Inhibition of neurite outgrowth of neuroblastoma Neuro-2a cells by cholera toxin B-subunit and anti-GM1 antibody

Extrinsic and intrinsic factors controlling axonal regeneration after spinal cord injury

Spinal cord injury is one of the most devastating conditions that affects the central nervous system. It can lead to permanent disability and there are around two million people affected worldwide. After injury, accumulation of myelin debris and formation of an inhibitory glial scar at the site of injury leads to a physical and chemical barrier that blocks axonal growth and regeneration. The mammalian central nervous system thus has a limited intrinsic ability to repair itself after injury. To improve axonal outgrowth and promote functional recovery, it is essential to identify the various intrinsic and extrinsic factors controlling regeneration and navigation of axons within the inhibitory environment of the central nervous system. Recent advances in spinal cord research have opened new avenues for the exploration of potential targets for repairing the cord and improving functional recovery after trauma. Here, we discuss some of the important key molecules that could be harnessed for repairing spinal cord injury.

A novel purification method for CNS projection neurons leads to the identification of brain vascular cells as a source of trophic support for corticospinal motor neurons

One of the difficulties in studying cellular interactions in the CNS is the lack of effective methods to purify specific neuronal populations of interest. We report the development of a novel purification scheme, cholera toxin beta (CTB) immunopanning, in which a particular CNS neuron population is selectively labeled via retrograde axonal transport of the cell-surface epitope CTB, and then purified via immobilization with anti-CTB antibody. We have demonstrated the usefulness and versatility of this method by purifying both retinal ganglion cells and corticospinal motor neurons (CSMNs). Genomic expression analyses of purified CSMNs revealed that they express significant levels of many receptors for growth factors produced by brain endothelial cells; three of these factors, CXCL12, pleiotrophin, and IGF2 significantly enhanced purified CSMN survival, similar to previously characterized CSMN trophic factors BDNF and IGF1. In addition, endothelial cell conditioned medium significantly promoted CSMN neurite outgrowth. These findings demonstrate a useful method for the purification of several different types of CNS projection neurons, which in principle should work in many mammalian species, and provide evidence that endothelial-derived factors may represent an overlooked source of trophic support for neurons in the brain.

Sphingolipid metabolites in neural signalling and function

Sphingolipid metabolites, such as ceramide, sphingosine, sphingosine-1-phosphate (S1P) and complex sphingolipids (gangliosides), are recognized as molecules capable of regulating a variety of cellular processes. The role of sphingolipid metabolites has been studied mainly in non-neuronal tissues. These studies have underscored their importance as signals transducers, involved in control of proliferation, survival, differentiation and apoptosis. In this review, we will focus on studies performed over the last years in the nervous system, discussing the recent developments and the current perspectives in sphingolipid metabolism and functions.

Ganglioside GM1 binding toxins and human neuropathy-associated IgM antibodies differentially promote neuritogenesis in a PC12 assay

PC12 cells undergo neuritogenesis upon nerve growth factor (NGF) activation of the TrkA receptor, an effect mimicked by the ganglioside GM1 binding B-subunit of cholera toxin (CTB). Modulation of neuritogenesis by a GM1 ligand indicates a possible pathway for pathophysiological actions of neuropathy-associated anti-GM1 antibodies. Here we examine the ability of GM1 binding toxins and antibodies to induce neuritogenesis, using a PC12 neurite outgrowth assay. Cholera toxin (CT) and commercially prepared CTB (sCTB, contaminated with traces of the adenyl cyclase activating CT A-subunit) were highly neuritogenic. Recombinant cholera toxin B-subunit (rCTB, free from CTA) induced a much smaller effect, suggesting that the potent effects of sCTB are largely due to contaminating CTA. The recombinant GM1 binding B-subunit of Escherichia coli heat-labile enterotoxin (rETxB) exhibited no neuritogenic activity, whilst rETx holotoxin, which activates adenyl cyclase, was highly neuritogenic. Monoclonal anti-GM1 IgM antibodies from human neuropathy subjects induced small neuritogenic effects. These data indicate that GM1/ligand interaction does not necessarily lead to neuritogenesis and suggest that a specialisation of CTB, not shared by anti-GM1 antibodies or rETxB, is required to activate TrkA. Our data also indicate that antibodies are unlikely to exert major modulatory effects on TrkA activity in patients with anti-GM1 antibody-associated peripheral neuropathies.

