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.     

Novel genomic locus with atypical G+C content that is required for extracellular polysaccharide production and virulence in Xanthomonas oryzae pv. oryzae.

Three exopolysaccharide (EPS)- and virulence-deficient mutants of Xanthomonas oryzae pv. oryzae, the causal agent of bacterial leaf blight of rice, were isolated by Tn5 mutagenesis. These insertions are not located within the gum gene cluster. A 40-kb cosmid clone that restored EPS production and virulence to all three mutants was isolated, and the three transposon insertions were localized to contiguous 4.3- and 3.5-kb EcoRI fragments that are included in this clone. Sequence data indicate that two of the transposon insertions are in genes that encode a putative sugar nucleotide epimerase and a putative glycosyl transferase, respectively; the third insertion is located between the glycosyl transferase gene and a novel open reading frame (ORF). A 5.5-kb genomic region in which these three ORFs are located has a G+C content of 5-1.7%, quite different from the G+C content of approximately 65.0% that is typical of X. oryzae pv. oryzae. Homologues of this locus have not yet been reported in any other xanthomonad.     

Subcellular Localization of Glycosyl Transferases Involved in Glycoprotein Biosynthesis in the Cotyledons of Pisum sativum L

Subcellular membrane fractions from 21-day-old pea (Pisum sativum) cotyledons that have associated UDP-N-acetylglucosamine N-acetylglucosaminyl transferase and GDP-mannose mannosyl transferase activities have been isolated and identified. The rough endoplasmic reticulum (RER) is the principal location of glycosyl transferases involved in the assembly of lipid-linked sugar intermediates and glycoproteins. Antimycin A-insensitive NADH-cytochrome c reductase activity was used to identify RER at a density of 1.165 g/cc in sucrose gradients. The high proportion of RER in this fraction was confirmed by electron microscopy.

Other mannosyl transferases are found at a density of 1.123 g/cc and 1.201 g/cc but these glycosyl transferases do not appear to be involved with the formation of lipid-linked sugar intermediates utilized in glycoprotein biosynthesis.

     

Biochemical and ultrastructural studies of ectoglycosyltransferase systems of murine L1210 leukemic cells

Intact murine L1210 leukemic cells incorporated significant quantities of [³H]-N-acetylneuraminic acid directly from CMP-N-acetylneuraminic acid. When pretreated with Vibrio cholerae neuraminidase, incorporation increased sixfold to tenfold. Biochemical studies comparing incorporation of N-acetyl-neuraminic acid from the nucleotide sugar with that from free sugar demonstrated that the relatively high levels of incorporation from CMP-N-acetyl-neuraminic acid could not be due to the incorporation of free sugar generated by extracellular degradation of the nucleotide sugar. Very little N-acetylneuraminic acid was taken up or incorporated by L 1210 cells from free sugar and this incorporation was not increased by neuraminidase pretreatment. Moreover, extracellular breakdown of CMP-N-acetylneuraminic acid during incubations with L 1210 cells was rather insignificant. Electron microscope autoradiography of cells incubated with CMP-N-acetylneuraminic acid demonstrated that greater than 84% of the incorporated radioactivity was associated with the plasma membrane and less than 1% with the Golgi apparatus. These findings are consistent with the conclusion that incroporation of N-acetylneuraminic acid from CMP-N-acetylneuraminic acid is the consequence of a cell surface sialytransferase system. Pretreatment of cells with the nonpenetrating reagent, diazonium salt of sulfonilic acid, significantly inhibited this ectoenzyme system while only marginally affecting galactose uptake and incorporation at the Golgi apparatus. Interestingly, incorporation from CMP-N-acetylneuraminic acid declined as the viability of the cell population declined. When taken together, the above evidence develops a rigorous argument for the presence of a sialyltransferase enzyme system at the cell surface of L 1210 cells. Studies directed towards the detection of a similar ectogalactosyltransferase system were also undertaken. Cells incubated in the presence of UDP-[³H]-galactose incorporated radioactivity into a macromolecular fraction. The presence of excess unlabeled galactose in the incubation medium significantly reduced this incorporation. Electron microscope autoradiographs of cells incubated with UDP-[³H]-galactose, demonstrated that incorporation occurred primarily at the Golgi apparatus. The grain distribution in these autoradiographs was similar to that for free galactose. Thus, the incorporation observed for L-1210 cells incubated in UDP-[³H]-galactose was due primarily to the intracellular utilization of free galactose generated by extracellular degradation of the nucleotide sugar. Inability t o demonstrate an ectogalacto-syltransferase system on L1210 cells does not rule out the possibility that the enzyme is present but undetectable due t o the absence of appropriate cell surface acceptor molecules.     

