Genetic regulation of GM4(NeuAc) expression in mouse erythrocytes

The polymorphic expression of GM4(NeuAc), GM3(NeuGc), GM2(NeuGc), and GM1(NeuGc) was found in erythrocytes of inbred strains of mice [Nakamura, K. et al. (1988) J. Biochem. 103, 201-208]. In this paper, we report the results of genetic analysis of the expression of GM4(NeuAc) and GM2(NeuGc). Ganglioside analysis of the progeny obtained on mating between BALB/c mice [GM4 (+)] and WHT/Ht or C57BL/6 mice [both GM4 (-)] indicated that the expression of GM4(NeuAc) is an autosomal dominant trait, and that WHT/Ht and C57BL/6 mice carry a defect on a single autosomal gene. We named this gene Gsl-4. On quantitative determination of galactosylceramide (GalCer), which is the biosynthetic precursor of GM4(NeuAc), the content of GalCer was found to be quite low in WHT/Ht erythrocytes, compared with in BALB/c erythrocytes. On analysis of GM4(NeuAc) and GalCer in 92 backcross mice produced on mating between BALB/c and WHT/Ht mice, it was found that 45 GM4(+) mice apparently expressed a detectable amount of GalCer and that 47 GM4(-) mice expressed an almost undetectable amount of GalCer. These results suggest that Gsl-4 controls the expression of GM4(NeuAc) by regulating the content of GalCer. Linkage analysis of Gsl-4 and the gene controlling GM2(NeuGc) in erythrocytes indicated that the two genes are not genetically linked. Comparison of the ganglioside expression in liver and erythrocytes of the same backcross mice suggested that the gene controlling GM2(NeuGc) expression in the liver (Ggm-2) is also responsible for the expression of GM2(NeuGc) in erythrocytes.     

Differences in liver ganglioside patterns in various inbred strains of mice

The ganglioside patterns in the liver of different inbred and hybrid strains of mice were investigated. The inbred strains were Balb/cAnNCr1BR, C57BL/6NCr1BR, DBA/2NCr1BR. C3H/HeNCr1BR; the hybrid strain was the Swiss albino. The following major gangliosides were found to be present in mouse liver: GM3-NeuAc; GM3-NeuGl, GM2 [a mixture of one species carrying N-acetylneuraminic acid (NeuAc) and one carrying N-glycollylneuraminic acid (NeuGl)], GM1 and GD1a-(NeuAc,NeuGl). The qualitative and quantitative patterns of liver gangliosides were markedly different in the various inbred strains of mice; in Balb/cAnNCr1BR strain, ganglioside GM2 was preponderant (99.2% of total ganglioside content); in C57BL/6NCr1BR, the major ganglioside was GM2 (90.4%), followed by GM3-NeuAc (5.6%) and GM3-NeuGl (4.0%); in DBA/2NCr1BR, GM2 accounted for 77.1%, GD1a-(NeuAc,NeuGl) 18.9% and GM1 3.1% of gangliosides; in C3H/HeNCr1BR, GM2 constituted 50.6%, GM1 22.8% and GD1a-(NeuAc,NeuGl) 22.1%. In the hybrid Swiss albino mice, liver ganglioside composition markedly varied from one animal to another, GM3-NeuGl, GM2 and GD1a-(NeuAc,NeuGl) being the predominant gangliosides in the various cases.     

Genetically regulated expression of UDP-N-acetylgalactosamine: GM3(NeuGc) N-acetylgalactosaminyltransferase [EC 2.4.1.92] activity in mouse liver

