Growth- and development-dependent expression of gangliosides in rat hepatocytes and liver tissues.

Expression of gangliosides in the liver was examined in primary cultures of hepatocytes from adult rats and liver tissues from rats of different ages. Hepatocytes were isolated from 7-week-old rat liver and cultured in L-15 medium containing insulin, dexamethasone and 10% fetal bovine serum. Hepatocytes proliferated only on the first day, and then ceased proliferation. The content of GD3 and GD1a increased during the period of active proliferation and reached a nearly constant level, whereas GM1, GD1b, GT1b, and GQ1b gradually increased throughout culture. Addition of EGF to the culture medium caused significant increases in the content of GD3, and to a lesser degree of GM3, but exhibited little effect on the expression of other ganglioside species. The specific induction of GD3 and GM3 expression by EGF was reproduced under serum-free conditions, despite the lack of hepatocyte proliferation. Expression of gangliosides in cultured hepatocytes was also modulated by cell density; higher cell density brought about increased content of GM1, GD1a, GD1b, GT1b, and GQ1b with concomitant reduction of GM3 in cells. The composition of gangliosides in liver tissues demonstrated a unique developmental pattern. GD3 and GD1a were strongly expressed in E-16 embryonic tissue and rapidly decreased with increasing age. GD1b, GT1b, and GQ1b were found only in postnatal liver tissues. These findings suggest that the expression of gangliosides in rat hepatocytes and liver tissues are regulated by growth- and development-dependent factors.     

Fibronectin binding to gangliosides and rat liver plasma membranes

Binding of fibronectins to gangliosides was tested directly using several different in vitro models. Using an enzyme-linked immunoabsorbent assay (ELISA), gangliosides were immobilized on polystyrene tubes and relative binding of fibronectin was estimated by alkaline phosphatase activity of conjugated second antibody. Above a critical ganglioside concentration, the gangliosides bound the fibronectin (GT1b congruent to GD1b congruent to GD1a greater than GM1 much greater than GM2 congruent to GD3 congruent to GM3) in approximately the same order of efficiency as they competed for the cellular sites of fibronectin binding in cell attachment assays (Kleinman et al., Proc natl acad sci US 76 (1979) 3367). Alternatively, these same gangliosides bound to immobilized fibronectin. Rat erythrocytes coated with gangliosides GM1, GD1a or GT1b bound more fibronectin than erythrocytes not supplemented with gangliosides. Using fibronectin in which lysine residues were radioiodinated, an apparent Kd for binding to mixed rat liver gangliosides of 7.8 X 10(-9) M was determined. This value compared favorably with the apparent Kd for attachment of fibronectin to isolated plasma membranes from rat liver of 3.7 X 10(-9) M for fibronectin modified on the tyrosine residue, or 6.4 X 10(-9) M for fibronectin modified on lysine residues. As shown previously by Grinnell & Minter (Biochem biophys acta 550 (1979) 92), fibronectin modified on tyrosine residues did not promote spreading and attachment of CHO cells. It did, however, bind to cells. In contrast, lysine-modified fibronectin both bound to cells and promoted cell attachment. Plasma membranes isolated from hepatic tumors in which the higher gangliosides that bind fibronectin were depleted bound 43-75% less [125I]fibronectin than did plasma membranes from control livers. The findings were consistent with binding of fibronectins to gangliosides, including the same gangliosides depleted from cell surfaces during tumorigenesis in the rat.     

