The high mannose oligosaccharide of phytohemagglutinin is attached to asparagine 12 and the modified oligosaccharide to asparagine 60

Phytohemagglutinin, the lectin of the common bean Phaseolus vulgaris, has a high mannose and a modified (fucosylated) oligosaccharide on each polypeptide. Fractionation by high performance liquid chromatography of tryptic digests of [³H]fucose or [³H]glucosamine labeled phytohemagglutinin, followed by amino acid sequencing of the isolated glycopeptides, shows that the high mannose oligosaccharide is attached to Asn¹² and the modified oligosaccharide to Asn⁶⁰ of the protein. In animal glycoproteins, high mannose chains are rarely found at the N-terminal side of complex chains.     

Glycoprotein biosynthesis in plants. Formation of lipid-linked oligosaccharides of mannose and N-acetylglucosamine by mung bean seedlings.

Cell-free enzyme particles from mung bean seedlings catalyze the incorporation of mannose from GDP-[¹⁴C]mannose and GlcNAc from UDP-[³H]GlcNAc into glycolipids and into glycoprotein. The most rapidly labeled product from GDP-mannose was characterized as a mannosyl-phosphoryl-polyisoprenol, whereas that from UDP-GlcNAc was a mixture of GlcNAc-(pyro)phosphoryl-polyisoprenol and a disaccharide composed of two N-acetylglucosamine residues attached to the polyisoprenol by a phosphoryl or pyrophosphoryl linkage. Radioactivity from GDP-mannose and UDP-GlcNAc was also incorporated into more polar lipids which have been partially characterized as a series of oligosaccharide-(pyro)phosphoryl-lipids. The mannose-labeled oligosaccharides released from these lipids by mild acid hydrolysis were found to contain GlcNAc at their reducing end indicating that these oligosaccharides contain both GlcNAc and mannose. Both the GlcNAc-labeled and the mannose-labeled oligosaccharides gave multiple radioactive peaks upon paper chromatography indicating that they are composed of a series of different sized oligosaccharides. Finally, radioactivity from GDP-[¹⁴C]mannose and UDP-[³H]GlcNAc is incorporated into an insoluble component. Ten percent of the mannose label and all of the GlcNAc label in this insoluble material could be solubilized by digestion with Pronase. The glycopeptides released by Pronase digestion appeared to be approximately the same size as the oligosaccharides from the lipid-linked oligosaccharides based on gel filtration chromatography on Sephadex G-50. The results are consistent with a mechanism for glycoprotein synthesis involving lipid-linked oligosaccharide intermediates.     

Biosynthetic processing of the oligosaccharide chains of cellular fibronectin

We have examined the maturation or processing of the oligosaccharides of cellular fibronectin in cultured chick embryo fibroblasts. Fibronectin was pulse-labeled with [2-³H]mannose or [³⁵S]methionine, and the turnover rates of carbohydrate and polypeptide portions of immunoprecipitated fibronectin were compared. The oligosaccharides on fibronectin were analyzed by gel electrophoresis for alterations in sensitivity to the enzyme endo-β-N-acetylglucosaminidase H, which specifically cleaves the ‘high-mannose’ class of asparagine-linked oligosaccharide. Incorporated mannose was removed only at early time points, suggesting that the structure of fibronectin oligosaccharides was altered due to processing.This possibility was confirmed by the analysis of glycopeptides generated by exhaustive pronase digestion. Two major glycopeptide structures were detected; their properties correspond to a ‘high-mannose’ oligosaccharide precursor and a ‘complex’ carbohydrate product. The precursor-product relationship of these two forms of oligosaccharide chains was demonstrated by pulse-chase labeling experiments. The precursor glycopeptide had an apparent size (M_r 2100) comparable to (Man)₉GlcNAc (M_r 2080), and was sensitive to endo-β-N-acetylglucosaminidase H; nearly all of the labeled mannose incorporated in a 10 min pulse was released from fibronectin glycopeptides by this enzyme. During a 90 min chase period, the glycopeptides became larger and increasingly resistent to endo-β-N-acetylglucosaminadase H cleavage. The final ‘complex’ or processed oligosaccharide structure contained approximately two-thirds less associated with the mature glycoprotein. They also indicate that the ‘complex’ structure is synthesized as a ‘high-mannose’ intermediate which is processed by the removal of mannose.     

