Incorporation and metabolism of ganglioside GM2 in skin fibroblasts from normal and GM2 gangliosidosis subjects

Ganglioside GM2, 3H-labeled in the sphingoid base, was added to the culture medium of normal and GM2 gangliosidosis fibroblasts. Ganglioside was found to adsorb rapidly to the cell surface, most of it could however be removed by trypsination. The trypsin-resistant incorporation was about 10 nmol/mg cell protein, after 48 h. The rates of adsorption and incorporation depended strongly on the concentration of fetal calf serum in the medium, higher serum concentrations being inhibitory. After various incubation times, the lipids were extracted, separated by thin-layer chromatography and visualized by fluorography. In normal cells a variety of degradation products as well as sphingomyelin was found whereas in GM2 gangliosidosis cells, only trace amounts of such products (mainly GA2) were found. In contrast, the higher gangliosides GM1 and GD1a were formed in comparable amounts (2.2-3.6% of total radioactivity after 92 h) in normal and pathologic cell lines. Supplementation of cells from GM2 gangliosidosis, variant AB, with purified GM2-activator protein restored ganglioside GM2 degradation to almost normal rates but had no effect on its glycosylation to gangliosides GM1 and GD1a. From these results we conclude that the synthesis of higher gangliosides from incorporated GM2 can occur by direct glycosylation and not only via lysosomal degradation and resynthesis from [3H]sphinganine-containing degradation products. Preliminary studies with subcellular fractionation after various times of [3H]ganglioside incorporation indicated biphasic kinetics for the net transport of membrane-inserted ganglioside to lysosomes, compatible with the notion that a portion of the glycolipids can also escape from secondary lysosomes and migrate to Golgi compartment or cell surface.     

A radiometric assay for ganglioside sialidase applied to the determination of the enzyme subcellular location in cultured human fibroblasts

A radiometric method for the assay of ganglioside sialidase in cultured human fibroblasts was set up. As substrate, highly radioactive (1.28 Ci/mmol) ganglioside GDla isotopically tritium-labeled at carbon C-3 of the long chain base was employed; the liberated, and TLC separated [3H]GM1 was determined by computer-assisted radiochromatoscanning. Under experimental conditions that provided a low and quite acceptable (4-5%) coefficient of variation, the detection limit of the method was 0.1 nmol of liberated GM1, using as low as 10 micrograms of fibroblast homogenate as protein. The detection limit could be lowered to 0.02-0.03 nmol, adopting conditions that, however, carried a higher analytical error (coefficient of variation over 10%). The content of ganglioside sialidase in human fibroblasts cultured in 75-cm2 plastic flasks was 5.8 +/- 2.5 (SD) nmol liberated GM1 h-1 mg protein-1. Subfractionation studies performed on fibroblast homogenate showed that the ganglioside sialidase was mainly associated with the light membrane subfraction that was rich in plasma and intracellular membranes. This subfraction displayed almost no sialidase activity on the artificial substrate 4-methylumbelliferyl-D-N-acetylneuraminic acid. A small but measurable ganglioside sialidase activity was also present in the lysosome-enriched subfraction, which contained a very high sialidase activity on the above artificial substrate. All this supports the hypothesis that human fibroblasts contain sialidases with different subcellular location and substrate specificity. Particularly, the sialidase acting on gangliosides seems to have two sites of subcellular location, a major one at the level of plasma membranes and/or intracellular organelles functionally related with the plasma membranes and a minor one in the lysosomes.     

Ganglioside GM3 sialidase activity in fibroblasts of normal individuals and of patients with sialidosis and mucolipidosis IV. Subcellular distribution and and some properties.