GM2 containing NeuGc was a major ganglioside in the liver of mouse strains such as BALB/c, DBA/2, C3H/He, and C57BL/10, whereas WHT/Ht mouse liver did not contain GM2(NeuGc) but contained GM3(NeuGc) as a major ganglioside. Since GM3(NeuGc) is a biosynthetic precursor of GM2(NeuGc), WHT/Ht liver was considered to lack the ability to synthesize GM2(NeuGc) from GM3(NeuGc) (Hashimoto, Y., et al. (1983) J. Biochem. 93, 895-901). In this study we measured the activity of UDP-N-acetylgalactosamine : GM3(NeuGc) N-acetylgalactosaminyltransferase in the liver of BALB/c, WHT/Ht, and their progeny. The transferase activity in the microsomal fraction of BALB/c liver was 2.10 +/- 0.32 X 10(-5) units/mg protein (means +/- S.D.), whereas no activity was detected in that of WHT/Ht liver, F1 hybrids between BALB/c and WHT/Ht expressed GM2(NeuGc) as well as the enzyme activity, the level of which was almost half that in BALB/c liver 1.10 +/- 0.12 X 10(-5) units/mg protein). The backcross generation of F1 to WHT/Ht segregated into two groups with respect to expression of GM2(NeuGc) and the transferase activity: 11 of the 21 mice analyzed expressed both GM2(NeuGc) and the transferase activity (1.28 +/- 0.18 X 10(-5) units/mg protein), whereas the rest expressed neither. These results suggest that the expression of GM2(NeuGc) is directly regulated by the activity of UDP-N-acetylgalactosamine: GM3(NeuGc) N-acetylgalactosaminyltransferase in mouse liver.     

Genetic polymorphism of ganglioside expression in mouse organs

In previous studies it was demonstrated that there are three variations as to the expression of liver gangliosides in inbred strains of mice; the first group expresses GM3(NeuGc) as a major component, the second group, GM2(NeuGc), and the third group, GM2(NeuGc), GM1 (NeuGc), and GD1a(NeuGc). In the present study, we attempted to determine which organs, if any, exhibit the same polymorphic variations as those observed in the liver. Thus, the gangliosides in spleen, thymus, heart, lung, kidney, testis, and erythrocytes, as well as those in liver, were examined using a TLC-mapping technique or by one-dimensional TLC. WHT/Ht, BALB/c, and ICR mice, which are typical strains as to the polymorphic expression of liver gangliosides, were used for the analysis. The presence of GM1 was confirmed by not only chemical detection on TLC plates but also with a TLC-immunostaining procedure using choleragenoid. These comparative studies indicated that only erythrocytes exhibited the same polymorphic variations of ganglioside expression as those in the liver, but the other six organs showed specific patterns which were not polymorphic. In addition to this, there were the following two interesting findings. Firstly, WHT/Ht mice, in which GM2(NeuGc) and GM1(NeuGc) are not expressed in the liver and erythrocytes, did not express a detectable amount of GM2(NeuGc) but expressed GM1(NeuGc) in all the other organs. Secondly, marked polymorphic variation was found in the expression of GM4(NeuAc) in the erythrocytes.     

Age-dependent changes in GM1 and GD1a expression in mouse liver

The ganglioside composition in the liver of SWR/J, A/J, and C57BL/10 (B10) mice was quantitatively analyzed at the ages of 2, 4, 6, 8, and 16 or 20 weeks by TLC-densitometric scanning. In all the strains, GM2, GM1, and GD1a were expressed at the age of 2 weeks. The contents of GM1 and GD1a in SWR/J, A/J, and B10 were 30, 10, and 1% at 4 weeks, and had decreased to 20, 5, and 0%, respectively, at 8 weeks. These results indicate that age-dependent changes in GM1 and GD1a expression occur in mouse liver, and that these three strains show different phenotypes as to this age-dependent expression.     

Two pathways for GM2(NeuGc) expression in mice: genetic analysis

We have reported that WHT/Ht mice express neither GM2(NeuGc) nor GM1(NeuGc) in the liver or erythrocytes due to a defect on the Ggm-2 gene, which was demonstrated to control the activity of UDP-GalNAc:GM3(NeuGc) N-acetylgalactosaminyltransferase in mouse liver, and, in addition, WHT/Ht mice do not express a detectable amount of GM2(NeuGc) but do express GM1(NeuGc) in tissues other than the liver and erythrocytes, such as the spleen, thymus, heart, lung, kidney, and testis [Nakamura et al. (1988) J. Biochem. 103, 201-208]. In order to determine whether the phenotype of WHT/Ht mice exhibiting an undetectable amount of GM2(NeuGc) in these tissues is genetically controlled or not, we analyzed the expression of gangliosides in the progeny obtained on backcross mating between (BALB/c X WHT/Ht)F1 and WHT/Ht mice, and in a GM2(NeuGc) congenic mouse, WHT.C. Concerning the expression of GM2(NeuGc) in the liver, lung, and kidney, 102 backcross mice could be segregated into two types. One type expressed a detectable amount of GM2(NeuGc) in the liver, lung, and kidney, and the other type did not. The ratio of the numbers of mice exhibiting these two types was 42: 60, indicating that the two phenotypes were genetically determined by the involvement of a single autosomal gene. Recombination as to GM2(NeuGc) expression in the liver, lung, and kidney was not detected among the 102 backcross mice. Analysis of the GM2(NeuGc) congenic mouse indicated that a detectable amount of GM2(NeuGc) was expressed in the liver, erythrocytes, lung, kidney, heart, spleen, and small intestine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alterations of membrane lipids and in gene expression of ganglioside metabolism in different brain structures in a mouse model of mucopolysaccharidosis type I (MPS I)

