Stimulation of neurite outgrowth in vitro by a glycero-ganglioside

Gangliosides of the Nervous System

This review begins by attempting to recount some of the pioneering discoveries that first identified the presence of gangliosides in the nervous system, their structures and topography. This is presented as prelude to the current emphasis on physiological function, about which much has been learned but still remains to be elucidated. These areas include ganglioside roles in nervous system development including stem cell biology, membranes and organelles within neurons and glia, ion transport mechanisms, receptor modulation including neurotrophic factor receptors, and importantly the pathophysiological role of ganglioside aberrations in neurodegenerative disorders. This relates to their potential as therapeutic agents, especially in those conditions characterized by deficiency of one or more specific gangliosides. Finally we attempt to speculate on future directions ganglioside research is likely to take so as to capitalize on the impressive progress to date.

The multi-tasked life of GM1 ganglioside, a true factotum of nature

GM1 ganglioside occurs widely in vertebrate tissues, where it exhibits many essential functions, both in the plasma membrane and intracellular loci. Its essentiality is revealed in the dire consequences resulting from genetic deletion. This derives from its key roles in several signalosome systems, characteristically located in membrane rafts, where it associates with specific proteins that have glycolipid-binding domains. Thus, GM1 interacts with proteins that modulate mechanisms such as ion transport, neuronal differentiation, G protein-coupled receptors (GPCRs), immune system reactivities, and neuroprotective signaling. The latter occurs through intimate association with neurotrophin receptors, which has relevance to the etiopathogenesis of neurodegenerative diseases and potential therapies. Here, we review the current state of knowledge of these GM1-associated mechanisms.

The role of gangliosides in brain development and the potential benefits of perinatal supplementation

The maternal diet provides critical nutrients that can influence fetal and infant brain development and function. This review highlights the potential benefits of maternal dietary ganglioside supplementation on fetal and infant brain development. English-language systematic reviews, preclinical studies, and clinical studies were obtained through searches on PubMed. Reports were selected if they included benefits and harms of maternal ganglioside supplementation during pregnancy or ganglioside-supplemented formula after pregnancy. The potential benefits of ganglioside supplementation were explored by investigating the following: (1) their role in neural development, (2) their therapeutic use in neural injury and disease, (3) their presence in human breast milk, and (4) their use as a dietary supplement during or after pregnancy. Preclinical studies indicate that ganglioside supplementation at high doses (1% of total dietary intake) can significantly increase cognitive development and body weight when given prenatally. However, lower ganglioside supplementation doses have no beneficial cognitive effects, even when given throughout pregnancy and lactation. In human clinical trials, infants given formula supplemented with gangliosides showed increased cognitive development and an increase in ganglioside content. Ganglioside supplementation may promote brain development and function in offspring when administered at the optimum dosage. We propose that prenatal maternal dietary supplementation with gangliosides throughout pregnancy may promote greater long-term effects on brain development and function. Before this concept can be encouraged in preconception clinics, future research and clinical trials are needed to confirm the ability of dietary gangliosides to improve cognitive development, but available results already encourage this area of research.

Ganglioside function in calcium homeostasis and signaling

Ganglioside function in eukaryotic cells encompasses a variety of modulatory interactions related to both development and mature cellular behavior. In relation to the nervous system this includes induction of neurite outgrowth and trophic/neuroprotective phenomena; more generally this applies to ganglioside effects on receptor function, adhesion reactions, and signal transduction mechanisms in neural and extraneural systems. Underlying many of these trophic effects are ganglioside-induced changes in cellular calcium, accomplished through modulation of Ca2+ influx channels, Ca2+ exchange proteins, and various Ca2+-dependent enzymes that are altered through association with gangliosides. A clear distinction needs to be drawn between intrinsic functions of gangliosides as naturally expressed by the cell and activities created by application of exogenous ganglioside(s) that may or may not reflect natural function. This review attempts to summarize findings in this area and point to possible future directions of research.

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.

