Gangliosides of rat eye lens: a severe reduction in the content of C-series gangliosides following streptozotocin treatment

Gangliosides of eye lenses from normal and experimentally induced diabetic rats were investigated by methods including glycolipid-overlay techniques. Adult rat eye lens showed a complex ganglioside pattern that consisted of six major ganglioside components. These gangliosides were identified as GM3, GD3, GD1a, GD1b, GT1b, and GQ1b based upon their reactivity to anti-GM1 antibody after in situ sialidase treatment and mobility on thin-layer chromatography (TLC). Gangliosides in eye lens were further characterized by TLC-immunostaining with A2B5, a specific monoclonal antibody directed toward c-series gangliosides. Eye lens contained GT3 as the main c-series ganglioside component. Unexpectedly, the relative concentration of GT3 in total gangliosides of eye lens was highest among neural and extra-neural tissues examined. Administration of streptozotocin to rats caused a severe reduction in the GT3 content in eye lenses as early as day 3 without apparent changes in the composition of major gangliosides. Alloxan failed to produce such an effect despite producing similar hyperglycemic conditions. These results suggest that rat eye lens probably contains a streptozotocin-susceptible cell type(s), which is highly enriched with c-series gangliosides.     

Tissue-specific expression of c-series gangliosides in the extraneural system

c-Series gangliosides in extraneural tissues from young and adult rats were examined using thin-layer chromatographic (TLC) immunostaining with a specific monoclonal antibody A2B5. The composition of c-series gangliosides significantly differed among tissues. In adult rats, while liver tissue contained GT1c, GQ1c, and GP1c, renal tissue had GT3 as the major c-series ganglioside with GT2 in a lesser amount. Pancreatic tissue expressed c-series gangliosides that consisted of GT3, GT2, GQ1c, and GP1c. In other tissues including adrenal, thyroid, and eye lens, GT3 constituted the main c-series ganglioside species. While total ganglioside contents of extraneural tissues were much lower than that of brain tissue, the proportions of c-series gangliosides to total gangliosides were higher in many extraneural tissues. Interestingly, eye lens had the highest GT3 content among rat tissues examined. The compositions and concentrations of c-series gangliosides in liver and kidney significantly differed between 5-day-old and 7-week-old rats, suggesting the development-dependent expression of c-series gangliosides in these tissues. These results suggest that the expression of c-series gangliosides in extraneural tissues is regulated in a tissue-specific manner.     

Subcellular distribution and biosynthesis of rat liver gangliosides

Gangliosides have generally been assumed to be localized primarily in the plasma membrane. Analysis of gangliosides from isolated subcellular membrane fractions of rat liver indicated that 76% of the total ganglioside sialic acid was present in the plasma membrane. Mitochondria and endoplasmic reticulum fractions, while containing only low levels of gangliosides on a protein basis, each contained approx. 10% of total ganglioside sialic acid. Gangliosides also were present in the Golgi apparatus and nuclear membrane fractions, and soluble gangliosides were in the supernatant. Individual gangliosides were non-homogeneously distributed and each membrane fraction was characterized by a unique ganglioside composition. Plasma membrane contained only 14 and 28% of the total GD1a and GD3, respectively, but 80-90% of the GM1, GD1b, GT1b and GQ1b. Endoplasmic reticulum, when corrected for plasma membrane contamination, contained only trace amounts of GM1, GD1b, GT1b and GQ1b, but 11 and 5% of the total GD1a and GD3, respectively. The ganglioside composition of highly purified endoplasmic reticulum was similar. Ganglioside biosynthetic enzymes were concentrated in the Golgi apparatus. However, low levels of these enzymes were present in the highly purified endoplasmic reticulum fractions. Pulse-chase experiments with [3H]galactose revealed that total gangliosides were labeled first in the Golgi apparatus, mitochondria and supernatant within 10 min. Labeled gangliosides were next observed at 30 min in the endoplasmic reticulum, plasma membrane and nuclear membrane fractions. Analysis of the individual gangliosides also revealed that GM3, GM1, GD1a and GD1b were labeled first in the Golgi apparatus at 10 min. These studies indicate that gangliosides synthesized in the Golgi apparatus may be transported not only to the plasma membrane, but to the endoplasmic reticulum and to other internal endomembranes as well.     

A specific loss of C-series gangliosides in pancreas of streptozotocin-induced diabetic rats.

