Membrane glycoprotein biosynthesis: Changes in levels of glycosyl transferases in fibroblasts transformed by oncogenic viruses

Fibroblasts transformed by oncogenic viruses were found to have greater enzymic activities of four membrane glycoprotein:glycosyl transferases on a cell or protein basis then two non-transformed fibroblastic lines. These enzymes are responsible for the synthesis of membrane glycoproteins; each of the four transferases studied, the polypeptide:N-acetylgalactosaminyl, glycoprotein:galactosyl, fetuin:fucosyl and PSM:fucosyl transferases, was more than twice as active in the transformed cell lines using both endogenous and added receptor. The most pronounced differences occurred with the doubly (SV-PY-3T3) transformed fibroblasts in all cases; with the N-acetylgalactosaminyl and galactosyl transferases the increase was 8–16 fold over the non-transformed cells. It was demonstrated that these results do not arise from a changed level of glycosidase activities.     

Platelet adhesiveness and aggregation: the collagen:glycosyl, polypeptide:N-acetylgalactosaminyl and glycoprotein:galactosyl transferases of human platelets

Four glycoprotein:glycosyl transferases were identified, purified, and characterized from human platelets. The enzymes present were collagen:glc, collagen:gal, polypeptide:galNAc, and glycoprotein:gal; the fetuin:glcNAc transferase was absent. Each of the 4 transferases was found to be almost exclusively bound to the platelet plasma membrane. Incubation of platelet homogenates without exogenous acceptors yielded no transfer of monosaccharide, indicating the complete lack of endogenous acceptors. These results lead to the interesting speculation that the transferases may not be responsible in the mature platelet for glycoprotein synthesis at all, but rather that they may function for intercellular adhesion and the primary step in hemostasis, the adhesion of collagen to platelets.     

SYNTHESIS OF GLYCOPROTEINS IN BRAIN: IDENTIFICATION, PURIFICATION AND PROPERTIES OF GLYCOSYL TRANSFERASES FROM PURIFIED SYNAPTOSOMES OF GUINEA PIG CEREBRAL CORTEX

Abstract— Four glycoprotein:glycosyl transferases (a fetuin:N-acetylglucosaminyl transferase; a bovine submaxillary mucin: N-acetylgalactosaminyl transferase; a collagen: glucosyl transferase and an orosomucoid: galactosyl transferase) were purified 34-, 45-, 37- and 47-fold, respectively, from synaptosomes prepared from guinea pig cerebral cortex. Purifications were achieved by centrifugation and by column chromatography on Sephadex G-100 and G-150 of 0 , 1% (w/v) Triton X-100 extractsof the purified cerebral cortical synaptosomes. The enzymes were separated from endogenous acceptors and were highly specific for specific macromolecular acceptors; small molecules were ineffective as acceptors. The fetuin: N-acetylglucosaminyl transferase functioned only with fetuin minus N-acetylneuraminic acid, galactose and N-acetylglucosamine; the bovine submaxillary mucin: N- acetylgalactosaminyl transferase with bovine submaxillary much minus N-acetylneuraminic acid and N-acetylgalactosamine; the collagen: glucosyl transferase with collagen minus glucose; and the orosomucoid: galactosyl transferase with either orosomucoid minus N-acetylneuraminic acid and galactose or fetuin minus N-acetylneuraminic acid and galactose. Each transferase required a specific (XDP)-monosaccharide for transfer. The transferases were entirely dependent on either Mn²⁺ or Mg²⁺ for activation and Fe²⁺ and Hg²⁺ inhibited each of the four enzymes. The optimum pH's for the enzymes were: for fetuin: N-acetylglucosaminyl transferase, 7 , 4–8.0; for bovine submaxillary mucin: N-acetylgalactosaminyl transferase, 7 , 7; for collagen: glucosyl transferase, 7 , 7 and for orosomucoid: galactosyl transferase, 6 , 6. The enzymes were distributed subsynaptosomally primarily in the synaptosomal plasma membrane and in the mitochondria of the synaptosome. The respective values for K_m (μM) and V_mex (pmoles/h/mg of protein) for the transferases were: fetuin: N-acetylglucosaminyl transferase, 12 and 143; for bovine submaxillary mucin: N-acetylgalactosaminyl transferase, 25 and 166; for collagen: glucosyl transferase, 4 and 10 and for orosomucoid:galactosyl transferase, 8 and 111.     