Mucopolysaccharidosis I (MPS I) is a congenital disorder caused by the deficiency of α-l-iduronidase (IDUA), with the accumulation of glycosaminoglycans (GAGs) in the CNS. Although GAG toxicity is not fully understood, previous works suggest a GAG-induced alteration in neuronal membrane composition. This study is aimed to evaluate the levels and distribution of gangliosides and cholesterol in different brain regions (cortex, cerebellum, hippocampus and hypothalamus) in a model using IDUA knockout (KO) mice (C57BL/6). Lipids were extracted with chloroform–methanol and then total gangliosides and cholesterol were determined, followed by ganglioside profile analyses. While no changes in cholesterol content were observed, the results showed a tissue dependent ganglioside alteration in KO mice: a total ganglioside increase in cortex and cerebellum, and a selective presence of GM3, GM2 and GD3 gangliosides in the hippocampus and hypothalamus. To elucidate this, we evaluated gene expression of ganglioside synthesis (GM3, GD3 and GM2/GD2 synthases) and degradation of (Neuraminidase1) enzymes in the cerebellum and hippocampus by RT-sq-PCR. The results obtained with KO mice showed a reduced expression of GD3 and GM2/GD2 synthases and Neuraminidase1 in cerebellum; and a decrease in GM2/GD2 synthase and Neuraminidase1 in the hippocampus. These data suggest that the observed ganglioside changes result from a combined effect of GAGs on ganglioside biosynthesis and degradation.     

Liver gangliosides of various animals ranging from fish to mammalian species

Liver gangliosides of different animal species were analyzed. Bony fish liver contained a major ganglioside that migrated faster than GM3 on thin-layer chromatography (TLC). This ganglioside was identified to be GM4 (NeuAc) by methods including product analysis after sialidase treatment and negative-ion electrospray ionization (ESI)-mass spectrometry (MS). The presence of GM4 (NeuGc) in fish liver was also demonstrated. The main ganglioside band of bovine liver consisted of two different molecular species, i.e. GD1a (NeuAc/NeuAc) and GD1a (NeuAc/NeuGc). Major gangliosides of liver tissue exhibited a distinct phylogenetic profile; GM4 was expressed mainly in lower animals such as bony fish and frog liver, whereas mammalian liver showed ganglioside patterns with smaller proportions of monosialo ganglioside species. While c-series gangliosides were consistently expressed in lower animals, they were found only in mammalian liver of particular species. No apparent trend was observed between the concentration of liver gangliosides and the phylogenetic stage of animals. The present study demonstrates the species-specific expression of liver gangliosides.     

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.     

The locus controlling liver GM1(NeuGc) expression is mapped 1 cM centromeric to H-2K

The polymorphic variation of liver GM1 (NeuGc) ganglioside was found in inbred strains of the mouse. The genetic analysis using C57BL/10 (GM1-negative) and SWR (GM1-positive) mice revealed that a single autosomal gene (Ggm-1) was involved in the expression of liver GM1(NeuGc) and that C57BL/10 mice lacking GM1(NeuGc) expression carried a defective gene on Ggm-1. Since our previous study on H-2 congenic mice indicated that Ggm-1 was linked to the H-2 complex, in this study we measured recombination frequencies among Ggm-1, Go-1 and H-2K in the backcross progeny between (C57BL/10 × SWR)F₁ and C57BL/10. Ggm-1 was mapped 1 cM centromeric to H-2K on chromosome 17.Abbreviations used in this paper GM1(NeuGc) Gal1-3GalNAc1-4 (NeuGc2-3)Gal1-4Glc1-ceramide - GM2(NeuGc) Gal1-4(Neu Gc2-3)Gal1-4Glc1-ceramide - GM3(NeuGc) NeuGc2-3Gal1-4 Glc1-ceramide - GD1a(NeuGc) NeuGc2-3Gal1-3GalNAc1-4 (NeuGc2-3)Gal1-4Glc1-ceramide     