GM1 ganglioside induced myocardial restoration and survival of mice with experimental Chagas' disease

In a previous work, our group reported that Albino Swiss male mice inoculated with T. cruzi to develop acute lethal infection by day 15 decreased parasitemia and survived when treated with total brain gangliosides (GT; 1 mg, daily). In this paper, GT were replaced by GM1 in 0.1 mg dose that caused diminished parasitemia from day 15 to 30 and survival of 80% by day 120 p.i. Treatment with GT 0.15 mg was ineffective. This indicates that GT effect was due to GM1 and that more sialyl residues on the same lipid moiety produces adverse results. GM1 was compared to other sialylated molecules: fetuine and colominic acid. Both of them increased parasitemias and death by day 16 p.i., suggesting that sialic residues favor parasite replication. Asialo-GM1 (0.1 mg daily) was also adverse. This pointed to GM1 not to other ganglioside or sphingolipid or sialoprotein as the active agent. Gangliosides are [Ca+2]i modulators, so GM1 was compared to nifedipine which blocks calcium channels only in the host. Nifedipine treated mice behaved as controls. It is proposed that if GM1 calcium modulation is involved it must be on the parasite rather than on the host. Electrocardiographic (ECG) records show that while infected mice die with bradycardia, treated mice survive and recover normal frequency. Uninfected treated mice showed no electrocardiographic alterations.

Glycosphingolipid-enriched signaling domain in mouse neuroblastoma Neuro2a cells. Mechanism of ganglioside-dependent neuritogenesis

Differentiation and neuritogenesis of mouse neuroblastoma Neuro2a cells are induced by exogenous ganglioside but are not induced by nerve growth factor because its receptor is absent in these cells. In view of the emerging concept of the "glycosphingolipid-enriched domain" (GEM), we studied the mechanism of the ganglioside effect, focusing on the structure and function of such a domain. GEM in Neuro2a cells, separated as a low density membrane fraction, contains essentially all glycosphingolipids and sphingomyelin, together with five signal transducer molecules (c-Src, Lyn, Csk, Rho A, Ha-Ras). (3)H-Labeled Il(3)NeuAc-LacCer (GM3), Gb4Cer (globoside), and Il(3)NeuAc-Gg4Cer (GM1) added exogenously to cells were incorporated and concentrated in the low density GEM fraction. In contrast, more than 50% of glycerophospholipids and 30% of cholesterol were found in the high density fraction. (3)H-Labeled phosphatidylcholine added exogenously to cells was incorporated exclusively in the high density fraction. c-Src, the predominant signal transducer in the microdomain, was coimmunoprecipitated with anti-GM3 antibody DH2 or with anti-Csk; reciprocally, Csk was coimmunoprecipitated with anti-c-Src, indicating a close association of GM3, c-Src, and Csk. Brief stimulation of an isolated GEM fraction by the exogenous addition of GM3, but not lactosylceramide, caused enhanced c-Src phosphorylation with a concomitant decrease of Csk level in GEM. A decreased Csk/c-Src ratio in GEM may cause activation of c-Src because Csk is a negative regulator of c-Src. The effect of exogenous GM3 on c-Src activity was also observed in intact Neuro2a cells. Activation of c-Src was followed by rapid and prolonged (60 min) enhancement of mitogen-activated protein kinase activity leading to neuritogenesis. Thus, the ganglioside induction of neuritogenesis in Neuro2a cells is mediated by GEM structure and function.

The role of GM1 and other gangliosides in neuronal differentiation. Overview and new finding

The pronounced increases in gangliosides belonging to the gangliotetraose family during the neurite outgrowth phase of neuronal differentiation have suggested a functional requirement for these substances related to process extension, arborization, and possibly synaptogenesis. Support for this hypothesis has come from a variety of experimental paradigms utilizing neuroblastoma cell lines, primary neuronal cultures, and observations on the developing nervous system. We have recently observed that differentiation of both primary neurons and neuroblastoma cells by Ca(2+)-elevating stimulants is characterized by upregulation of GM1 in the nuclear membrane. Immunostaining revealed these Ca(2+)-induced neurites to have axonal characteristics. Recent work has indicated that nuclear GM1 facilitates efflux of nuclear Ca2+, thereby contributing to the reduced level of nuclear Ca2+ that characterizes the differentiated neuron. Thus, while GM1 is generally recognized as a pluripotent molecule with several modulatory roles in the plasma membrane of developing and mature neurons, regulation of Ca2+ flux across the nuclear membrane is proposed as another critical function of this ganglioside in neuronal development, with special relevance to axonogenesis.

