Ganglioside biosynthesis. Characterization of CMP-N-acetylneuraminic acid : lactosylceramide sialyltransferase in Golgi apparatus from rat liver.

An enzyme that transfers sialic acid from GMP-sialic acid to lactosylceramide was concentrated 40-50 times in Golgi apparatus from rat liver relative to total homogenates. This enzyme required detergents as dispersing agents. Of the numerous detergents tested, the combination Tween 80-Triton CF-54 (1 : 2, w/w) was the most effective in stimulating the reaction. Two apparent pH optima, at 6.35 and 5.5, were observed. The enzyme showed no requirement for a divalent cation. The Km values calculated for CMP-N-acetylneuraminic acid and lactosylceramide were 2.7 - 10(-3) and 1.3 - 10(-4) M, respectively. The enzyme could not be dissociated from Golgi apparatus fractions by treatment with ultrasound, indicating that it is tightly associated with the membrane. The newly synthesized GM3, the product of the reaction, was incorporated into or became tightly associated with the membranes of the Golgi apparatus.     

Characterization of a CMP-sialic acid:lactosylceramide sialyltransferase activity in cultured hamster cells

Previous studies have shown a strong correlation between reduced levels of GM3 ganglioside and an increase in the oncogenic transformation of cultured cells. CMP-sialic acid:lactosylceramide sialyltransferase, which catalyzes GM3 synthesis, was characterized in cultured hamster fibroblasts (NIL-8) with respect to substrate binding, pH optimum, detergent requirements, metal ion requirements, activity during cell cycle phases and activity during cell growth phases. The apparent Km values for CMP-sialic acid and lactosylceramide were 0.16 and 0.11 mM, respectively. The enzyme required Mn2+ (15 mM) for maximal, but Mg2+ and Ca2+ were able to substitute to a lesser extent. Triton CF-54 (0.3%, w/v) compared to other nonionic detergents gave the greatest enzyme activation, while ionic detergents inhibited the enzyme. A broad pH optimum (4.5-8.0) was obtained, with maximum activity at pH 6.5 in cacodylate-HCl buffer. No buffer effects on enzyme activity were seen. Sialyltransferase activity was found to be highest in the M and G1 phases of the cell cycle and in the contact-inhibited phase of cell growth.     

Ganglioside biosynthesis in rat liver. Characterization of UDP-N-acetylgalactosamine -- GM3 acetylgalactosaminyltransferase

UDP-N-acetylgalactosamine--GM3 acetylgalactosaminyltransferase (GM2-synthase) was studied in a Golgi-rich fraction from rat liver. Activity in a cell-free system required the presence of detergents; octyl glucoside was found to be the most effective in stimulating the enzyme. Optimal activity of GM2-synthase was obtained at pH 7.2, in the presence of 0.8% octyl glucoside, 10 mM Mn2+ and 5 mM CDP-choline. The latter was used to counteract the rapid sugar nucleotide hydrolysis caused by a nucleotide pyrophosphatase activity in the Golgi fraction. The apparent Km values for UDP-N-acetylgalactosamine and added GM3 were 0.035 mM and 0.1 mM, respectively. Different results were obtained if endogenous GM3 only was used as the glycolipid acceptor. In this case, the apparent Km value for UDP-N-acetylgalactosamine was 0.18 mM and Co2+ and Fe2+ exceeded Mn2+ in activating GM2-synthase. Under optimal assay conditions and in the presence of added GM3 and 5 mM CDP-choline, the specific activity of the enriched Golgi fraction was measured to be 25-30 nmol X mg protein-1 X h-1; with endogenous GM3 as the sole glycolipid acceptor, V was calculated to be 9 nmol X mg protein-1 X h-1.     

Sub-Golgi distribution in rat liver of CMP-NeuAc GM3- and CMP-NeuAc:GT1b alpha 2----8sialyltransferases and comparison with the distribution of the other glycosyltransferase activities involved in ganglioside biosynthesis