Gangliosides as paramyxovirus receptor. Structural requirement of sialo-oligosaccharides in receptors for hemagglutinating virus of Japan (Sendai virus) and Newcastle disease virus

A sensitive assay system for receptor activity of gangliosides to paramyxovirus was developed. This system involves incorporation of gangliosides into neuraminidase-treated chicken erythrocytes (asialoerythrocytes) followed by estimation of virus-mediated agglutination and hemolysis. The asialoerythrocytes coated with I-active ganglioside (Sia alpha 2-3Gal beta 1-4GlcNAc beta 1-3(Gal alpha 1-3Gal beta 1-4GlcNAc beta 1-6)Gal beta 1-4GlcNAc beta 1-3Gal beta 1-4Glc beta 1-Cer) were effectively agglutinated by hemagglutinating virus of Japan (HVJ, Sendai virus). The hemolysis of the asialoerythrocytes mediated by HVJ was restored to the highest level by labeling the cells with gangliosides possessing lacto-series oligosaccharide chains, i.e., I-active ganglioside, N-acetylneuraminosylparagloboside (SiaPG(NeuAc)), and i-active ganglioside (Sia alpha 2-3Gal beta 1-4GlcNAc beta 1-3Gal beta 1-4GlcNAc beta 1-3Gal beta 1-4Glc beta 1-Cer). The specific receptor activity of ganglioside GD1a possessing a gangliotetraose chain was lower than those of the gangliosides described above. Gangliosides GM3, GD3, GM1a, GD1b, SiaPG(NeuGc) showed little effect on the restoration of HVJ-mediated hemolysis. On infection with Newcastle disease virus (NDV), the highest specific restoration of lysis was found in chicken asialoerythrocytes coated with SiaPG(NeuAc or NeuGc) and GM3(NeuAc or NeuGc), whereas those coated with I-active ganglioside, GD3, GM1a, and GD1b showed very low NDV-mediated hemolysis. The above results indicate that the determinants of receptor for HVJ contain sialylated branched and/or linear lacto-series oligosaccharides carried by I,i-active gangliosides and SiaPG(NeuAc) and sialosylgangliotetraose chain carried by GD1a. The determinants for NDV are carried by SiaPG(NeuAc or NeuGc) containing linear lacto-series oligosaccharide and GM3(NeuAc or NeuGc). The absence of detectable binding of free oligosaccharides obtained from I-active ganglioside and sialoglycoprotein GP-2 isolated from bovine erythrocyte membranes as HVJ receptor (Suzuki, Y., et al. J. Biochem. (1983) 93, 1621-1633; (1984) 95, 1193-1200) indicates that HVJ recognizes the sialooligosaccharides oriented out of the lipid bilayer in the cell membranes where the hydrophobic ceramide or peptide backbone of the receptor is integrated.     

Obesity causes a shift in metabolic flow of gangliosides in adipose tissues

Obesity is associated with insulin resistance and a mild chronic inflammation in adipose tissues. Recent studies suggested that GM3 ganglioside mediates dysfunction in insulin signaling. However, it has not been determined the ganglioside profiling in adipose tissues of obese animals. Here, we for the first time examined semi-quantitative ganglioside profiles in the adipose tissues of high fat- and high sucrose-induced obese, diabetic C57BL/6J mice by TLC and HPLC/mass spectrometry. In control adipose tissues GM3 dominated with traces of GM1 and GD1a; obesity led to a dramatic increase in GM2, GM1, and GD1a with the GM3 content unchanged. Similar results were obtained in KK and KKAy mice. Adipocytes separated from stromal vascular cells including macrophages contained more of those gangliosides in KKAy mice than in KK mice. These results underscore those gangliosides in the pathophysiology of obesity-related diseases.     