Gangliosides in pancreas, kidney, and liver tissues from streptozotocin-induced diabetic rats were analyzed by methods including thin-layer chromatographic (TLC) immunostaining with a specific monoclonal antibody to c-series gangliosides. In rats suffering diabetes for one month, the composition of major gangliosides in pancreatic tissue was almost identical to control, except for a slight increase in the content of GM3. Though c-series gangliosides such as GT3, GT2, GQ1c, and CP1c were expressed in normal pancreatic tissue, they were practically lost in pancreas of diabetic animals. A specific loss of c-series gangliosides was also observed in pancreatic tissue from rats suffering diabetes only for three days. While the composition of major gangliosides in the kidney did not change, streptozotocin-induced diabetic conditions brought about significant increases in contents of practically all major ganglioside species in liver tissue. No change was observed in the amount and composition of c-series gangliosides in both tissues. These results strongly suggest that c-series gangliosides are specifically localized in pancreatic B cells.     

Characterization of Sialyltransferase-IV Activity and Its Involvement in the c-Pathway of Brain Ganglioside Metabolism

Abstract: To characterize the sialyltransferase-IV activity in brain tissues, the activities of GM1b-, GD1a-, GT1b-, and GQ1c-synthases in adult cichlid fish and rat brains were examined using GA1, GM1, GD1b, or a cod brain ganglioside mixture as the substrate. The GD1a-synthase activity in the total membrane fraction from cichlid fish brain required divalent cations such as Mg²⁺ or Mn²⁺ and Triton CF-54 for its full activity. The V_max value was 1,340 pmol/mg of protein/h at an optimal pH of 6.5, whereas the apparent K_m values for CMP-sialic acid and GM1 were 172 and 78 µM, respectively. Cichlid fish and rat brains also contained GM1b-, GT1b-, and GQ1c-synthase activities. The ratio of GM1b-, GD1a-, and GT1b-synthase activities in fish brain was 1.00:0.89:1.13, respectively, and in rat brain 1.00:0.60:0.63. Incubation of fish brain membranes with a cod brain ganglioside mixture, which contains GT1c, and [³H]CMP-sialic acid produced radiolabeled GQ1c. It is interesting that the adult rat brain also contains an appreciable level of GQ1c-synthase activity despite its very low concentrations of c-series gangliosides. The GD1a- or GQ1c-synthase activity in fish and rat brain was inhibited specifically by coincubation with the glycolipids that serve as the substrates for other sialyltransferase-IV reactions. Thus, the GD1a-synthase activity was inhibited by GA1 and GD1b, but not by LacCer, GM3, or GD3. In a similar manner, the synthesis of GQ1c was suppressed by GA1, GM1, and GD1b, but not by LacCer, GM3, or GD3. The GD1a-synthase activity directed toward endogenous GM1 was inhibited by GA1 or GT1b, whereas the endogenous GT1b-synthase activity was suppressed by GA1 or GM1. GA1, GM1, and GD1b did not affect the endogenous GM3- and GD3-synthase activities. These results clearly demonstrate that sialyltransferase-IV in brain tissues catalyzes the reaction for GQ1c synthesis in the c-pathway as well as the corresponding steps in the asialo-, a-, and b-pathway in ganglioside biosynthesis.     

Characterization of nuclear gangliosides in rat brain: concentration, composition, and developmental changes

Nuclear gangliosides were characterized using two distinct fractions of large (N1) and small (N2) nuclear populations from rat brain. The ganglioside concentration of N1 nuclei from adult rat brain was 0.92 microg sialic acid/mg protein, which was about 3.8 times higher than that of N2 nuclei. N1 and N2 nuclear gangliosides showed similar compositional profiles; they contained major gangliosides of GM1, GD1a, GD1b, and GT1b, with GM3 in lesser amounts. c-Series gangliosides such as GT3, GQ1c, and GP1c were also detected in both nuclear preparations. Nuclear localization of gangliosides was confirmed by immunofluorescence with anti-GM1 antibody, cholera toxin B subunit, and c-series ganglioside-specific monoclonal antibody A2B5. Developmental changes of nuclear gangliosides were examined using rats of different ages ranging from embryonic day 14 (E14) to postnatal 7 weeks. The concentration of N1 nuclear gangliosides changed only slightly during development and did not correlate with that of whole-brain gangliosides. The developmental pattern of ganglioside composition of N1 nuclei was also distinguished from that of microsomal membranes; the ganglioside changes in N1 nuclei included reduced expression of di- and polysialogangliosides at E16 and higher proportions of GM3 at early and late stages of the period. These findings suggest that gangliosides in nuclear membranes are developmentally regulated in a distinct manner in brain cells.     