Developmental Changes in Ganglioside Composition and Synthesis in Embryonic Rat Brain

Developmental changes in ganglioside composition and biosynthesis was studied in rat brain between embryonic day (E) 14 and birth. In E14 brains, GM3 and GD3 were predominant. At E16, "b" series gangliosides, such as GD1b, GT1b, and GQ1b, increased in content. After E18, "a" series gangliosides such as GM1, GD1a, and GT1a increased in content, and the content of GM3 and GD3 markedly decreased. Because of these changes in composition, we determined the activities, in homogenates of embryonic brains, of two key enzymes of ganglioside synthesis: sialyltransferase for the synthesis of GD3 from GM3 and N-acetylgalactosaminyltransferase for GM2 synthesis from GM3. The sialyltransferase activity (GM3----GD3) was constant between E14 and E18 but decreased rapidly from E18 to birth. In contrast, the N-acetylgalactosaminyltransferase activity (GM3----GM2) increased between E14 and E18 but was constant from E18 to birth. These changes in ganglioside composition and enzymatic activities indicate that during development there is a shift from synthesis of the simplest gangliosides of the "a" and "b" pathways to synthesis of the more complex gangliosides.     

Specific ganglioside changes in extraneural tissues of adult rats with hypothyroidism

Adults rats with hypothyroidism were prepared by administration of 6-propyl-2-thiouracil (PTU) or methimazole, and the tissues were examined for their gangliosides through methods including glycolipid-overlay techniques. Normal thyroid tissue contained GM3, GD3, and GD1a as the major gangliosides, with GM1, GD1b, GT1b, and GQ1b in lesser amounts. The goitrous tissue of PTU-induced hypothyroid rats had higher concentrations of GM1 and GD1a with a concomitant decrease of GM3. The amount of GT3 in thyroid tissue was increased in hypothyroid animals. While normal liver tissue had a complex ganglioside pattern with a- and b-series gangliosides, the PTU-induced hypothyroid tissue showed a simpler ganglioside profile that consisted mainly of a-series gangliosides with almost undetectable amounts of b-series gangliosides. The expression of c-series gangliosides was suppressed in the hypothyroid liver tissue. Heart tissue had higher contents of GM3 and GT3 than control. No apparent change was observed in the compositions of major and c-series gangliosides in other extraneural tissues (i.e., kidney, lung, spleen, thymus, pancreas, testis, skeletal muscle, and eye lenses), and neural tissues (i.e., cerebrum and cerebellum) from PTU-induced hypothyroid rats. The ganglioside changes of thyroid, liver, and heart tissues were reproduced in corresponding tissues of methimazole-induced hypothyroid rats. These results suggest that hypothyroid conditions affect the biosynthesis and expression of gangliosides in specific tissue and cell types.     

Age-related changes in GM1, GD1a, GT1b components of gangliosides in Wistar albino rats

In this study, age-related changes of GM1, GD1a, GT1b fractions of gangliosides were investigated in whole brain of male Wistar albino rats. Insignificant increases were detected in GM1 values from the third to the 24th month, whereas GD1a and GT1b concentrations of ganglioside in 24-month-old rats decreased significantly as compared to 6-month-old rats. Although there were no significant differences in the GD1a/GT1b ratio of any groups, GM1/GD1a and GM1/GT1b ratios were significantly increased as compared to 6-month-old rats. The increase in the ratios of gangliosides are not due to an increase of GM1 fractions; they result from a decrease of GD1a and GT1b fractions of gangliosides. In conclusion, the concentration of ganglioside decreased with ageing.     

Stimulatory Effects of Growth Hormone and Thyroxine on the Concentration of Gangliosides in the Snell Dwarf Cerebrum

The concentration of gangliosides in the Snell dwarf mouse cerebrum was monitored from postnatal day 5 to day 40. In the dwarf cerebrum, the concentration of total gangliosides increased up to postnatal day 20 and then stopped, whereas in the control cerebrum, it continued to increase up to postnatal day 40. At postnatal day 40, the ganglioside level in the dwarf cerebrum was 70% of that in the control cerebrum. Among the ganglioside species, the concentrations of GM4, GM2, GM1, GD1a, GD3, GD1b, GT1b, and GQ1b were significantly lower in the dwarf cerebrum than in the controls at postnatal day 40. The reduced concentrations of ganglioside species GM2, GD1a, GD3, GD1b, and GQ1b were completely restored by administration of bovine growth hormone (GH) during the first 20 days of postnatal life. The reduced concentration of the GM1 and GM4 species were most efficiently restored by administration of bovine GH plus thyroxine (T4) during the second 20 days of postnatal life. These results indicate that the lower ganglioside concentrations in the dwarf cerebrum can be elevated by hormone therapy and that there exist distinct GH and T4 actions on the enzymes participating in ganglioside metabolism.     

