Glycoprotein synthesis in lysolecithin-treated cells using sugar nucleotides as glycosyl donors

The 3T3 cells were treated with 50 mu g/ml lysolecithin (LL) followed by the addition of exogenously supplied radiolabelled sugar nucleotides to serve as direct glycosyl donors. These were found to be 1.5 to 3.0 times more active than untreated cells in their glycosyl transferase activities depending on the particular sugar nucleotide used. Mannosyl transferase activity was not inhibited by 2-deoxyglucose or mannose-1-phosphate, indicating that the sugar nucleotide remained intact throughout the assay period. Preincubation of the cells with tunicamycin caused an 85% decrease in mannosyl transfer, which suggested that the normal pathway of glycosylation via lipid intermediates was still operable in the treated cells. Fractionation of control and LL-treated cells after incubation with UDP[3H]galactose revealed that only microsomal and cytosolic proteins from the treated cells were radioactive. Thus, intracellular labelling of permeabilized cells was allowed. About 80% of the radiolabeled product was glycoprotein in nature, based upon its solubilization with pronase.     

Nucleotides and related compounds in bracken

The role of sugar nucleotides in polysaccharide synthesis is discussed. The presence of acid soluble nucleotides in bracken rhizomes was demonstrated (20 μmol/kg fresh weight) and the uridine series was shown to predominate accounting for some 80% of the total. The following were identified, UDP-glucose (60%), UDP-galactose (15%), UDP-xylose (9%), UDP-arabinose (3%), UDP-glucuronic acid (4%), GDP-mannose (6%) and GDP-fucose (3%). It is probable that these sugar nucleotides supply the full complement of sugars identified in the carbohydrate fractions of bracken.     

Glycoprotein synthesis in lysolecithin-treated cells using sugar nucleotides as glycosyl donors

Summary The 3T3 cells were treated with 50 μg/ml lysolecithin (LL) followed by the addition of exogenously supplied radiolabelled sugar nucleotides to serve as direct glycosyl donors. These were found to be 1.5 to 3.0 times more active than untreated cells in their glycosyl transferase activities depending on the particular sugar nucleotide used. Mannosyl transferase activity was not inhibited by 2-deoxyglucose or mannose-1-phosphate, indicating that the sugar nucleotide remained intact throughouth the assay period. Preincubation of the cells with tunicamycin caused an 85% decrease in mannosyl transfer, which suggested that the normal pathway of glycosylation via lipid intermediates was still operable in the treated cells. Fractionation of control and LL-treated cells after incubation with UDP[³H]galactose revealed that only microsomal and cytosolic proteins from the treated cells were radioactive. Thus, intracellular labelling of permeabilized cells was allowed. About 80% of the radiolabeled product was glycoprotein in nature, based upon its solubilization with pronase. This work was supported by institutional funds granted by Texas Woman's University.     

Reconstitution into proteoliposomes and partial purification of the Golgi apparatus membrane UDP-galactose, UDP-xylose, and UDP-glucuronic acid transport activities.

Previous studies in vitro on proteoglycan biosynthesis from our laboratory have shown that nucleotide sugar precursors of all the sugars of the linkage oligosaccharides (xylose, galactose, and glucuronic acid) and of the glycosaminoglycans (N-acetylglucosamine, N-galactosamine, and glucuronic acid) are transported by specific carriers into the lumen of Golgi vesicles. More recently, we also reported the reconstitution in phosphatidylcholine liposomes of detergent-solubilized Golgi membrane proteins containing transport activities of CMP-sialic acid and adenosine-3'-phosphate-5'-phosphosulfate. We have now completed the successful reconstitution into liposomes of the Golgi membrane transport activities of UDP-galactose, UDP-xylose, and UDP-glucuronic acid. Transport of these nucleotide sugars into Golgi protein proteoliposomes occurred with the same affinity, temperature dependence, and sensitivity to inhibitors as observed with intact Golgi vesicles. Preloading of proteoliposomes with UMP, the putative antiporter for Golgi vesicle transport of these nucleotide sugars, stimulated transport of the nucleotide sugars by 2-3-fold. Transport of UDP-xylose into Golgi protein proteoliposomes was dependent on the presence of endogenous Golgi membrane lipids while that of UDP-galactose and UDP-glucuronic acid was not. This suggests a possible stabilizing or regulatory role for Golgi lipids on the UDP-xylose translocator. Finally, we have also shown that detergent-solubilized Golgi membrane translocator proteins can be partially purified by an ion-exchange chromatographic step before successful reconstitution into liposomes, demonstrating that this reconstitution approach can be used for the biochemical purification of these transporters.     