Expression of c-series gangliosides in rat hepatocytes and liver tissues

C-series gangliosides in rat hepatocytes and liver tissues were analyzed by thin-layer chromatographic (TLC) immunostaining with the specific monoclonal antibody A2B5. Primary cultures of hepatocytes isolated from adult rats were immunostained positively by A2B5. TLC immunostaining with A2B5 of gangliosides from the cells suggested that rat hepatocytes express c-series gangliosides including GT3, GT1c, GQ1c, and GP1c. Expression of c-series gangliosides in cultured hepatocytes was modulated by growth conditions of cells. The amount of GT3 was increased significantly by epidermal growth factor, while the contents of polysialo species such as GT1c, GQ1c, and GP1c were enhanced by higher cell density in culture. Examination of c-series gangliosides in rat liver tissues showed a unique developmental profile with a shift from GT3-dominant to polysialo species-dominant composition in late embryonic stages. These results suggest that the expression of c-series gangliosides in rat hepatocytes is regulated in a growth- and development-dependent manner.     

Composition of gangliosides from ovine testis and spermatozoa

Gangliosides were extracted and purified from ovine testis and ejaculated spermatozoa which contained, respectively, 57 and 9 nmol lipid-bound sialic acid per gram wet weight. Fourteen gangliosides were resolved by thin-layer chromatography of testicular gangliosides, of which eleven were purified in sufficient quantity to enable a complete compositional analysis of the carbohydrate residues to be performed. None of the gangliosides contained fucose, but several contained N-glycolylneuraminic acid as a component of the sialic acid species. Relative migration on thin-layer chromatograms relative to known standards, compositional analysis, and selective degradation by specific enzymes were used as the basis for identification. Testis contained members of the ganglio series (GM1, GD1a, GD1b, GT1b, GQ1b), hematoside series (GM3, GD3), and sialosylparagloboside in the molar ratio of 54:40:6, respectively. Testicular GM3, GM1, GD3, GD1a, GD1b and GT1b ran as double bands on thin-layer chromatography which could be accounted for by observed differences in the fatty acid moiety. In addition, the slower migrating band of each pair contained some or all of its sialic acid residues as N-glycolylneuraminic acid, whereas the faster migrating band contained exclusively N-acetylneuraminic acid, except for GM3 where N-acetylneuraminic acid was the sole species in both bands. Thin-layer chromatography of sperm gangliosides revealed seven bands comigrating with equivalent testicular gangliosides. These coincided with the slower migrating bands of testicular GM3, GM1, GD3, GD1a, both bands of GD1b, and possibly both bands of GT1b. Sperm contained only trace amounts of sialosylparagloboside but, in addition, two unidentified bands which were absent from testis were also observed. The molar ratio of the ganglio series to the hematoside series in sperm was 42:58 with GM3 accounting for 42% of total gangliosides.     

A new thin-layer chromatographic approach for separation of multisialogangliosides: Novel gangliosides fractions in the embryonic chicken brain

A novel thin-layer chromatographic procedure has been developed that permits rapid, high-resolution separation of complex ganglioside mixtures and direct densitometric quantification. A special advantage of the new procedure, performed by two different consecutive runs on high-performance thin-layer chromatography plates, is an excellent separation of multisialogangliosides containing more than three sialic acid residues. Using the new procedure, 10 unidentified fractions were detected in embryonic chick brains. These gangliosides were clearly distinguishable from the known gangliosides, GM1, GD3, GD1a, GD2, GD1b, GT1b, and GQ1b. Eight of these “additional” fractions were also found in the brains of rays. From published data on the cod fish brain, 6 of the novel fractions are suggested to correspond to GT3, GT2, GT1c, GQ1c, GP1c, and GP1b. Four fractions, moving on thin-layer chromatography plates below the suggested GP1c have not been reported previously in any vertebrate. Due to their very slow migration rates they may contain gangliosides with six, seven, or more sialic acid residues. During development of the chicken, the relative amounts of the newly detected fractions decrease in favor of GT1b and GD1a.     