Human brain gangliosides in development, aging and disease.

In this study, brain gangliosides in prenatal and postnatal human life and Alzheimer's disease were analyzed. Immunohistochemically, the presence of the "c"-series of gangliosides (GQ1c) was only registered in the embryonic brain at 5 weeks of gestation. Biochemical results indicated a two-fold increase in ganglioside concentration in the human cortex between 16 and 22 weeks of gestation. The increasing ganglioside concentration was based on an increasing GD1a ganglioside fraction in all regions analyzed except in the cerebellar cortex, which was characterized by increasing GT1b. During prenatal human development, regional differences in ganglioside composition could only be detected between the cerebrum ("a"-pathway) and the cerebellum ("b"-pathway). Between birth and 20-30 years of age, a cerebral neocortical difference of ganglioside composition occurred, characterized by the lowest GD1a in visual cortex. Analyzing the composition of gangliosides in cortical regions during aging, they were observed to follow region-specific alterations. In the frontal cortex, there was a greater decrease in GD1a and GM1 than in GT1b and GD1b, but in the occipital (visual) cortex there was no change in individual gangliosides. In hippocampus, GD1a moderately decreased, whereas other fractions were stable. In the cerebellar cortex, GD1b and GT1b fractions decreased with aging. In Alzheimer's disease, we found all ganglio-series gangliosides (GM1, GD1a, GD1b, GT1b) to be decreased in regions (temporal and frontal cortex and nucleus basalis of Meynert) involved in pathogenesis of disease. In addition, in Alzheimer's disease we found simple gangliosides (GN2, GM3) to be elevated in the frontal and parietal cortex, which might correlate accelerated lysosomal degradation of gangliosides and/or astrogliosis occurring during neuronal death.     

Dissociation of the Stellate Morphology from Intracellular Cyclic AMP Levels in Cultured Rat Brain Astroglial Cells: Effects of Ganglioside GMl and Lysophosphatidylserine

Secondary microcultures of newborn rat cerebrum astroglial (AG) cells, maintained in a serum-free, chemically defined medium, were treated with various agents known to elevate intracellular cyclic AMP (cAMP) levels. Earlier studies had shown these drugs to induce a process-bearing (stellate) morphology in the AG cells, a response that was antagonized by the presence of gangliosides. One millimolar dibutyryl cyclic AMP (dBcAMP), 10 microM forskolin, 12 nM cholera toxin, and 30 microM isoproterenol all raised intracellular cAMP levels, from basal values of 3 pmol/10(6) cells to 30-30,000 pmol/10(6) cells, depending on the agent tested. dBcAMP caused the greatest elevation, and forskolin the least. The timing and/or the level of the AMP response did not precisely correlate with those of the stellation response. Values of ED50 with the four agents, as determined for the cAMP response, were always higher than stellation ED50 values in all treatments, and ED50 did not correlate with the maximal levels of cyclic AMP induced by the four agents. The capacity of ganglioside GM1 to block the stellation response to the four agents was not accompanied by a similar capacity to block the cAMP responses. Lysophosphatidylserine (lysoPS) had the capacity to induce AG cell stellation as well, without altering the basal level of cAMP. Both lysoPS and gangliosides, therefore, may act directly on the cellular machinery underlying the stellation response without involving changes in intracellular AMP.     

