Lipid-mediated glycosylation of a white matter membrane glycoprotein with an apparent molecular weight of 24,000.

White matter membrane preparations from pig brain catalyze the transfer of [¹⁴C]mannose from exogenous [¹⁴C]mannosylphosphoryldolichol into an endogenous oligosaccharide lipid. Under the same incubation conditions label is also incorporated into endogenous membrane glycoproteins. The enzymatic labeling of both classes of endogenous acceptors is stimulated by the addition of Ca²⁺. Several enzymatic properties of the mannosyltransferase activity responsible for the transfer of mannose from mannosylphosphoryldolichol into the oligosaccharide lipid intermediate have been examined. The [Man-¹⁴C] oligosaccharide lipid synthesized by this in vitro system has the solubility, hydrolytic and chromatographic characteristics of a pyrophosphate-linked oligosaccharide derivative of dolichol. The free [Man-¹⁴C]oligosaccharide liberated from the carrier lipid by mild acid treatment is estimated to contain 8 glycose units. All of the [¹⁴C]mannosyl units in the [Man-¹⁴C]oligosaccharide derived from exogenous [¹⁴C]mannosylphosphoryldolichol are released as free [¹⁴C]mannose by an α-mannosi-dase. No [¹⁴C]mannose is released during incubation with a β-mannosidase. The presence of an N,N′-diacetylchitobiose unit at the reducing end of the lipid-bound [Man-¹⁴C]oligosaccharide is indicated by its susceptibility to digestion by endo-β-N-acetylglucosaminidase H. Pronase digestion of the enzymatically labeled [Man-¹⁴C]glycoprotein yields a single [Man-¹⁴C]gly-copeptide fraction on Bio-Gel P-6 that appears to be slightly larger than the free [Man-¹⁴C]oligosac-charide released from the carrier lipid by mild acid hydrolysis. The [Man-¹⁴C]glycopeptide is cleaved by endo-β-N-acetylglucosaminidase H, and the neutral [Man-¹⁴C]oligosaccharide product appears to be identical to the product formed when the lipid-bound [Man-¹⁴C]oligosaccharide is degraded by the endoglycosidase. The glycopeptide linkage in the [Man-¹⁴C]glycoprotein is stable to mild alkali treatment. These results are consistent with the dolichol-linked [Man-¹⁴C]oligosaccharide, mannosy-lated via exogenous [¹⁴C]mannosylphosphoryldoiichol, being subsequently transferred en bloc from dolichyl pyrophosphate to asparagine residues in endogenous membrane polypeptide acceptors. SDS-polyacrylamide gel electrophoresis of the [Man-¹⁴C]glycoprotein, labeled when white matter membranes are incubated with [¹⁴C]mannosylphosphoryldolichol. revealed a major labeled polypeptide with an apparent mol wt of 24,000. A minor labeled membrane glycoprotein is also seen, having an apparent mol wt of 105,000.     

Glycoprotein synthesis in plants: I. Role of lipid intermediates

The enzymic processes involved in glycoprotein synthesis have been studied using crude extracts obtained from developing cotyledons of Phaseolus vulgaris harvested at the time of active deposition of vicilin. Radioactivity from GDP-[¹⁴C]mannose can be incorporated by crude extracts into a single chloroform-methanol-soluble product as well as into insoluble product(s). Mannose is the sole ¹⁴C-labeled constituent of the lipid. The kinetics of incorporation of ¹⁴C, as determined by pulse and pulse-chase experiments using GDP-[¹⁴C]mannose, as well as direct incorporation from added [¹⁴C]mannolipid, shows that the mannolipid is an intermediate in the synthesis of the insoluble product(s). The characteristics of the mannolipid are consistent with it being a mannosyl phosphoryl polyprenol. The mannose is apparently attached to the lipid via a monophosphate linkage. Of the radioactivity in the insoluble product(s), about 20% is pronase-digestible during a “pulse experiment.” After a chase with unlabeled GDP-mannose, about 40% is pronase-digestible; the other 60% is as yet uncharacterized. A radioactive product soluble in a mixture of chloroform-methanol-H₂O can be extracted from the insoluble residue obtained during a pulse, but is no longer present after a chase. This product may be a lipid oligosaccharide, the final intermediate in glycoprotein synthesis. Data are presented on incorporation from UDP-N-[¹⁴C]acetylglucosamine into both chloroform-methanol-soluble and -insoluble product(s). The results are consistent with an involvement of lipid intermediates in the glycosylation of protein in this system, and support the concept that the mechanisms of glycoprotein synthesis in higher plants are similar to those which have been reported for mammalian systems.     