Ganglioside GD3 and its mimetics induce cytochrome c release from mitochondria

Ganglioside GD3 induced the release of cytochrome c from isolated rat liver mitochondria. This process was completely prevented by cyclosporin A and partially prevented by a cysteine protease inhibitor, n-acetyl-leu-leu-norleucinal. Cyclosporin A is a potent inhibitor of the permeability transition pore, whereas n-acetyl-leu-leu-norleucinal has no effect on this pore. These results indicate that the release of cytochrome c from mitochondria requires both the opening of the permeability transition pore and a cysteine protease inhibitor-sensitive mechanism. Gangliosides GD1a, GD1b, GT1b, and GQ1b along with the synthetic GD3 mimetics TMS-42 and CI-22, which are glycerophospholipids carrying a disialo residue, also induced cytochrome c release. In contrast, gangliosides GM1, GM2, and GM3 did not induce cytochrome c release. These results indicate that two sialo residues must play an important role in the induction of cytochrome c release by gangliosides.     

Tetrasialoganglioside GQ1b Reactive Monoclonal Antibodies: Their Characterization and Application for Quantification of GQ1b in Some Cell Lines of Neuronal and Adrenal Origin(S)

Seven monoclonal antibodies (MAbs) directed to tetrasialoganglioside (GQ1b) were established, purified GQ1b being used for immunization and hybridoma screening. All of the MAbs reacted strongly with GQ1b, although they also reacted with other gangliosides, with different specificities and reactivities. Some MAbs (1H10, 2C7, and 3F4) reacted with GD3, GT1a, GQ1b, and GP1c. MAb 1H4 showed broad specificity. It reacted with GD3, GD1b, GD2, GT1a, GT1b, GO1b, GQ1c, and GP1c. MAbs 7F5, 4E7, and 4F10 recognized GT1a, GQ1b, and GP1c. MAb 4F10 was more specific for GQ1b than the other MAbs. Using MAb 4F10, we determined, by means of an immunoassay, the quantities of endogenous GQ1b in some neuronal and adrenal cell lines, GOTO (human neuroblastoma), Neuro2a (mouse neuroblastoma), and PC12 (rat pheochromocytoma). PC12 and Neuro2a cells contained at least 5.1 X 10(6) and 3.9 X 10(5) molecules/cell of GQ1b, respectively. In contrast, no GQ1b was detected in GOTO cells, which are known for their specific neuritogenic response to this particular ganglioside when exogenously added.     

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.     

Developmental changes of glycosphingolipids and expression of glycogenes in mouse brains

Glycosphingolipids (GSLs) and their sialic acid-containing derivatives, gangliosides, are important cellular components and are abundant in the nervous system. They are known to undergo dramatic changes during brain development. However, knowledge on the mechanisms underlying their qualitative and qualitative changes is still fragmentary. In this investigation, we have provided a detailed study on the developmental changes of the expression patterns of GSLs, GM3, GM1, GD3, GD1a, GD2, GD1b, GT1b, GQ1b, A2B5 antigens (c-series gangliosides such as GT3 and GQ1c), Chol-1alpha (GT1aalpha and GQ1balpha), glucosylceramide, galactosylceramide (O1 antigen), sulfatide (O4 antigen), stage-specific embryonic antigen-1 (Lewis x) glycolipids, and human natural killer-1 glycolipid (sulfoglucuronosyl paragloboside) in developing mouse brains [embryonic day 12 (E12) to adult]. In E12-E14 brains, GD3 was a predominant ganglioside. After E16, the concentrations of GD3 and GM3 markedly decreased, and the concentrations of a-series gangliosides, such as GD1a, increased. GT3, glucosylceramide, and stage-specific embryonic antigen-1 were expressed in embryonic brains. Human natural killer-1 glycolipid was expressed transiently in embryonic brains. On the other hand, Chol-1alpha, galactosylceramide, and sulfatide were exclusively found after birth. To provide a better understanding of the metabolic basis for these changes, we analyzed glycogene expression patterns in the developing brains and found that GSL expression is regulated primarily by glycosyltransferases, and not by glycosidases. In parallel studies using primary neural precursor cells in culture as a tool for studying developmental events, dramatic changes in ganglioside and glycosyltransferase gene expression were also detected in neurons induced to differentiate from neural precursor cells, including the expression of GD3, followed by up-regulation of complex a- and b-series gangliosides. These changes in cell culture systems resemble that occurring in brain. We conclude that the dramatic changes in GSL pattern and content can serve as useful markers in neural development and that these changes are regulated primarily at the level of glycosyltransferase gene expression.     