GLYCOSYL TRANSFERASE ACTIVITY IN NORMAL AND SCRAPIE-AFFECTED MOUSE BRAIN

—The conditions required for the optimal activity of several glycosyl transferases were determined in normal and scrapie-affected mouse brain. Particulate preparations were analysed for fucosyl, galactosyl, mannosyl and N-acetyl glucosaminyl transferase activity using endogenous acceptors. Solubilized preparations were analysed for fucosyl, galactosyl and sialyl transferase activity using defined exogenous acceptors. The activity of each of these enzymes was followed at intervals throughout the development of scrapie in the mouse. In the endogenous system no change was found in the fucosyl and mannosyl transferase activities of the scrapie material, but the levels of galactosyl and N-acetyl glucosaminyl transferase began to rise as clinical signs of scrapie developed i.e. at 15–16 weeks post-inoculation. In the exogenous system the levels of galactosyl and fucosyl transferase began to rise in the scrapie material at 11–12 weeks post-inoculation, rising to twice the normal value at 18–20 weeks. Sialyl transferase showed no change in activity.     

Synergistic cytolytic activity by combined populations of peritoneal T lymphocytes and macrophages during the L5178Y cell tumor-dormant state in DBA/2 mice

It was previously reported that the establishment of the L5178Y cell tumor-dormant state in DBA/2 mice is mediated principally by a peritoneal cytolytic T-cell response that reaches peak levels 4 days after L5178Y cell challenge, lyses more than 99% but less than 100% of peritoneal L5178Y cells, and gradually wanes to background levels by 40–70 days postchallenge (DPC). At this time the majority of mice are clinically normal, and contain a relatively small number of L5178Y cells in the peritoneal cavity. During the tumor-dormant state, mice that harbor more than 10⁴ L5178Y cells contain peritoneal macrophage-mediated cytolytic activity. We report here that tumor-dormant mice that contain fewer than 10⁴ peritoneal L5178Y cells also produce cytolytic activity in vitro, but that it is synergistic, in that the cytolytic activity of adherent (AD) peritoneal cells (PEC) and nonadherent (NAD) PEC cultured together is greater than the additive lysis produced by these cell populations when cultured separately. This synergistic cytolytic activity is: (1) effector cell density dependent, (2) dependent on the tumor-dormant status of the NAD and AD PEC donor mice, (3) protracted in its kinetics during a 48-hr in vitro assay, and (4) dependent on an interaction between NAD T cells and AD phagocytic macrophages. The consistent detection of this in vitro-assayed cytolytic activity in PEC of tumor-dormant mice which harbor small endogenous tumor burdens suggests that it reflects an in vivo cytotoxic effector mechanism involved in the long-term maintenance of the tumor-dormant state.     

Glycoprotein biosynthesis: Folic acid effects on glycoprotein:glycosyl transferase activities of rat kidney and liver

Folic acid at 14 μM to 1.4 mM increased the activity of the collagen:glc and fetuin:gal and decreased the activity of the fetuin:NANA glycoprotein:glycosyl transferases of rat liver and kidney in vitro; highest effects were found with 1.4 mM folic acid. 1.4 mM folic acid increased kidney fetuin:gal activity 5-fold and decreased fetuin:NANA activity 3-fold. At 1.4 mM, folinic acid and p-methylaminobenzoic acid were totally inactive toward the transferases, methasquin was moderately active, and homofolic, tetrahydrohomofolic and methotrexate were very active toward the transferases. In all instances, however, the fetuin:gal and collagen:glc transferases were activated while the fetuin: NANA transferase was inhibited. From the data presented, folic acid is viewed as a possible control molecule in the synthesis of glycoprotein.     