Transport of UDP-galactose in plants. Identification and functional characterization of AtUTr1, an Arabidopsis thaliana UDP-galactos/UDP-glucose transporter

The synthesis of non-cellulosic polysaccharides and glycoproteins in the plant cell Golgi apparatus requires UDP-galactose as substrate. The topology of these reactions is not known, although the orientation of a plant galactosyltransferase involved in the biosynthesis of galactomannans in fenugreek is consistent with a requirement for UDP-galactose in the lumen of the Golgi cisternae. Here we provide evidence that sealed, right-side-out Golgi vesicles isolated from pea stems transport UDP-galactose into their lumen and transfer galactose, likely to polysaccharides and other acceptors. In addition, we identified and cloned AtUTr1, a gene from Arabidopsis thaliana that encodes a multitransmembrane hydrophobic protein similar to nucleotide sugar transporters. Northern analysis showed that AtUTr1 is indeed expressed in Arabidopsis. AtUTr1 is able to complement the phenotype of MDCK ricin-resistant cells; a mammalian cell line deficient in transport of UDP-galactose into the Golgi. In vitro assays using a Golgi-enriched vesicle fraction obtained from Saccharomyces cerevisiae expressing AtUTr1-MycHis is able to transport UDP-galactose but also UDP-glucose. AtUTr1- MycHis does not transport GDP-mannose, GDP-fucose, CMP-sialic acid, UDP-glucuronic acid, or UDP-xylose when expressed in S. cerevisiae. AtUTr1 is the first transporter described that is able to transport UDP-galactose and UDP-glucose. Thus AtUTr1 may play an important role in the synthesis of glycoconjugates in Arabidopsis that contain galactose and glucose.     

Stimulation of deoxyribonucleic acid excision repair in human fibroblasts pretreated with sodium butyrate

The effect of pretreatment with sodium butyrate on DNA excision repair was studied in intact and permeable confluent (i.e., growth-inhibited) diploid human fibroblasts. Exposure to 20 mM sodium butyrate for 48 h increased subsequent ultraviolet (UV)-induced [methyl-3H]thymidine incorporation by intact AG1518 fibroblasts by 1.8-fold and by intact IMR-90 fibroblasts by 1.2-1.3-fold. UV-induced incorporation of deoxy[5-3H]cytidine, deoxy[6-3H]cytidine, and deoxy[6-3H]uridine, however, showed lesser degrees of either stimulation or inhibition in butyrate-pretreated cells. This result suggested that measurements of butyrate's effect on DNA repair synthesis in intact cells are confounded by simultaneous changes in nucleotide metabolism. The effect of butyrate on excision repair was also studied in permeable human fibroblasts in which excision repair is dependent on exogenous nucleotides. Butyrate pretreatment stimulated UV-induced repair synthesis by 1.3-1.7-fold in permeable AG1518 cells and by 1.5-2-fold in permeable IMR-90 cells. This stimulation of repair synthesis was not due to changes in repair patch size or composition or in the efficiency of DNA damage production but rather resulted from a butyrate-induced increase in the rate of damage-specific incision of DNA. The increased rate of incision in butyrate-pretreated cells could be due either to increased levels of enzymes mediating steps in excision repair at or before incision or to alterations in chromatin structure making damage sites in DNA more accessible to repair enzymes.     

Activation of chloride secretion in cystic fibrosis cells and tissues by the substituted imidazole SRI 2931

Recent interest in nucleotides and related agents as part of clinical trials in cystic fibrosis (CF) therapy have elicited efforts to identify novel compounds capable of activating transepithelial chloride (Cl(-)) transport in CF cells and tissues. From a library of nucleosides, bases, and other substituted heterocycles, 341 compounds were screened for their ability to activate anion transport in CF cells grown on permeable supports. One compound, SRI 2931, was found to confer prolonged and potent activity when administered to the apical surfaces of CF pancreatic epithelial cells, primary CF nasal epithelial cells, non-CF human colonic epithelial cells, and intact tissue taken from mouse models for CF. Concentrations of SRI 2931 (20 microM), which activated Cl(-) transport, had minimal effect on cell proliferation. SRI 2931 was not calcium (Ca(2+)) or cAMP dependent, suggesting important differences from conventional chloride secretagogues. The compound selectively released ATP from the apical, but not basolateral, surfaces of CF cells grown on permeable supports. The magnitude, longevity, and mechanism of action of the response provide a tool for dissecting pathways of epithelial ATP extracellular signaling and Cl(-) permeability.     