STORAGE OF PHOSPHORUS IN NITROGEN-FIXING ANABAENA FLOS-AQUAE (CYANOPHYCEAE)1

P accumulation and metabolic pathway in N₂-fixing Anabaena flos-aquae (Lyngb.) Bréb were investigated in P-sufficient (20 μMP) and P-limited (2 μMP) turbidostats in combined N-free medium. The cyanobacterium grew at its maximum rate (μ_max, 1.13 d^?1) at the high P concentration and at 65% of μ_max under P limitation, with total cell P concentrations (Q_P) at steady states of 12.0 and 5.2 fmol·cell^?1, respectively. At steady state, polyphosphates (PP_i) accounted for only 3% of Q_P (0.4 fmol·cell^?1) in P-rich cells. Its concentration in P-limited cells was 5.8% (0.3 fmol·cell^?1). On the other hand, sugar P was very high at 22% of Q_P in P-rich cells and was undetectable in P-limited cells. Pulse chase experiments with ³²P showed that P-rich cells initially incorporated the labeled P into the acid-soluble PP_i fraction within the first few minutes and to a lesser extent into nucleotide P. Radioactivity in the PP_i then declined rapidly with concomitant increases in sugar P and nucleotide P fractions. In contrast, in P-limited cells, no radiolabel was detected in acid-soluble PP_i, and ³²P was initially incorporated into nucleotide P, sugar P, and ortho P fractions. The latter two fractions then subsequently declined. Therefore, under N₂-fixing conditions the cyanobacteria appeared to store P as sugar P and also utilize P through different pathways under P-rich and -limited conditions. When nitrate was supplied as the N source under P-sufficient conditions, PP_i accounted for about 15% of steady-state Q_P, but no sugar P was detected. Therefore, the same organism stored P in different cell P fractions depending on its N sources.     

Stimulation of cell wall biosynthesis and structural changes in response to cytokinin- and elicitor-treatments of suspension-cultured Phaseolus vulgaris cells

Qualitative sugar flux into cell wall polysaccharides has been determined for two model systems. The first, treatment of suspension-cultured French bean (Phaseolus vulgaris L.) cells with an increase in the cytokinin/auxin ratio and in the concentration of sucrose, models some aspects of differentiation. Wall changes are characterised by up to a five-fold increase in thickness due to the laying down of extra wall material. Sugar flux following labelling of cells with [¹⁴C]-sucrose was examined during the period of maximum extractable catalytic activities of the enzymes of sugar nucleotide conversion determined previously. Increased secretion was observed in all major groups of polysaccharides, particularly the cellulosic fraction. Analysis of the sugars in the hemicellulosic fraction indicated that the newly synthesised polysaccharide was most probably xylan. It was confirmed by immunolocalisation of xylan in these walls. This treatment thus increases incorporation into the wall of components characteristic of secondary wall. In the second system, which models the defence response, suspension cultures were treated with an elicitor from the walls of Colletotrichum lindemuthianum. Again, sugar flux was determined by labelling cells with [¹⁴C]-sucrose and examined during the period determined previously of maximum extractable catalytic activities of the enzymes of sugar nucleotide conversion. Increased secretion into unextractable polymers was the major change and was consistent with the occurrence of oxidative processes leading to immobilisation of some wall components. Callose, a polysaccharide characteristic of the defence response was immunolocalised in these walls but not in those of control cells.     