Biosynthesis of polyuronides inMucor rouxii: Partial characterization of fucosyl transferase

Most of the fucosyl transferase activity fromMucor rouxii was detected in a crude membrane fraction. The enzyme transferredl-fucose from GDP-fucose to endogenous and exogenous acceptors. When crude membrane fractions were treated with neutral detergents such as Trition X-100 or Brij 36 T enzyme activity became dependent on exogenous acceptors such as mucoric acid or mucoran. Brij-treated membrane fractions showed maximum fucosyl transferase activity at pH 6.5, and at a temperature between 22 and 28°C. The cations Mn²⁺, Mg²⁺, Co²⁺, Zn²⁺, Fe²⁺, and Ca²⁺ activated the enzyme about twofold. The former was slightly more stimulatory at 4 mM. Km for GDP-fucose was 10 μM. Evidence was obtained that mucoric acid serves as acceptor for fucosyl moieties. Acid hydrolysis of the product synthesized from GDP-fuc by Brij-treated membrane fractions revealed fucose as the major radioactive sugar.     

Sialyltransferase activity in regenerating rat liver

Liver microsomal fractions catalyse the transfer of sialic acid from CMP-N-acetyl-neuraminic acid to various exogenous acceptors such as desialylated fetuin, desialylated human Tamm–Horsfall glycoprotein and desialylated bovine submaxillary-gland mucin. An increase in the rate of incorporation of sialic acid into desialylated glycoproteins was found after a lag period (7h) in regenerating liver. The increase was maximum 24h after partial hepatectomy for all acceptors tested. At later times after operation the sialyltransferase activity remained high only for desialylated fetuin. No soluble factors from liver or serum of partially hepatectomized animals influenced the activity of the sialyltransferases bound to the microsomal fraction. The sensitivity of sialyltransferases to activation by Triton X-100, added to the incubation medium, was unchanged in the microsomal preparation from animals 24h after sham operation or partial hepatectomy. The full activity of sialyltransferases towards the various desialylated acceptors showed some differences. Human Tamm–Horsfall glycoprotein was a good acceptor of sialic acid only when desialylated by mild acid hydrolysis. After this treatment, but not after enzymic hydrolysis, a decrease in molecular weight of human Tamm–Horsfall glycoprotein was observed. Further, the sialyltransferase activity as a function of incubation temperature gave different curves according to the acceptor used. The relationship between the biosynthesis of glycoproteins by regenerating liver and the sialyltransferase activity of microsomal fraction after partial hepatectomy is discussed.     

PARTICULATE AND SOLUBILIZED FUCOSYL TRANSFERASES FROM MOUSE BRAIN

The transfer of [¹⁴C]fucose from GDP-[U-¹⁴C]fucose to endogenous and exogenous acceptors by particulate and solubilized preparations from mouse brain is described. Suspensions of brain microsomes incorporated [¹⁴C]fucose into a heterogenous group of glycoprotein products, which have a distribution on gel electrophoresis similar to those synthesized in vivo. Fucosyl transferase, extracted from brain microsomes by Triton X-100, transferred [¹⁴C]fucose from GDP-[U-¹⁴C]fucose to terminal galactose residues exposed by mild acid hydrolysis of porcine plasma glycoprotein. Comparison of the specific activities of the solubilized fucosyl transferase from a number of organs showed that, in the presence of the exogenous acceptor which was used, the transferase of brain was more active than the transferases from all other organs tested, with the exception of kidney. Examination of subcellular fractions of brain, with endogenous and exogenous acceptors, showed that activity was limited to fractions containing microsomal membranes, whereas synaptosomal and other fractions were virtually inactive.     