Decreased transfer of oligosaccharide from oligosaccharide-lipid to protein acceptors in regenerating rat liver

The transfer of [14C]glucose from UDP-[14C]glucose to lipid intermediates and glycoproteins was decreased in regenerating rat liver microsomes 24 h after partial hepatectomy. In regenerating liver microsomes, the concentration of free dolichyl phosphate (Dol-P) was significantly decreased. However, it was only about 10% of total Dol-P, which was not significantly changed. On the addition of exogenous Dol-P, the transfer of [14C]glucose to glycoproteins was still decreased, while the decrease of the transfer to lipid intermediates was no longer observed. These results suggest that the glycoprotein synthesis is not regulated by the amount of Dol-P in regenerating liver microsomes. Oligosaccharide obtained from [14C]glucosyl-oligosaccharide-lipid was not distinguishable between regenerating liver and control by paper chromatography. The oligosaccharide transfer to protein in microsomes was compared by using [14C]glucosyl-oligosaccharide-lipid as oligosaccharide donor. The transfer of oligosaccharide to endogenous proteins decreased to 77% of control in regenerating liver and the transfer to exogenously added denatured alpha-lactalbumin decreased to 59% of control. Therefore, it is unlikely that the acceptor capacity of endogenous protein is decreased in regenerating liver. Neither the change in oligosaccharide-lipid under the condition for oligosaccharide transfer assay nor the stability of oligosaccharide transferase was different between regenerating liver and control. These results strongly suggest that the decrease in the activity of the oligosaccharide transferase in microsomes causes the decrease of glycoprotein synthesis in regenerating liver, which was shown in our previous studies.     

Polyprenol phosphates and mannosyl transferases in Phaseolus aureus

The transfer of mannose from GDP[¹⁴C]mannose to lipid and to insoluble polymer by a particulate preparation of Phaseolus aureus has been investigated. The evidence favours the lipid being a prenol phosphate mannose. Of a range of prenol phosphates tried, betulaprenol phosphate was the most effective exogenous acceptor of mannose. Most of the insoluble [¹⁴C]polymer formed was glycoprotein in nature although small quantities of ¹⁴C were associated with glucomannan and galactoglucomannan fractions. Time studies failed to reveal a typical precursor-product relationship between the lipid and polymer fractions but on incubation of [¹⁴C]mannolipid with the particulate fraction a small transfer (0·5–0·7%) of [¹⁴C] to polymer was detected. p-Hydroxymercuribenzoate inhibited (by 90%) the transfer of [¹⁴C] from GDP[¹⁴C]-mannoseto polymer and simultaneously increased (3-fold) the [¹⁴C] recovered in the lipid fraction. The effect was nullified by mercaptoethanol. Attempts to solubilize the transfer system were only partially successful. The formation of a chromatographically identical mannolipid was demonstrated in particulate fractions of Codium fragile and tomato roots.     

Glycoprotein Synthesis in Plants: III. Interaction between UDP-N-Acetylglucosamine and GDP-Mannose as Substrates

This report presents evidence that enzymes present in crude extracts prepared from developing cotyledons of Phaseolus vulgaris can catalyze the transfer of radioactivity from UDP-N-[¹⁴C]acetylglucosamine into a chitobiosyl-lipid, lipid-oligosaccharide, and glycoprotein. Kinetic evidence supports the concept that the N-acetylglucosamine-containing lipids are precursors to the glycoprotein. Evidence is also presented which shows an interaction between GDP-mannose and UDP-N-acetylglucosamine when used as substrates for the synthesis of lipid-oligosaccharide and glycoprotein. Kinetic evidence, as well as isolation and characterization of the oligosaccharides released from lipid by mild acid hydrolyses, support the conclusion that mannose and N-acetylglucosamine are contained in the same oligosaccharide and that N-acetylglucosamine is present at the reducing end of the oligosaccharide. Ninety-eight per cent of the radioactivity which is incorporated from UDP-N-[¹⁴C]acetylglucosamine into the insoluble residue is solubilized by protease treatment. The glycopeptide released is quite similar in size and composition to the glycopeptide released by proteolytic digestion of vicilin, the major storage protein of Phaseolus vulgaris.     