Gangliosides activate cultured rat brain microglia

Microglia, brain resident macrophages, are activated in brain injuries and several neurodegenerative diseases. However, microglial activators that are produced in the brain are not yet defined. In this study, we showed that gangliosides, sialic acid-containing glycosphingolipids, could be a microglial activator. Gangliosides induced production of nitric oxide (NO) and tumor necrosis factor-alpha (TNF-alpha) and expression of cyclooxygenase-2 (COX-2). The effect of gangliosides on NO release increased dose-dependently in the range of 10-100 microgram/ml; however, the effect decreased at concentrations higher than 200 microgram/ml. Specific types of gangliosides showed differential effects on microglial activation. Similar to gangliosides, GT1b induced production of NO and TNF-alpha and expression of COX-2. However, GM1 and GD1a induced expression of COX-2 but had little effect on NO and TNF-alpha release. The effect of gangliosides and GT1b on NO release was reduced in the presence of neuraminidase, which removes sialic acid residues from gangliosides and GT1b. Gangliosides activated extracellular signal-regulated kinase significantly but activated c-jun N-terminal kinase/stress-activated protein kinase and p38 relatively weakly. The inhibition of extracellular signal-regulated kinase by PD98059 reduced NO release from both gangliosides- and GT1b-treated microglia whereas inhibition of p38 by SB203580 increased it rather slightly. Gangliosides activated NF-kappaB, and N-acetyl cystein, an inhibitor of NF-kappaB, reduced NO release. These results suggest that gangliosides could be a microglial activator that functions via activation of mitogen-activated protein kinase and NF-kappaB.     

The specificity of monoclonal antibody A2B5 to c-series gangliosides

To examine the specificity of monoclonal antibody A2B5, four A2B5-reactive gangliosides (designated as G-1, G-2, G-3 and G-4) were purified from bonito fish brain. Ganglioside-1, -2, and -3 migrated above GD1b, below GQ1b, and far below GQ1b on thin-layer chromatography. Ganglioside-4 had the slowest chromatographic mobility and migrated below G-3. The structures of these gangliosides were characterized by overlay analysis with glycolipid-specific ligands, product analysis after sialidase or mild acid treatment, and electrospray ionization-mass spectrometry (ESI-MS). Accordingly, G-1, G-2 and G-3 were identified to be GT3, GQ1c and GP1c, respectively. The ganglioside G-4 was shown to have the following structure: NeuAc-NeuAc-NeuAc-Galbeta1-3Gal NAcbeta1-4(NeuAc-NeuAc-NeuAcalpha2-3)Galbeta1-4Glcbeta1-1'Cer. The antibody A2B5 reacted with these c-series gangliosides, but not with GD3 and other gangliosides and neutral glycosphingolipids. The antigenic epitope for A2B5 was assumed to include the trisialosyl residue connected to the inner galactose of the hemato- or ganglio-type oligosaccharide structure of gangliosides. Phylogenetic analysis of brain gangliosides using the A2B5 preparation demonstrated that c-series gangliosides are enriched in lower animals, especially bony fish of different species. The monoclonal antibody A2B5 would be a useful tool for examining the distribution and function of c-series gangliosides.     

Gangliosides of dogfish (Squalus acanthias) brain

Eighteen gangliosides were isolated from dogfish (Squalus acanthias) brain, and their structures and compositions were determined by methylation analysis, enzymatic hydrolysis and partial hydrolysis with mild acid. Tetra- and pentasialogangliosides were also analysed by liquid secondary ion mass spectrometry. The dogfish brain gangliosides were characterized by a variety of molecular species. The most abundant ganglioside was GM2 (22.8% of the total sialic acid content), followed by GQ1c (16.0%), GP1c (13.4%), and GD2 (12.5%). The abundance of gangliosides containing a gangliotriaose core (GM2 and GD2), and c-series polysialogangliosides (GQ1c and GP1c) was a prominent feature of dogfish brain, differing from the brain gangliosides of teleosts and other vertebrates. A battery of trisialogangliosides was also found. A ganglioside which had an a- and -series hybrid-structure (IV³NeuAc,III⁶NeuAc,II³NeuAc-Gg₄Cer) comprised 1.4% of the total. The major fatty acids comprised 16:0, 18:0, 18:1, 22:1 and 24:1. The gangliosides with a gangliotriaose core predominantly contained 22:1. Sphinganine and 4-sphingenine comprised the long-chain bases.     