Glycosyl transferases of baby-hamster-kidney (BHK) cells and ricin-resistant mutants. N-glycan biosynthesis

Five cell lines of ricin-resistant BHK cells have been assayed for gross carbohydrate analysis of cellular glycoproteins, for the activities of several glycosidases and of specific glycosyl transferases active in assembly of N-glycans of glycoproteins. The latter enzymes include sialyl transferase using asialofetuin as glycosyl acceptor, fucosyl transferases using asialofetuin and asialoagalactofetuin acceptors, galactosyl transferases using ovalbumin, ovomucoid and N-acetylglucosamine as acceptors and N-acetylglucosaminyl transferases using ovalbumin and glycopeptides as acceptors. Cell line RicR14, binding less ricin than normal BHK cells, contains reduced amounts of sialic acid, galactose and N-acetylglucosamine in cellular glycoproteins and lacks almost completely N-acetylglucosamine transferase I, an essential enzyme in assembly of ricin-binding carbohydrate sequences of N-glycans. These cells also contain reduced levels of N-acetylglucosamine transferase II active on a product of N-acetylglucosamine transferase I action. Sialyl transferase activity is severely depressed while fucose-(alpha 1 leads to 6)-N-acetylglucosamine fucosyl transferase activity is increased. Cell lines RicR15, 17, 19 and 21 showed partial deficiencies in galactosyl and N-acetylglucosaminyl transferases. A hypothesis is put forward to account for the different carbohydrate compositions and ricin binding properties of glycoproteins synthesised by these cells in terms of the determined enzyme defects, the normal level of sialyl transferases detected in RicR15 and RicR21 cells and the elevated levels of sialyl and fucosyl transferases detected in RicR17 and 19 cells. None of the above changes in glycosyl transfer reactions in the RicR cell lines are due to enhanced glycosidase or sugar nucleotidase activities in the mutant cells.     

UDP-N-acetylglucosamine-glycoproteinN-acetylglucosaminyltransferase in regenerating rat liver

The assay condition for N-acetylglucosaminyltransferase activities in rat liver microsomal fraction was developed. The enzyme activities towards endogenous acceptors within 48 h after partial hepatectomy were lower than in controls, exceeding the control level by 96 h, and then higher than in controls up to 240 h after the operation. The changes in N-acetylglucosaminyltransferase activities towards exogenous acceptor (UPD-2-acetamido-2-deoxy-D-glucose: glycoprotein 2-acetamido-2-deoxy-D-glucosyltransferase, EC 2.4.1.51) were consistent with those in the enzyme activities towards endogenous acceptors at 144 h, but not at 48 h, after the operation. The contents of protein and the levels of protein-bound hexosamine in the liver microsomes were decreased at early period of liver regeneration.These results suggest that the acceptor capacity of liver microsomal proteins is diminished during first 48 h of the regeneration. This may be responsible for the decreased transfer of the amino sugar to nascent glycoproteins. However, the enzyme activity was enhanced at 144 h and the level of endogenous acceptors may increase.     

Glycoprotein biosynthesis in the developing rat brain IV. Effects of guanosine nucleotides on soluble glycoprotein galactosyl- and N-acetylgalactosaminyltransferases

The effects of GTP on soluble cerebral glycoprotein galactosyl- and N-acetylgalactosaminyltransferases were studied. The transfer of galactose from UDP-galactose to both endogenous and exogenous acceptors was stimulated by GTP while the transfer of N-acetylgalactosamine to endogenous and defined exogenous acceptors was inhibited by the nucleotide. Similar results were obtained with β,γ-methylene GTP, a structural analog of GTP. Evidence is presented which suggests that GTP is as an allosteric modulator of these two glycosyltransferases.     

Modification of Sindbis Virus Glycoprotein by Host-Specified Glycosyl Transferases

The amino acid sequence of the membrane glycoprotein of Sindbis virus is specified by the viral genome, but it has not been determined whether the carbohydrate portion of this molecule is specified by the cell or by the virus. We have examined two of the enzyme activities which catalyze transfer of monosaccharides to glycoprotein (sialyl and fucosyl transferases). Comparison of particulate enzyme preparations from infected and uninfected cells showed no difference in either the specific activity or acceptor specificity of these enzymes. This is impressive in view of the fact that the Sindbis membrane glycoprotein is the only glycoprotein synthesized in the infected cell. It was also determined that sialyl transferase from uninfected cells is capable of transferring ((3)H) sialic acid to acceptor prepared from Sindbis membrane glycoprotein. These results imply that at least some of the carbohydrate of the virus glycoprotein can arise by host modification.     