Posttranslational Protein Modification: Biosynthetic Control Mechanisms in the Glycosylation of the Major Myelin Glycoprotein by Schwann Cells

The posttranslational processing of the asparagine-linked oligosaccharide chain of the major myelin glycoprotein (P0) by Schwann cells was evaluated in the permanently transected, adult rat sciatic nerve, where there is no myelin assembly, and in the crush injured nerve, where there is myelin assembly. Pronase digestion of acrylamide gel slices containing the in vitro labeled [3H]mannose and [3H]fucose P0 after electrophoresis permitted analysis of the glycopeptides by lectin affinity and gel filtration chromatography. The concanavalin A-Separose profile of the [3H]mannose P0 glycopeptides from the transected nerve revealed the high-mannose-type oligosaccharide as the predominant species (72.9%), whereas the normally expressed P0 glycoprotein that is assembled into the myelin membrane in the crushed nerve contains 82.9-91.9% of the [3H]mannose radioactivity as the complex-type oligosaccharide chain. Electrophoretic analysis of immune precipitates verified the [3H]mannose as being incorporated into P0 for both the transected and crushed nerve. The high-mannose-type glycopeptides of the transected nerve isolated from the concanavalin A-Sepharose column were hydrolyzed by endo-beta-N-acetylglucosaminidase H, and the oligosaccharides were separated on Biogel P4. Man8GlcNAc and Man7GlcNAc were the predominant species with radioactivity ratios of 12.5/7.2/1.4/1.0 for the Man8, Man7, Man6, and Man5 oligosaccharides, respectively. Jack bean alpha-D-mannosidase gave the expected yields of free Man and ManGlcNAc from these high-mannose-type oligosaccharides. The data support the notion that at least two alpha-1,2-mannosidases are responsible for converting Man9GlcNAc2 to Man5GlcNAc2. The present experiments suggest distinct roles for each mannosidase and that the second mannosidase (I-B) may be an important rate-limiting step in the processing of this glycoprotein with the resulting accumulation of Man8GlcNAc2 and Man7GlcNAc2 intermediates. Pulse chase experiments, however, demonstrated further processing of this high-mannose-type oligosaccharide in the transected nerve. The [3H]mannose P0 glycoprotein with Mr of 27,700 having the predominant high-mannose-type oligosaccharide shifted its Mr to 28,500 with subsequent chase. This band at 28,500 was shown to have the complex-type oligosaccharide chain and to contain fucose attached to the core asparagine-linked GlcNAc residue. The extent of oligosaccharide processing of this down-regulated glycoprotein remains to be determined.     

Glycoprotein biosynthesis in quiescent and stimulated thymocytes and a T-cell lymphoma.

Quiescent thymocytes, mitogen-stimulated thymocytes and acute-leukaemic lymphoblasts provide a model for the study of protein glycosylation in quiescent cells, mitotically active non-malignant and malignant cells respectively. The biosynthesis of both complex and high-mannose-type oligosaccharides was monitored by metabolic labelling with [6-3]fucose and [2-3H]mannose. Bio-Gel P6 elution profiles of [6-3H]fucose-labelled glycopeptides showed that quiescent thymocytes and stimulated thymocytes synthesized qualitatively and quantitatively similar glycopeptides; however, higher-molecular-weight glycopeptides were synthesized by the acute-leukaemic lymphoblasts. The amount of [2(-3)H]mannose incorporated into glycopeptide by quiescent thymocytes was less than 10% of that incorporated by stimulated thymocytes. The Bio-Gel P6 elution profile of [2(-3)H]mannose-labelled glycopeptides from acute leukaemic lymphoblasts was qualitatively similar to that of stimulated thymocytes, with about 40% of the radioactivity incorporated into one glycopeptide peak. This glycopeptide was characterized by Bio-Gel P6 and concanavalin A affinity chromatography, radioactive-sugar analysis, sensitivity to alpha-mannosidase and endoglycosidase H and resistance to beta-glucosaminidase as containing a high-mannose oligosaccharide, possible of Man7-8GlcNAc2 structure. Pulse/chase experiments indicated that this high-mannose oligosaccharide was an end product and not a biosynthetic intermediate. It is concluded that higher-molecular-weight fucose-labelled glycopeptides are characteristic of the malignant cell type, and the synthesis of high-mannose oligosaccharide, Man7-8GlcNAc2, in stimulated thymocytes and acute-leukaemic lymphoblasts is associated with mitotically active cells.     

