N-glycolyl GM1 ganglioside as a receptor for simian virus 40

Carbohydrate microarrays have emerged as powerful tools in analyses of microbe-host interactions. Using a microarray with 190 sequence-defined oligosaccharides in the form of natural glycolipids and neoglycolipids representative of diverse mammalian glycans, we examined interactions of simian virus 40 (SV40) with potential carbohydrate receptors. While the results confirmed the high specificity of SV40 for the ganglioside GM1, they also revealed that N-glycolyl GM1 ganglioside [GM1(Gc)], which is characteristic of simian species and many other nonhuman mammals, is a better ligand than the N-acetyl analog [GM1(Ac)] found in mammals, including humans. After supplementing glycolipid-deficient GM95 cells with GM1(Ac) and GM1(Gc) gangliosides and the corresponding neoglycolipids with phosphatidylethanolamine lipid groups, it was found that GM1(Gc) analogs conferred better virus binding and infectivity. Moreover, we visualized the interaction of NeuGc with VP1 protein of SV40 by molecular modeling and identified a conformation for GM1(Gc) ganglioside in complex with the virus VP1 pentamer that is compatible with its presentation as a membrane receptor. Our results open the way not only to detailed studies of SV40 infection in relation to receptor expression in host cells but also to the monitoring of changes that may occur with time in receptor usage by the virus.     

Regulatory roles of ganglioside GQ1b in neuronal cell differentiation of mouse embryonic stem cells

Gangliosides play an important role in neuronal differentiation processes. The regulation of ganglioside levels is related to the induction of neuronal cell differentiation. In this study, the ST8Sia5 gene was transfected into mESCs and then differentiated into neuronal cells. Interestingly, ST8Sia5 gene transfected mESCs expressed GQ1b by HPTLC and immunofluorescence analysis. To investigate the effects of GQ1b over-expression in neurogenesis, neuronal cells were differentiated from GQ1b expressing mESCs in the presence of retinoic acid. In GQ1b expressing mESCs, increased EBs formation was observed. After 4 days, EBs were co-localized with GQ1b and nestin, and GFAP. Moreover, GQ1b co-localized with MAP-2 expressing cells in GQ1b expressing mESCs in 7-day-old EBs. Furthermore, GQ1b expressing mESCs increased the ERK1/2 MAP kinase pathway. These results suggest that the ST8Sia5 gene increases ganglioside GQ1b and improves neuronal differentiation via the ERK1/2 MAP kinase pathway.     

N-butyldeoxygalactonojirimycin reduces neonatal brain ganglioside content in a mouse model of GM1 gangliosidosis

GM1 gangliosidosis is a glycosphingolipid (GSL) lysosomal storage disease caused by a genetic deficiency of acid beta-galactosidase (beta-gal), the enzyme that catabolyzes GM1 within lysosomes. Accumulation of GM1 and its asialo form (GA1) occurs primarily in the brain, leading to progressive neurodegeneration and brain dysfunction. Substrate reduction therapy aims to decrease the rate of GSL biosynthesis to counterbalance the impaired rate of catabolism. The imino sugar N-butyldeoxygalactonojirimycin (NB-DGJ) is a competitive inhibitor of the ceramide-specific glucosyltransferase that catalyzes the first step in GSL biosynthesis. Neonatal C57BL/6J (B6) and beta-gal knockout (-/-) mice were injected daily from post-natal day 2 (p-2) to p-5 with either vehicle or NB-DGJ at 600 mg or 1200 mg/kg body weight. These drug concentrations significantly reduced total brain ganglioside and GM1 content in the B6 and the beta-gal (-/-) mice. Drug treatment had no significant effect on viability, body weight, brain weight, or brain water content in the B6 and beta-gal (-/-) mice. Significant elevations in neutral lipids (GA1, ceramide, and sphingomyelin) were observed in the NB-DGJ-treated beta-gal (-/-) mice, but were not associated with adverse effects. Also, NB-DGJ treatment of B6 and beta-gal (-/-) mice from p-2 to p-5 had no subsequent effect on brain ganglioside content at p-21. Our results show that NB-DGJ is effective in reducing total brain ganglioside and GM1 content at early neonatal ages. These findings suggest that substrate reduction therapy using NB-DGJ may be an effective early intervention for GM1 gangliosidosis and possibly other GSL lysosomal storage diseases.     