Sensitive assays for the determination of the ganglioside sialidase activity of fibroblast homogenates were established using ganglioside GM3, 3H-labelled in the sphingosine moiety, as a substrate. Ganglioside GM3 sialidase activity was greatly stimulated by the presence of the non-ionic detergent Triton X-100 and was further enhanced by salts such as NaCl; the optimal pH was 4.5. The subcellular localization of this activity was determined by fractionation using free-flow electrophoresis and found to be exclusively associated with the marker for the plasma membrane, but not with that for lysosomes. This Triton-stimulated ganglioside sialidase activity was selectively inhibited by preincubating intact cells in the presence of millimolar concentrations of Cu2+, suggesting that the activity resides on the external surface of the plasma membrane. In normal fibroblasts homogenates, ganglioside GM3 sialidase was also greatly stimulated by sodium cholate. In contrast to the Triton X-100-activated reaction, however, it was not diminished by prior incubation of intact cells in the presence of Cu2+. Only after cell lysis was Cu2+ inhibitory. the cholate-stimulated ganglioside sialidase activity thus paralleled the behaviour of the lysosomal 4-methylumbelliferyl-alpha-D-N-acetylneuraminic acid (4-MU-NeuAc) sialidase. In fibroblasts from sialidosis patients, the cholate-stimulated ganglioside GM3 sialidase activity, but not that of the Triton-activated enzyme, was profoundly diminished. In fibroblasts from patients with mucolipidosis IV (ML IV), both the Triton X-100- and the cholate-stimulated ganglioside GM3 sialidase activities were in the range of normal controls. The Triton-activated enzyme was associated with the plasma membrane in the same manner as in normal cells. Our findings suggest that, in human fibroblasts, there exist two sialidases that degrade ganglioside GM3: one on the external surface of the plasma membrane, and another that is localized in lysosomes and seems identical with the activity that acts on sialyloligosaccharides and 4-MU-NeuAc. As neither activity was found to be deficient in ML IV fibroblasts, our results argue against the hypothesis of a primary involvement of a ganglioside GM3 sialidase in the pathogenesis of ML IV.     

Repair of BHK cell surface ganglioside GM3 after its degradation by extracellular sialidase

Treatment of BHK fibroblasts with V. cholerae sialidase for 20 min caused the breakdown of about 70% of total cellular ganglioside GM3 and the production of an approximately equivalent amount of lactosylceramide. On removal of the enzyme, a slow resynthesis of GM3 from lactosylceramide was observed, equivalent to about 5-6%/h of the degraded GM3. Resynthesis of degraded surface ganglioside has not previously been observed, but its magnitude is similar to previous measurements of the rate of protein resialylation after sialidase treatment. This suggests that resialylation of both lipid and protein is limited by vesicular transport of plasma membrane components through the trans-Golgi network [TGN] where sialyltransferase is thought to be localized. In contrast, resynthesis of sphingomyelin which has been degraded at the cell surface by exogenous sphinogomyelinase is about five times faster than resynthesis of GM3 and may involve non-vesicular transport of ceramide.     

A part of glucosylceramide formed from exogenous lactosylceramide is not degraded to ceramide but re-cycled and glycosylated in the Golgi apparatus

The subcellular fate of glucosylceramide (GlcCer) formed from exogenous lactosylceramide (LacCer) in rat liver is investigated. LacCer radiolabeled on different positions of the molecule was intravenously administered to rats as a liposomal dispersion. A Golgi apparatus fraction 140-fold enriched in specific markers and constituted by intact cisternal stacks, as well as the lysosomal and plasma membrane fractions concurrently prepared from the same homogenate, were then studied in order to determine the time course of radioactive glycosphingolipids. LacCer quickly decreased with time in the plasma membrane, whereas in the lysosomes it increased up to 4 h and decreased thereafter. In both fractions results were regardless of the labeling position. In the Golgi apparatus, LacCer increased up to 12 h and then decreased. In this fraction, the radioactivity values of [Glc-3H]LacCer were over twice those of [Gal-3H]LacCer. GlcCer was found only after [Glc-3H]LacCer administration. In the lysosomes, its time course provided a peak similar in shape but delayed in timing with respect to that of LacCer. Conversely, in the Golgi apparatus GlcCer was earlier formed, but earlier consumed, than LacCer. Gangliosides increased in the Golgi apparatus until 4 h and then decreased after 12 h, whereas in the plasma membrane they were progressively accumulated. In both fractions the amount of [Glc-3H]gangliosides was over twice that of [Gal-3H]gangliosides was over twice that of [Gal-3H]gangliosides. Since we demonstrated that the sugars released in the course of LacCer degradation (LacCer----galactose + GlcCer----glucose + ceramide) are not incorporated into glycoconjugates, we conclude that a part of GlcCer formed during the lysosomal degradation of LacCer actually reaches the Golgi apparatus where it undergoes successive glycosylation.     