Differential Effects of Glycosphingolipids n Protein Kinase C Activity in PC12D Pheochromocytoma Cells

Previous studies have shown that certain glycosphingolipids may function as modulators of protein kinase C (PKC) activity. To study the structure-activity relationship, we examined the effects of 17 gangliosides, 10 neutral glycolipids, as well as sulfatide, psychosine and ceramide on PKC activity in PC12D cells. Using an in vitro assay system, we found that all but one (GQ1b) ganglioside inhibited PKC activity at concentrations between 25 and 100 &mgr;M, and the potency was proportional to the number of sialic acid residues. However, at lower concentrations several gangliosides, including GM1 and LM1 behaved as mild activators of PKC activity. GQ1b had no effect within the range 0.1-10 &mgr;M, but acted as a mild activator of PKC activity at 25 &mgr;M. On the other hand, fucosyl-GM1 and GM1 containing blood group B determinant, which are abundant in PC12 cells, were potent inhibitors of PKC activity. Among the neutral glycosphingolipids tested, LacCer, Gb3, GalGb3, and GA1, all of which have a terminal galactose residue, were found to be ineffective or acted as mild activators of PKC activity. In contrast, GA2, Gb4 and Gb5 which have a terminal N-acetylgalactosamine residue, were potent inhibitors of the PKC activity. Thus, the terminal sugar residue may play a pivotal role in determining the effect of glycosphingolipids in modulating PKC activity. In addition, we also found that GalCer containing normal fatty acids acted as potent activators of PKC activity. Ceramide and GlcCer appeared to be ineffective in modulating PKC activity, wheras psychosine and sulfatides appeared to be inhibitory. We conclude that the carbohydrate head groups and the hydrophobic groups of gangliosides and neutral glycolipids may modulate the PKC system in unique manners, which may in turn affect various biological processes in the cell. Copyright 1994 S. Karger AG, Basel

Protection of neuro-2a cells against calcium ionophore cytotoxicity by gangliosides

Gangliosides are known to assert both neuritogenic and neuroprotective effects when applied to a variety of neuroblastoma and primary neuronal cultures. We have developed a model employing Neuro-2a neuroblastoma cells with Ca2+ ionophore A23187 as neurotoxic agent causing neurite retraction and eventual cell death. Gangliosides attenuated the toxicity of this substance, increasing both cell survival and neurite stability. In one series of experiments, cells were exposed to A23187 for 24 hr and then incubated in fresh medium (washout) for 18 hr; gangliosides were present at varying times. The paradigm in which cells were only preincubated (2 hr) with ganglioside provided no benefit, nor did incubation of the cells in both ionophore and ganglioside during the 24-hr exposure period. Significant protection was achieved by exposing the cells to ganglioside after washout of A23187, or continuously throughout the whole period. Bovine brain ganglioside mixture and the four major components (GM1, GD1a, GD1b, GT1b) applied individually were all effective. By contrast, GM3 and GM1-alcohol, a neutral derivative of GM1, provided little or no protection. Dichlorobenzamil, an inhibitor of the Na(+)-Ca2+ exchanger, tended to block the neurite stabilizing effect of gangliosides, suggesting that the mechanism might involve potentiation of this antiporter.

Stimulation of neurite outgrowth in neuroblastoma cells by neuraminidase: putative role of GM1 ganglioside in differentiation

Treatment of three neuroblastoma cell types in culture with neuraminidase resulted in enhanced neurite outgrowth. These included the mouse Neuro-2A and rat B104 and B50 lines. The morphological changes depended on the presence of exogenous Ca2+ and were accompanied by modest but statistically significant increases in 45Ca2+ influx. Neuraminidase-stimulated neuritogenesis was blocked by the B subunit of cholera toxin (cholera B) and anti-GM1 antibody, a finding suggesting the effect was due to an increased amount of GM1 on the cell surface. Cholera B also blocked the increase in 45Ca2+ influx. The mouse N1A-103 line, previously characterized as "neurite minus," did not respond to neuraminidase with either neurite outgrowth or enhanced Ca2+ influx. These results point to an influence of GM1 on neuritogenesis in cells with differentiation potential and suggest a mechanism involving modulation of Ca2+ flux.

Gangliosides stimulate calcium flux in neuro-2A cells and require exogenous calcium for neuritogenesis

The neuritogenic effect of exogenous ganglioside has been documented with a variety of neuronal and neuroblastoma systems, but the mechanism is not understood. Involvement of Ca2+ is suggested by this study which demonstrates that treatment of Neuro-2A cells with bovine brain gangliosides (BBG) in Ca2(+)-depleted medium failed to produce neurite outgrowth. This was in contrast to treatment with retinoic acid or dibutyryl cyclic AMP which induced differentiation under the same conditions. Addition of BBG to Neuro-2A cells caused small, but significant, increases in both influx and efflux of Ca2+. It thus appears that although neuritogenesis can proceed by more than one mechanism, that induced by BBG requires exogenous Ca2+ and involves stimulation of Ca2+ flux.