Using a sucrose density gradient fractionation of a highly purified Golgi apparatus from rat liver, we determined the sub-Golgi distribution of CMP-NeuAc:GM3 ganglioside alpha 2----8sialyltransferase (GM3-SAT) and CMP-NeuAc:GT1b ganglioside alpha 2----8sialyltransferase (GT1b-SAT), in comparison with that of the other glycosyltransferase activities involved in ganglioside biosynthesis. While GM3-SAT was recovered in several density fractions, GT1b-SAT was mainly found on less dense sub-Golgi membranes; this indicates that these two activities are physically separate. Moreover, with regard to the monosialo pathway, CMP-NeuAc:lactosylceramide alpha 2----3sialyltransferase, UDP-GalNAc:GM3 ganglioside beta 1----4N-acetylgalactosaminyltransferase, UDP-Gal:GM2 ganglioside beta 1----3galactosyltransferase, and CMP-NeuAc:GM1 ganglioside alpha 2----3sialyltransferase were resolved from more dense to less dense fractions, respectively. In the disialo pathway, UDP-GalNAc:GD3 ganglioside beta 1----4N-acetylgalactosaminyltransferase, UDP-Gal:GD2 ganglioside beta 1----3galactosyltransferase and CMP-NeuAc:GD1b ganglioside alpha 2----3sialyltransferase co-distributed with the corresponding activities of the monosialo pathway. These last results indicate that many Golgi glycosyltransferases involved in ganglioside biosynthesis are localized in the order in which they act.     

The phosphatidylinositol kinase of rat brain

1. The presence of a phosphatidylinositol kinase in homogenates of adult rat brain was shown by using labelled ATP or labelled phosphatidylinositol. 2. The kinase was activated by Mg(2+) or Mn(2+) and inhibited by Ca(2+), Cu(2+), K(+), Na(+) and F(-). 3. The detergents sodium deoxycholate, Cutscum and Triton X-100 markedly stimulated the reaction; sodium taurocholate, Tween-20 and cetyltrimethyl-ammonium bromide were less effective. 4. The activity of the enzyme was dependent on SH groups. 5. The subcellular distribution of the kinase in brain resembled that of Na(+)-plus-K(+)-stimulated adenosine triphosphatase and 5'-nucleotidase.     

Peroxidase-amplified assay of sialidase activity toward gangliosides.

Sialidase assays were carried out with the substrate, ganglioside GD1a, coated onto enzyme immunoassay plate wells. Following the incubation of GD1a with sialidase from V. cholerae, the amount of ganglioside GM1 produced was measured as follows: cholera toxin B subunit conjugated to horseradish peroxidase was added to specifically bind to GM1, and then the amount of bound peroxidase was determined in a colorimetric enzymatic assay. In the absence of detergent, linearity for the detection of GM1 was 0 to 0.5 pmol per well, and the sensitivity for sialidase detection was about 3 fmol of product formed per minute. The addition of detergent (Triton CF-54) to the assay reduced the sensitivity and increased the amount of substrate required. Application of this assay for the detection of cell-derived neutral (pH 6.5) sialidase activities in the conditioned medium of human skin fibroblasts is described.     

Purification and properties of two enzymes catalyzing galactose transfer to GM2 ganglioside from rat liver Golgi

An enzyme activity which catalyzed the transfer of galactose from UDP-galactose to GM2 ganglioside was demonstrated in rat liver homogenate and enriched 38-fold in specific activity by preparation of Golgi membranes. This activity could be solubilized from Golgi membranes by sonication and extraction with 1% Triton X-100. The solubilized activity catalyzed the formation of GM1 ganglioside and was completely dependent upon the addition of acceptor. The rate of galactose incorporation was constant for up to 5 h at 30 degrees C. This enzyme activity was further purified by gel filtration on Sepharose CL-6B and ion exchange chromatography on DEAE-Sepharose. The elution position on gel filtration corresponded to a molecular weight for the enzyme of 38,000 which was in good agreement with that obtained by sedimentation velocity studies. Ion exchange chromatography resolved GM2 ganglioside galactosyltransferase into two species. The more basic enzyme (I) comprising 28% of the recovered activity was not retarded by the column, whereas enzyme II was eluted from the resin following the application of a salt gradient. Net purification was 120- to 140-fold for each enzyme with a total recovery of 42%. Unlike the activity in the Golgi extract, the purified enzymes I and II were labile to freezing and could be stored at -20 degrees C only in the presence of 50% glycerol. Both enzymes I and II had similar molecular weights and Michaelis constants and both had a strict requirement for Mn2+. Properties which distinguish the two enzymes included pH optima (enzyme I 7.0, enzyme II 6.0) and surfactant requirements. Neither enzyme was active following removal of Triton X-100 from the preparation. Among a series of glycolipids tested for ability to serve as substrates for galactose transfer only GM2 and asialo-GM2 ganglioside served as acceptors.     