Comparison of ganglioside profiles in nuclei and whole cells of NG108-15 and NG-CR72 lines: changes in response to different neuritogenic stimuli

The plasma and nuclear membranes of neural cells have been shown to express gangliosides to a limited extent before, and at increasing levels during, differentiation. Recent studies employing qualitative cytochemistry have shown that GM1 expression in particular is significantly elevated in both membranes by specific neuritogenic agents. The present study provides a more complete description of ganglioside patterns of the 2 membranes of NG108-15 cells and a mutated form of the latter lacking gangliotetraose gangliosides. Nuclei of wild type NG108-15 cells were found to contain predominantly GM1 and GD1a, whereas whole cells had those in addition to substantial amounts of GM2 and GM3. GM1 and GD1a levels increased 2--3.5-fold in both whole cells and nuclei following axonogenic stimulation, but changed little in response to dendritogenic agents. GM2 expression, limited to the plasma membrane, showed little if any change with axonogenic stimuli but a 1.5--2-fold increase following treatment with dendritogenic agents. GM3 resembled GM2 in being virtually absent from the nuclear membrane, while its presence in the plasma membrane showed only modest change at most with any of the stimuli. The gangliotetraose ganglioside-deficient mutant cell line, NG-CR72, had significantly higher basal levels of GM2 in the plasma membrane compared to wild type NG108-15 cells, and this level increased significantly on treatment with dendritogenic agents. Basal GM3 levels were greatly reduced in the mutant cells and changed little with any of the stimuli. As expected, nuclei of NG-CR72 cells were virtually devoid of gangliosides. These mutant cells were previously shown to extend well defined dendritic neurites but were incapable of forming stable axonal processes. This study thus demonstrates major differences in the ganglioside content of wild type and mutated NG108-15 cells and their nuclei, and in their response to different neuritogenic stimuli.

Endogenous GM1 ganglioside of the plasma membrane promotes neuritogenesis by two mechanisms

The influence of GM1 on the neuritogenic phase of neuronal differentiation has been highlighted in recent reports showing upregulation of this ganglioside in the plasma and nuclear membranes concomitant with axonogenesis. These changes are accompanied by alterations in Ca2+ flux which constitute an essential component of the signaling mechanism for axon outgrowth. This study examines 2 distinct mechanisms of induced neurite outgrowth involving plasma membrane GM1, as expressed in 3 neuroblastoma cell lines. Growth of Neuro-2a and NG108-15 cells in the presence of neuraminidase (N'ase), an enzyme that increases the cell surface content of GM1, caused prolific outgrowth of neurites which, in the case of Neuro-2a, could be blocked by the B subunit of cholera toxin (Ctx B) which binds specifically to GM1; however, the latter agent applied to NG108-15 cells proved neuritogenic and potentiated the effect of N'ase. With N18 cells, the combination was also neuritogenic as was Ctx B alone, whereas N'ase by itself had no effect. Neurite outgrowth correlated with influx of extracellular Ca2+, determined with fura-2. Treatment of NG108-15 and N18 cells with Ctx B alone caused modest but persistent elevation of intracellular Ca2+ while a more pronounced increase occurred with the combination Ctx B + N'ase. Treatment with N'ase alone also caused modest but prolonged elevation of intracellular Ca2+ in NG108-15 and Neuro-2a but not N18; in the case of Neuro-2a this effect was blocked by Ctx B. Neuro-2a and N18 thus possess 2 distinctly different mechanisms for neuritogenesis based on Ca2+ modulation by plasma membrane GM1, while NG108-15 cells show both capabilities. The neurites stimulated by N'ase + Ctx B treatment of N18 cells were shown to have axonal character, as previously demonstrated for NG108-15 cells stimulated in this manner and for Neuro-2a cells stimulated by N'ase alone.

Upregulation of nuclear GM1 accompanies axon-like, but not dendrite-like, outgrowth in NG108-15 cells

Recent work has demonstrated that induced neurite outgrowth in neuroblastoma cells and spontaneous differentiation of primary neurons in culture are accompanied by upregulation of GM1 ganglioside in the nuclear envelope. Previous reports have depicted morphological variations in the nature of stimulated neurites resulting from different neuritogenic agents, and a recent study by this laboratory demonstrated that such stimulants could be divided into two categories: those which induce axon-like neurites (group I) as opposed to those that stimulate dendrite-like outgrowths (group II). The former includes KCl, ionomycin, neuraminidase, and cholera toxin B subunit (all agents which elevate intracellular Ca2+), while the latter group is comprised of retinoic acid, dibutyryl cAMP, exogenous GM1, and low serum treatment. The present study was undertaken to determine whether differences in neuritic phenotype could be correlated with upregulation of nuclear GM1. The neuroblastoma x glioma NG108-15 cell line was employed because of its ability to respond robustly to a variety of neuritogenic stimuli. It was found that although both groups of stimulants are capable of inducing stable neurites (terminal differentiation) in this cell line, nuclear GM1 is elevated only in the presence of group I stimulants. Thus, a correlation is indicated between axonogenesis and upregulation of GM1 in the nuclear envelope. Additionally, these two events appear to coincide with elevation of intracellular Ca2+. Conversion of cells to the differentiated phenotype, with or without nuclear GM1 elevation, was found to depend in some cases on concentration of stimulant and duration of treatment.