Excision repair of UV damage in human fibroblasts reversibly permeabilized by lysolecithin

We have examined nucleotide excision repair synthesis in confluent human diploid fibroblasts permeabilized with lysolecithin. Following a UV dose of 12 J/m2, maximal incorporation of [alpha 35S]dNTPs occurred at a lysolecithin concentration (approximately 80 micrograms/ml) where slightly more than 90% of the cells were initially permeable to trypan blue. However, autoradiography of cells, permeabilized at this lysolecithin concentration, demonstrated that only about 20% of the total cell population incorporated significant levels of 35S into DNA. This result presumably reflected the fact that approximately 20% of the total cell population remained permeable for much longer periods of time (up to 2 h) than the remaining cell population (less than 20 min). The incorporation of dNTPs by UV-irradiated, permeabilized cells appeared to be bona fide excision repair synthesis since: (1) Incorporation was completely absent in unirradiated, permeabilized cells and in irradiated, permeabilized repair-deficient cells. (2) Nucleotides incorporated in the presence of BrdUTP were associated with normal density DNA. (3) The apparent Km for all 4 dNTPs was 50-100 nM, in agreement with past reports on human fibroblasts irreversibly permeabilized by cell lysis. (4) DNA associated with the newly incorporated dNTPs underwent ligation and rearrangements in chromatin structure analogous to what is observed in intact human cells. Repair incorporation of dNTPs was rapid and linear during the first 2 h after UV irradiation and permeabilization. After this time, incorporation ceased or continued at a much slower rate. Cell viability experiments and autoradiography demonstrated that the cells permeabilized to [3H]dNTPs were capable of carrying out DNA replication and cell division. Thus, confluent human diploid fibroblasts can be reversibly permeabilized to labeled dNTPs by lysolecithin for the study of excision repair following physiologic doses of UV radiation. However, under these conditions, only a fraction of the cells remain permeable for an extended period of time.     

Purine metabolism abnormalities in a hyperuricosuric subclass of autism

A subclass of patients with classic infantile autism have uric acid excretion which is >2 S.D.s above the normal mean. These hyperuricosuric autistic individuals may comprise approx. 20% of the autistic population. In order to determine the metabolic basis for urate overexcretion in these patients, de novo purine synthesis was measured in the cultured skin fibroblasts of these patients by quantification of the radiolabeled purine compounds produced by incubation with radiolabeled sodium formate. For comparison, de novo purine synthesis in normal controls, in normouricosuric autistic patients, and cells from patients with other disorders in which excessive uric acid excretion is seen was also measured. These experiments showed that de novo purine synthesis is increased approx. 4-fold in the hyperuricosuric autistic patients. This increase was less than that found in other hyperuricosuric disorders. No unusual radiolabeled compounds (such as adenylosuccinate) were detected in these experiments, and no gross deficiencies of radiolabeled nucleotides were seen. However, the ratio of adenine to guanine nucleotides produced by de novo synthesis was found to be lower in the cells of the hyperuricosuric autistic patients than in the normal controls or the cells from patients with other disorders. These results indicate that the hyperuricosuric subclass of autistic patients have increased de novo purine synthesis, and that the increase is approximately that expected for the degree of urate overexcretion when compared to other hyperuricosuric disorders. No particular enzyme defect was suggested by either gross deficiency of a radiolabeled compound or the appearance of an unusual radiolabeled compound, and no potentially neurotoxic metabolites were seen. Although an enzyme defect responsible for the accelerated purine synthesis was not identified, the abnormal ratio of adenine to guanine nucleotides suggests a defect in purine nucleotide interconversion.     

Translocation of UDP-N-acetylglucosamine into vesicles derived from rat liver rough endoplasmic reticulum and Golgi apparatus

A mixture of UDP-N-acetylglucosamine labeled with different radioisotopes in the uridine and glucosamine was used to show that the intact sugar nucleotide was translocated across the membrane of vesicles derived from rat liver rough endoplasmic reticulum (RER) and Golgi apparatus. Translocation was dependent on temperature, saturable at high concentrations of sugar nucleotide, and inhibited by treatment of vesicles with proteases, suggesting protein carrier mediated transport. Translocation of UDP-GlcNAc by RER-derived vesicles appeared to be specific since these vesicles were unable to translocate UDP-galactose, in contrast to those derived from the Golgi apparatus. Preliminary results suggest that the mechanism of UDP-GlcNAc translocation into RER-derived vesicles is via a coupled exchange with lumenal nucleoside monophosphate. This is similar to the recently postulated mechanism for translocation of sugar nucleotides into vesicles derived from the Golgi apparatus.     