Differential distribution of major gangliosides in rat central nervous system detected by specific monoclonal antibodies

We investigated the localization of major gangliosides in adultrat brain by an immunofluorescence technique with mouse monoclonalantibodies (MAbs). Five MAbs (GMB16, GMR17, GGR12, GMR5 andGMR13) that specifically recognize gangliosides GM1, GD1a, GD1b,GT1b and GQ1b, respectively, were used. We have found that thereis a cell type-specific expression of the ganglioside in therat central nervous system. In cerebellar cortex, GM1 was expressedin myelin and some glial cells. GD1a was detected exclusivelyin the molecular layer. GD1b and GQ1b were present restrictedlyon the granular layer; GD1b was detected on the surface of thegranular cell bodies, whereas GQ1b was present in the cerebellarglomerulus. GT1b was distributed intensely in both the molecularlayer and the granular layer. In cerebral cortex, GM1 was detectedin some glial cells. Dense staining was limited to the whitematter. GD1a was distributed in layers I, II/III and Va, andthe upper part of layer VI, whereas GQ1b was localized in layersIV and Vb, and the lower part of layer VI. GD1b was detectedbeneath layer III. GT1b appeared to be distributed throughoutall layers. In other regions, such as hippocampal formationand spinal cord, the expression of the ganglioside was alsohighly localized to a specific cell type and layer. ganglioside monoclonal antibody rat brain     

Effect of rat liver gangliosides on the interaction of liposomes with rat hepatocytes in vitro

The influence of rat liver GM1, GM2, GD1 and GT1 gangliosides on the interaction of liposomes with rat hepatocytes was investigated. It was shown that liposomes coated with GM1 and GT1 are effectively bound and captured by hepatocytes. Preincubation of hepatocytes with N-acetylglucosamine and D-galactose reduced the binding of GM1- and GT1-liposomes by those cells. The data obtained suggest that there are binding sites for some gangliosides on the surface of rat hepatocytes.     

Induction of GM1a/GD1b synthase triggers complex ganglioside expression and alters neuroblastoma cell behavior; a new tumor cell model of ganglioside function

Neuroblastoma is the most common extracranial solid tumor in children and tumor ganglioside composition has been linked to its biological and clinical behavior. We recently found that high expression of complex gangliosides that are products of the enzyme GM1a/GD1b synthase predicts a more favorable outcome in human neuroblastoma, and others have shown that complex gangliosides such as GD1a inhibit metastasis of murine tumors. To determine how a switch from structurally simple to structurally complex ganglioside expression affects neuroblastoma cell behavior, we engineered IMR32 human neuroblastoma cells, which contain almost exclusively (89%) the simple gangliosides (SG) GM2, GD2, GM3, and GD3, to overexpress the complex gangliosides (CG) GM1, GD1a, GD1b and GT1b, by stable retroviral-mediated transduction of the cDNA encoding GM1a/GD1b synthase. This strikingly altered cellular ganglioside composition without affecting total ganglioside content: There was a 23-fold increase in the ratio of complex to simple gangliosides in GM1a/GD1b synthase-transduced cells (IMR32-CG) vs. wild type (IMR32) or vector-transfected (IMR32-V) cells with essentially no expression of the clinical neuroblastoma marker, GD2, confirming effectiveness of this molecular switch from simple to complex ganglioside synthesis. Probing for consequences of the switch, we found that among functional properties of IMR32-CG cells, cell migration was inhibited and Rho/Rac1 activities were altered, while proliferation kinetics and cell differentiation were unaffected. These findings further implicate cellular ganglioside composition in determining cell migration characteristics of tumor cells. This IMR32 model system should be useful in delineating the impact of ganglioside composition on tumor cell function.     

Ganglioside binding pattern of CD33-related siglecs

Our study deals with the interaction of CD33 related-siglecs-5,-7,-8,-9,-10 with gangliosides GT1b, GQ1b, GD3, GM2, GM3 and GD1a. Siglec-5 bound preferentially to GQ1b, but weakly to GT1b, whereas siglec-10 interacted only with GT1b ganglioside. Siglec-7 and siglec-9 displayed binding to gangliosides GD3, GQ1b and GT1b bearing a disialoside motif, though siglec-7 was more potent; besides, siglec-9 interacted also with GM3. Siglec-8 demonstrated low affinity to the gangliosides tested compared with other siglecs. Despite high structural similarity of CD33 related siglecs, they demonstrated different ganglioside selectivity, in particular to the Neu5Acalpha2-8Neu5Ac motif.     

