored rapid axonal degeneration. Therefore, the proteasome does not appear to be necessary as a general effector of protein degradation during axonal degeneration. Rather, the proteasome functions in the regulation of signaling pathways that control axonal survival and degeneration. Specifically, the down-regulation of the MEK/Erk pathway by the proteasome plays roles in Wallerian degeneration of severed axons and axonal pruning in response to local NGF deprivation. Identification of the pathways that regulate axonal survival and degeneration will provide possible target sites for pharmacological treatments of neurodegenerative diseases and traumatic injury.

Neuronal models for studying lipid metabolism and transport.

New methods have been developed for studying lipid metabolism and transport in primary cultures of neurons. Sympathetic neurons from rats and mice, as well as retinal ganglion neurons from rats, can be cultured in three-compartmented culture dishes in which the cell bodies reside in a compartment separate from that housing the distal axons. In addition, the three compartments contain completely independent fluid environments. Consequently, these neuronal cultures represent an excellent model for studying the intra-neuronal transport of lipids and proteins between cell bodies and distal axons. In addition, compartmented neuron cultures are particularly appropriate for investigating factors that regulate axonal growth and neuronal survival. The application of the compartmented culture model for use with murine neurons has opened up many new possibilities for studying lipid metabolism in neurons derived from genetically modified mice. Examples are given in which compartmented cultures of primary neurons have been used in studies on (i) lipid analysis of distal axons and cell bodies/proximal axons, (ii) immunoblotting of neuronal proteins involved in lipid metabolism, (iii) the compartmentalization of lipid metabolism, (iv) the role of lipids in axonal growth and survival, and (v) intracellular lipid transport.

Retrograde support of neuronal survival without retrograde transport of nerve growth factor.

Application of nerve growth factor (NGF) covalently cross-linked to beads increased the phosphorylation of TrkA and Akt, but not of mitogen-activated protein kinase, in cultured rat sympathetic neurons. NGF beads or iodine-125-labeled NGF beads supplied to distal axons resulted in the survival of over 80% of the neurons for 30 hours, with little or no retrograde transport of iodine-125-labeled NGF; whereas application of free iodine-125-labeled NGF (0.5 nanograms per milliliter) produced 20-fold more retrograde transport, but only 29% of the neurons survived. Thus, in contrast to widely accepted theory, a neuronal survival signal can reach the cell bodies unaccompanied by the NGF that initiated it.

Retrograde transport of neurotrophins: fact and function.

Retrograde signals generated by nerve growth factor (NGF) and other neurotrophins promote the survival of appropriately connected neurons during development, and failure to obtain sufficient retrograde signals may contribute to neuronal death occurring in many neurodegenerative diseases. The discovery over 25 years ago that NGF supplied to the axon terminals is retrogradely transported to the cell bodies suggested that NGF must reach the cell body to promote neuronal survival. Research during the intervening decades has produced a refinement of this hypothesis. The current hypothesis is that NGF bound to TrkA at the axon terminal is internalized into signaling endosomes, with NGF in their lumens bound to phosphorylated TrkA in their membranes, which are retrogradely transported to the cell bodies, where TrkA activates downstream signaling molecules that promote neuronal survival and regulate many aspects of neuronal gene expression. This model has been extrapolated to retrograde signaling by all neurotrophins. We consider the evidence for this model, focusing on results of experiments with neurons in compartmented cultures. Results to date indicate that while the transport of signaling endosomes containing NGF bound to TrkA may carry retrograde signals, retrograde survival signals can be carried by another mechanism that is activated by NGF at the axon terminal surface and travels to the cell body unaccompanied by the NGF that initiated it. It is hypothesized that multiple mechanisms of retrograde signaling exist and function under different circumstances. The newly discovered potential for redundancy in retrograde signaling mechanisms can complicate the interpretation of experimental results.