Metabolic activities in human skin fibroblasts preloaded with labeled GM2-ganglioside

Confluent cultures of human skin fibroblasts were maintained for 10 days with sphingosine labeled [3H]GM2. Labeled medium was then replaced with normal medium and the cells maintained for 42 days with weekly medium changes. Cells were harvested at regular intervals and cells, medium, and trypsin digest supernatant analyzed for [3H]GM2 and its metabolic products. The ganglioside can be membrane associated and removed by trypsin, or membrane incorporated and trypsin insensitive. The membrane incorporated material is apparently transported to the lysosomes slowly by membrane flow, where 80% of the cellular GM2 can be metabolized by day 42. [3H]GM2 as well as its metabolic products in control cells is continuously released into the medium, during which it can also become associated with the cell surface membrane. There is no detectable metabolism of the [3H]GM2 in GM2 gangliosidosis cell lines over the extended post-labeling period, indicating that there is no residual enzyme activity in these cells. Undegraded GM2 is continuously released into the medium and remains associated with the cell surface membrane as well.     

Endocytosis of exogenous GM1 ganglioside and cholera toxin by neuroblastoma cells.

Cholera toxin (CT) covalently linked to horseradish peroxidase (HRP) is a specific cytochemical marker for its receptor, the monosialoganglioside GM1. The binding and endocytosis of exogenous [3H]GM1 by cultured murine neuroblastoma cells (line 2A [CCl-131] ), which contain predominantly GM3, was examined by quantitative electron microscope autoradiography. The relationship between exogenous receptor, [3H]GM1, and CT HRP was studied in double labeling experiments consisting of autoradiographic demonstration of [3H]GM1 and cytochemical visualization of HRP. Exogenous [3H]GM1 was not degraded after its endocytosis by cells for 2 h at 37 degrees C. Quantitative studies showed similar grain density distributions in cells treated with [3H]GM1 alone and in cells treated with [3H]GM1 followed by CT-HRP. Qualitative studies conducted in double labeling experiments showed autoradiographic grains over the peroxidase-stained plasma membrane, lysosomes, and vesicles at the trans aspect of the Golgi apparatus. The findings indicate that exogenous glycolipid is associated with the plasmid membrane of deficient cells and undergoes endocytosis. The quantitative ultra-structural autoradiographic studies are consistent with the hypothesis that the spontaneous endocytosis of exogenous [3H]GM1 controls the subsequent uptake of CT-HRP.     

Selective ganglioside desialylation in the plasma membrane of human neuroblastoma cells*

Gangliosides of the plasma membrane are important modulatorsof cellular functions. Previous work from our laboratory hadsuggested that a plasma membrane sialidase was involved in growthcontrol and differentiation in cultured human neuroblastomacells (SK-N-MC), but its substrates had remained obscure. Wenow performed sialidase specificity studies in subcellular fractionsand found ganglioside GM3 desialylating activity in presenceof Triton X-100 to be associated with the plasma membrane, butabsent in lysosomes. This Triton-activated plasma membrane enzymedesialylated also gangliosides GDla, GD1b, and GT1b, therebyforming GM1; cleavage of GM1 and GM2, however, was not observed.Sialidase activity towards the glycoprotein fetuin with modifiedC-7 sialic acids and towards 4-methylumbelliferyl neuraminatewas solely found in lysosomal, but not in plasma membrane fractions. The role of the plasma membrane sialidase in ganglioside desialylationof living cells was examined by following the fate of [³H]galactose-labelledindividual gangliosides in pulse-chase experiments in absenceand presence of the extracellular sialidase inhibitor 2-deoxy-2,3-dehydro-N-acetylneuraminicacid. When the plasma membrane sialidase was inhibited, radioactivityof all gangliosides chased at the same rate. In the absenceof inhibitor, GM3, GD1a, GD1b, GD2, GD3 and GT1b were degradedat a considerably faster rate in confluent cultures, whereasthe GM1-pool seemed to be filled by the desialylation of highergangliosides. The results thus suggest that the plasma membranesialidase causes selective ganglioside desialylation, and thatsuch surface glycolipid modification triggers growth controland differentiation in human neuroblastoma cells. ganglioside neuroblastoma cells plasma membrane sialidase     

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.     

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.     

Secretary sialidase activity and GM3 ganglioside

The sialidase activities with GM3 ganglioside and sialyllactitol were demonstrated in the conditioned medium of human fibroblasts. pH versus activity profiles of conditioned medium with GM3 as substrate suggested the presence of two sialidases with optimal activities at pH 4.5 and pH 6.5. The GM3 sialidase activity at pH 6.5 was suppressed in the medium of contact-inhibited cells. This sialidase may function in the metabolism of cell surface GM3 since there was a selective loss of labeled sialic acid from GM3 at different times of incubation after pulse-labeling with a radioactive sialic acid precursor ([3H]N-acetyl-mannosamine) and a radioactive ceramide precursor ([14C]serine). In addition, a sialidase inhibitor, 2-deoxy-2, 3-dehydro-N-acetyl-neuraminic acid (NeuAc-2-en) resulted in a reversible growth inhibitory effect and the suppression of the sialidase activity in the medium. We have speculated that GM3 hydrolysis on the cell surface by the sialidase may be coordinated with the cell cycle and may be at its maximum during early in the G1 phase.     