Enzymatic and chemical oxidation of gangliosides in cultured cells: effects of choleragen.

Cell surface glycolipids of normal human fibroblasts and NCTC2071 cells (transformed mouse fibroblasts) were labeled by incubating the intact cells with either galactose oxidase or sodium periodate, followed by reduction of the oxidized sugar residues with NaB3H4. In intact human fibroblasts, incorporation of 3H was increased with increasing time of exposure to galactose oxidase prior to treatment with NaB3H4. Following limited exposure to galactose oxidase, more label was incorporated into the larger glycolipids. Although labeling of the monosialoganglioside GM1 was maximal by 16 h, not all of the GM1 in the intact cells appeared to be accessible to galactose oxidase, since 10 to 12 times more GM1 was labeled when cells were disrupted before incubation with the enzyme. The human fibroblasts contained approximately 8 X 10(6) molecules of GM1 per cell. Maximal binding of choleragen (5 X 10(5) molecules of [125I]choleragen per cell) completely prevented cholevented oxidation of GM1 in intact fibroblasts by galactose oxidase but only partially protected the sialic acid moiety of GM1 from oxidation by periodate. Choleragen had little effect on the enzymatic or chemical oxidation of other glycolipids. NCTC 2071 cells do not contain endogenous GM1 but incorporate exogenous GM1 from the culture medium. When bound to NCTC 2071 cells, exogenous GM1 was protected by choleragen from oxidation by galactose oxidase or whether endogenous or taken up from the incubation medium, are, after interaction with choleragen, less accessible to oxidation by periodate or galactose oxidase.     

Replicative DNA synthesis in permeable fibroblasts from normal individuals and ataxia-telangiectasia patients

Replicative DNA synthesis in normal human fibroblasts was inhibited by 50% when they were X-irradiated (8 Gy) and made permeable 30 min later, whereas only a slight inhibition (20%) was observed in similarly treated ataxia-telangiectasia cells. Treatment of irradiated normal cells with caffeine (2 mM) before permeabilization reversed the inhibitory effects of X-rays, buf caffeine had no effect on DNA synthesis in permeable ataxia-telangiectasia cells. Diadenosine tetraphosphate (0.1 mM) did not affect DNA synthesis in permeable normal fibroblasts.     

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.     

In vivo administration of low-dose human interleukin-2 induces lymphokine-activated killer cells for enhanced cytolysis in vitro

We have examined the effect of the intradermal administration of IL-2 on the generation of natural killer (NK) cell and lymphokine-activated killer (LAK) cell activity. Peripheral blood mononuclear cells (PBMC) obtained from borderline lepromatous (BL) and lepromatous leprosy (LL) patients and normal volunteers prior to and after IL-2 injection were stimulated in vitro with IL-2 and their cytolytic activities compared against 51Cr labeled target K562 cells, Daudi cells, and monocytes. Before IL-2 administration, PBMC obtained from BL/LL patients and normal volunteers possessed similar levels of NK cell activity indicating that the NK cell activity of the BL/LL patients was intact. LAK cell activity was induced with IL-2 in vitro in both BL/LL patients and in normal volunteers. The level of LAK cell activity in BL/LL patients was, however, suboptimal. A single intradermal dose of 25 micrograms IL-2 had no effect on the phenotype of circulating mononuclear cells in either patients or normal volunteers. However, 6-12 days after IL-2 injection and subsequent restimulation of the PBMC with IL-2 in vitro, cytolytic activity of LAK cells obtained from the BL/LL patients was enhanced while cells from normal volunteers expressed the same high levels of activity as observed before IL-2 injection.     