Tissue-specific expression of GM3(NeuGc) and GD3(NeuGc) in epithelial cells of the small intestine of strains of inbred rats. Absence of NeuGc in intestine and presence in kidney gangliosides of brown Norway and spontaneously hypertensive rats

The ganglioside composition of the epithelial cells of the small intestine was investigated in 15 strains of inbred rats. Most of these strains had GM3 as the only detectable ganglioside. In addition to GM3, small amounts of GD3 were found in four strains, AVN, BN, DA, and LE. The fatty acid content of the ceramide portion was composed of a large, although variable, percentage of 2-hydroxy fatty acids. The sphingoid base was always C18-4D-hydroxysphinganine. The highly prominent sialic acid was N-glycolylneuraminic acid (NeuGc) in most strains. However in two strains, Brown Norway (BN) and spontaneously hypertensive rats (SHR), NeuAc was the only sialic acid of the gangliosides of the intestinal epithelium. The analysis of the ganglioside composition of the epithelium of the small intestine of the first generation hybrids of SHR with DA and BN, respectively, demonstrated that the expressions of GM3 (NeuGc) and GD3 were genetically transmitted as dominant traits and that BN and SHR were likely to carry the same deficient gene that led to the expression of GM3(NeuAc) instead of GM3(NeuGc) in the small intestine. For comparison, the sialic acid composition of kidney gangliosides was analyzed in some strains. 21-23% of the kidney gangliosides was GM3(NeuGc) in all tested strains, including BN and SHR. Therefore, the ganglioside composition of the intestinal epithelium could vary in the rat species, and the defect of N-glycolylneuraminic acid was not only strain-specific but also occurred in a tissue-specific way among strains of inbred rats.     

Generation of murine monoclonal antibodies specific for N-glycolylneuraminic acid-containing gangliosides.

We generated two murine monoclonal antibodies (MAbs) specific for mono- and disialylgangliosides having N-glycolylneuraminic acid (NeuGc) as their sialic acid moiety, respectively, by immunizing C3H/HeN mice with these purified gangliosides adsorbed to Salmonella minnesota followed by fusion with mouse myeloma cells. By use of a wide variety of glycolipids, including NeuGc-containing gangliosides, the precise structures recognized by these two antibodies were elucidated through enzyme-linked immunosorbent assay and immunostaining on thin-layer chromatography. One MAb, GMR8, which was generated by immunizing the mice with purified GM3(NeuGc), reacted specifically with gangliosides having NeuGc alpha 2----3Gal- terminal structures, such as GM3(NeuGc), IV3NeuGc alpha-Gg4Cer, IV3NeuGc alpha-nLc4Cer, V3NeuGc alpha-Gb5Cer, and GD1a(NeuGc, NeuGc). None of the other gangliosides having internal NeuGc alpha2----3Gal- sequences, such as GM2(NeuGc) and GM1(NeuGc), nor corresponding gangliosides having NeuAc alpha 2----3Gal- sequences, nor neutral glycolipids were recognized. Thus, the epitope structures recognized by the MAb were found to be strictly NeuGc alpha 2----3Gal- terminal structures. In contrast, the other MAb, GMR3, which was generated by immunizing the mice with purified GD3(NeuGc-NeuGc-) adsorbed to the bacteria, reacted specifically with gangliosides having NeuGc alpha 2----8NeuGc alpha 2----3Gal- terminal sequences, such as GD3(NeuGc-NeuGc-), IV3NeuGc alpha 2-Gg4Cer, IV3NeuGc alpha 2-nLc4Cer, and V3NeuGc alpha 2-Gb5Cer, but did not react with corresponding gangliosides having NeuAc as their sialic acid moiety or with the neutral glycolipids tested. The epitope structures recognized by the MAb were suggested to be NeuGc alpha 2----8NeuGc alpha 2----3Gal- terminal structures. Using these MAbs, we determined the distribution of such gangliosides in the spleen, kidney, and liver of several mice strains. Novel gangliosides reactive with these MAbs were detected in these tissues.     

A GM1b-derived disialoganglioside GD1c is the predominant ganglioside of rat thymocytes.