Lysosomal and plasma membrane ganglioside GM3 sialidases of cultured human fibroblasts. Differentiation by detergents and inhibitors

Cultured human fibroblasts contain two sialidases that degrade gangliosides such as GM3: a lysosomal activity that appears identical with the activity towards water-soluble substrates and that is deficient in the genetic lysosomal disorder sialidosis, and another enzyme that seems localized on the external surface of the plasma membrane. In this report we show that both enzymes can be differentiated in the presence of each other by choice of the detergent used for activation, and also by the inhibitory action of some polyanionic compounds such as sulphated glycosaminoglycans. The lysosomal ganglioside GM3 sialidase is greatly stimulated by sodium glycodeoxycholate and, to lesser degrees, by sodium glycocholate and sodium cholate. The ganglioside GM3 sialidase of the plasma membrane is not measurably active under the conditions of the lysosomal enzyme but is specifically activated by the non-ionic detergent Triton X-100. The glycodeoxycholate-stimulated, but not the Triton-activated, ganglioside GM3 sialidase activity was profoundly diminished in cell lines from patients with the lysosomal disorders sialidosis and galactosialidosis; however, both activities were normal in fibroblasts from patients with mucolipidosis IV, previously thought to be a ganglioside sialidase deficiency disorder. Both the lysosomal and the plasma membrane ganglioside GM3 sialidases were inhibited by sialic acids, suramin, dextran sulphate and sulphated glycosaminoglycans. Among the latter, heparin and heparan sulphate showed a much higher inhibitory potency towards the plasma membrane ganglioside GM3 sialidase than towards the lysosomal onw.(ABSTRACT TRUNCATED AT 250 WORDS)     

Uncoupling of ganglioside biosynthesis by Brefeldin A

We have studied the effect of Brefeldin A (BFA), an antiviral antibiotic, on glycosphingolipid metabolism in primary cultured cerebellar cells. Cells were labeled metabolically with [14C]galactose, or pulse-labeled with precursors of glycosphingolipid biosynthesis; i.e., [14]serine, [3H]palmitic acid or [3H]sphingosine. In all cases BFA (1 microgram/ml) strongly inhibited (75-95%) ganglioside biosynthesis beyond the stage of GM3 and GD3, that is the formation of GM1, GD1a, GT1b and GQ1b. Simultaneously an accumulation of GlcCer, LacCer, GM3 and GD3 was observed (up to 2000%). These effects could be reversed fully by removal of the BFA from the culture medium. These results indicate that the LacCer-, GM3- and GD3-synthases of murine cerebellar cells are localized together on the proximal site of the Golgi apparatus, probably in the cis-Golgi compartment. It is probable that sphingomyelin synthase and some of the other glycosyltransferases involved in ganglioside biosynthesis are localized in distinct compartments beyond the cis Golgi.     

Sialidase activities of cultured human fibroblasts and the metabolism of GM3 ganglioside

Free sialic acid has been found in the cell-conditioned medium of human foreskin fibroblasts. It is proposed that the accumulation of extracellular sialic acid may result from the hydrolysis of GM3 ganglioside on the cell surface of these fibroblasts. Sialidase activities with GM3 ganglioside and sialyllactitol as substrates were demonstrated in cell-conditioned medium, and the levels of their activities correlated positively with cell density. The GM3 sialidase activity at pH 4.5 was 4.1 and 38 pmol/h/ml of medium at sparse and confluent densities, respectively; the corresponding activities with sialyllactitol as the substrate were 12 and 75 pmol/h/ml of medium (pH 4.5). The pH versus activity profiles with GM3 as the substrate suggested the presence of a second sialidase with an optimal activity at pH 6.5 in the conditioned medium of preconfluent cells. This activity was virtually absent in the medium of contact-inhibited cells and could not be assayed with sialyllactitol as the substrate. The turnover of cell surface GM3 was assessed by pulse labeling human foreskin fibroblasts with a radioactive precursor of sialic acid ([1-14C]N-acetylmannosamine) and a radioactive precursor of ceramide ([3,3-3H2]serine). During a chase period of 24 h turnover of the doubly labeled cellular GM3 was observed; there was a loss of about 35% of the 14C-labeled sialic acid without any measureable loss of 3H-labeled ceramide from GM3. We have speculated that the enzyme-catalyzed removal of sialic acid from the GM3 ganglioside on the extracellular aspect of the plasma membrane may be a necessary event involved in the modulation of cell growth.     