Activities of Five Different Sialyltransferases in Fish and Rat Brains

Abstract: To investigate the role of Sialyltransferases in the metabolism of brain gangliosides, we examined activities of five different Sialyltransferases (GM3-, GD3-, GT3-, GD1a-, and GT1a-synthase) using total membrane preparations from cichlid fish and Sprague-Dawley rat brains, and analyzed the relationship between the enzyme activities and the ganglloside compositions. The patterns of sialyltransferase activities in fish and rat brains differed from each other. In fish brain, the GM3-synthase activity was lower than GD3-synthase activity, whereas the opposite relationship was observed in rat brain. The GT3-synthase reaction with fish brain membranes produced radiolabeled GM3, GD3, and a ganglioside that was identified as GT3 based on mobility on TLC using two different solvent systems. No GT3-synthase activity was detected in rat brain. The GD1a-and GT1a-synthase activities in fish brain were higher than those in rat brain. Although GT1a was a single radiolabeled ganglioside in fish GT1a-synthase reaction, this ganglioside could not be detected in rat brain. The ratios of GM3-, GD3-, GT3-, GD1a-, and GT1a-synthase activities in fish and rat brain were 23:31:4:28:14 and 61:21:0:18:0, respectively. Ganglioside analysis showed that fish brain was enriched with c-series gangliosides including GT3 and polysialo-species, whereas a-and b-se-ries gangliosides were major components in rat brain. These results suggest that the species-specific expression of gangliosides in brain tissues may be regulated, at least in part, at the level of sialyltransferase activities.     

Gangliosides of organ-confined versus metastatic androgen-receptor-negative prostate cancer

Prior development of a unique androgen-receptor (AR)-negative cell line (HH870) from organ-confined (T2b) human prostate cancer (CaP) enabled comparison of the gangliosides associated with normal and neoplastic prostate epithelial cells, organ-confined versus metastatic (DU 145, PC-3), and AR-negative versus AR-positive CaP cell lines. Resorcinol-HCl and specific monoclonal antibodies were used to characterize gangliosides on 2D-chromatograms, and to visualize them on the cell surface with confocal-fluorescence microscopy. AR-negative cells expressed GM1b, GM2, GD2, GD1a, and GM3. GM1a, GD1b, and GT1b were undetectable. GM1b and GD1a were more prominent in AR-negative than in AR-positive cells. PC-3 and HH870 cells were unique in the expression of O-acetylGD2 (O-AcGD2) and two alpha2,3-sialidase-resistant, alkali-susceptible GMR17-reactive gangliosides. Expression of GD1a, GM1b, doublets of GD3, GD2, and O-AcGD2, and the presence of an additional alkali-labile-14.G2a-reactive ganglioside, two alkali-susceptible, and three alkali-resistant GMR17-reactive gangliosides makes HH870 a potential component of a polyvalent-vaccine for active-specific immunotherapy of CaP.     

Immunoglobulin G-class mouse monoclonal antibodies to major brain gangliosides

Mice genetically engineered to lack complex gangliosides are improved hosts for raising antibodies against those gangliosides. We report the generation and characterization of nine immunoglobulin G (IgG)-class monoclonal antibodies (mAbs) raised against the four major brain gangliosides in mammals. These include (designated as ganglioside specificity-IgG subclass) two anti-GM1 mAbs (GM1-1, GM1-2b), three anti-GD1a mAbs (GD1a-1, GD1a-2a, GD1a-2b), one anti-GD1b mAb (GD1b-1), and three anti-GT1b mAbs (GT1b-1, GT1b-2a, GT1b-2b). Each mAb demonstrated high specificity, with little or no cross-reactivity with other major brain gangliosides. Enzyme-linked immunosorbent assay (ELISA) screening against 14 closely related synthetic and purified gangliosides confirmed the high specificity, with no significant cross-reactivity except that of the anti-GD1a mAbs for the closely related minor ganglioside GT1a alpha. All of the mAbs were useful for ELISA, TLC immunooverlay, and immunocytochemistry. Neural cells from wild-type rats and mice were immunostained to differing levels with the anti-ganglioside antibodies, whereas neural cells from mice engineered to lack complex gangliosides (lacking the ganglioside-specific biosynthetic enzyme UDP-GalNAc:GM3/GD3 N-acetylgalactosaminyltransferase) remained unstained, demonstrating that most of the mAbs react only with gangliosides and not with related structures on glycoproteins. These mAbs may provide useful tools for delineation of the expression and function of the major brain gangliosides and for probing the pathology of anti-ganglioside autoimmune diseases.     