Antibodies against gangliosides and ganglioside complexes in Guillain-Barré syndrome: new aspects of research

Guillain-Barré syndrome (GBS) is an acute autoimmune neuropathy, often preceded by an infection. Serum anti-ganglioside antibodies are frequently elevated in titer. Those antibodies are useful for diagnosis. Some of them also may be directly involved in the pathogenetic mechanisms by binding to the regions where the respective target ganglioside is specifically localized. We have recently found the presence of the antibody that specifically recognizes a new conformational epitope formed by two gangliosides (ganglioside complex) in the acute-phase sera of some GBS patients. In particular, the antibodies against GD1a/GD1b and/or GD1b/GT1b complexes are associated with severe GBS requiring artificial ventilation. Some patients with Miller Fisher syndrome also have antibodies against ganglioside complexes including GQ1b; such as GQ1b/GM1 and GQ1b/GD1a. Gangliosides along with other components as cholesterol are known to form lipid rafts, in which the carbohydrate portions of two different gangliosides may form a new conformational epitope. Within the rafts, gangliosides are considered to interact with important receptors or signal transducers. The antibodies against ganglioside complexes may therefore directly cause nerve conduction failure and severe disability in GBS. More study is needed to elucidate the roles of the antibodies against ganglioside complexes.     

Antibodies against gangliosides and ganglioside complexes in Guillain–Barré syndrome: New aspects of research

Guillain–Barré syndrome (GBS) is an acute autoimmune neuropathy, often preceded by an infection. Serum anti-ganglioside antibodies are frequently elevated in titer. Those antibodies are useful for diagnosis. Some of them also may be directly involved in the pathogenetic mechanisms by binding to the regions where the respective target ganglioside is specifically localized. We have recently found the presence of the antibody that specifically recognizes a new conformational epitope formed by two gangliosides (ganglioside complex) in the acute-phase sera of some GBS patients. In particular, the antibodies against GD1a/GD1b and/or GD1b/GT1b complexes are associated with severe GBS requiring artificial ventilation. Some patients with Miller Fisher syndrome also have antibodies against ganglioside complexes including GQ1b; such as GQ1b/GM1 and GQ1b/GD1a. Gangliosides along with other components as cholesterol are known to form lipid rafts, in which the carbohydrate portions of two different gangliosides may form a new conformational epitope. Within the rafts, gangliosides are considered to interact with important receptors or signal transducers. The antibodies against ganglioside complexes may therefore directly cause nerve conduction failure and severe disability in GBS. More study is needed to elucidate the roles of the antibodies against ganglioside complexes.     

Targeted analysis of ganglioside and sulfatide molecular species by LC/ESI-MS/MS with theoretically expanded multiple reaction monitoring

Matrix-assisted laser desorption/ionization-mass spectrometry (MALDI-MS) has been applied primarily to the analysis of glycosphingolipids separated from other complex mixtures by TLC, but it is difficult to obtain quantitative profiling of each glycosphingolipid among the different spots on TLC by MALDI-MS. Thus, the development of a convenient approach that utilizes liquid chromatography/electrospray ionization (LC/ESI)-MS has received interest. However, previously reported methods have been insufficient to separate and distinguish each ganglioside class. Here we report an effective method for the targeted analysis of theoretically expected ganglioside molecular species by LC/ESI tandem mass spectrometry (LC/ESI-MS/MS) in combination with multiple reaction monitoring (MRM). MRM detection specific for sialic acid enabled us to analyze ganglioside standards such as GM1, GM2, GM3, GD1, and GT1 at picomolar to femtomolar levels. Furthermore, other gangliosides, such as GD2, GD3, GT2, GT3, and GQ1, were also detected in glycosphingolipid standard mixtures from porcine brain and acidic glycolipid extract from mouse brain by theoretically expanded MRM. We found that this approach was also applicable to sulfatides contained in the glycosphingolipid mixtures. In addition, we established a method to separate and distinguish regioisomeric gangliosides, such as GM1a and -1b, GD1a, -1b, and -1c, and GT1a, -1b, and -1c with diagnostic sugar chains in the MRM.