The thin-layer chromatographic (TLC) pattern of gangliosides of rat thymocytes showed a profile characterized by the occurrence of a predominant ganglioside which did not correspond to any reference gangliosides of rat brain. The ganglioside was isolated from rat thymus, and characterized by compositional analysis, methylation analysis, sialidase treatment, negative-ion fast atom bombardment (FAB) mass spectrometry, and proton NMR spectroscopy. The structure was elucidated to be NeuGc alpha 2-8NeuGc alpha 2-3Gal beta 1-3GalNac beta 1-4Gal beta 1-4Glc beta 1-1Cer. This is the major ganglioside of rat thymus lymphoid cells and is one of the GM1b-derived gangliosides, GD1c, having two N-glycolylneuraminic acids. This is the first report on the occurrence of GD1c in normal animal cells.     

Induction of cellular immunity by anti-idiotypic antibodies mimicking GD2 ganglioside

Gangliosides are potentially useful targets for tumor destruction by antibodies. However, the role of gangliosides in T cell-mediated immunity to tumors is unclear. We produced three murine monoclonal anti-idiotypic antibodies (Ab2) against a monoclonal antibody (Ab1) that binds strongly to melanoma-associated GD2 ganglioside and weakly to GD3 ganglioside. All three Ab2 induced anti-anti-idiotypic antibodies (Ab3) with Ab1-like binding specificity to tumor cells and antigen in rabbits. The Ab3 specifically bound to GD2(+) tumor cells and isolated GD2, and shared idiotopes with the Ab1. Two of the three Ab2 induced GD2-specific delayed-type hypersensitivity responses in BALB/c and C57BL/6 mice, but not in C57BL/6/CD4(-/-) mice. Peripheral blood mononuclear cells (PBMC) from a melanoma patient proliferated specifically in response to in vitro stimulation with Ab2. Proliferation was accompanied by Th1-type cytokine production. Our studies demonstrate the induction of ganglioside-specific T cell-dependent immunity by Ab2 in mice. These T cells showed specific reactivity to ganglioside expressed by tumor cells.     

A single autosomal gene controlling the expression of the extended globoglycolipid carrying SSEA-1 determinant is responsible for the expression of two extended globogangliosides

Two extended globogangliosides, designated as Z1 and Z2, were purified from the kidney of DBA/2 mice. By means of GLC, 1H-NMR spectroscopy, negative-ion fast atom bombardment mass spectrometry, methylation analysis, and enzymatic digestion, the structures of Z1 and Z2 were determined to be NeuGc alpha 2-3Gal beta 1-3GalNAc beta 1-3Gal alpha 1-4Gal beta 1-4Glc beta 1-Cer and NeuGc alpha 2-8NeuGc alpha 2-3Gal beta 1-3GalNAc beta 1-3Gal alpha 1-4Gal beta 1-4Glc beta 1-Cer, respectively. Since Z1 and Z2 were not detectable in the kidney of C57BL/10 and 6, BALB/c, and WHT/Ht mice, the mode of genetic control on Z1 and Z2 expression was examined by mating experiments between C57BL/10 or BALB/c and DBA/2. The results indicated that the expression of Z1 and Z2 is a recessive phenotype and that DBA/2 mice carry a single autosomal recessive gene. In the previous paper, we reported that DBA/2 mice do not express GL-Y (Gal beta 1-4(Fuc alpha 1-3)GlcNAc beta 1-6(Gal beta 1-3)Gb4Cer) but express GL-X (Gal beta 1-3Gb4Cer) in the kidney (J. Biochem. 101, 553-562 (1987)), and that a single autosomal defective gene responsible for the defective GL-Y expression was identified by genetic analysis (J. Biochem. 101, 563-568 (1987)).(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism of exogenous gangliosides GM1 and chemically modified GM1 in mice