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.     

Intact Golgi synthesize complex branched O-linked chains on glycoside primers: evidence for the functional continuity of seven glycosyltransferases and three sugar nucleotide transporters

We examined the functional co-localization and continuity of glycosyltransferases and sugar nucleotide transporters in the Golgi of two Chinese hamster ovary (CHO) cell lines that synthesize different types of O-linked oligosaccharides. CHO cells normally synthesize primarily Sia2,3Gal1,3GalNAc- on glycoproteins. CHO cells transfected with core-2 GlcNAc transferase (Core 2) can synthesize glycoproteins containing branched O-linked oligosaccharides with poly-N-acetyllactosamines. CHO lines incubated with [³H]galactose and GalNAc--phenyl (GAP) as a primer, synthesize labeled glycoside products that faithfully resemble those found on the endogenous acceptors: CHO cells make Sia2,3[³H]Gal1,3GAP, while CHO Core2 cells synthesize GAPs with complex branched chains including poly-N-acetyllactosamines. To determine if isolated Golgi preparations make similar products, we prepared Golgi by established homogenization methods, documented their intactness, and added tracer UDP-[³H]Gal, unlabeled sugar nucleotides, and GAP. CHO Golgi preparations synthesized only Sia2,3[³H]Gal1,3GAP. CHO Core2, also made this product and a small amount of Core-2 GlcNAc transferase-dependent products. No endogenous glycoproteins were labeled. However, when either cell line was gently permeabilized with streptolysin-O or given hypo-osmotic shock, both GAP and endogenous acceptors were efficiently glycosylated within an intact functional Golgi lumen and remained there. Significantly, Golgi from CHO Core2 cells made mostly branched GAP products including some with poly-N-acetyllactosamines as complex as those made and secreted by living cells incubated with GAP. These results suggest that the lumen of the Golgi apparatus is functionally continuous or interconnected. Once glycosides diffuse into the Golgi lumen, they have access to all the sugar nucleotide transporters and glycosyltransferases used for complex GAP-based products without requiring metabolic energy or inter-vesicular transport. Glycosylation of artificial acceptors could be used to track the functional continuity or co-localization of multiple glycosyltransferases and transporters under conditions where Golgi morphology disintegrates and/or reappears.     

Bacterial glycoglycerolipid synthases: processive and non-processive glycosyltransferases in mycoplasma

Glycoglycerolipids are abundant membrane components in the photosynthetic tissues of plants and in cyanobacteria, with highly conserved structures (galactolipids). In non-photosynthetic bacteria, glycoglycerolipids are also widespread but with higher structural diversity. They are synthesized by the action of glycosyltransferases (GT), which transfers a glycosyl unit from a sugar nucleotide donor to diacylglycerol to form monoglycosyldiacylglycerol followed by a second transfer to give diglycosyldiacylglycerol. Both transferase activities are catalysed by different GT enzymes in plants, and many bacteria; however, processive enzymes, in which a single GT transfers the first and second (and eventually more) glycosyl units are also found in some bacteria. In this review, we summarize the diversity of glycosyltransferases involved in glycolipid biosynthesis in bacteria, focussing on mycoplasma enzymes and comparing processive and non-processive glycolipid synthases. Since glycoglycerolipids are key structural components of the plasma membrane in mycoplasmas, the glycolipid synthases involved in their biosynthesis are proposed as targets for the design of new antibiotics against mycoplasma infections.     