Bag1 is a regulator and marker of neuronal differentiation

Bag 1 acts as a co-chaperone for Hsp70/Hsc70. We report here that stable over-expression of Bag1 in immortalized neuronal CSM14.1 cells prevents death following serum deprivation. Bag1 over-expression slowed the proliferative rate of CSM14.1 cells, resulted in increased levels of phospo-MAP kinases and accelerated neuronal differentiation. Immunocytochemistry revealed mostly nuclear localization of Bag1 protein in these cells. However, during differentiation in vitro, Bag1 protein shifted from predominantly nuclear to mostly cytosolic in CSM14.1 cells. To explore in vivo parallels of these findings, we investigated Bag1 expression in the developing mouse nervous system using immunohistochemical methods. Early in brain development, Bag1 was found in nuclei of neuronal precursor cells, whereas cytosolic Bag1 staining was observed mainly after completion of neuronal precursor migration and differentiation. Taken together, these findings raise the possibility that the Bag1 protein is expressed early in neurogenesis in vivo and is capable of modulating neuronal cell survival and differentiation at least in part from a nuclear location.     

GM1 ganglioside contributes to retain the neuronal conduction and neuronal excitability in visceral and baroreceptor afferents

GM1 ganglioside has a great impact on the function of nodes of Ranvier on myelinated fiber, suggesting its potential role to maintain the electrical and neuronal excitability of neurons. Here we first demonstrate that visceral afferent conduction velocity of myelinated and unmyelinated fibers are reduced significantly by tetrodotoxin (TTX) or cholera toxin-B subunits (CTX-B), and only the effects mediated by CTX-B are prevented by GM1 pre-treatment. At soma of myelinated A and unmyelinated C-type nodose ganglion neurons (NGNs), the action potential spike frequency reduced by CTX-B is also prevented by GM1. Additionally, the current density of both TTX-sensitive (TTX-S) and TTX-resistant (TTX-R) Na⁺ channels were significantly decreased by CTX-B without changing the voltage-dependent property. These data confirm that endogenous GM1 may play a dominant role in maintaining the electrical and neuronal excitability via modulation of sodium (Na⁺) channel around nodes and soma as well, especially TTX-S Na⁺ channel, which is also confirmed by the reduction of spike amplitude and depolarization. Similar data are also extended to fluorescently identified and electrophysiologically characterized aortic baroreceptor neurons. These findings suggest that GM1 plays an important role in the neural modulation of electric and neuronal excitability in visceral afferent system.     

Notch1 is required for neuronal and glial differentiation in the cerebellum.

The mechanisms that guide progenitor cell fate and differentiation in the vertebrate central nervous system (CNS) are poorly understood. Gain-of-function experiments suggest that Notch signaling is involved in the early stages of mammalian neurogenesis. On the basis of the expression of Notch1 by putative progenitor cells of the vertebrate CNS, we have addressed directly the role of Notch1 in the development of the mammalian brain. Using conditional gene ablation, we show that loss of Notch1 results in premature onset of neurogenesis by neuroepithelial cells of the midbrain-hindbrain region of the neural tube. Notch1-deficient cells do not complete differentiation but are eliminated by apoptosis, resulting in a reduced number of neurons in the adult cerebellum. We have also analyzed the effects of Notch1 ablation on gliogenesis in vivo. Our results show that Notch1 is required for both neuron and glia formation and modulates the onset of neurogenesis within the cerebellar neuroepithelium.     

Fluorescent derivatives of ganglioside GM1 function as receptors for cholera toxin

A fluorescent derivative of ganglioside GM1 was prepared by oxidation of the sialic acid residue with sodium periodate and reaction of the resulting aldehyde with Lucifer yellow CH. The biological activity of the fluorescent derivative was compared with that of native GM1 using GM1-deficient rat glioma C6 cells. When the cells were exposed to either native or fluorescent GM1, their ability to bind 125I-labeled cholera toxin was increased to a similar extent. This increase in binding was directly proportional to the amount of ganglioside added to the medium. The affinity of the toxin for cells treated with either native or fluorescent GM1 also was similar. More importantly, the fluorescent GM1 was as effective as native GM1 in enhancing the responsiveness of the cells to cholera toxin. Thus, the ganglioside-treated cells exhibited a 9-fold increase in toxin-stimulated cyclic AMP production over cells not exposed to GM1. There was a similar increase in iodotoxin binding and toxin-stimulated cyclic AMP accumulation in cells treated with other GM1 derivatives containing rhodaminyl or dinitrophenyl groups. On the basis of these results, it is clear that these modified gangliosides retain the ability to function as receptors for cholera toxin. Consequently, fluorescent gangliosides are likely to be useful as probes for investigating the dynamics and function of these membrane components.     