Four unreported types of glycans containing mannose-6-phosphate are heterogeneously attached at three sites (including newly found Asn 233) to recombinant human acid alpha-glucosidase that is the only approved treatment for Pompe disease

Myozyme is a recombinant human acid alpha-glucosidase (rhGAA) that is currently the only drug approved for treating Pompe disease, and its low efficacy means that a high dose is required. Mannose-6-phosphate (M6P) glycosylation on rhGAA is a key factor influencing lysosomal enzyme targeting and the efficacy of enzyme replacement therapy (ERT); however, its complex structure and relatively small quantity still remain to be characterized. This study investigated M6P glycosylation on rhGAA using liquid chromatography (LC)–electrospray ionization (ESI)–high-energy collisional dissociation (HCD) tandem mass spectrometry (MS/MS). The glycans released from rhGAA were labeled with procainamide to improve mass ionization efficiency and the sensitivity of MS/MS. The relative quantities (%) of 78 glycans were obtained, and 1.0% of them were glycans containing M6P (M6P glycans). These were categorized according to their structure into 4 types: 3 newly found ones, comprising high-mannose-type M6P glycans capped with N-acetylglucosamine (GlcNAc) (2 variants, 17.5%), hybrid-type M6P glycans (2 variants, 11.2%), and hybrid-type M6P glycans capped with GlcNAc (3 variants, 6.9%), as well as high-mannose-type M6P glycans (3 variants, 64.4%). HCD-MS/MS spectra identified six distinctive M6P-derived oxonium ions. The glycopeptides obtained from protease-digested rhGAA were analyzed using nano-LC-ESI-HCD-MS/MS, and the extracted-ion chromatograms of M6P-derived oxonium ions confirmed three M6P glycosylation sites comprising Asn 140, Asn 233 (newly found), and Asn 470 attached heterogeneously to nine M6P glycans (two types), eight M6P glycans (four types), and seven M6P glycans (two types), respectively. This is the first study of rhGAA to differentiate M6P glycans and identify their attachment sites, despite rhGAA already being an approved drug for Pompe disease.     

Glycans of synaptosomal plasma membrane glycoproteins from adult rat forebrain: Characterization after fractionation by concanavalin A-Sepharose affinity chromatography

Glycopeptides obtained by exhaustive proteolytic digestion of synaptosomal plasma membranes from adult rat forebraini were separated by affinity chromatography on concanavalin A-Sepharoe. Concanavalin A-binding glycopeptides are essentially made up of mannose and N-acetylglucosamine in a molar ration of 3.45:1, whereas glycopeptides not bound to concanavalin A have a complex monosaccharide composition. By gel filtration on Bio-Gel P-30, concanavalin A-binding glycopeptides appear as low-molecular-weight glycopeptides (migrating like ovalbumin glycopeptides), whereas glycopeptides not bound to concanavalin A behave as high-molecular-weight glycopeptides (migrating like fetuin glycopeptides). Comparison of concanavalin A-binding glycopeptides from rat brain synaptosomal plasma membranes with concanavalin A-binding glycoproteins isolated from the same membrane fraction shows clear differences in monosccharide composition. We demonstrate here that this discrepancy is due to the presence on most concanavalin A-binding glycoprotein subunits of at least two different types of glycan: in addition to the concanavalin A-binding glycans, these glycoprotein subunits carry other glycans which do not interact with concanavalin A. Biological implications of the presence of two (or more) types of glycan on the same polypeptide are discussed.     

Oligosaccharide Chains of Avian RNA Tumor Virus Glycoproteins Contain Heterogeneous Oligomannosyl Cores

Chicken embryo fibroblasts (C/E phenotype) infected with subgroups B and C of the Prague strain of Rous sarcoma virus were radiolabeled with either [6-(3)H]-glucosamine or [2-(3)H]mannose, and virus was purified from the growth medium. The large envelope glycoprotein, gp85, was the only major radiolabeled component of purified virus. Pronase-digested glycopeptides from purified virus were analyzed by a combination of (i) gel filtration with columns of Sephadex G15/G50 and Bio-Gel P4 and (ii) enzymatic digestion of the oligosaccharide chains with specific exoglycosidases and endo-beta-N-acetylglucosaminidases. The rather broad molecular weight distribution (approximately 2,000 to 4,000) for glycopeptides in these studies and previous studies in other laboratories was shown to represent actual heterogeneity in the carbohydrate moieties: (i) the glycopeptides contained both mannose-rich, neutral chains and complex, acidic chains with terminal sialic acid; and (ii) both classes of asparagine-linked carbohydrate structures exhibited heterogeneity in the size of the oligomannosyl core (a mixture of approximately 5 to 9 mannose units for the neutral structures, and 3 or 5 mannose units for the acidic structures). With the [2-(3)H]mannose-labeled glycopeptides from Rous sarcoma virus, Prague strain subgroup C, most of the oligosaccharide chains were high-molecular-weight, acidic structures, with similar numbers of 3-mannose and 5-mannose core structures.     