Evidence for the enzymatic transfer of N-acetylglucosamine from UDP-N-acetylglucosamine into dolichol derivatives and glycoproteins by calf brain membranes

Incubating white matter membranes with UDP-N-acetyl-[¹⁴C]glucosamine in the presence of Mg²⁺ and AMP resulted in the labeling of two major glycolipids, a minor glycolipid and several membrane-associated glycoproteins. The addition of AMP protected the labeled sugar nucleotide from degradation by a membrane-bound sugar nucleotide pyrophosphatase activity. While no labeled oligosaccharide lipid was recovered in a CHCl₃CH₃OHH₂O (10:10:3) extract after incubating with only UDP-N-acetyl-[¹⁴C] glucosamine, Mg²⁺, and AMP, the inclusion of unlabeled GDP-mannose led to the formation of an N-acetyl-[¹⁴C]glucosamine-labeled oligosaccharide lipid that was soluble in CHCl₃CH₃OHH₂O (10:10:3). The [GlcNAc-¹⁴C]oligosaccharide unit was released by treatment with 0.1 N HCl in 80% tetrahydrofuran at 50 °C for 30 min and appears to have the same molecular size as the lipid-linked [mannose-¹⁴C] oligosaccharide, formed enzymatically by white matter membranes as judged by their elution behavior on Bio-Gel P-6. The incorporation of N-acetyl-[¹⁴C]glucosamine into glycolipid was stimulated by exogenous dolichol monophosphate, but inhibited by UMP or tunicamycin, a glucosamine-containing antibiotic. Although UMP and tunicamycin drastically inhibited the labeling of glycolipid, these compounds had very little effect on the labeling of glycoproteins. The major glycolipids have the chemical and Chromatographic characteristics of N-acetylglucosaminylpyrophosphoryldolichol and N,N′-diacetylchitobiosylpyrophosphoryldolichol. When the labeled glycoproteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, four labeled polypeptides were observed, having apparent molecular weights of 145,000, 105,000, 54,000, and 35,000. Virtually all of the N-acetyl-[¹⁴C]glucosamine was released when the labeled glycopeptides, produced by pronase digestion, were incubated with an exo-β-N-acetylglucosaminidase, indicating that all of the N-acetyl-[¹⁴C]glucosamine incorporated under these conditions is attached to white matter membrane glycoproteins at nonreducing termini.     

A dolichol-linked trisaccharide from central nervous tissue: structure and biosynthesis.