Immunosuppression by human gangliosides: I. Relationship of carbohydrate structure to the inhibition of T cell responses.

Causes of cellular immunodeficiency frequently associated with cancer remain poorly understood. One possible mechanism is tumor cell membrane shedding of immunosuppressive molecules, such as the sialic acid-containing glycosphingolipids, gangliosides. To explore this interesting hypothesis and establish structure-activity relationships, we examined the effects of a series of highly purified human gangliosides on T cell function. In all, ten individual molecular species of two major biosynthetic pathways were compared for their ability to inhibit human T cell proliferative responses. They include GM1, GD1a, GD1b, and GT1b (the predominant normal brain species), and GM4, GM3, GM2, GD3, GD2 and GQ1b. Strikingly, each HPLC-purified molecule, from the simplest monosialoganglioside to the most complex polysialoganglioside, had potent inhibitory activity; even the ganglioside with the most elemental carbohydrate structure (GM4, one sialic acid linked to a monosaccharide) strongly inhibits T cell proliferative responses to tetanus toxoid (ID90 = 1.5 microM). The data also reveal a complex interplay between elements of oligosaccharide structure in determining immunosuppressive activity. Sialic acid is critical to maximal activity, and (i) immunosuppression is most potent in gangliosides containing a terminal sialic acid. (ii) Total desialylation almost abolishes activity and (iii) partial alteration (lactone formation) reduces activity. (iv) Activity is generally but not always higher with higher numbers of sialic acid residues/molecule, and (v) some larger neutral glycosphingolipids retain measurable immunosuppressive activity. Overall, the potent inhibition by gangliosides supports the hypothesis that shedding of these molecules by tumors creates a highly immunosuppressive microenvironment around the tumor, thereby inhibiting the function of infiltrating host leukocytes and contributing to diminished T cell responses in cancer.     

Gangliosides Inhibit Platelet-Derived Growth Factor-Stimulated Receptor Dimerization in Human Glioma U-1242MG and Swiss 3T3 Cells

Abstract: We previously showed that gangliosides inhibit DNA synthesis in Swiss 3T3 cells stimulated with platelet-derived growth factor (PDGF) in a dose-responsive manner. This correlated with the inhibitory effects of several gangliosides (except GM3) on tyrosine phosphorylation of the PDGF receptor (PDGFR). [³⁵S]Methionine-labeled Swiss 3T3 cells were incubated either with or without gangliosides and stimulated with PDGF, and proteins were cross-linked with bis(sulfosuccinimidyl) suberate. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that two protein bands (170 and 350 kDa) were specifically immunoprecipitated with an anti-PDGFR antibody. Using both Swiss 3T3 and human glioma U-1242MG cells, western blots with anti-PDGFR and anti-phosphotyrosine antibodies confirmed that these bands were the PDGFR monomer and dimer, respectively, and that phosphotyrosine was present in these bands only after cells were stimulated with PDGF. Of the gangliosides tested, GM1, GM2, GD1a, GD1b, GD3, and GT1b, but not GM3, inhibited the formation of the 350-kDa band. These results demonstrate that all gangliosides tested, except GM3, probably inhibit PDGF-mediated growth by preventing dimerization of PDGFR monomers. Loss of more complex gangliosides in human gliomas would permit unregulated activation of the PDGFR, contributing to uncontrolled growth stimulation. We propose that ganglioside inhibition of receptor dimerization is a novel mechanism for regulating and coordinating several trophic factor-mediated cell functions.     

