O-acetylated sialic acids in gangliosides from pig spleen lymphocytes

The sialic acid content of gangliosides from pig spleen lymphocytes was studied by thin-layer chromatography. N-glycolylneuraminic acid and N-acetylneuraminic acid were detected for the first time in this material as the major sialic acids. In addition, two other sialic acids, tentatively designated O-acetylated sialic acids, according to their RF values on cellulose plates, were also found. We have detected several gangliosides showing a retarded migration pattern in two dimensional thin-layer chromatography with an intermediate ammonia treatment. One of these gangliosides could be an O-acetylated derivative of the disialoganglioside GD3, since after de-O-acetyation it co-migrates with GD3. Another ganglioside co-migrated with GM2 before the alkaline treatment; however, after the treatment it was also retarded and co-migrates with GD3.     

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.     

Isolation and characterization of gangliosides from pig lymphocytes

Two major gangliosides from pig spleen lymphocytes, accounting for 57% of the total lipid-bound sialic acids, were isolated and purified to homogeneity by column chromatography on DEAE-Sephadex and silica gel. They were identified as GM3 (II3Neu5GcLacCer), and GD3 (II3(Neu5Gc)2LacCer), by thin-layer chromatography in comparison with standards and by analysis of the constituent sugars. The major fatty acids of these gangliosides were stearic acid and myristic acid, respectively. In addition to these gangliosides, GD2 and bands comigrating on thin-layer chromatography with authentic GM2, GM1, GD1a and GD1b were found. These compounds also occur in pig peripheral blood lymphocytes, where, however, GD3 represents about 70% of the total lipid-bound sialic acid.     

Monoclonal antibody R24 distinguishes between different N-acetyl- and N-glycolylneuraminic acid derivatives of ganglioside GD3

Monoclonal antibody (MAb) R24 was previously shown to be directed toward ganglioside GD3 [Pukel, C. S., Lloyd, K. O., Travassos, L. R., Dippold, W. G., Oettgen, H. F., and Old, L. J. (1982) J. Exp. Med. 155, 1133-1147]. The structural specificity of the MAb has now been further characterized based on binding to structurally related glycolipids, including four GD3 derivatives with different N-acetylneuraminic acid (NeuAc) and N-glycolylneuraminic acid (NeuGc) substituents. Three assay systems (enzyme immunostaining on thin-layer chromatography, enzyme-linked immunosorbent assay, and immune adherence inhibition assay) were used. MAb R24 was found to react with (NeuAc-NeuAc-)GD3 and (NeuAc-NeuGc-)GD3 but not with (NeuGc-NeuAc-)GD3 or (NeuGc-NeuGc-)GD3. These results clearly indicate that the outer sialic acid (Sia) moiety of GD3 is crucial and must be a NeuAc residue, while the inner sialic acid is less involved in binding to the MAb and can be either NeuAc or NeuGc. The MAb was also found to cross-react weakly with two gangliosides, GT1a and GQ1b, but none of other gangliosides nor neutral glycolipids tested reacted. These findings suggest that the epitope detected by MAb R24 is the trisaccharide structure NeuAc alpha 2----8Sia alpha 2----3Gal-, which must be in a terminal position.     