Calf brain membranes have previously been shown to enzymatically transfer N-acetyl[¹⁴C]glucosamine from UDP-N-acetyl[¹⁴C]glucosamine into N-acetyl[¹⁴C]glucosami-nylpyrophosphoryldolichol, N,N′-diacetyl[¹⁴C]chitobiosylpyrophosphoryldolichol and a minor labeled product with the chemical and chromatographic properties of a [¹⁴C]trisaccharide lipid (Waechter, C. J., and Harford, J. B. (1977) Arch. Biochem. Biophys.181, 185–198). This paper demonstrates that incubating calf brain membranes containing endogenous, prelabeled N-acetyl[¹⁴C]glucosaminyl lipids with unlabeled GDP-mannose enhances the formation of the [¹⁴C]trisaccharide lipid. The intact [¹⁴C]trisaccharide lipid behaves like a dolichol-bound trisaccharide, in which the glycosyl group is linked via a pyrophosphate bridge, when chromatographed on SG-81 paper or DEAE-cellulose. Mild acid treatment releases a water-soluble product that comigrates with authentic β-Man-(1→4)-β-GlcNAc(1→4)-GlcNAc. The free [¹⁴C]trisaccharide is converted to N,N′-diacetyl[¹⁴C]chitobiose by incubation with a highly purified β-mannosidase. These findings indicate that the trisaccharide lipid formed by calf brain membranes is β-mannosyl-N,N′-diacetylchito-biosylpyrophosphoryldolichol. The two glycosyltransferases responsible for the enzymatic conversion of the N-acetylglucosaminyl lipid to the trisaccharide lipid have been studied using exogenous, purified [¹⁴C]glycolipid substrates. Calf brain membranes enzymatically transfer N-acetylglucosamine from UDP-N-acetylglucosamine to exogenous N-acetyl[¹⁴C] glucosaminylpyrophosphoryldolichol to form [¹⁴C]disaccharide lipid. The biosynthesis of [¹⁴C]disaccharide lipid is stimulated by unlabeled UDP-N-acetylglucosamine under conditions that inhibit N-acetylglucosaminylpyrophosphoryldolichol synthesis. Unlike the formation of N-acetylglucosaminylpyrophosphoryldolichol the enzymatic addition of the second N-acetylglucosamine residue is not inhibited by tunicamycin. Exogenous purified [¹⁴C] disaccharide lipid is enzymatically mannosylated by calf brain membranes to form the [¹⁴C] trisaccharide lipid. The formation of the [¹⁴C]trisaccharide lipid from exogenous [¹⁴C] disaccharide lipid is stimulated by unlabeled GDP-mannose and Mg²⁺, and inhibited by EDTA. Exogenous dolichyl monophosphate is also inhibitory. These results strongly suggest that the calf brain mannosyltransferase involved in the synthesis of the trisaccharide lipid requires a divalent cation and utilizes GDP-mannose, not mannosylphosphoryldolichol, as the direct mannosyl donor.     

Incorporation of glucose into lipid-linked saccharides in aorta and its inhibition by amphomycin

The particulate enzyme from pig aorta catalyzed the transfer of glucose from UDP-glucose into glucosyl-phosphoryl-dolichol, into lipid-linked oligosaccharides, and into glycoprotein. Radioactive lipid-linked oligosaccharides were prepared by incubating the extracts with GDP-[¹⁴C]mannose and UDP-[³H]glucose. When the labeled oligosaccharides were run on Bio-Gel P-4, the two different labels did not exactly coincide; the ³H peak eluted slightly earlier indicating that it was of higher molecular weight than the ¹⁴C material, but there was considerable overlap. The purified oligosaccharide(s) contained glucose, mannose, and N-acetylglucosamine but the ratios of these sugars varied from one enzyme preparation to another, probably depending on the endogenous oligosaccaride-lipids present in the microsomal preparation. Treatment of the [³H]glucose-labeled oligosaccharide with α-mannosidase gave rise to a ³H-labeled oligosaccharide which moved somewhat faster on Bio-Gel P-4 than the original oligosaccharide, suggesting it had lost one or two sugar residues. These data indicate that mannose and glucose are in the same oligosaccharide. The antibiotic, amphomycin, inhibited the transfer of glucose from UDP-glucose into the lipid-linked saccharides. However the synthesis of glucosyl-phosphoryl-dolichol was much more sensitive then was the synthesis of lipid-linked oligosaccharides. The glucose-labeled oligosaccharide produced in the absence of amphomycin was of high molecular weight based on paper chromatography. But in the presence of partially inhibitory concentrations of antibiotic, the oligosaccharide migrated more rapidly on paper chromatograms. However, amphomycin had no effect on the synthesis of glucosyl-ceramide by the aorta extracts. In fact, the antibiotic may stimulate glucosyl-ceramide by making more of the substrate, UDP-glucose, available for synthesis of this lipid.     

Effect of dexamethasone on the synthesis of dolichol-linked saccharides and glycoproteins in hepatocytes prepared from control and inflamed rats.