1H NMR spectroscopy of carbohydrates from the G glycoprotein of vesicular stomatitis virus grown in parental and Lec4 Chinese hamster ovary cells

Carbohydrate moieties derived from the G glycoprotein of Vesicular Stomatitis Virus (VSV) grown in parental Chinese hamster ovary (CHO) cells and the glycosylation mutant Lec4 have been analyzed by high-field ¹H NMR spectroscopy. The major glycopeptides of $\text{CHO}\text{VSV}$ and $\text{Lec4}\text{VSV}$ were purified by their ability to bind to concanavalin A-Sepharose. The carbohydrates in this fraction are of the biantennary, complex type with heterogeneity in the presence of α(2,3)-linked sialic acid and α(1,6)-linked fucose residues. A minor $\text{CHO}\text{VSV}$ glycopeptide fraction, which does not bind to concanavalin A-Sepharose but which binds to pea lectin-agarose, was also investigated by ¹H NMR spectroscopy. These carbohydrates are complex moieties which appear to contain N-acetylglucosamine in β(1,6) linkage. Their spectral properties are most similar to those of a triantennary complex oligosaccharide containing a 2,6-disubstituted mannose α(1,6) residue. Carbohydrates of this type are not found among the glycopeptides of VSV grown in the Lec4 CHO glycosylation mutant.     

Incorporation of [C]Glucosamine and [C]Mannose into Glycolipids and Glycoproteins in Cotyledons of Pisum sativum L

Developing pea cotyledons incorporate radioactivity in vivo from [¹⁴C]glucosamine and [¹⁴C]mannose into glycolipids and glycoproteins. Several different lipid components are labeled including neutral, ionicnonacidic, and acidic lipids. The acidic lipids labeled in vivo appear similar to the polyisoprenoid lipid intermediates formed in vitro in pea cotyledons. Radioactivity from [¹⁴C]glucosamine and [¹⁴C]mannose is also incorporated into glycopeptides. Considerable redistribution of [¹⁴C]mannose into other glycosyl components found in endogenous glycoproteins is observed. An N-acetylglucosamine to asparagine glycopeptide linkage has been isolated from [¹⁴C]glucosamine-labeled glycoproteins.     

Characterization of oligosaccharides of highly purified glycoprotein gC of herpes simplex virus type 1 (HSV-1)

The envelope membrane glycoprotein gC of HSV-1 was purified from Triton X-100 extracts of virus-infected BHK-21 or HEp-2 cells by a single step immuno-affinity column using monoclonal anti-gC antibody. The analysis of the purified [³H]G1cN labeled glycoprotein gC (by gel filtration on Bio-Gel P4) before and after digestion with endo-β-N-acetylglucosaminidase (endo D) indicated that gC contains Asn-linked “complex type” oligosaccharides. No “high mannose” type oligosaccharides were detected. Fractionation of radio-labeled glycopeptides of gC on a column of concanavalin A-sepharose suggested that glycopeptides have “diantennary” and “triantennary” and/or “tetra antennary” structures. Tunicamycin inhibited the incorporation of [¹⁴C]GalN or [³H]GlcN into gC in HSV-1 infected BHK-21 or HEp-2 cells. Gel filtration analysis of [³H]GlcN labeled gC following β-elimination reaction failed to indicate O-glycosidically linked oligosaccharides.     