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.     

The plasma membrane-associated sialidase MmNEU3 modifies the ganglioside pattern of adjacent cells supporting its involvement in cell-to-cell interactions

We describe herein the enzyme behavior of MmNEU3, the plasma membrane-associated sialidase from mouse (Mus musculus). MmNEU3 is localized at the plasma membrane as demonstrated directly by confocal microscopy analysis. In addition, administration of the radiolabeled ganglioside GD1a to MmNEU3-transfected cells, under conditions that prevent lysosomal activity, led to its hydrolysis into ganglioside GM1, further indicating the plasma membrane topology of MmNEU3. Metabolic labeling with [1-(3)H]sphingosine allowed the characterization of the ganglioside patterns of COS-7 cells. MmNEU3 expression in COS-7 cells led to an extensive modification of the cell ganglioside pattern, i.e. GM3 and GD1a content was decreased to about one-third compared with mock-transfected cells. At the same time, a 35% increase in ganglioside GM1 content was observed. Mixed culture of MmNEU3-transfected cells with [1-(3)H]sphingosine-labeled cells demonstrates that the enzyme present at the cell surface is able to recognize gangliosides exposed on the membrane of nearby cells. Under these experimental conditions, the extent of ganglioside pattern changes was a function of MmNEU3 transient expression. Overall, the variations in GM3, GD1a, and GM1 content were very similar to those observed in the case of [1-(3)H]sphingosine-labeled MmNEU3-transfected cells, indicating that the enzyme mainly exerted its activity toward ganglioside substrates present at the surface of neighboring cells. These results indicate that the plasma membrane-associated sialidase MmNEU3 is able to hydrolyze ganglioside substrates in intact living cells at a neutral pH, mainly through cell-to-cell interactions.     

Synthesis and uptake of gangliosides by choleragen-responsive human fibroblasts.

Human fibroblasts, cultured in medium containing 10% fetal calf serum, responded dramatically to choleragen with an increase in cyclic adenosine monophosphate content to greater than 48 times basal levels. Analysis of these cells for gangliosides indicated that the major ganglioside was N-acetylneuraminylgalactosylglucosylceramide (GM3) with trace amounts (less than or equal to 100 pmol/mg of protein) of other gangliosides including GM1, the putative choleragen receptor. Although the cells contained three glycosyltransferases required for ganglioside synthesis, the N-acetylgalactosaminyltransferase activity necessary for the conversion of GM3 to more complex gangliosides was not detected. When the cells were grown in medium containing [14C]galactose or N-acety[3H]mannosamine, however, all of the gangliosides became labeled, indicating that the cells can synthesize complex gangliosides. Although fetal calf serum contains gangliosides including GM1, [3H]GM1 was taken up poorly from the growth medium and uptake at the rate observed could have accounted for less than 2% of the GM1 content of the cells. When the cells were incubated in chemically defined medium containing [3H]GM1 at the concentrations present in fetal calf serum, rapid uptake of the ganglioside occurred and the total GM1 content of the cells increased threefold in less than 3 h. Thus, although the cells are capable of binding exogenous gangliosides, the gangliosides in fetal calf serum are in a form not readily available to the cells.     

Uptake, cell penetration and metabolic processing of exogenously administered GM1 ganglioside in rat brain

GM1 ganglioside, after intravenous injection into rats, is absorbed and taken up by various organs and tissues, including brain. The capacity of brain to take up gangliosides, referred to weight unit, is comparable to that of kidney and muscle. After injection of [Gal-³H]GM1 a relevant portion of brain associated radioactivity resided in the soluble fraction and was of a volatile nature. After brain subcellular fractionation, the lysosomal, plasma membrane and Golgi apparatus fractions carried the highest specific radioactivity. In addition, an enriched fraction of brain capillaries was highly labelled, suggesting that GM1 ganglioside is also tightly bound to the vessel walls.

The metabolic events encountered in brain by exogenous gangliosides were investigated, in detail, after intracisternal injection of [Sph-³H]GM1. The results obtained demonstrate that GM1 is extensively metabolized in brain. Besides the degradation products (GM2, GM3, lactosylceramide, glucosylceramide, ceramide), compounds of a biosynthetic origin were also found to be formed: these include GD1a, GD1b and sphingomyelin.