Hepatocytes were prepared from control and inflamed rats. The incorporation of [14C]mannose into protein was increased in inflamed compared with control hepatocytes. The incorporation of [14C]mannose into protein was also increased when the hepatocytes were cultured in presence of dexamethasone (1 microM), either from control or inflamed rats. At the same time the incorporation of [14C]mannose into dolichol phosphate mannose and dolichol-linked oligosaccharide was increased due to inflammation. The presence of dexamethasone in the hepatocyte culture caused an increased formation of these two products; in particular its effect on oligosaccharide lipid formation was very pronounced. The ratios of activities of formation of [14C]mannose-labelled oligosaccharide lipid in inflamed over control hepatocytes gradually decrease when increasing amounts of exogenous dolichol phosphate was added in cell homogenate assay mixture. These results suggest that the increase of oligosaccharide lipid formation in inflammation could be due to a higher concentration of endogenous dolichol phosphate, as was shown for dolichol phosphate mannose formation in inflammation [Sarkar & Mookerjea (1984) Biochem. J. 219, 429-436]. In contrast, the ratio of activities of [14C]mannose-labelled oligosaccharide lipid between dexamethasone-treated and untreated hepatocytes shows only a slight increase when increasing concentrations of exogenous dolichol phosphate were added to the assays. This suggests that the stimulation of dolichol pyrophosphate oligosaccharide synthesis observed in dexamethasone treatment is probably due to the higher level of enzymes involved in oligosaccharide synthesis rather than higher level of endogenous dolichol phosphate in these cells.     

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.     

Trans-α-xylosidase and trans-β-galactosidase activities, widespread in plants, modify and stabilize xyloglucan structures

Cell‐wall components are hydrolysed by numerous plant glycosidase and glycanase activities. We investigated whether plant enzymes also modify xyloglucan structures by transglycosidase activities. Diverse angiosperm extracts exhibited transglycosidase activities that progressively transferred single sugar residues between xyloglucan heptasaccharide (XXXG or its reduced form, XXXGol) molecules, at 16 μm and above, creating octa‐ to decasaccharides plus smaller products. We measured remarkably high transglycosylation:hydrolysis ratios under optimized conditions. To identify the transferred monosaccharide(s), we devised a dual‐labelling strategy in which a neutral radiolabelled oligosaccharide (donor substrate) reacted with an amino‐labelled non‐radioactive oligosaccharide (acceptor substrate), generating radioactive cationic products. For example, 37 μm [Xyl‐³H]XXXG plus 1 mm XXLG‐NH₂ generated ³H‐labelled cations, demonstrating xylosyl transfer, which exceeded xylosyl hydrolysis 1.6‐ to 7.3‐fold, implying the presence of enzymes that favour transglycosylation. The transferred xylose residues remained α‐linked but were relatively resistant to hydrolysis by plant enzymes. Driselase digestion of the products released a trisaccharide (α‐[³H]xylosyl‐isoprimeverose), indicating that a new xyloglucan repeat unit had been formed. In similar assays, [Gal‐³H]XXLG and [Gal‐³H]XLLG (but not [Fuc‐³H]XXFG) yielded radioactive cations. Thus plants exhibit trans‐α‐xylosidase and trans‐β‐galactosidase (but not trans‐α‐fucosidase) activities that graft sugar residues from one xyloglucan oligosaccharide to another. Reconstructing xyloglucan oligosaccharides in this way may alter oligosaccharin activities or increase their longevity in vivo. Trans‐α‐xylosidase activity also transferred xylose residues from xyloglucan oligosaccharides to long‐chain hemicelluloses (xyloglucan, water‐soluble cellulose acetate, mixed‐linkage β‐glucan, glucomannan and arabinoxylan). With xyloglucan as acceptor substrate, such an activity potentially affects the polysaccharide’s suitability as a substrate for xyloglucan endotransglucosylase action and thereby modulates cell expansion. We conclude that certain proteins annotated as glycosidases can function as transglycosidases.     

Dietary effects on the formation of dolichyl monophosphate mannose by microsomal preparations of rat adipose tissue

Microsomal preparations from rat adipose tissue catalyse the transfer of [¹⁴C]mannose from GDP-[¹⁴C]mannose to an endogenous acceptor forming a [¹⁴C]mannosyl lipid. The mannosyl lipid co-chromatographs with hen oviduct dolichyl monophosphate β-mannose on three solvent systems. It is stable to mild alkaline hydrolysis, but strong alkaline treatment yields a compound that co-migrates with mannose 1-phosphate. The mannosyl lipid is labile to mild acid hydrolysis, yielding [¹⁴C]mannose. Formation of the compound is reversible by GDP, but not GMP, and is stimulated by exogenous dolichyl phosphate.