Translocation of cytidine 5′-monophosphosialic acid across golgi apparatus membranes

Golgi apparatus, isolated from rat liver, incorporate [¹⁴C]sialic acid from CMP[¹⁴C]sialic acid into endogenous glycolipid and glycoprotein acceptors. Incorporation of [¹⁴C]sialic acid into endogenous glycoprotein acceptors was stimulated an average of 3-fold by Triton X-100 at an optimal concentration of 0.05% and was inhibited at higher concentrations. Incorporation of [¹⁴C]sialic acid into endogenous glycolipid acceptors was not stimulated by detergent. The major glycolipid product was identified by thin-layer chromatography as the ganglioside G_d3. SDS-polyacrylamide gel electrophoresis of the glycoprotein products demonstrated incorporation of [¹⁴C]sialic acid into 6–7 major bands. Neuraminidase studies determined that approximately 60% of the [¹⁴C]sialic acid incorporated into endogenous acceptors in the absence of detergent had a luminal orientation. Furthermore, electron microscopy studies showed that the isolated Golgi apparatus fraction consisted of intact membrane cisternae. Our results demonstrate that sialylation of cisternal acceptors located on the inside of the membrane occurs in the absence of detergent. They are consistent with carrier-mediated transport as a mechanism to allow CMPsialic acid to traverse the Golgi apparatus membrane and to be used to glycosylate endogenous glycoprotein and glycolipid acceptors.     

Hamster hepatocyte-mediated activation of procarcinogens to mutagens in the L5178Y/TK mutation assay

Eight procarcinogens including three nitrosamines, three polycyclic hydrocarbons, and two aromatic amines were tested for mutagenic potential at the thymidine kinase (TK) locus in L5178Y mouse lymphoma cells co-cultivated with viable hamster hepatocytes. All eight chemicals produced substantial mutagenic activity as indicated by increased trifluorothymidine resistance in L5178Y cells treated in the presence of hepatocytes. Mutagenic responses to benzo[a]pyrene, 3-methyl-cholanthrene, N-nitrosodiethylamine, and N-nitrosodipropylamine first increased, then plateaued within the range of mutagen concentrations tested, while consistent dose-dependent increases in mutant frequencies were observed following 2-aminoanthracene, 2-aminofluorene, or N-nitrosodimethylamine treatments. The relatively flat portions of the mutant frequency curves for benzo[a]pyrene and 3-methylcholanthrene coincided with maximum chemical solubility as obvious from visible or microscopically detectable precipitate. These hamster cells readily facilitated the metabolism of 1,2-benzanthracene to a detectable mutagen and were especially competent in the activation of the two aromatic amines. Thus, cultured hamster hepatocytes can activate a variety of chemical carcinogens including polycyclic hydrocarbons to mutagens in a whole cell-mediated in vitro assay using L5178Y/TK^+/? cells as the target organism.     

Glycosyltransferases with endogenous acceptor activity in plasma membranes isolated from rat liver

Plasma membrane fractions from rat liver exhibited glycosyltransferase activity with endogenous membrane-associated acceptors and either UDP-galactose, UDPglucose, UDP-N-acetylglucosamine, or GDPmannose donors. Of these, incorporation into non-lipid acceptors was most active with UDP-galactose and only with UDPgalactose and UDPmannose was there incorporation into endogenous lipid acceptors. CMP-N-acetylneuraminic acid was inactive as a donor with the isolated plasma membranes. In order to demonstrate transferase activity, low concentrations of substrate sugar nucleotides and short incubation times were used as well as sulfhydryl protectants and a phosphatase inhibitor (NaF) in the reaction mixtures. The findings support the concept of surface localization of at least a galactosyl transferase in cells of rat liver.     