All the above results could indicate that gangliosides, after intravenous administration to rats, are taken up by brain, bind to the capillary network, penetrate into neural cells, associate to both plasma membranes and intracellular structures and undergo metabolic processing with formation of a number of products of both catabolic and biosynthetic origin.     

GT3 Synthesis in the Proximal Golgi Occurs in a Compartment Different from Those for GD3 and GM3 Synthesis

Abstract: Previous studies from this laboratory have shown that synthesis of GT3, the precursor of c series gangliosides, occurs in proximal Golgi compartments, as has been shown for the synthesis of GM3 and GD3, the precursors of a and b series gangliosides, respectively. In this work we studied whether the synthesis of GM3, GD3, and GT3 occurs in the same or in different compartments of the proximal Golgi. For this, we examined in retina cells (a) the effect of monensin, a sodium ionophore that affects mostly the trans Golgi and the trans Golgi network function, on the metabolic labeling of glycolipids from [³H]Gal by cultured cells from 7- and 10-day chick embryos and (b) the labeling in vitro of endogenous glycolipids of Golgi membrane preparations from 7-day embryos incubated with UDP-[³H]Gal. In (a), 1 µM monensin produced a twofold accumulation of radioactive glucosylceramide and a decrease to ～50 and 20% of total ganglioside labeling in 7- and 10-day cells, respectively. At both ages, monensin produced a threefold accumulation of radioactive GM3 and an inhibition of >90% of GT3, GM1, GD1a, and GT1b synthesis. GD3 synthesis was inhibited ～30 and 70%, respectively, in 7- and 10-day cells. In (b), >80% of the [³H]Gal was incorporated into endogenous glucosylceramide to form radioactive lactosylceramide. About 90% of [³H]Gal-labeled lactosylceramide was converted into GM3, and most of this in turn into GD3 when unlabeled CMP-NeuAc was also present in the incubation system. Under the same conditions, however, <5% of labeled GD3 was converted into GT3. Golgi membranes incubated with CMP-[³H]NeuAc incorporated ～20% of [³H]NeuAc into endogenous GT3, and this percentage was not affected by 1 µM monensin. These results indicate that synthesis of GT3 is carried out in a compartment of the proximal Golgi different from those for lactosylceramide, GM3, and GD3 synthesis. Results from the experiments with monensin point to the cis/medial Golgi as the main compartment for coupled synthesis of lactosylceramide, GM3, and GD3 and to the trans Golgi as the main compartment for synthesis of GT3.     

The influence of ganglioside insertion into brain membranes on the rate of ganglioside degradation by membrane-bound sialidase

Microsomal membranes isolated from calf brain contain a sialidase which cleaves ganglioside substrates naturally occurring within these membranes as well as exogenously added [3H]ganglioside GD1a. Micelles of [3H]ganglioside GD1a bind to the microsomal membranes in two steps. The first step, called adsorption, is fast and reversible by treatment with trypsin; the second step, called uptake, is slower and not reversible. The product of the enzymic degradation, [3H]ganglioside GM1, is exclusively located in the ganglioside pool taken up by the sialidase-bearing membranes, and not in the trypsin-releasable pool. Electron spin resonance (ESR) studies using a spin-labelled analogue of ganglioside GD1a indicate that the ganglioside uptake by microsomal membranes is accompanied by the disappearance of the micellar structure and by the 'dilution' of the probe molecules with membrane lipids. These findings suggest that exogenously added ganglioside substrate inserts into the microsomal membrane before it is recognized as substrate by the membrane-bound sialidase. Therefore, the influence of pH, ionic strength and membrane-fluidizing agents on the degradation rate measured with exogenous ganglioside GD1a does not only reflect kinetic parameters of the enzymic reaction itself but also the velocity of ganglioside insertion. Increasing ionic strength reduces the degradation rate. The acceleration of insertion with falling pH values shifts the measured pH optimum of the ganglioside degradation to lower values (pH 3.6) and masks the substantial residual sialidase activity at pH 5-7. The membrane-fluidizing alcohol n-hexanol greatly accelerates ganglioside insertion as well as ganglioside degradation. The latter was clearly demonstrated by studying the hydrolysis of endogenous ganglioside substrates, and is due to a decrease of the apparent Km value and an increase in the Vmax value. The Vmax value was also enhanced by freezing and thawing of the microsomal membranes.