Purification and identification of dTDP-oleandrose, the precursor of the oleandrose units of the avermectins

The nucleotide sugar precursor of the oleandrose units of the avermectins has been purified from a mutant of Streptomyces avermitilis, which does not synthesize any avermectins but which converts avermectin aglycones to their respective disaccharides. This precursor has been identified as dTDP-oleandrose. The purification was achieved by anion exchange and reverse phase high performance liquid chromatography. The purified nucleotide sugar had an absorption spectra characteristic of thymidine, released dTMP when treated with phosphodiesterase, and possessed an NMR spectrum in which three resonances characteristic of oleandrose were seen in addition to the thymidine signals. The enzyme, avermectin aglycone dTDP-oleandrose glycosyltransferase, which catalyzes the stepwise addition of oleandrose to the avermectin aglycones, has been demonstrated in cell-free extracts and (NH4)2SO4 fractions of cell-free extracts of S. avermitilis. The enzyme is specific for dTDP-oleandrose as the glycosyl donor but utilizes all avermectin aglycones as glycosyl acceptors. The stoichiometry between dTDP-oleandrose consumed in the reaction and oleandrose units transferred to the avermectin mono- and disaccharide was found to be 1:1.     

Glucocorticoids change the nucleotide and sugar nucleotide pool sizes in cultured human skin fibroblasts

Fibroblasts in culture were treated with the glucocorticoid budesonide. The nucleotide and sugar nucleotide pools were quantitated after separation by isotachophoresis. Steroid treatment induced a 40% increase of the UDP-N-acetylhexosamine pool and a 30% increase of the UDP-glucuronic acid pool whereas the UTP pool was diminished. These effects became apparent after 24 h of incubation and a new steady state was attained after 48 h of incubation. The 3'-phosphoadenosine-5'-phosphosulfate pool was probably not influenced by the glucocorticoid treatment. The half-life of the UDP-N-acetylhexosamine pool was considerably longer in treated than in control cells. The efflux from the UDP-N-acetylhexosamine pool was also lowered in the treated cells. The changed efflux may be due to a decreased glycoconjugate synthesis induced by glucocorticoid treatment. The rate of equilibration of [14C]glucose and [3H]glucosamine with the UDP-N-acetylhexosamine pool was changed by glucocorticoid treatment; especially that of [3H]glucosamine was decreased.     

Glycoprotein Metabolism in the Cotyledons of Pisum sativum during Development and Germination

The glycoprotein nature of legumin and vicilin, the reserve globulins in the cotyledons of Pisum sativum was studied. Legumin from mature seed was found to contain 1% neutral sugars (mannose and glucose) and 0.1% amino sugar (glucosamine), whereas vicilin contained 0.3% neutral sugar (mannose) and 0.2% amino sugar (glucosamine). On the basis of the incorporation of ¹⁴C-labeled glucosamine, it appeared that not all of the component subunits of the reserve proteins are glycosylated to the same extent. In addition, it has been established that glycosylation occurs after peptide synthesis. During seed development there was a change in neutral sugars and amino sugar ratio in vicilin. During germination, the neutral sugars and the amino sugar content of the glycoproteins declined. These findings are discussed in relation to the synthesis and degradation of the glycosyl component of the glycoproteins.     

A simple and efficient method for the preparation of GDP-fucose.

A crude extract from hog submaxillary gland was found to synthesize guanosine diphosphate (GDP)-fucose, when incubated with fucose, ATP and GTP, the two enzymatic steps (fucose

fucose-1-phosphate

GDP-fucose) proceeding without noticeable side reactions. Column chromatography on Dowex 1 (HCO₃^?), gel filtration on Sephadex G-15 and preparative paper chromatography gave pure GDP-fucose in an overall yield of 81%. The sugar nucleotide was shown to be active as a glycosyl donor in fucose-incorporating systems.     

Synthesis of Cyclodextrin glycosyl transferase by immobilized cells of Bacillus circulans

The cells of Bacillus circulans (ATCC 21783) immobilized in sodium alginate gel matrix were able to synthesize the extracellular enzyme, Cyclodextrin glycosyl transferase (CGTase, E.C. 2.4.1.19) which is industrially employed for the preparation of cyclodextrins. Optimization for the maximum production of enzyme was carried out by varying the cell density (3.3–53.5 kg/m³) in the gel and the incubation temperature (30°–42°C). The CGTase activity was found to be the highest (45 units/cm³) with maximum cell loading at 37°C. The reusability of immobilized cells was ascertained by repeated batch experiments. The enzyme activity exhibited was in the range of 50 to 55 units/cm³ in each batch. The continuous synthesis of CGTase by immobilized cells has been demonstrated by operating a fluidized bed reactor at a dilution rate 1.1 · 10^–4 sec^–1 for a period of 15 days. The enzyme activity has decreased to 42.5 units/cm³ from an initial value of 61 units/cm³ during continuous operation.The authors are grateful to Dr. A.D. Damodaran, Director, Regional Research Laboratory, Trivandrum for his keen interest and encouragement and to Department of Biotechnology, Government of India, New Delhi for financial support.     