The kinetics of transfer of [¹⁴C]mannose from GDP-[¹⁴C]mannose to form dolichyl monophosphate mannose were studied by using preparations derived from rats fed on one of four diets: G (high glucose), L (high lard), F (fructose) or GC (high glucose, 0.9% cholesterol). The K_m and V_max. values for transfer from GDP-mannose were virtually indistinguishable in the four preparations.

In the absence of exogenous dolichyl phosphate, the largest amount of transfer of [¹⁴C]mannose into the mannosyl lipid was observed with preparations from fructose-fed animals. Preparations from glucose-fed animals showed about 60% as much transfer, whereas membranes from rats fed the other diets showed intermediate values between the fructose- and glucose-fed animals. The inclusion of cholesterol in the glucose diet elicited an increase in transfer of mannose.

Under conditions of saturating exogenous dolichyl phosphate, preparations from lard-fed animals have 1.5 times as much enzyme activity as do preparations from animals fed the other three diets.

     

Formation of lipid-linked mono- and oligosaccharides from GDP-mannose by castor bean endosperm homogenates

A crude organelle preparation from germinating castor bean endosperm catalysed the incorporation of mannose from GDP[¹⁴C]mannose into acid-labile mannolipids. Solubility and chromatographic properties have identified the most rapidly synthesized products as mannosyl-phosphoryl-polyisoprenol, while the more polar lipid formed was shown to contain oligosaccharide. Little radioactivity from GDP[¹⁴C]mannose accumulated in insoluble product in the cell-free system, but supplying GDP[¹⁴C]mannose to intact endosperm tissue has shown that the major incorporation product in vivo is glycoprotein. This product was readily solubilized by either pronase or sodium dodecyl sulphate treatment suggesting it was membrane bound glycoprotein. Incorporation of mannose into mannosyl-phosphoryl-polyisoprenol during the cell-free assay was stimulated by the addition of dolichol monophosphate. This enzymic activity was optimal at pH 7.5 and in the presence of 10 mM Mg²⁺. The K_m for GDP-mannose was estimated to be 5×10^-7 M. Cellular mannosyl transferase activity changed markedly during early post-germinative growth; from being absent in the dry seed, enzyme activity increased to peak between the second and third days of growth and subsequently declined.Abbreviations TCA trichloroacetic acid - SDS sodium dodecyl sulphate     

The participation of lipid-linked oligosaccharide in synthesis of membrane glycoproteins.

Membrane preparations from hen oviduct catalyze the transfer of mannose from GDP-mannose into three components: mannosyl phosphoryl polyisoprenol, oligosaccharide-lipid, and glycoprotein. Eivence that mannosyl phosphoryl polyisoprenol serves as a mannosyl donor for synthesis of both oligosaccharide-lipid and glycoproteins was previously reported (Waechter, C.J., Lucas, J.J., and Lennarz, W.J. (1973) J. Biol. Chem. 248, 7570-7579). In this study the oligosaccharide-lipid has been isolated, and the oligosaccharide has been partially characterized. Based on paper chromatography the oligosaccharide chain contains 7 to 9 glycose units. The glycose at the reducing terminus is N-acetylglucosamine, whereas mannose is found at the nonreducing end. When UDP-N-acetyl[14C]glucosamine is incubated with oviduct membranes in the absence of GDP-mannose, a 14C-labeled chitobiosyl lipid, but little oligosaccharide-lipid is synthesized. When GDP-mannose is also present in the incubation mixture an oligosaccharide-lipid is formed containing N-acetyl[14C]glucosaminyl residues. This oligosaccharide-lipid is chromatographically identical with the [14C]mannose-containing oligosaccharide-lipid isolated in the earlier study cited above. When the N-acetyl[14C]glucosamine-oligosaccharide released from the oligosaccharide-lipid by mild acid is treated with partially purified alpha-mannosidase the major radioactive product is [14C]chitobiose. Evidence that the [14C]mannose-containing oligosaccharide-lipid serves as an oligosaccharide donor for glycoprotein synthesis was obtained by incubation of partially purified oligosaccharide-lipid with the membranes. The products of this incubation were shown to be glycoproteins on the basis of their sensitivity to pronase, as determined by both gel filtration and paper electrophoresis. Similar experiments, using oligosaccharide-lipid doubly labeled with [14C]mannose and N-acetyl[3H]glucosamine, provided evidence that the oligosaccharide chain of the oligosaccharide-lipid is transferred en bloc to glycoprotein s.     