Gangliosides in Human Fetal Brain

The ganglioside concentration and composition were determined in 42 human fetal brains from gestational week 10 to 22, a period that is morphologically characterized by rapid neuroblast proliferation and migration. The ganglioside concentration was constant during this period, approximately 1 mumol of ganglioside sialic acid/g of fresh tissue weight. At gestational week 10 the ganglioside pattern was dominated by gangliosides of the ganglio b series, with the major ganglioside being GT1b, contributing 40% of total ganglioside sialic acid, whereas GD1b and GD3 contributed only 15 and 10%, respectively. The proportion of b series ganglioside decreased to gestational week 22, with the most pronounced relative reduction affecting GD3, but also GT1b and GD1b to a lesser extent. The ganglioside GQ1b increased in content from gestational week 10 and peaked around week 16. The proportion of GD1a increased markedly between gestational week 12 and 14 and slowly between week 14 and 18 and then increased rapidly from week 20. Ganglioside GM1 underwent a similar change. Gangliosides of the lacto series contributed 6-10% of ganglioside sialic acid between gestational week 10 and 15, and thereafter the proportion slowly decreased. 3'-isoLM1 decreased rapidly in content from gestational week 10 (20 nmol/g of fresh weight) to week 22 (less than 0.5 nmol/g of fresh weight), whereas the gangliosides of the neolacto series (3'-LM1 and 3',8'-LD1) showed a slower and less marked decline in level. The biological significance of the ganglioside changes is discussed.     

Gangliosides in rat kidney: composition, distribution, and developmental changes

Gangliosides in rat kidney were analyzed for their composition, regional distribution, and developmental changes. Renal tissue from 7-week-old rats showed a GM3-dominant pattern with GD3 and several minor ganglioside components including GM4, GM2, GD1a, and an unknown ganglioside (ganglioside X). The tissue also contained c-series gangliosides that included GT3 as the main component with GT2 in a lesser amount. Ganglioside analysis of cortical and medullary regions of renal tissue suggested the restricted localization of some gangliosides. While GM4 and GD3 were enriched in the cortical region, GM2 was distributed mainly in the medullary area. Renal gangliosides showed unique developmental profiles during a period from Embryonic Day 20 (E20) to 7 weeks postnatal. The content of renal gangliosides increased from E20, reached the highest around Postnatal Day 1, and thereafter, decreased rapidly to the adult level. The ratio of N-glycolylneuraminic acid to total sialic acids in gangliosides tended to change in inverse proportion to the amount of total sialic acids. The composition of major gangliosides in renal tissues shifted from GD3-dominant to GM3-dominant patterns with advancing ages. While GM1 was expressed only at early stages of the development, GM4, GM2, and ganglioside X appeared after Postnatal Day 3. The expression of c-series gangliosides was less affected through the period examined. These results suggest that gangliosides may be implicated with development and function of rat kidney.     

Acidic glycosphingolipids of cock testis elucidated by mass spectrometry and NMR spectroscopy

The main acidic glycosphingolipids (GSLs) of cock testis were identified as GalCer I³-sulfate and gangliosides GM4, GM3, GD3 and GT3. They contained N-acetylneuraminic acid as the major sialic acid, and ceramides composed mainly of sphingosine (dl8:1) and C18–24 non-hydroxy fatty acids. Appreciable amounts of hydroxy fatty acids were detected only in the GM4 preparation.     

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.     

猪脑中提取高纯度神经节苷脂

应用凝胶层析和离心液相层析法,从猪脑中提取高纯度神经节苷脂(Gls).按脂结合唾液酸(LBSA)计为30.1%,经硅胶薄层层析,580nm扫描结果表明含5种Gls,即:GM1为19.5%,GD3为13.8%,GD1a为27.8%,GD1b为14.2%和GT1b为19.3%.     

Distribution of gangliosides in parenchymal and non-parenchymal cells of rat liver

Parenchymal and non-parenchymal cells were isolated from rat liver with purities of more than 90%. Total and ganglioside sialic acid contents were higher in non-parenchymal cells than in parenchymal cells. Thin-layer chromatography of gangliosides showed that the main component in rat liver was ganglioside GM3 and that this was abundant in non-parenchymal cells. Parenchymal cells had ganglioside GD1b as the main component and less GM3 than non-parenchymal cells. These results suggested that the main ganglioside of rat liver, GM3, arises mainly from non-parenchymal cells.     