Synthesis of unnatural sugar nucleotides and their evaluation as donor substrates in glycosyltransferase-catalyzed reactions

New unnatural sugar nucleotides, UDP-Fuc and CDP-Fuc were synthesized from fucose-beta-1-phosphate and nucleotide monophosphates activated as morpholidates. Furthermore, a nucleotide analogue was prepared by phosphorylation of 1-(beta-D-ribofuranosyl)cyanuric acid, itself obtained as a protected derivative by condensation of the persilylated derivative of cyanuric acid with 1-O-acetyl-2,3,5-tri-O-benzoyl-beta-D-ribofuranose in 74% yield. This phosphate activated according to the same procedure was condensed with fucose-beta-1-phosphate, affording a new sugar nucleotide conjugate (NDP-Fuc) which was evaluated together with UDP-Fuc, CDP-Fuc and ADP-Fuc, as fucose donors in alpha-(1-->4/3)-fucosyltransferase (FucT-III) catalyzed reaction. Fucose transfer could be observed with each of the donors and kinetic parameters were determined using a fluorescent acceptor substrate. Efficiency of the four analogues towards FucT-III was in the following order: UDP-Fuc=ADP-Fuc>NDP-Fuc>CDP-Fuc. According to the same strategy ADP-GlcNAc was prepared from AMP-morpholidate and N-acetylglucosamine-alpha-1-phosphate; tested as a glucosaminyl donor towards Neisseria meningitidis N-acetylglucosaminyl transferase (LgtA), ADP-GlcNAc was recognized with 0.1% efficiency as compared with UDP-GlcNAc, the natural donor substrate.     

Homology between O-linked GlcNAc transferases and proteins of the glycogen phosphorylase superfamily

The O-linked GlcNAc transferases (OGTs) are a recently characterized group of largely eukaryotic enzymes that add a single beta-N-acetylglucosamine moiety to specific serine or threonine hydroxyls. In humans, this process may be part of a sugar regulation mechanism or cellular signaling pathway that is involved in many important diseases, such as diabetes, cancer, and neurodegeneration. However, no structural information about the human OGT exists, except for the identification of tetratricopeptide repeats (TPR) at the N terminus. The locations of substrate binding sites are unknown and the structural basis for this enzyme's function is not clear. Here, remote homology is reported between the OGTs and a large group of diverse sugar processing enzymes, including proteins with known structure such as glycogen phosphorylase, UDP-GlcNAc 2-epimerase, and the glycosyl transferase MurG. This relationship, in conjunction with amino acid similarity spanning the entire length of the sequence, implies that the fold of the human OGT consists of two Rossmann-like domains C-terminal to the TPR region. A conserved motif in the second Rossmann domain points to the UDP-GlcNAc donor binding site. This conclusion is supported by a combination of statistically significant PSI-BLAST hits, consensus secondary structure predictions, and a fold recognition hit to MurG. Additionally, iterative PSI-BLAST database searches reveal that proteins homologous to the OGTs form a large and diverse superfamily that is termed GPGTF (glycogen phosphorylase/glycosyl transferase). Up to one-third of the 51 functional families in the CAZY database, a glycosyl transferase classification scheme based on catalytic residue and sequence homology considerations, can be unified through this common predicted fold. GPGTF homologs constitute a substantial fraction of known proteins: 0.4% of all non-redundant sequences and about 1% of proteins in the Escherichia coli genome are found to belong to the GPGTF superfamily.     