Biosynthesis and characterization of large dolichyl diphosphate-linked oligosaccharides in Sacchromyces cerevisiae

Yeast membranes incorporate radioactivity from GDP[¹⁴C]mannose into various glycolipids. These can be separated by thin layer chromatography into at least seven components.The major component has been identified previously as dolichyl monophosphate mannose. Only one additional component is not sensitive to mild alkaline saponification, but is hydrolyzed instead under mild acidic conditios. This latter glycolipid has all the characteristics of a polyprenyl diphosphate oligosaccharide with a sugar moiety of more than 12 hexose units. It runs like dolichyl diphosphate derivatives on a DEAE column and evidence is presented that the lipid moiety is a polyprenol.When radioactive Dol-PP-di-N-acetylchitobiose is incubated with yeast membranes in the presence of non-radioactive GDPmannose a small amount of a larger lipid oligosaccharide is formed besides the previously-described Dol-PP-(GlcNAc₂ mannose. This oligosaccharide has all the properties of the glycolipid described above. Its formation is greatly increased when Triton is omitted from the incubation. Radioactivity of the polyprenyl diphosphate [¹⁴C]oligosaccharide is transferred to ethanol-insoluble material, most likely endogenous membrane glycoproteins.     

Involvement of dolichol phosphates as intermediates in the mannosyl and galactosyl transferases of rat testicular germ cell Golgi apparatus membranes

Isolated Golgi apparatus membranes from the germinal elements (spermatocytes and early spermatids) of rat testis were examined for their ability to incorporate [14C]mannose and [14C]galactose into glycolipid and glycoprotein fractions. Transfer of mannose from GDP-[14C]mannose into a Lipid I fractions (GPD:MPP mannosyl transferase activity), identified as mannosyl phosphoryl dolichol, showed optimal activity at 1.5 mM manganese and at pH 7.5. Low concentrations of Triton X-100 (0.1%) stimulated transferase activity in the presence of exogenous dolichol phosphate (Dol-P); however, inhibition occurred at Triton X-100 concentrations greater than 0.1%. Maximal activity of this GDP:MPP mannosyl transferase occurred at 25 microM Dol-P. Activity using endogenous acceptor was 2.34 pmole/min/mg, whereas in the presence of 25 microM Dol-P the specific activity was 284 pmole/min/mg, a stimulation of 125-fold. Incorporation of mannose into a Lipid II (oligosaccharide pyrophosphoryl dolichol) and a glycoprotein fraction was also examined. In the absence of exogenous Dol-P, rapid incorporation into Lipid I occurred with a subsequent rise in Lipid II and glycoprotein fractions suggesting precursor-product relationships. Addition of exogenous Dol-P to galactosyl transferase assays showed only a minor stimulation, less than twofold, in all fractions. Over the concentration range of 9.4 to 62.5 micrograms/ml Dol-P, only 1% of radioactive product accumulated in the combined lipid fractions. These observations suggest that the mannose transfer involves Dol-P intermediates and also that spermatocyte Golgi membranes may be involved in formation of the oligosaccharide core as well as in terminal glycosylations.     

Evidence for mannolipids as intermediates in mannose transfer to thyroid rough microsomal glycoproteins.

Thyroid rough microsomes catalyzed the transfer of mannose from GDP-mannose to endogeneous glycoprotein(s) and to glycolipids comprising a recently described dolichol phosphomannose extractable with usual organic solvents and a material tentatively identified as an oligosaccharide lipid. The labeling of the two lipids was consistent with a role in mannose transfer to glycoprotein(s). When partially purified dolichol phospho[14C] mannose was incubated with rough microsomes, a part of the label appeared in the second lipid, suggesting a role as intermediate, and less rapidly in glycoprotein(s). Sodium dodecyl sulfate/polyacrylamide gel electrophoresis did not allow to ascertain whether or not the glycoproteins receiving label from these sugar lipids comprised thyroglobulin precursors.     