Nerve growth factor-induced neurite formation in PC12 cells is independent of endogenous cellular gangliosides

The PC12 rat pheochromocytoma cell line is an established model for nerve growth factor (NGF)-induced neurite formation. It has been shown that when gangliosides are added to the culture medium of PC12 cells, NGF-induced neurite formation of PC12 cells is enhanced. To determine the role of endogenous cellular gangliosides themselves in NGF-elicited neurite formation, we depleted cellular gangliosides using the new specific glucosylceramide synthase inhibitor, d, l-threo-1-phenyl-2-hexadecanoylamino-3-pyrrolidino-1-propanol.HCl (PPPP). 0.5-2 microM PPPP rapidly inhibited ganglioside synthesis and depletedcellular gangliosides. Nonetheless, over a concentration range of 5-100 ng/ml NGF, in both low serum and serum-free medium, neurite formation was normal. Even pretreatment of PC12 cells for up to 6 days with 1 microM PPPP followed by cotreatment with PPPP and NGF for 10 days, still did not inhibit neurite formation. The conclusion that ganglioside depletion did not block neurite formation stimulated by NGF was supported by the lack of effect of PPPP, under these same conditions, on cellular acetylcholine esterase activity, a neuronal differentiation marker (73.8 +/- 12.1 versus 67.2 +/- 4.6 nmol/min/mg protein at 50 ng/ml NGF; control versus 1 microM PPPP). These findings, together with previous studies showing enhancement of NGF-induced neurite formation by exogenous gangliosides, underscore the vastly different effects that exogenous gangliosides and endogenous gangliosides may have upon cellular functions.

The role of globo-series glycolipids in neuronal cell differentiation--a review

Alterations in glycolipid composition as well as glycosyltransferase activities during cellular differentiation and growth have been well documented. However, the underlying mechanisms for the regulation of glycolipid expression remain obscure. One of the major obstacles has been the lack of a well defined model system for studying these phenomena. We have chosen PC12 pheochromocytoma cells as a model because (a) the properties of these cells have been well characterized, and (b) they respond to nerve growth factor (NGF) by differentiating into sympathetic-like neurons and are amenable to well-controlled experimentation. Thus, PC12 cells represent a suitable model for studying changes in glycolipid metabolism in relation to cellular differentiation. We have previously shown that subcloned PC12 cells accumulate a unique series of globo-series neutral glycolipids which are not expressed in parental PC12 cells. This unusual change in glycolipid distribution is accompanied by changes in the activities of specific glycosyltransferases involved in their synthesis and is correlated with neuritogenesis and/or cellular differentiation in this cell line. We have further demonstrated that changes in the glycosyltransferase activities may be modulated by the phosphorylation states of the cells via protein kinase systems. We conclude that these unique globo-series glycolipids may play a functional role in the initiation and/or maintenance of neurite outgrowth in PC12 cells.

Inhibition of endogenous ganglioside synthesis does not block neurite formation by retinoic acid-treated neuroblastoma cells

Gangliosides are believed to play a critical role in cellular differentiation. To test this concept, we determined the effect of inhibition of endogenous ganglioside synthesis upon neurite formation induced by retinoic acid in LAN-5 human neuroblastoma cells. Ganglioside synthesis and content of LAN-5 cells exposed for 6 days to 10 microM D-threo-1-phenyl-2-decanoylamino-3-morpholino-1-propanol (D-PDMP) (an inhibitor of glucosylceramide synthase) were reduced by >90%. However, these ganglioside-depleted cells were not blocked from forming neurites when exposed to 10 microM retinoic acid. Even more extensive treatment of LAN-5 cells with 20 microM D-PDMP (6 day pretreatment followed by 6 days together with 10 microM retinoic acid) still did not block the retinoic acid-induced neurite formation. An element of neuroblastoma tumor cell differentiation, neurite formation, is therefore dependent neither on an intact cellular ganglioside complement nor on new ganglioside synthesis.