Effects of daunorubicin on ganglioside expression and neuronal differentiation of mouse embryonic stem cells

Gangliosides are implicated in neuronal development processes. The regulation of ganglioside levels is closely related to the induction of neuronal cell differentiation. In this study, the relationship between ganglioside expression and neuronal cell development was investigated using an in vitro model of neural differentiation from mouse embryonic stem (mES) cells. Daunorubicin (DNR) was applied to induce the expression of gangliosides in embryoid body (EB) (4+). We observed an increase in expression of gangliosides in all stages of EBs by treatment of DNR (2microM). High-performance thin-layer chromatography (HPTLC) showed that gangliosides GD3, GD1a, GT1b, and GQ1b increased in DNR-treated 7-day-old EB (4+) [EB (4+):7]. DNR treatment significantly increased the expression of gangliosides, especially GT1b and GQ1b in comparison to control cells. Interestingly, GQ1b co-localized with microtubule-associated protein 2 (MAP-2) expressing cells in DNR-treated EB (4+):7. The co-localization of GQ1b and MAP-2 was found in neurite-bearing cells in DNR-treated 15-day-old EB (4+) [EB (4+):15], whereas no significant expression of GQ1b and less neurite formation were observed in untreated control. Also, the expression of synaptophysin and NF200, both neuronal markers associated with neruites, was increased by DNR treatment. These results demonstrate that DNR increases expression of gangliosides, especially GQ1b, in differentiating neuronal cells. Further, neurite-bearing neuronal cell differentiation can be facilitated by DNR, possibly through the induction of gangliosides. Thus, the present data suggest that DNR is beneficial for facilitating neuronal differentiation from ES cells and among the gangliosides analyzed in the present study, GQ1b is mainly involved in neurite formation.     

Neurite outgrowth in dorsal root neuronal hybrid clones modulated by ganglioside GM1 and disintegrins.

Subclones of F11 neuronal hybrid cells (neuroblastoma x dorsal root ganglion neurons) have segregated differing and/or overlapping neuritogenic mechanisms on three substrata--plasma fibronectin (pFN) with its multiple receptor activities, cholera toxin B subunit (CTB) for binding to ganglioside GM1, and platelet factor-4 (PF4) for binding to heparan sulfate proteoglycans. In this study, specific cell surface receptor activities for the three substrata were tested for their modulation during neuritogenesis by several experimental paradigms, using F11 subclones representative of three differentiation classes (neuritogenic on pFN only, on CTB only, or on all three substrata). When cycloheximide was included in the medium to inhibit protein synthesis during the active period, neurite formation increased significantly for all subclones on all three substrata, virtually eliminating substratum selectivity for differentiation mediated by cell surface integrin, ganglioside GM1, or heparan sulfate proteoglycans. Therefore, one or more labile proteins (referred to as disintegrins) must modulate functions of matrix receptors (e.g., integrins) mediating neurite formation. To verify whether cycloheximide-induced neuritogenesis was also regulated by integrin interaction with cell surface GM1, two approaches were used. When (Arg-Gly-Asp-Ser)-containing peptide A was added to the medium, it completely inhibited cycloheximide-induced neuritogenesis on all three substrata of all subclones, indicating stringent requirement for cell surface integrin function in these mechanisms. In contrast, when CTB or a monoclonal anti-GM1 antibody was also added to the medium, cycloheximide-induced neuritogenesis was amplified further on pFN and sensitivity to peptide A inhibition was abolished. Therefore, in some contexts ganglioside GM1 must complex with integrin receptors at the cell surface to modulate their function. These results also indicate that (a) cycloheximide treatment leads to loss of substratum selectivity in neuritogenesis, (b) this negative regulation of neurite outgrowth is affected by integrin receptor association with labile regulatory proteins (disintegrins) as well as with GM1, and (c) complexing of GM1 by multivalent GM1-binding proteins shifts neuritogenesis from an RGDS-dependent integrin mechanism to an RGDS-independent receptor mechanism.     

Organization of ganglioside GM1 in phosphatidylcholine bilayers

Molecules of the ganglioside GM1 are randomly distributed in liquid-crystalline 1-palmitoyl-2-oleoyl phosphatidylcholine bilayers. This conclusion is based on a freeze-etch electron microscopic study using ferritin-conjugated cholera toxin and cholera toxin alone as ganglioside labels. The average number of GM1 molecules under a label is calculated by a novel method from the dependence of the fraction of bilayer area covered by the label on the mole fraction of GM1 in the bilayer.     