Occurrence of a new hematoside in the kidney of guinea pig

We have isolated a new hematoside from guinea pig kidney. Like the usual hematoside (II3NeuAc LacCer), isolated from human erythrocytes, this new hematoside contained glucose, galactose, and N-acetylneuraminic acid in an equimolar proportion. By thin-layer chromatography (TLC), however, it migrated faster than the usual hematoside. After mild alkaline hydrolysis the TLC mobility of this ganglioside became identical to that of the usual hematoside. The sialic acid in this ganglioside was susceptible to Clostridial neuraminidase. Based on TLC mobility and the results of periodate oxidation, the sialic acid of the new hematoside was identified as 9-O-acetyl-N-acetylneuraminic acid. Therefore, the structure of this new hematoside is 9-O-Ac-NeuAc alpha 2 leads to 3Gal beta 1 leads to 4GLc beta 1 leads to 1'Cer.     

Glycosphingolipids of human plasma

A number of glycosphingolipids, including 10 gangliosides, not previously identified in human plasma have been characterized. The plasma contains 2 micrograms of lipid-bound sialic acid/ml plasma and 54% of the gangliosides are monosialo, 30% disialo, 10% trisialo, and 6% tetrasialo. Individual glycosphingolipids were purified by high-performance liquid chromatography and thin-layer chromatography, and were characterized on the basis of their chromatographic mobility, carbohydrate composition, hydrolysis by glycosidases, methylation analysis, and immunostaining with anti-glycosphingolipid antibodies. The monosialogangliosides were identified as GM3, GM2, sialosyl(2-3)- and sialosyl(2-6)lactoneotetraosylceramides, sialosyllacto-N-nor-hexaosylceramide, and sialosyllacto-N-isooctaosylceramide. The major gangliosides in the polysialo fractions contained a ganglio-N-tetraose backbone and were identified as GD3, GD1a, GD1b, and GQ1b. The most abundant neutral glycosphingolipids were glucosyl, lactosyl, globotriaosyl, globotetraosyl and lactoneotetraosylceramides. The other neutral glycosphingolipids, tentatively identified by immunostaining with monoclonal antibodies, contained H1, Lea, Leb, and lacto-N-fucopentose III (X hapten) structures.     

Isolation and characterization of major gangliosides from frog liver

Four major gangliosides isolated from frog liver were characterized by compositional analysis involving GLC and GC-MS, methylation analysis, chromium trioxide oxidation, and enzymatic hydrolysis. The results revealed that the most major ganglioside in the tissue was GM4 containing N-acetylneuraminic acid and the others were GM4 containing N-glycolylneuraminic acid, GD1a, and a fucosyl ganglioside which was tentatively assigned to be alpha-galactosyl alpha-fucosyl GM1. This is the first report describing the presence of GM4 containing N-glycolylneuraminic acid. The fatty acids in both GM4 were mainly alpha-hydroxylated, and those in the fucosyl ganglioside were exclusively nonhydroxy fatty acids. The GD1a contained both nonhydroxy and alpha-hydroxy fatty acids in a ratio of about 3:2. The predominant species were 22:0, 23:0, 24:0, and 24:1 in both species of the fatty acids. The long-chain bases of these four gangliosides consisted of C18-sphingosine and C18-phytosphingosine together with significant amounts of C16 to C19 dihydroxy and trihydroxy bases with iso and anteiso structures.     

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.     

Densitometric quantification of brain gangliosides separated by two-dimensional thin layer chromatography