Trophic effect of cholera toxin B subunit in cultured cerebellar granule neurons: modulation of intracellular calcium by GM1 ganglioside

Survival of cerebellar granule cells (CGC) in culture was significantly improved in the presence of cholera toxin B subunit (Ctx B), a ligand which binds to GM1 with specificity and high affinity. This trophic effect was linked to elevation of intracellular calcium ([Ca2+]i), and was additive to that of high K+. Survival was optimized when Ctx B was present for several days during the early culture period. 45Ca2+ and cell survival studies indicated the mechanism to involve enhanced influx of Ca2+ through L-type voltage-sensitive channels, since the trophic effect was blocked by antagonists specific for that channel type. Inhibitors of N-methyl-D-aspartate receptor/channels were without effect. During the early stage of culture Ctx B, together with 25 mM K+, caused [Ca2+]i to rise to 0.2-0.7 microM in a higher proportion of cells than 25 mM K+ alone. A significant change in the nature of GM1 modulation of Ca2+ flux occurred after 7 days in culture, at which time Ctx B ceased to elevate and instead reduced [Ca2+]i below the level attained with 25 mM K+. GM1 thus appears to serve as intrinsic inhibitor of one or more L-type Ca2+ channels during the first 7 days in vitro, and then as intrinsic activator of (possibly other) L-type channels after that period. This is the first demonstration of a modulatory role for GM1 ganglioside affecting Ca2+ homeostasis in cultured neurons of the CNS.

Cholera toxin binds to differentiating neurons in the developing murine basal ganglia

Cell-surface expression of gangliosides in the developing mammalian central nervous system is temporally-regulated in a cell-type and regionally specific fashion. Gangliosides may be involved in cell-cell and cell-matrix interactions, and can act synergystically with several growth factors or growth factor receptors. Thus, a role for gangliosides in the regulation of neuronal stem cell proliferation and differentiation has been suggested. We have previously shown that cholera toxin B subunit (CTB), which binds to the ganglioside GM1, binds heterogeneously to dissociated neuroepithelial cells from the developing mouse telencephalon. We stained fixed sections of the ganglionic eminences (GE) of fetal mouse brains and found that CTB labels regions which contain differentiating neurons, but does not stain the rapidly dividing neuroepithelial cells in the ventricular zone. We dissociated cells from the GE on day 14 of gestation (E14), labeled the cells with CTB-FITC, and separated them by flow cytometry. We found the highest level of CTB binding in postmitotic cells which had begun to express markers of neuronal differentiation. When CTB-sorted cells were placed into short-term (48 h) cell culture, high CTB binding continued to correlate with fewer numbers of proliferating cells and larger numbers of differentiating neurons. CTB binding and fluorescence activated cell sorting appear to be useful for separating populations of differentiating neurons from immature, proliferating cells. These studies further lead us to suggest that GM1 plays a role in the differentiation of neurons in the basal ganglia.

GM2 ganglioside and pyramidal neuron dendritogenesis

GM2 ganglioside, although scarce in normal adult brain, is the predominant ganglioside accumulating in several types of lysosomal disorders, most notably Tay-Sachs disease. Pyramidal neurons of cerebral cortex in Tay-Sachs, as well as many other types of neuronal storage disorders, are known to exhibit a phenomenon believed unique to storage disorders: growth of ectopic dendrites. Recent studies have shown that a common metabolic abnormality shared by storage diseases with ectopic dendrite growth is the abnormal accumulation of GM2 ganglioside. The correlation between increased levels of GM2 and the presence of ectopic dendrites has been found in both ganglioside and nonganglioside storage disorders, the latter including sphingomyelin-cholesterol lipidosis, mucopolysaccharidosis, and alpha-mannosidosis. Quantitative HPTLC analysis has shown that increases in GM2 occur in proportion to the incidence of ectopic dendrite growth, whereas other gangliosides, including GM1, lack similar increases. Immunocytochemical studies of all nonganglioside storage diseases which exhibit ectopic dendritogenesis have revealed heightened GM2 ganglioside-immunoreactivity in the cortical pyramidal cell population, whereas nerurons in normal adult brain exhibit little or no staining for this ganglioside. Further, studies examining disease development have consistently shown that accumulation of GM2 ganglioside precedes growth of ectopic dendrites, indicating that it is not simply occurring secondary to new membrane production. These findings have prompted an examination for a similar relationship between GM2 ganglioside and dendritogenesis in cortical neurons of normal developing brain. Results show that GM2 ganglioside-immunoreactivity is consistently elevated in immature neurons during the period when they are undergoing active dendritic initiation, but this staining diminishes dramatically as the dendritic trees of these cells mature. Collectively, these studies on diseased and normal brain offer compelling evidence that GM2 ganglioside plays a pivotal role in the regulation of dendritogenesis in cortical pyramidal neurons.