Different contributions of the indirect effects of γ-rays on the cytotoxicity in M10 and XRCC4 transfected M10 cells

The protective effects of dimethyl sulfoxide (DMSO) against cell killing by ¹³⁷Cs γ-rays were investigated in XRCC4-deficient cell line M10, XRCC4-complemented M10 and the parental mouse leukemia cell line L5178Y. Cell survival was determined by the colony-forming ability. M10 cells were more sensitive to γ-ray-induced cell death than L5178Y and complemented M10 cells. Cell survival was increased in both M10 and L5178Y in the presence of DMSO. However, estimation of the DMSO-protectable fraction revealed a smaller protectable fraction for M10 cells than for L5178Y cells, indicating that indirect effects contributed in a smaller extent to the cytotoxicity in M10 than that in L5178Y. This effect is due to XRCC4 deficiency, since transfection of XRCC4 cDNA into M10 cells restored the radioprotective effects of DMSO to the level seen in L5178Y. In M10 cells, the killing effects of high LET radiation (Auger electrons from ¹²⁵I-antipyrine, carbon ions with an LET of 166 keV μm⁻¹) were similar to those of low LET radiation (¹³⁷Cs γ-rays, characteristic X-rays from ¹²⁵I-bovine serum albumin). We discuss that lethal lesions produced by indirect actions in L5178Y and XRCC4-complemented M10 cells may differ, at least in part, from DNA double-strand breaks repairable by non-homologous end joining.     

Redox activity at the surface of oat root cells

Electron transport activity at the cell surface of intact oat seedlings (Avena sativa L. cv Garry) was examined by measuring the oxidation and/or reduction of agents in the medium bathing the roots. Oxidation of NADH with or without added electron acceptors and reduction of ferricyanide by an endogenous electron donor were detected. The activities appear to be due to electron transfer at, or across, the plasma membrane and not due to reagent uptake or leakage of oxidants or reductants. NADH-ferricyanide oxidoreductase activity was also detected in plasma membrane-enriched preparations from Avena roots. Based on redox responses to pH, various ions, and to a variety of electron donors and acceptors, the results indicate that more than one electron transport system is present at the plasma membrane.     

Intracellular localization of GDP-l-fucose: Glycoprotein and CMP-sialic acid: Apolipoprotein glycosyltransferases in rat and pork livers

A GDP-l-fucose:glycoprotein fucosyltransferase which transfers l-fucose to terminal β-N-acetyl-d-glucosaminyl residues of sialidase-, β-galactosidase-treated α₁-acid glycoprotein and a CMP-sialic acid:glycoprotein sialyltransferase acting on sialidase-treated apolipoprotein-Ala₁ from human very low density lipoprotein have been shown to be concentrated in rat liver Golgi apparatus preparations at enrichments of 40- and 45-fold, respectively, and in pork liver Golgi-rich fractions at enrichments of 35- and 20-fold, respectively. A second fucosyltransferase acting on sialidase-treated α₁-acid glycopretein was absent from rat liver and was enriched only 13-fold in a pork liver Golgi-rich fraction. The smooth-surfaced microsome fraction was the only other rat liver subcellular fraction with appreciable levels of the GDP-l-fucose: β-N-acetyl-d-glucosaminide fucosyltransferase and the lipoprotein sialyltransferase (enrichments of 2.6- and 5.2-fold, respectivley). This enrichment could not be attributed to the plasma membrane content of the smooth microsome fraction since plasma membrane fractions from rat liver were shown to have relatively low concentrations of these two transferases (enrichments of 0.3 or less). Rat liver plasma membrane was also shown to have similarly low relative specific activities for three other glycosyltransferases (sialyl-, galactosyl-, and N-acetylglucosaminyl-). The accurate determination of the glycosyltransferase activities of the plasma membrane fraction required the use of relatively low concentrations of plasma membrane and relatively high concentrations of nucleotide-sugars in order to avoid interference by the high nucleotide-sugar pyrophosphatase and hydrolase activities of this fraction.