Ganglioside GM1(NeuAc), labeled at the C-3 position of sphingosine with tritium, was injected into C3H/He, C57BL/10, B10.AQR mice intraperitoneally. The incorporation and the distribution of the radioactivity in various organs were examined. The injected [3H]GM1(NeuAc) was mainly incorporated in the liver and hydrolyzed sequentially. Sialic acid of ganglioside GM1(NeuAc) and metabolites was converted to N-glycolyl type from N-acetyl type. An appreciable amount of the sphingosine moiety in the administered GM1(NeuAc), moreover, was reutilized, being converted to sphingomyelin, and incorporated into alkyl chain of the ether lipid in phosphatidylethanolamine. The distributions of radioactivity in the metabolites of GM1(NeuAc) administered to the three strains of mice were different from each other. In other organs, GM1(NeuAc) was incorporated and metabolized only slightly. The N-methylamide, at the carboxyl group of the sialic acid, of the labeled ganglioside GM1(GM1(NeuAc)-NMe) was injected into C3H/He mice. Most of the administered [3H]GM1(NeuAc)-NMe was incorporated in the liver, and was metabolized to GM3(NeuAc)-NMe, via GM2(NeuAc)-NMe, within 24 h. GM3(NeuAc)-NMe was the only radioactive compound in the subsequent 10 weeks, but disappeared from the liver gradually. N-Methylamide-modified gangliosides were resistant to hydrolysis by mouse hepatic sialidase, to elongation by glycosyltransferase and to N-glycolylation at N-acetylneuraminic acid by monooxygenase.     

Increased glycosphingolipid levels in serum and aortae of apolipoprotein E gene knockout mice

The apolipoprotein E gene knockout (apoE-/-) mouse develops atherosclerosis that shares many features of human atherosclerosis. Increased levels of glycosphingolipid (GSL) have been reported in human atherosclerotic lesions; however, GSL levels have not been studied in the apoE-/- mouse. Here we used HPLC methods to analyze serum and aortic GSL levels in apoE-/- and C57BL/6J control mice. The concentrations of glucosyl ceramide (GlcCer), lactosyl ceramide (LacCer), GalNAcbeta1-4Galbeta1-4Glc-Cer (GA2), and ceramide trihexoside (CTH) were increased by approximately 7-fold in the apoE-/- mouse serum compared with controls. The major serum ganglioside, N-glycolyl GalNAcbeta1-4[NeuNAcalpha2-3]Galbeta1-4Glc-Cer (N-glycolyl GM2), was increased in concentration by approximately 3-fold. A redistribution of GSLs from HDL to VLDL populations was also observed in the apoE-/- mice. These changes were accompanied by an increase in the levels of GSLs in the aortic sinus and arch of the apoE-/- mice. The spectrum of gangliosides present in the aortic tissues was more complex than that found in the lipoproteins, with the latter represented almost entirely by N-glycolyl GM2 and the former comprised of NeuNAcalpha2-3Galbeta1-4Glc-Cer (GM3), GM2, N-glycolyl GM2, GM1, GD3, and GD1a. In conclusion, neutral GSL and ganglioside levels were increased in the serum and aortae of apoE-/- mice compared with controls, and this was associated with a preferential redistribution of GSL to the proatherogenic lipoprotein populations. The apoE-/- mouse therefore represents a useful model to study the potential role of GSL metabolism in atherogenesis.     

Glycosphingolipids of normal bovine and enzootic bovine leukosis lymph node cells

We analyzed glycosphingolipids from normal lymph node cells of seven cattle and lymph node cells of eight cattle with enzootic bovine leukosis. The neutral glycosphingolipids and gangliosides were analyzed by thin-layer chromatography. Both normal and tumorous lymph node cells had GlcCer, LacCer, and GbOse3Cer as major neutral glycosphingolipids. In the ganglioside fraction, GM3 was the predominant component in both normal and tumorous lymph node cells, and another component, ganglioside Gx fraction, was also prominent in tumorous lymph node cells. The structure of this ganglioside Gx fraction was elucidated by thin-layer chromatography, sugar analysis, neuraminidase digestion, and permethylation studies. This ganglioside Gx fraction was found to be a mixture of four ganglioside species. The structures of individual gangliosides Gx (1 to 4) were characterized as follows. 1: GD3, NeuAc alpha 2-8NeuAc alpha 2-3Gal1-4Glc-Cer. 2: GD3, NeuAc alpha 2-8NeuGc alpha 2-3Gal1-4Glc-Cer. 3: GD3, NeuGc alpha 2-8NeuAc alpha 2-3Gal1-Glc-Cer. 4: GD3, NeuGc alpha 2-8NeuGc alpha 2-3Gal1-4Glc-Cer. These GD3 species may be formed as a result of the induced synthesis inassociation with malignant transformation.