GM1 ganglioside enhances Ret signaling in striatum

It has been proposed that GM1 ganglioside promotes neuronal growth, phenotypic expression, and survival by modulating tyrosine kinase receptors for neurotrophic factors. Our studies tested the hypothesis that GM1 exerts its neurotrophic action on dopaminergic neurons, in part, by interacting with the GDNF (glia cell‐derived neurotrophic factor) receptor complex, Ret tyrosine kinase and GFRα1 co‐receptor. GM1 addition to striatal slices in situ increased Ret activity in a concentration‐ and time‐dependent manner. GM1‐induced Ret activation required the whole GM1 molecule and was inhibited by the kinase inhibitors PP2 and PP1. Ret activation was followed by Tyr1062 phosphorylation and PI3 kinase/Akt recruitment. The Src kinase was associated with Ret and GM1 enhanced its phosphorylation. GM1 responses required the presence of GFRα1, and there was a GM1 concentration‐dependent increase in the binding of endogenous GDNF which paralleled that of Ret activation. Neutralization of the released GDNF did not influence the Ret response to GM1, and GM1 had no effect on GDNF release. Our in situ studies suggest that GM1 via GFRα1 modulates Ret activation and phosphorylation in the striatum and provide a putative mechanism for its effects on dopaminergic neurons. Indeed, chronic GM1 treatment enhanced Ret activity and phosphorylation in the striatum of the MPTP‐mouse and kinase activation was associated with recovery of dopamine and DOPAC deficits.

     

Preparation of GM1 ganglioside with sialidase-producing marine bacteria as a microbial biocatalyst.

This paper describes the preparation of monosialoganglioside GM1 with sialidase-producing marine bacteria as a microbial biocatalyst. A new sialidase-producing bacterium, identified tentatively as Pseudomonas sp. strain YF-2, was isolated from seawater by enrichment culture with ganglioside as the sole source of carbon. When YF-2 was cultured in a synthetic medium containing crude bovine brain gangliosides at 25 degrees C for 3 days, 80 to 90% of the gangliosides were converted to GM1. GM1 was then purified from the supernatant of YF-2 culture by C18 reverse-phased chromatography, followed by DEAE-Sephadex A25 anion-exchange chromatography. In a typical experiment, 178 mg of highly purified GM1 was obtained from 500 mg of the crude ganglioside fraction. The GM1 induced neurite outgrowth of neuroblastoma Neuro2a cells at a concentration of 33 to 100 microM in the presence of fetal calf serum. Sialidase was purified 33-fold with 13.3% recovery from the culture supernatant of YF-2. The purified enzyme hydrolyzed polysialogangliosides to produce GM1 but did not act on GM1. It was therefore concluded that polysialogangliosides in the culture of strain YF-2 were converted to GM1 by this sialidase.     

Engagement of endogenous ganglioside GM1a induces tyrosine phosphorylation involved in neuron-like differentiation of PC12 cells

Using the cholera toxin B subunit (CTB) that specifically binds to ganglioside GM1a on the plasma membrane, we investigated intracellular signaling mediated by endogenous GM1a involved in neuronal differentiation of PC12 cells. The treatment with CTB induced morphological alternations of PC12 cells, such as augmentation of the cell body, neurite extension, and branched spikes of tips of neurites. The neurite extension induced with CTB was strongly suppressed by the pretreatment of tyrosine kinase inhibitors in a dose-dependent manner. Western blotting analysis showed that CTB induced tyrosine phosphorylation of several cellular proteins with molecular masses around 120, 70, and 45-40 kDa in PC12 cells. Some of the proteins identified were extracellular-signal regulated kinase (ERKs) (ERK1 and ERK2). The peak activation of ERKs lasted for 60-90 min and gradually decreased thereafter. Immunoprecipitation analysis demonstrated that the intracellular events induced with CTB are not related with the activation of Trk proteins, suggesting that signals evoked by ligation of endogenous GM1a are unique and distinct from those induced with exogenous GM1a. Although the presence of a tyrosine kinase inhibitor, genistein, at a concentration of 10 microM diminished the neurite extension of PC12 cells induced with CTB, ERK activation was still observed. However, pretreatment with a MEK inhibitor, PD98059, abolished the activation of ERKs induced with CTB in a dose-dependent manner and only attenuated the morphological alternations of PC12 cells. Considered together, we concluded that tyrosine phosphorylation induced with CTB was responsible for neuron-like differentiation of PC12 cells and that the MEK-ERK cascade is part of the biological signals mediated by endogenous ganglioside GM1a on PC12 cells.     