Rat dorsal root ganglion gangliosides during early development until senescence

The gangliosides of male rat dorsal root ganglia were studied during aging from the first day postnatally until senescence at 24 months. The ganglioside contents increased drastically until 12 months after birth and thereafter did not change considerably, and the increase pattern was in parallel with the increase of wet weight of the tissues. The major gangliosides of the dorsal root ganglia were GM3, LM1 (sialosyl-lactoneotetraosylceramide), unknown ganglioside X, GD1a, GD1b, GT1b and GQ1b. The most drastic changes in ganglioside composition were observed between the ages of postnatal day 1 and 1.5 months. The unknown ganglioside X (dominant at postnatal day I) decreased up to 1.5 months. In contrast, LM1, a minor ganglioside postnatal day 1, increased until 1.5 months of age. Except for these changes, the other gangliosides were present at almost constant ratios in the component profiles during aging until senescence.

Derivatives of ganglioside GM1 as neuronotrophic agents: comparison of in vivo and in vitro effects

Exogenously administered gangliosides have been shown to behave as neuronotrophic/neuritogenic agents in a variety of cell culture systems and animal models, but it is not known whether they operate by the same mechanism in vivo and in vitro. To probe this question we have employed two derivatives of GM1 lacking the negative charge: the methyl ester (GM1-CH3) and the NaBH4 reduction product of the latter (GM1-OH) in which the carboxyl group is replaced by a primary alcohol. Both derivatives proved to be as neuritogenic as GM1 in 3 cell culture systems: neuro-2A cels, PC12 cells and explanted dorsal root ganglia. However, GM1-OH proved ineffective when applied to two animal models involving reduction of cholinergic markers in: (a) hippocampus following lesion of the lateral fimbria and (b) nucleus basalis magnocellularis following cortical lesion; GM1-CH3 showed marginal activity in (a) but more in (b), possibly owing to slow hydrolysis to GM1 which was highly active in both animal models. These results indicate the necessity of a negative change on the ganglioside molecule for in vivo but not in vitro activity and point to different mechanisms for the trophic effects of exogenous gangliosides.

The role(s) of gangliosides in neural differentiation and repair: a perspective

Gangliosides, sialylated glycosphingolipids, are found in greatest concentration in the brain. While they were first characterized as a unique class of lipids almost 50 years ago, little is known regarding their actual function. It is known that (a) ganglioside composition changes during development, (b) different types of neural cells have specific gangliosides associated with them, (c) the accumulation of gangliosides in certain inborn errors of metabolism results in the formation of aberrant meganeurites, and (d) gangliosides appear to enhance recovery from certain neural traumas. Recent work suggests that it is the oligosaccharide portion of the ganglioside that carries much of the biological specificity. Coupled with observations that ganglioside-binding proteins are present on the plasma membranes of cells, it suggests the hypothesis that gangliosides present on the surface of one cell may interact with specific ganglioside-binding proteins, "receptors," on target cells. As a result of the ganglioside-binding protein interaction, a signal could be transmitted to the cell. This might occur via modulation of the effect of the endogenous ganglioside on the activity of a kinase(s) or by an alteration in ionic flux. The signal would initiate the appropriate cellular response.

Ganglioside function in the development and repair of the nervous system. From basic science to clinical application

Gangliosides play important roles in the normal physiological operations of the nervous system, in particular that of the brain. Changes in ganglioside composition occur in the mammalian brain not only during development, but also in aging and in several neuropathological situations. Gangliosides may modulate the ability of the brain to modify its response to cues or signals from the microenvironment. For example, cultured neurons are known to respond to exogenous ganglioside with changes characteristic of cell differentiation. Gangliosides can amplify the responses of neurons to extrinsic protein factors (neuronotrophic factors) that are normal constituents of the neuron's environment. The systemic administration of monosialoganglioside also potentiates trophic actions in vivo and improves neural responses following various types of injury to the adult mammalian central nervous system. The possible molecular mechanism(s) underlying the ganglioside effects may reflect an action in modulating ligand-receptor linked transfer of information across the plasma membrane of the cell.