Glycosylation of endogenous lipids and proteins by preparations of chicken embryo fibroblasts

Glycosylation of endogenous phosphoisoprenyl lipids and membrane-associated proteins was shown to occur in preparations of chicken embryo fibroblasts incubated with GDP[¹⁴C]mannose and UDP-N-acetylglucosamine. The two preparations used were cells released from the culture dishes by buffered saline containing EDTA and crude membranes from those cells. Both β-mannosyl-phosphoryldolichol and oligosaccharide-phosphoryl lipids with five to eight sugar residues were labelled under the conditions employed. The oligosaccharide isolated from the octasaccharide-lipid fraction was shown to be heterogeneous after an analysis of the products formed by treatment of the oligosaccharide with glycosidases. Some of the oligosaccharides appeared to contain N-acetylglucosamine at positions external to that of [¹⁴C]mannose. Lipids with oligosaccharide moieties of different structures were made by the two preparations. The results of pulse-chase experiments were consistent with the glycosylated lipids being intermediates in glycoprotein biosynthesis.     

Effect of divalent metal ions on the synthesis of oligosaccharide side chains of Neurospora crassa glycoproteins

Neurospora crassa membrane preparations incorporated mannose from GDP-mannose-[¹⁴C] in the presence of Mg²⁺ into a polyprenol lipid and side chains of protein acceptor(s), which are labile on hydrolysis in weak base. The addition of Mn²⁺ to the reaction mixtures does not affect mannosyl lipid synthesis but it stimulates the transfer of mannose to larger oligosaccharide chains resistant to β-elimination and the transfer of a second mannosyl unit to form an O-glycosidically linked mannobiosyl side chain. Incubation of particulate preparations with polyprenol-mannose-[¹⁴C] in the presence of Mg²⁺ and Mn²⁺ also results in the transfer of a single mannose to the protein. When non-radioactive GDP-mannose is added to this reaction mixture, however, β-elimination yields mannobiose. The mannobiose is labeled in the reducing sugar only. These results indicate that the first mannose of this mannobiosyl side chain is transferred via a lipid intermediate, but the second mannose is transferred directly from GDP-mannose. In the presence of Mg²⁺ and Mn²⁺, mannose apparently is also transferred from polyprenol-mannose-[¹⁴C] to side chains which are resistant to hydrolysis.     

Evidence for two catabolic endoglycosidase activities in β-mannosidase-deficient goat fibroblasts

Cultured skin fibroblasts derived from Nubian goats deficient in lysosomal β-mannosidase, which had previously been shown to accumulate storage oligosaccharides with the structures Manβ4GlcNAcβ4GlcNAc and Manβ4GlcNAc (in the ratio of 2.7:1) were evaluated for their ability to catabolize exogenous [³H]GlcN-labelled glycoproteins isolated from the secretions of cultured goat or human fibroblasts. Regardless of the source of exogenous labelled glycoprotein, affected goat fibroblasts took up the labelled glycoprotein from the culture medium and subsequently accumulated the same major labelled oligosaccharide, identified as Manβ4GlcNAcβ4GlcNAc; no such oligosaccharide accumulated in normal goat fibroblasts under the same conditions. Tunicamycin-treated affected fibroblasts also took up labelled exogenous glycoprotein and accumulated labelled storage trisaccharide, further suggesting the direct accumulation of storage trisaccharide from impaired glycoprotein-associated oligosaccharide catabolism. Treatment of metabolically labelled affected fibroblasts with leupeptin, an inhibitor of lysosomal cathepsins, resulted in the 2- to 6-fold inhibition of trisaccharide accumulation, while having little effect on the uptake of [³H]GlcN or the accumulation of labelled disaccharide. The results are most consistent with the presence of two endoglycosidases, an endo-β-N-acetylglucosaminidase and an endo-aspartylglucosaminidase, in goat fibroblasts. These two activities, rather than heterogeneous core oligosaccharide structures, are responsible for the ultimate accumulation of storage oligosaccharides with one and two GlcNAc residues at their reducing terminus.