肝癌组织中GD3合成酶的纯化

ＧＤ３合成酶是膜嵌合蛋白,定位于高尔基体,经过制作微粒体,Ｔｒｉｔｏｎ增溶、ＡＨ－Ｓｅｐｈａｒｏｓｅ及ＧＭ３－Ｇｌａｓｓｂｅａｄｓｅ及ＧＭ３－Ｇｌａｓｓｂｅａｄｓ亲和层析等步骤,二乙基亚硝胺诱发大鼠肝癌组织中的ＳＴ２被纯化了３１５９７倍,得率为０．３５％。ＳＤＳ－聚丙烯酰胺凝胶电泳后银染色呈１条蛋白着色带,分子量为５５ｋｄ。     

Special considerations in the purification of the GM3 ganglioside forming enzyme, CMP-sialic acid:lactosylceramide alpha 2-3 sialyltransferase (SAT-1): solubilization of SAT-1 with lauryldimethylamine oxide

Lauryldimethylamine oxide (LDAO) was employed in the purification of the GM3 ganglioside forming enzyme, CMP-sialic acid:lactosylceramide alpha 2-3 sialyltransferase (SAT-1) (4). This detergent has advantages over the typically employed Triton detergents in the solubilization and stabilization of this sialyltransferase. Crude protein fractions solubilized from rat liver Golgi by several such detergents are very similar in composition as determined by two-dimensional gel electrophoresis. However, LDAO appears to activate and stabilize SAT-1 activity. It is possible that SAT-1 activation involves the structurally similar hydrophobic moieties and quaternary amino groups of LDAO and phosphatidylcholine.     

Effects of detergents and choline-containing phospholipids on human spleen glucocerebrosidase.

1. Glucocerebrosidase, extracted from human spleen lysosomal membrane by sodium cholate and recovered in a high speed centrifugation supernatant, aggregated following removal of the detergent. 2. Re-solubilization of the enzymatic activity from the aggregate was achieved by treatment with the non-ionic detergents Triton X-100 and Tween 20. The anionic detergents sodium cholate and sodium taurocholate and the cationic detergents cetyltrimethylammonium bromide and cetylpyridinium chloride were also effective. The solubilizing capacity of the anionic detergents was smaller than that of the nonionic detergents. Quantitative evaluation of the solubilizing capacity of the cationic detergents was not feasible because of their being potent inhibitors of glucocerebrosidase activity. 3. Treatment of the enzyme aggregate with acetone rendered it buffer-soluble. 4. In addition to the above cationic detergents some choline-containing and highly hydrophobic phospholipids were found to inhibit the glucocerebrosidase activity.     

Cytidine-5'-monophospho-N-acetylneuraminic acid galactosyl-N-acetylgalactosaminyl-(N-acetylneuraminyl)-galactosyl-glucosylceramide sialyltransferase in the neurohypophysis of the rabbit.

1. Cytidine-5'-monophospho-N-acetylneuraminic acid: (galactosyl-N-acetyl-galactosaminyl-(N-acetylneuraminyl)-galactosyl-glucosylceramide sialyltransferase (CMP-NAcNeu: monosialoganglioside (GM1) sialyltransferase) activity was demonstrated in the neurohypophysis of the rabbit. 2. Optimum activity occurred at pH 6.5 and required the presence of exogenous galactosyl-N-acetylgalactosaminyl-(N-acetylneuraminyl)-galactosyl-glucosylceramide (GM1 ganglioside), detergent (Triton X-100), and divalent cation (Mn2+, Mg2+ or Ca2+). 3. The product of the reaction was characterized as N-acetylneuraminyl-galactosyl-N-acetylgalactosaminyl-(N-acetylneuraminyl)-galactosyl-glucosylceramide (GD1a) by ascending thin-layer chromatography. 4. Physiological stimulation of vasopressin secretion, by the substitution of 2.2% NaCl for drinking water for 14 days, had no effect on the enzyme activiity or the ganglioside content of the tissue.     

Rat liver Golgi galactosyltransferases. Distinct enzymes for glycolipid and glycoprotein acceptor substrates.