Ganglioside stimulation of nerve growth factor synthesis in cultured rat Schwann cells

To investigate effects of gangliosides on nerve growth factor (NGF) synthesis/secretion by Schwann cells, we obtained Schwann cells from dorsal sensory ganglia of one-day old Wistar rats and cultured them with various concentrations of a mixed ganglioside comprising GM1, GD1a, GD1b, and GT1b. NGF synthesis was evaluated by the measurement of NGF concentration in the conditioned medium using an enzyme immunoassay. In the continuous presence of 10(-3) M gangliosides, the NGF concentration in the medium showed a four fold increase on the 4th day, and it then decreased by the 8th day. The present results indicate that gangliosides promote the production/synthesis of NGF by Schwann cells.     

Biosynthesis of gangliosides in primary cultures of rat hepatocytes. Determination of the net synthesis of individual gangliosides by incorporation of labeled N-acetylmannosamine

The ganglioside content of rat hepatocytes increases several-fold during the first 6 days in monolayer culture. To correlate increased levels with rates of de novo synthesis, the incorporation of N-acetyl-[6-3H]D-mannosamine into individual gangliosides was determined. The calculation of synthetic rates was made possible by the simultaneous measurement of the specific radioactivity of the immediate sialic-acid donor, CMP-Neu5Ac. The CMP-Neu5Ac content of hepatocytes was found by HPLC analysis to be 30.5 nmol/g of plated cells. The specific radioactivity of this precursor pool reached a constant plateau 5 h after addition of the labeled N-acetyl-mannosamine and remained constant for at least 70 h. The incorporation into individual gangliosides was measured in primary cultures of rat hepatocytes between 72 and 144 h after seeding. During this period, the increase in ganglioside levels was greatest. The highest rates of incorporation were seen in GD1a followed by GM3, GM1, GD3 and the polysialylated compounds. The following rates of synthesis (nmol per 60 h and mg of protein) were calculated: GD1a 0.68, GM3 0.59, GM1 0.36, GD3 0.13 and GT1 0.02. These values are compared with the net increase of the gangliosides as measured by the resorcinol reaction.     

Ganglioside-specific binding protein on rat brain membranes

A derivative of ganglioside GT1b (IV3NeuAc,II3(NeuAc)2-GgOse4) with an active ester in its lipid portion was synthesized and covalently attached to bovine serum albumin (BSA). The conjugate, having four GT1b molecules per albumin molecule [GT1b)4BSA) was radioiodinated and used to probe rat brain membranes for ganglioside binding proteins. A ganglioside-specific, high affinity (KD = 2-4 nM), saturable (Bmax = 13-20 pmol/mg membrane protein) binding site for 125I-(GT1b)4BSA was demonstrated on detergent-solubilized rat brain membranes adsorbed to filters. 125I-(GT1b)4BSA binding was tissue-specific (more than 35-fold greater to brain than to liver membranes) and was nearly eliminated by pretreatment of brain membrane-adsorbed filters with trypsin (1 microgram/ml). Underivatized gangliosides added as mixed detergent-lipid micelles blocked 125I-(GT1b)4BSA binding to brain membranes; structurally related GQ1b, GT1b, and GD1b were the most potent (half-maximal inhibition at 70-110 nM), while half-maximal inhibition by other gangliosides (GD3, GD1a, GM3, GM2, and GM1) required 5-20-fold higher concentrations. Other sphingolipids, neutral glycosphingolipids, and glycoproteins were poor inhibitors, and treatment of (GT1b)4BSA with neuraminidase attenuated its binding. Although most phospholipids were noninhibitory, phosphatidylinositol and phosphatidylglycerol inhibited half-maximally at 400-600 nM. However, inhibition of 125I-(GT1b)4BSA binding by gangliosides was competitive and reversible while that by phosphatidylinositol and phosphatidylglycerol was not. Ganglioside-protein conjugate binding reveals ganglioside-specific brain membrane receptors.