A procedure for accurate densitometric quantification of gangliosides separated by two-dimensional thin layer chromatography is reported. The procedure was set up employing 9 different pure gangliosides and was applied to the analysis of calf and pig brain gangliosides. Silica gel high performance thin layer plates, 10 × 10 cm. were two-dimensionally developed at 18–20 C with the following solvents: chloroform methanol 0.2% aqueous CaCl₂, 50/40/10 by volume, for the first run; n-propanol 17 M NH₄OH/water, 6/2/1 by volume for the second run. Ganglioside spots were visualized by spraying with an Ehrlich reagent, which is specific for sialic acid, and heating at 120 C for 15 min. The spots were quantified by sequential scanning densitometry, linear responses being obtained for ganglioside amounts on the plate ranging from 0.1 to 6 nmol as bound sialic acid. The reproducibility of densitometric responses resulted to be acceptable since the standard deviation values were lower than ± 15% of the mean values also for those ganglioside species contained in minor proportions. The ganglioside mixtures of calf and pig brain were resolved in about 20 spots. Of these 9 corresponded to gangliosides GM3, GM2, GM1, Fuc-GM1, GD1a, GD1b, Fuc-GD1b, GT1b and GQ1b, which were identified with certainty and quantified. The identification of GM3 (carrying N-glycolylneuraminic acid), GD3, GD1a (carrying N-acetyl- and N-glycolyl-neuraminic acid) and GT1a was only tentative. All the other spots corresponded to unidentified gangliosides, some of them possibly new species.     

Glycosyltransferase Activities in Cultured Endothelial Cells of Bovine Brain Microvascular Origin

Bovine brain microvascular endothelial cells (BMECs) express GM3 (NeuAc) and GM3 (NeuGc) as the major gangliosides, and GM1, GD1a, GD1b, GT1b as well as sialosylparagloboside and sialosyllactosaminylparagloboside as the minor species. To investigate the metabolic basis of this ganglioside pattern, the activities of eight glycosyltransferases (GM3-, GD1a-, GD3-, LM1-, GM2 (NeuAc)-, GM2 (NeuGc)-, LacCer-, and GM1-synthases) in cultured BMECs were studied. It was found that BMECs possessed high activities of GM3- and GD1a-synthases, and low activities of GM2-, GM1-, and GD3-synthases. Thus, the present study provides evidence that endothelial cells are capable of synthesizing gangliosides in situ and that the high content of GM3 in BMEC is closely associated with high activities of GM3-synthase and low activities of GM2-, GM1-, and GD3-synthases.     

Gangliosides in serum immune complexes from tumor-bearing patients

Immune complexes in the serum of tumor-bearing patients were adsorbed from whole blood or plasma on a protein A-Sepharose column. The adsorbed material was eluted, precipitated and analyzed for gangliosides. All precipitates obtained from eight patients at different treatment occasions contained gangliosides at concentrations varying from 0.1 to 12.2 nmol sialic acid/mg protein. The compositions of gangliosides were similar among the patients, regardless of the type of cancer, and quite different from that of normal serum. Most (75-85% of total sialic acid) belonged to the gangliotetraose series, of which 26-33% was GM1, 26-34% GD1a, 8-17% GD1b, and 5-13% GT1b. However, the dominant ganglioside in normal serum, GM3, was present in only trace amounts, which ruled out a nonspecific adsorption of serum ganglioside by protein A-Sepharose. Similar results were obtained for whole blood and plasma treatments, and these results suggest a specific interaction between gangliosides of the gangliotetraose series and serum immunoglobulins, either by the gangliosides acting as antigens and forming immune complexes or by their binding to already formed complexes.     

GANGLIOSIDE1−COMPOSITION OF BRAIN IN TAY-SACHS DISEASE: INCREASED AMOUNTS OF GD2 AND N-ACETYL-β-D-GALACTOSAMINYL GD1a GANGLIOSIDE