D-aspartate oxidase in mammalian brain and choroid plexus

Abstract— Synaptosomes from guinea-pig cerebral cortex contain a fetuin: sialyl glyco-protein: glycosyl transferase; evidence is presented which indicates that both a sialyl transferase; evidence is presented which indicates that both a sialyl transferase and endogenous acceptors were located in the synaptosome ‘ghost’ fractions. Following solubilization of synaptosomes with Triton X-100 and the use of fetuin minus NANA as acceptor, 25 per cent of the transferase was recovered after centrifugation and column chromatography on Sephadex G-100 and G-200 with a 64·0-fold purification. The enzyme had a pH optimum of 6·3, required no divalent metal cation for activity, and exhibited high activity with either fetuin minus sialic acid, prothrombin minus sialic acid, Tamm-Horsfall glycoprotein minus sialic acid, or orosomucoid minus sialic acid as acceptor; neither BSM nor PSM minus NANA functioned as an effective acceptor. The fetuin:sialyl transferase using fetuin minus sialic acid and CMP-sialic acid as substrates a and b, respectively, gave the following kinetic constants when using the Cleland bisubstrate model: K_a= 35μM; K_b= 3 μM; K_ia, = 25 μM; K_ib= 25μM; and V₁= 92 pmoles. min^?1.mg^?1 of protein. The following divalent cations inhibited the reaction: Ba²⁺ > Hg²⁺ > Pb²⁺ > Cu²⁺.     

Amplification of pyridine nucleotide pools in mitogen-stimulated human lymphocytes

NAD⁺ levels in resting human lymphocytes obtained from 20 donors were found to be 69.9 ± 21.7 pmols/10⁶ cells. After 3 days of phytohemagglutinin (PHA) stimulation the NAD⁺ levels rose to 452 ± 198 pmols/10⁶ cells. NADH, NADP⁺ and NADPH also increased in mitogen-stimulated lymphocytes, but the major portion of the increase in total pyridine nucleotide pools was accounted for by the increase in NAD⁺. When PHA-stimulated lymphocytes were incubated in nicotinamide-deficient growth medium, there was no significant increase in their total pyridine nucleotide pools; however, the ratios of oxidized to reduced pyridine nucleotides changed in a similar fashion to cells grown in medium containing nicotinamide. When lymphocytes in nicotinamide-deficient medium were stimulated with PHA they increased their levels of DNA synthesis and cell replication in a similar fashion to cells growing in nicotinamide-supplemented media. Human lymphocytes were able to synthesize pyridine nucleotides from nicotinamide or nicotinic acid; however, in the absence of a preformed pyridine ring they did not efficiently use tryptophan for the synthesis of NAD. Uptake of [carbonyl-¹⁴C]nicotinamide and conversion to NAD was markedly increased in PHA-stimulated lymphocytes; these cells also showed a marked increase in activity of the enzyme adenosine-triphosphate-nicotinamide mononucleotide (ATP-NMN) adenylyl transferase.     

Characterization of a CV-1 cell cycle. III. Biophysical parameters.

Membrane preparations from three independently selected concanavalin A-resistant cell lines incorporated si$\text{g}$nificantly less GDP-[¹⁴C]mannose into lipid, oligosaccharide-lipid and protein fractions than preparations obtained from parental wild populations. The results from experiments with membranes from a revertant concanavalin A-resistant line more closely resembled the wild-type populations. The amount of mannose label incorporated into glycoprotein in the variant cells was higher than expected if it is assumed that the pathway GDP-mannose → mannolipid → oligosaccharide-lipid → mannoprotein is functioning in these cells. Evidence is presented to suggest that conversion of mannose label to fucose occurs in wild-type and variant cell lines and that this pathway may be of greater importance in the variant cells; this result could explain at least in part, the higher than expected levels of ¹⁴C-label in glycoprotein in the variant cell lines. The changes in the glycosyl transferase activities in these lectin-resistant cell lines are probably involved in determining the concanavalin A-resistant property and the accompanying complex phenotype exhibited by these variant cell lines.