Affinity chromatography of branched oligosaccharides in rat liver β-glucuronidase

Rat liver microsomal and lysosomal β-glucuronidase-derived glycopeptides were obtained by extensive Pronase digestion followed by N-[¹⁴C]acetylation and desialylation by neuraminidase treatment. These glycopeptides were studied by sequential chromatography on lectin-affinity columns such as concanavalin A, lentil lectin, Phaseolus vulgaris erythroagglutinin, Ricinus communis agglutinin I, Triticum vulgaris agglutinin, Glycine max agglutinin and Ulex europaeus agglutinin. Using serial lectin affinity chromatography approach combined with neuraminidase treatment allowed us to show the unexpected presence of complex tri- and/or tetraantennary type glycans (40.8 and 17.0% for microsomal and lysosomal enzyme, respectively). Moreover, the application of neuraminidase treatment revealed that complex biantennary type glycans, present on lysosomal β-glucuronidase, are almost fully sialylated while the same type of glycans present on microsomal enzyme do not contain sialic acid. Furthermore, the results obtained confirmed that microsomal and lysosomal β-glucuronidases possess high mannose and/or hybrid type glycans (19.6 and 36.6%, respectively), and complex biantennary type glycans (38.9 and 46.4%, respectively).     

Synthesis of sulfated glycoproteins by glial precursor cells

Populations of enriched glial precursor cells and astrocytes isolated from primary cultures of newborn rat brain were used to study the synthesis of sulfated glycoproteins. Both cell types incorporated [³H]glucosamine and [³⁵S]sulfate into carbohydrate side chains of proteoglycans and glycoproteins. The rate of incorporation of [³H]glucosamine into the oligosaccharides and the pattern of distribution of the label into high mannose and complex glycopeptides recovered from the glycoproteins appeared to be similar for the two glial cell types. However, clear differences were noted in the rate of oligosaccharide sulfation activities. Thus the cultures of precursor glia were about four times more active than cultures enriched in astroglia in their ability to incorporate [³⁵S]sulfate into glycoproteins.     

The molecular size of glycans liberated by hydrazinolysis from semliki forest virus proteins

The glycans of well characterized, [6-³H]galactose-labelled glycopeptides, GC-4 from bovine IgG₁ as well as GP-V-2 and GP-V-5 from α₁-acid glycoprotein, were liberated by hydrazinolysis. Molecular weights close to the expected values were observed by gel filtration. Desialated glycans of Semliki Forest virus proteins were likewise liberated by hydrazinolysis and subjected to gel filtration. Metabolically labelled [1-³H]galactose-oligosaccharides of the mixed viral proteins revealed an apparent molecular weight of 1800. The bi-antennary glycan liberated from the reference glycopeptide GC-4 was of 1750 daltons. A mixture of [2-³H]mannose-labelled E₁-and E₂-proteins of the virus contained L-type glycans of 1800 daltons (formerly called A-type), and M-type glycans of 1200 daltons (formerly called B-type). A fraction of the E₃-glycans isolated by affinity chromatography on Concanavalin A-Sepharose showed an average molecular weight of 2150, a value intermediate between the three- and four-antennary glycans liberated from the reference glycopeptides GP-V-5 and GP-V-2. The rest of the E₃-glycans were of 1850 daltons, a value close to the bi-antennary GC-4 glycan. We suggest that the comparatively large size of the E₃-glycans and the exposed position of E₃-proteins on the viral surface may be interrelated.     

Modification of oligosaccharide-lipid synthesis and protein glycosylation in glucose-deprived cells

Incubation of vesicular stomatitis virus-infected glucose-starved baby hamster kidney cells with [³⁵S]methionine results in the synthesis of all viral proteins. However, as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tryptic peptide mapping, the G protein is abnormally glycosylated. Metabolic labeling of the oligosaccharide-lipid precursors with [³H]mannose for 15 min, followed by Chromatographic and enzymatic analysis, indicates that the radiolabeled lipid-linked oligosaccharides are devoid of glucose in contrast to the glucosylated oligosaccharide-lipids synthesized by cells grown in the presence of glucose. Also, in contrast to control cells, examination of the glycopeptide fraction reveals the presence of [³H]mannose-labeled glycopeptides which are resistant to erado-β-N-acetylglucos-aminidase H and are smaller in size than glycopeptides from mature vesicular stomatitis virus. In order to observe these effects, a minimum time of 5 h of glucose deprivation is necessary and the addition of 55 μm glucose or mannose to the medium reverses these effects. These results indicate that vesicular stomatitis virus-infected BHK cells deprived of glucose are unable to glucosylate the oligosaccharide-lipid intermediates and, consequently, are unable to glycosylate the G protein normally.     

Analysis by lectin affinity chromatography of N-linked glycans of BHK cells and ricin-resistant mutants.