Two enzymes that catalyse the transfer of galactose from UDP-galactose to GM2 ganglioside were partially purified from rat liver Golgi membranes. These preparations, designated enzyme I (basic) and enzyme II (acidic), utilized as acceptors GM2 ganglioside and asialo GM2 ganglioside as well as ovalbumin, desialodegalactofetuin, desialodegalacto-orosomucoid, desialo bovine submaxillary mucin and GM2 oligosaccharide. Enzyme II catalysed disaccharide synthesis in the presence of the monosaccharide acceptors N-acetylglucosamine and N-acetylgalactosamine. The affinity adsorbent alpha-lactalbumin-agarose, which did not retard GM2 ganglioside galactosyltransferase, was used to remove most or all of galactosyltransferase activity towards glycoprotein and monosaccharide acceptors from the extracted Golgi preparation. After treatment of the extracted Golgi preparation with alpha-lactalbumin-agarose, enzyme I and enzyme II GM2 ganglioside galactosyltransferase activities, prepared by using DEAE-Sepharose chromatography, were distinguishable from transferase activity towards GM2 oligosaccharide and glycoproteins by the criterion of thermolability. This residual galactosyltransferase activity towards glycoprotein substrates was also shown to be distinct from GM2 ganglioside galactosyltransferase in both enzyme preparations I and II by the absence of competition between the two acceptor substrates. The two types of transferase activities could be further distinguished by their response to the presence of the protein effector alpha-lactalbumin. GM2 ganglioside galactosyltransferase was stimulated in the presence of alpha-lactalbumin, whereas the transferase activity towards desialodegalactofetuin was inhibited in the presence of this protein. The results of purification studies, comparison of thermolability properties and competition analysis suggested the presence of a minimum of five galactosyltransferase species in the Golgi extract. Five peaks of galactosyltransferase activity were resolved by isoelectric focusing. Two of these peaks (pI 8.6 and 6.3) catalysed transfer of galactose to GM2 ganglioside, and three peaks (pI 8.1, 6.8 and 6.3) catalysed transfer to glycoprotein acceptors.     

Ganglioside biosynthesis in Golgi apparatus of rat liver. Stimulation by phosphatidylglycerol and inhibition by tunicamycin

Golgi vesicles were isolated and purified from rat liver, in which the specific activities of glycosyltransferases (e.g. GM3:CMP-NeuAc sialyltransferase, GD3 synthase; GM3:UDP-GalNAc galactosaminyltransferase, GM2 synthase) were 50-60-times enriched relative to microsomes or total homogenate. Synthesis of gangliosides GM2 and GM1 in such Golgi vesicles is, in the absence of any detergents, stimulated 6-fold and 20-fold respectively by phosphatidylglycerol. Other phospholipids like phosphatidylethanolamine and phosphatidylserine are also significantly stimulatory. With 50 micrograms Golgi protein and 1 nmol UDP-GalNAc, optimal stimulation of GM2 synthase was obtained with 20 micrograms of phosphatidylglycerol and 7.5 nmol of the lipid acceptor GM3. Under the same experimental conditions this stimulation exceeds (by about 40%) that obtained with optimal amount (200 micrograms) of the detergent octylglucoside. Phosphatidylglycerol, on the other hand, has virtually no stimulatory activity on the synthesis of ganglioside GD3 either in the presence of Mg2+ or Mn2+, indicating that facilitation by phospholipid of GM3 transport into Golgi vesicles was not the basis of stimulation of GM2 synthesis. Tunicamycin inhibits the synthesis of gangliosides GM2 and GM1 in isolated Golgi vesicles, but only in the absence of detergents. In the presence of phosphatidylglycerol, GM2 synthesis, for example, was inhibited by 60% by 2 micrograms tunicamycin and more than 85% by 10 micrograms tunicamycin, per 50 micrograms Golgi membrane protein. The inhibition was stronger on GM1 synthesis: 85% with 2.5 micrograms of the antibiotic. The dependence on phosphatidylglycerol and the degree of inhibition by tunicamycin of the synthetic activities are strictly dependent on the intactness of the Golgi vesicles: both phenomena become increasingly less evident when the vesicles are pelleted, and frozen and thawed several times, and completely disappear when the vesicles are solubilized by detergents or disrupted by ultrasonication. Furthermore, tunicamycin inhibition is reversible by increased concentration of phosphatidylglycerol. All these results indicate that phosphatidylglycerol does not stimulate, and tunicamycin does not inhibit, the transferases themselves; rather, the two opposing effects might relate to carrier-mediated transport, e.g. of nucleotide sugars, across Golgi vesicles.     