Zymosterol is located in the plasma membrane of cultured human fibroblasts

Zymosterol (5 alpha-cholesta-8(9),24-dien-3 beta-ol) comprised a negligible fraction of the mass of sterol in cultured human fibroblasts but was well labeled biosynthetically with radioactive acetate. Treatment of cells with triparanol, a potent inhibitor of sterol delta 24-reductase, led to a marked increase in labeled zymosterol while its mass rose to 1 mol% of total sterol. All of this sterol could be chased into cholesterol. Furthermore, cell homogenates converted exogenous radiolabeled zymosterol to cholesterol. Three lines of evidence suggested that biosynthetically labeled zymosterol was associated with the plasma membrane. 1) About 80% of radiolabeled zymosterol was oxidized by the impermeant enzyme, cholesterol oxidase, in glutaraldehyde-fixed intact cells. 2) Sucrose density gradient analysis of homogenates showed that the equilibrium buoyant density profile of newly synthesized zymosterol was identical with that of the plasma membrane. 3) Newly synthesized zymosterol was transferred as readily from fixed intact fibroblasts to exogenous acceptors as was cholesterol. Given that cholesterol is synthesized within the cell, it is unclear why most of the zymosterol is in the plasma membrane. The pathway of cholesterol biosynthesis may compel zymosterol to flux through the plasma membrane. Alternatively, plasma membrane zymosterol may represent a separate pool, in equilibrium with the zymosterol in the intracellular biosynthetic pool.     

Phosphohydrolases on the cell surface of BHK cells: loss during long term culture.

Low passage BHK 21/13 cells contain two cell surface enzymes, a nucleotide pyrophosphatase and a monophosphoester hydrolase, which together hydrolyze exogenous UDP-galactose to free galactose. During serial passage, BHK cells successively lose both enzymes. Concomitant with the loss of these enzymatic activities, changes in cell morphology, as well as in the serum requirement for the initiation of DNA synthesis, were observed. Clonal sublines of BHK cells were isolated, which differed qualitatively in their ability to hydrolyze UDP-galactose. Clonal BHK sublines, which exhibited both enzymatic activities on their cell surface, resembled low passage BHK cells in morphology and serum requirement for the initiation of DNA synthesis. Sublines not containing these enzymes resembled BHK cells of high passage cultures. The ability of intact BHK cells to hydrolyze exogenous nucleotide sugars may serve as an indicator for the progression of BHK cells from a normal to a more transformed state.     

Ectogalactosyltransferase studies in fibroblasts and concanavalin A- stimulated lymphocytes

In this communication, we have demonstrated that hydrolysis of the nucleotide sugar can cause errors in the detection of an ectoglycosyltransferase. Spleen cell suspensions can incorporate radioactivity when incubated with labeled UDP-galactose, but all the activity is due to decomposition of the nucleotide sugar and uptake of the free sugar. The fibroblast cell lines can incroporate carbohydrate directly from UDP-galactose. Several criteria are presented with can be used to demonstrate that a nucleotide sugar is the direct carbohydrate donor.     

Ecto-protein kinase activity of fibroblasts.

Isolated, intact dermal fibroblasts can transfer the terminal phosphate of adenosine triphosphate, [γ-³²P]ATP, to an exogenously added macromolecule (histone). The incorporation of labeled phosphate to histone is attributed to an extracellularly directed protein kinase activity (ecto-kinase) which cannot be accounted for by soluble cytoplasmic protein kinase that might have been released and become bound to cell membranes during the cell preparation. The addition of soluble cytoplasmic enzyme preparations to the cell suspension was fully recoverable in the supernatant and the first wash. The activity of ectokinase was abolished by incubation of intact cells with trypsin for 5 min, whereas the activity of cytoplasmic enzyme was unaffected by the trypsin treatment. These data suggest that dermal fibroblasts contain protein kinase on the outer surface of plasma membrane which can phosphorylate exogenously added macromolecules. The ecto-protein kinase activity is dependent on cell number, time of incubation, and the concentration of Mg²⁺ in the reaction mixture. Lineweaver-Burk plot analyses yielded K_m values for ATP and histone of 7 × 10^?5 and 3 × 10^?6m, respectively. The ecto-protein kinase activity of normal fibroblasts and fibrosarcoma cells were also compared. The enzyme activity of normal cells was higher than that of the malignant cells and was not significantly affected by cyclic nucleotides, whereas the activity of the malignant cells were stimulated by the addition of micromolar concentrations of the cyclic nucleotides.     

Glutathione specifically labeled with isotopes

A procedure for synthesis of glutathione selectivity labeled with isotopes is described. A strain of Escherichia coli enriched in its content of gamma-glutamylcysteine synthetase and glutathione synthetase by recombinant DNA techniques is immobilized in a carrageenan matrix and treated with toluene to render the cells more permeable to the substrates. The immobilized cell matrix is incubated with a mixture containing the appropriately labeled amino acid, the other amino acid constituents of glutathione, ATP, and acetylphosphate. The radiolabeled product is isolated by column chromatography.