Normal baby hamster kidney (BHK) fibroblasts and ricin-resistant (RicR) mutants of BHK cells derived from them were labelled metabolically with [3H]mannose or [3H]fucose. Glycopeptides obtained by digestion of disrupted cells with Pronase were separated by affinity chromatography on concanavalin A-Sepharose. In the normal BHK cells major glycopeptide fractions were obtained consisting of tetra- and tri-antennary sialylated complex glycans, bi-antennary sialylated glycans, and neutral oligomannosidic chains. The majority of bi-antennary chains were shown to contain a fucosyl-(alpha 1-6)-N-acetylglucosaminyl sequence in the core region by their ability to bind to a lentil lectin affinity column. All of the mutant cell lines examined were found to accumulate oligomannosidic glycans in cellular glycoproteins: complex sialylated glycans were either absent or greatly reduced in amount. Analysis of fractions isolated from concanavalin A-Sepharose by Bio-Gel P-4 chromatography and glycosidase degradation indicated that the glycans accumulating in RicR14 cells have the general structure: (formula; see text) and derivatives having fewer alpha-mannosyl units. We have also analysed the glycopeptides released by trypsin treatment from the surface of the normal and mutant cells, as well as those obtained by proteolysis of fibronectin isolated from the medium. The glycopeptide profiles of the cell-surface-derived material and of fibronectin showed for the mutant cells a marked accumulation of oligomannosidic chains at the expense of complex oligosaccharide chains. Hence, the alterations in glycan structure detected in bulk cellular glycoproteins of RicR cells are expressed also in cell surface glycoproteins and in fibronectin, a secreted glycoprotein.     

Glycopeptides from rat brain glycoproteins

The lipid-free protein residue of rat brain tissue was treated with papain to solubilize the heteropolysaccharide chains of the tissue glycoproteins. The glycopeptides were separated into non-dialyzable and dialyzable glycopeptide preparations. Each preparation was then sorted out into groups of glycopeptides by means of electrophoresis and gel filtration. The quantitatively predominant glycopeptides were the alkali-stable glycopeptides (Group A) which accounted for 64% of the glycopeptide carbohydrate recovered from rat brain. Most of the group A glycopeptides appeared in the non-dialyzable preparation. The molecular weight of the glycopeptides of Group A ranged from approximately 5200–3700. The largest glycopeptide molecule in this mixture possessed the highest electrophoretic mobility and contained one fucose, four N-acetylneuraminic acid (NANA), six N-acetylglucosamine, four galactose, and three mannose residues per molecule. The spectrum of glycopeptides isolated in this group showed a progressive decrease in NANA rsidues, NANA and galactose residues, and NANA, galactose, and N-acetylglucosamine residues which could be correlated with a progressive decline in molecular weight and electrophoretic mobility. Some of the glycopeptides in each fraction recovered from this group of glycopeptides contained sulfate ester groups.A second group of glycopeptides (Group C glycopeptides) accounted for 25% of the total glycoprotein carbohydrate recovered from rat brain. These were recoverd from the dialyzable glycopeptide preparation, and resolved into three fractions by column electrophoresis. These glycopeptides do not contain sulfate, are composed predominately of mannose and N-acetylglucosamine, and possess a molecular weight of approximately 3000.Several minor groups of glycopeptides were detected. Alkali-labile glycopeptides (Group B) appeared in the non-dialyzable glycopeptide preparation. The dialyzable glycopeptide preparation contained glycopeptides (Group E) which contained N-acetylgalactosamine and glucose. These had a molecular weight of approximately 2000. Group D glycopeptides recovered from the dialyzable glycopeptide preparation contained variable amounts of NANA, mannose, galactose, N-acetylglucosamine, and sulfate. These possessed a molecular weight of approximately 2900.     