Localization in the Golgi apparatus of rat liver UDP-Gal:glucosylceramide beta 1----4galactosyltransferase

The presence and subcellular localization of UDP-Gal:glucosylceramide beta 1----4galactosyltransferase (GalT-2) was investigated in rat liver. For this purpose, purified Golgi apparatus, endoplasmic reticulum, and plasma membrane fractions were prepared from the liver and used as the enzyme source for detecting GalT-2. A pure Golgi apparatus, highly enriched in many glycosyltransferases, was the only fraction where GalT-2 was measurable. The reaction product formation rate under appropriate assay conditions, which requires high detergent concentration and Mn2+, was low but comparable with that of other glycosyltransferases. The product formation was stimulated by exogenously added acceptor GlcCer, donor UDP-Gal, and Golgi protein. The reaction product was a single spot that was identified by chromatographic behavior, sensitivity to beta-galactosidase, and permethylation studies as Gal beta 1----4Glc beta 1----1'Cer (lactosylceramide). A metabolic experiment, performed by determining the glycosphingolipids which became radioactive in the above subcellular fractions prepared from the liver of animals treated with glucose-labeled glucosylceramide, further indicated that the in vivo glycosylation of glucosylceramide takes place in the Golgi apparatus.     

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.     

Regulation of ganglioside biosynthesis by enzyme complex formation of glycosyltransferases

Three key regulatory enzymes in ganglioside biosynthesis, sialyltransferase I (ST1), sialyltransferase II (ST2), and N-acetylgalactosaminyltransferase I (GalNAcT), have been expressed as fusion proteins with green, yellow, or red fluorescent protein (GFP, YFP, or RFP) in F-11A cells. F-11A cells are a substrain of murine neuroblastoma F-11 cells that contain only low endogenous ST2 and GalNAcT activity. The subcellular localization of the fusion proteins has been determined by fluorescence microscopy, and the ganglioside composition of these cells was analyzed by high-performance thin-layer chromatography (HPTLC). ST2-GFP (85 kDa) shows a distinct Golgi localization, whereas ST1-YFP (85 kDa) and GalNAcT-RFP (115 kDa) are broadly distributed in ER and Golgi. Untransfected F-11A cells contain mainly GM3, whereas stable transfection with ST2 or GalNAcT results in the predominant expression of b-series complex gangliosides (BCGs). This result indicates that the expression of ST2 enhances the activity of endogenous GalNAcT and vice versa. The specificity of this reaction has been verified by in vitro activity assays with detergent-solubilized enzymes, suggesting the formation of an enzyme complex between ST2 and GalNAcT but not with ST1. Complex formation has also been verified by co-immunoprecipitation of ST2-GFP upon transient transfection with GalNAcT-HA-RFP and by GFP-to-RFP FRET signals that are confined to the Golgi. FRET analysis also suggests that ST2-GFP binds tightly to pyrene-labeled GM3 but not to ST1. We hypothesize that an ST2-GM3 complex is associated with GalNAcT, resulting in the enhanced conversion of GM3 to GD3 and BCGs in the Golgi. Taken together, our results support the concept that ganglioside biosynthesis is tightly regulated by the formation of glycosyltransferase complexes in the ER and/or Golgi.     

Oligosialogangliosides inhibit GM2- and GD3-synthesis in isolated Golgi vesicles from rat liver

The effect of end-product gangliosides (GD1a, GT1b, GQ1b) on the activities of two key enzymes in ganglioside biosynthesis, namely GM2-synthase and GD3-synthase in rat liver Golgi apparatus, has been investigated in detergent-free as well as in detergent-containing assays. In detergent-free intact Golgi vesicles, phosphatidylglycerol was used as a stimulant. This phospholipid was earlier shown to stimulate the activity of GM2-synthase without disrupting the vesicular intactness; it has, however, no effect on GD3-synthase (Yusuf, H.K.M., Pohlentz, G., Schwarzmann, G. & Sandhoff, K. (1983) Eur. J. Biochem. 134, 47-54). In the presence of this stimulant, all higher gangliosides inhibited the activity of GM2-synthase, the inhibition being more profound with increasing negative charge of the inhibiting gangliosides. These inhibitions are unspecific, but they do not exclude an end-product regulation of ganglioside biosynthesis. In detergent-solubilized Golgi membranes, on the other hand, the inhibition pattern was completely different. Here, ganglioside GD1a was the strongest inhibitor of GM2-synthase, followed by GM1 and GM2, but GT1b also inhibited this enzyme appreciably, in fact more strongly than GM1 or GM2. On the other hand, GQ1b had no effect at all. Conversely, GD3-synthase activity was most strongly inhibited by GQ1b, followed by GT1b, but GD1a also inhibited this enzyme almost as strongly as GT1b. These latter findings indicate that feed-back control of the a- and the b-series pathways of ganglioside biosynthesis is probably not specific, but the pathways appear to be inhibited more preferably by their respective end-products than by any other gangliosides of the same of the other series.     