A procedure for the preparation of GM3 ganglioside from GM1-lactone

A simple procedure is described for preparing GM3 ganglioside, from a few milligrams to grams, from GM1-lactone (Sonnino et al., (1985) Glycoconjugate J 2: 343-54) [1]. The synthesis was carried out under the following optimal conditions: 30 mM GM1-lactone in 0.25 M H2SO4 in DMSO, 30 min, 70 degrees C, nitrogen atmosphere, strong stirring. The yield of GM3 was 55%. The procedure applied to milligram amounts of GD1b-dilactone gave GD3 ganglioside.     

Aminopeptidase as a marker for macrophage differentiation

Thioglycolate medium, rich in peptides, causes an inflammation reaction in mice upon i.p. injection. It induces from the 2nd to the 6th day an increase in aminopeptidase, an enzyme bound to the plasma membrane of macrophages. This increase is up to 30-fold per cell and is due to a 10–20-fold increase in enzyme concentration per unit area of the membrane.     

Occurrence of glycosylation and deglycosylation of exogenously administered ganglioside GM1 in mouse liver.

Ganglioside GM1, 3H-labelled at the level of terminal galactose or of sphingosine, was intravenously injected into Swiss albino mice and some steps in its metabolic fate in the liver were investigated. After administration of [3H]sphingosine-labelled GM1 all major liver gangliosides [GM3, GM2, GM1, GD1a-(NeuAc,NeuGl)] became radioactive, the radioactivity residing in all cases on the sphingosine moiety. The specific radioactivity was highest in GM1, which carried about 53% of the radioactivity incorporated into gangliosides, followed by GM2, with 34.5% of incorporated radioactivity, GM3 and GD1a-(NeuAc,NeuGl), both with about 5% of incorporated radioactivity. After administration of [3H]galactose-labelled GM1 the only radioactive gangliosides present in the liver were GM1 and GD1a-(NeuAc,NeuGl), the former carrying about 95% of the total ganglioside-incorporated radioactivity, the latter about 3%. Both gangliosides were radioactive exclusively in the terminal galactose residue. According to these results exogenously administered GM1, after being taken up by the liver, is mainly degraded to GM2 and GM3, a part being, however, sialylated to GD1a-(NeuAc,NeuGl). All this suggests that exogenous GM1 may be involved in the metabolic routes of endogenous liver gangliosides.     

Precursor-product relationship between GM1 and GD1a biosynthesized from exogenous GM2 ganglioside in rat liver

The demonstration of a precursor-product relationship in the course of GM1 and GD1a biosynthesis is described in the present paper. We injected rats with GM2 gangliosides [GalNAc beta 1----4(NeuAc alpha 2----3)Gal beta 1----4Glc beta 1----1'Cer] of brain origin, which were isotopically radiolabeled on the GalNAc ([GalNAc-3H]GM2) or sphingosine ([Sph-3H]GM2) residue. We then compared the time-courses of GM1 and GD1a biosynthesis in the liver after the administration of each radiolabeled GM2 derivative. After the administration of [GalNAc-3H]GM2, GM1, and GD1a were both present as doublets, that could be easily resolved on TLC. The lower spot of each doublet was identified as a species having the typical rat brain ceramide moiety and represented gangliosides formed through direct glycosylation of the injected GM2. The upper spot of each doublet was identified as a species having the typical rat liver ceramide moiety and represented gangliosides formed through recycling of the [3H]GalNAc residue, released during ganglioside catabolism. After the administration of [Sph-3H]GM2, only ganglioside with the rat brain ceramide moiety were found, that represented the sum of ganglioside formed through direct glycosylation and those formed through recycling of some sphingosine-containing fragments. In each case, the time-course of GM1 and GD1a biosynthesis exhibited a precursor-product relationship. The curve obtained from the direct glycosylation showed a timing delay with respect to those obtained from recycling of GM2 fragments. These results are consistent with the hypothesis that the sequential addition of activated sugars to a sphingolipid precursor is a dissociative process, catalyzed by physically independent enzymatic activities.     

Synthesis of a fluorescent ganglioside GM1 derivative and screening of a synthetic peptide library for GM1 binding sequence motifs

A ganglioside GM1 probe bearing a dark-red fluorescent dye at the sphingosine moiety of the molecule was prepared by a convenient one-pot synthesis. The labeled GM1 permitted the detection of the natural ganglioside GM1 ligand Escherichia coli heat-labile enterotoxin subunit B (EtxB) in picomole quantities on a solid support. When an epitope mapping of several ganglioside binding proteins and protein fragments was performed by screening a cellulose membrane-bound synthetic library of 64 16mer peptides with the new probe, several peptides displaying ganglioside GM1 affinity could be identified. We consider the labeled glycolipid described herein a versatile tool for manifold biochemical investigations.