Glycosylation of nascent polypeptide chains in Aspergillus niger

Polysomes were isolated from Aspergillus niger and were characterized on sucrose gradients in several ways. First, they were found to be susceptible to degradation by treatment with RNase or EDTA. Second, they were labeled after treating mycelia with short pulses of [³H]uridine or [³H]leucine prior to polysome isolation. Third, they were capable of stimulating incorporation of [³H]leucine into trichloroacetic acid-precipitable material in a chick reticulocyte cell-free protein-synthesizing system. When isolated [³H]leucine pulse-labeled polysomes were treated with either EDTA-RNase or puromycin, 80–90% of the radioactivity was released, indicating that only the nascent polypeptide chains were labeled. After exposing mycelia for 1 min to [¹⁴C]mannose, the polysomes were exclusively labeled, indicating that initial glycosylation takes place on nascent polypeptide chains. Preincubation of mycelia with 2-deoxyglucose followed by pulse-labeling with [³H]leucine and [¹⁴C]mannose showed that 2-deoxy-d-glucose inhibits both protein synthesis and glycosylation. However, similar preincubation with tunicamycin caused an 80% drop in [¹⁴C]mannose label in the polysomes, but only a 10–20% drop of [³H]leucine label, suggesting that glycosylation of nascent chains in A. niger involves an oligosaccharide-lipid intermediate, since it has been shown that tunicamycin inhibits the synthesis of such an intermediate. When isolated polysomes were placed into an in vitro glycosylating mixture containing Mn²⁺, GDP-[¹⁴C]mannose, and smooth membranes from A. niger nascent chains were labeled. This reaction was shown to be dependent on addition of polysomes to the mixture and was not inhibited by 2-deoxy-d-glucose or tunicamycin. Both in vivo and in vitro glycosylated nascent chains were found to have about the same size range, and so it is suggested that in vitro no new oligosaccharide chains were synthesized, but preexisting chains were extended.     

Abnormal processing of the modified oligosaccharide side chains of phytohemagglutinin in the presence of swainsonine and deoxynojirimycin

Phytohemagglutinin, the glycoprotein lectin of the common bean, Phaseolus vulgaris, has both high-mannose (Man_8-9GlcNAc₂) and modified oligosaccharide side chains. The modified side chains have glucosamine, mannose, fucose, and xylose in the molar ratios 2:3.8:0.6:0.5, and are resistant to hydrolysis by endoglycosidase H. Synthesis and processing of side chains in the presence of 1-deoxynojirimycin, an inhibitor of α-glucosidase, results in the formation of chains which are all alike. They are sensitive to endoglycosidase H, do not contain fucose, and are largely resistant to α-mannosidase. This indicates that they are probably high-mannose chains blocked by terminal glucose residues. Synthesis and processing of side chains in the presence of swainsonine, an inhibitor of α-mannosidase II, results in the formation of normal high-mannose chains, and of modified chains which contain fucose residues, are resistant to endoglycosidase H, and can be distinguished from normal modified chains only by the presence of extra mannose residues.

Processing of the phytohemagglutinin modified chains of PHA under normal conditions involves the attachment of peripheral N-acetylglucosamine residues in the Golgi complex and their subsequent removal in the protein bodies. The attachment of the N-acetylglucosamine residues is largely inhibited by deoxynojirimycin but still occurs in the presence of swainsonine. The results presented in this work show that processing of the asparagine-linked oligosaccharides is under the control of several glycosidases and glycosyltransferases and involves the formation of intermediate products.

     

Reduced mannose incorporation into GDP-mannose and dolichol-linked intermediates of N-glycosylation in hamster liver during vitamin A deficiency

Summary The molecular mechanism of reduced incorporation of radioactively labeled mannose into hamster liver glycoconjugates during the progression of vitamin A deficiency was investigated. In particular the in vivo incorporation of [2-³H]mannose into GDP-mannose, dolichyl phosphate mannose (Dol-P-Man), lipid-linked oligosaccharides, and glycopeptides of hamster liver was examined. Hamsters maintained on a vitamin A-free diet showed a reduction in the incorporation of mannose into GDP-mannose about 10 days before clinical signs of vitamin A deficiency could be observed. The decrease in [2-³H]mannose incorporated into GDP-mannose was accompanied by a reduction in label incorporated into Dol-P-Man, lipid linked oligosaccharides and glycopeptides, which became more severe with the progression of vitamin A deficiency. By the time they reached a plateau stage of growth, hamsters fed the vitamin A-free diet showed a 50% reduction in the amount of [2-³H]mannose converted to GDP-mannose, and the radioactivity associated with Dol-P-Man and glycopeptides was reduced by approximately 60% as compared to retinoic acid-supplemented controls. These results strongly indicate that the reduced incorporation of mannose into lipidic intermediates and glycoproteins observed during vitamin A deficiency is due to impaired GDP-mannose synthesis.Abbreviations Dol-P-Man Dolichyl Phosphate Mannose - Dol-P Dolichyl Phosphate