Purification and properties of GM2 synthase, UDP-N-acetylgalactosamine: GM3 beta-N-acetylgalactosaminyltransferase from rat liver

A UDP-N-acetylgalactosamine:ganglioside GM3 beta-N-acetylgalactosaminyltransferase which catalyzes the conversion of ganglioside GM3 to GM2 has been purified over 6300-fold from a Triton X-100 extract of rat liver particulate fractions by hydrophobic chromatography and affinity chromatography on GM3-acid-Sepharose. The purified enzyme has two identical subunits of 64,000 daltons. The enzyme has a pH optimum of pH 6.7-6.9 and requires divalent cations such as Mn2+ and Ni2+. In studies on substrate specificity GM3 containing N-acetylneuraminic acid (GM3(NeuAc] and GM3 containing N-glycolylneuraminic acid were both good acceptors for the purified enzyme. The plots of the activity of transferase as a function of GM3(NeuAc) showed sigmoidal relationships. The oligosaccharide of GM3, sialyllactose, was also a good acceptor, which indicates that the preferred acceptor substrate has the possible structure NeuAc alpha 2- or NeuGc alpha 2-3 Gal beta 1-4Glc-OR.     

Solubilization and stabilization of human liver glycoprotein sialyltransferase.

Triton X-100 is increasingly effective in solubilizing human liver glycoprotein (asialofetuin) sialytransferase (CMP-N-acetylneuraminate:D-galactosyl-glycoprotien N-acetylneuraminyltransferase, EC 2.4.99.1) activity as its concentration is increased in the homogenizing buffer. At the optimal concentration of 1.5% (v/v), essentially all of the homogenate sialyltransferase activity was solubilized into the supernatant fluid. Higher concentrations of Triton X-100 inhibited sialyltransferase activity. Several kinetic properties of the solubilized asialofetuin-sialyltransferase activity were compared to those of the membrane-bound enzyme(s) (in homogenates made without Triton X-100 or in resuspended pellets). No major difference was apparent, suggesting that solubilization has not significantly altered the properties of sialyltransferase. The solubilized sialyltransferase activity is quite unstable, losing approximately 50% of its activity after one week of storage at 4 degrees C. Various detergents (Zwittergent, sodium taurocholate and sodium deoxycholate) are differentially effective in stabilizing the solubilized activity. Sodium taurocholate (1.5%, w/v) was most effective with no loss in activity after 40 days and minimal loss (14%) after 60 days storage at 4 degrees C. The solubilized sialyltransferase preparation retains full activity after storage in the frozen state (-20 degrees C) for at least 159 days.     

Action of ortho- and paramyxovirus neuraminidase on gangliosides. Hydrolysis of ganglioside GM1 by Sendai virus neuraminidase

The action of neuraminidase of influenza A virus, Sendai virus and Newcastle disease virus particles on bovine brain ganglioside GM1 and the properties of Sendai virus neuraminidase for GM1 were studied. With Sendai virus, GM1 was hydrolyzed to asialo-GM1 (GA1) and N-acetylneuraminic acid even in the absence of surfactant or other additives, while the hydrolysis of GM1 by Newcastle disease virus or influenza A virus was very low or undetectable under the same conditions. The formation of GA1 by Sendai virus neuraminidase was confirmed by thin-layer chromatography and immunodiffusion test using anti-GA1 antiserum. The apparent Km of Sendai virus neuraminidase for GM1 hydrolysis was found to be 2.67 x 10(-4) M and the optimum pH was 5.6. GM3, GM2 and oligosaccharide of GM1 were hydrolyzed more effectively than GM1 in the absence of surfactant (GM3 greater than GM2 greater than oligosaccharide of GM1 greater than GM1). The hydrolysis of GM1 by the Sendai virus enzyme was stimulated by the addition of sodium cholate or sodium taurocholate, but was inhibited by divalent cations (10 mM), Ca2+, Mg2+, ZN2+, Fe2+ and CU2+. In the absence of the surfactant, Sendai virus neuraminidase hydrolyzed GM1 more efficiently than Arthobacter ureafaciens neuraminidase which has been reported recently as being an adequate enzyme to hydrolyze ganglioside GM1 as a substrate.