Abstract— The ganglioside composition of the brain of a patient with Tay-Sachs disease (TS-brain) was determined by a newly developed ganglioside-mapping procedure and compared with that of an age-matched control brain. GM2 ganglioside was the predominant component in TS-brain and the following gangliosides were also found, GM1, GD1a, GD1b and GT1 (major gangliosides in normal brain), and GM3, GD3, GD2 and GD1a-GAN (minor or undetectable components of normal brain). Individual gangliosides were isolated by column chromatography using a combination of DEAE-Sepharose, Iatrobeads and Silica Gel 60 and their structures were confirmed by comparing them with authentic standards using TLC, analysing their carbohydrate compositions by gas-liquid chromatography and cleaving them sequentially with glycosidases. The amounts of individual components were measured by quantitative densitometric scanning of the thin-layer plates. As a reflection of myelin breakdown, no sialosylgalactosyl ceramide was detectable in TS-brain. Although the total amounts of all gangliosides except GM2 in TS-brain were low, there were normal molar ratios of the main gangliosides in normal brain, that is, GM1, GD1a, GD1b and GT1. In comparison with the amount of GDla ganglioside, the amounts of GM2, GD2 and GD1a-GAN, which contain N-acetylgalactosamine as a terminal carbohydrate residue, were all elevated in TS-brain. The long chain bases of individual gangliosides contained both C-18 and C-20 sphingosine in different ratios and the ratio of C-20 to C-18 increased in the gangliosides in the order: GM2 < GM1 < GD1a < GD1a-GAN < GD1b < GT1 in both normal brain and TS-brain. In contrast, GD2 and GD3 gangliosides consisted mainly of C-18 sphingosine. The C-20 to C-18 ratios of individual gangliosides in the TS-brain were lower than those of age-matched control brain. Hexosaminidase from Turbo cornutus showed the same specific activity and K_m value in catalysing the cleavage of terminal N-acetylgalactosaminyl residues from GM2, GD2 and GD1a-GAN, suggesting that the brain gangliosides that increase in Tay-Sachs disease may be cleaved by the same enzyme.     

The sialic acid residue of exogenous GM1 ganglioside is recycled for biosynthesis of sialoglycoconjugates in rat liver.

In order to assess metabolic recycling of sialic acid, GM1 ganglioside [nomenclature of Svennerholm (1964) J. Lipid. Res. 5, 145-155; IUPAC-IUB Recommendations (1977) Lipids 12, 455-468], 14C-radiolabelled at the acetyl group of sialic acid, was intravenously injected into Wistar rats, and the presence of radioactive sialic acid in liver sialoglycolipids (gangliosides) and sialoglycoproteins was ascertained. A time-course study (20 min-72 h) showed that the radioactivity present in the liver distributed in the following fractions, with reciprocal proportion varying with time: the protein (glycoprotein) fraction, the ganglioside fraction and the diffusible fraction, which contained low-Mr compounds, including sialic acid. Ganglioside-linked radioactivity gradually decreased with time; protein-linked radioactivity appeared soon after injection (20 min), reached a maximum around 20 h, then slowly diminished; diffusible radioactivity provided a sharp peak at 4 h, then rapidly decreased till disappearing after 40 h. The behaviour of bound radioactivity in the individual liver gangliosides was as follows: (a) rapid diminution with time in GM1, although with a lower rate at the longer times after injection; (b) early appearance (20 min) with a peak at 1 h, followed by continuous diminution, in GM2; (c) early appearance (20 min), peak at 1 h, diminution till 4 h, followed by a plateau, in GM3; (d) appearance at 60 min, maximum around 40 h and slow diminution thereafter, in GD1a, GD1b and GT1b. A detailed study, accomplished at 40 h after injection, demonstrated that almost all radioactivity present in the protein fraction was released by mild acid treatment and recovered in purified sialic acid; most of radioactive glycoprotein-bound sialic acid was releasable by sialidase action. In addition, the radioactivity present in the different gangliosides was exclusively carried by sialic acid and present in both sialidase-resistant and sialidase-labile residues. Only in the case of GD1a was the specific radioactivity of sialidase-resistant sialic acid superior to that of sialidase-releasable sialic acid. The results obtained lead to the following conclusions: (a) radioactive GM3 and GM2 were produced by degradation of GM1 taken up; GM3 originated partly by a process of neosynthesis; (b) radioactive GM1 consisted in part of residual exogenous GM1 and in part of a neosynthetized product; (c) radioactive GD1a originated in part by direct sialylation of GM1 taken up and in part by a neosynthetic process; (d) radioactive GD1b and GT1b resulted only from neosynthesis.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.