Synthesis of retinylphosphate mannose in yeast and its possible involvement in lipid-linked oligosaccharide formation.

A membrane fraction from Saccharomyces cerevisiae as well as a mannosyltransferase purified therefrom was shown to catalyze the transfer of mannose from GDPmannose to retinyl phosphate. The product formed has chromatographic and chemical properties characteristic for retinylphosphate mannose. The enzyme requires divalent cations. Mg2+ is more effective than Mn2+ with an optimum concentration around 25 mM. Amphomycin at a concentration of 0.1 mg/ml inhibits the reaction to 50%. Glycosyl transfer was specific for mannose residues from GDPmannose and did not occur with dolichylphosphate mannose nor with UDP galactose; UDPglucose is a poor donor. Formation of retinylphosphate mannose is inhibited by dolichyl phosphate. This observation as well as similarities between retinylphosphate mannose and dolichylphosphate mannose synthesis in respect to ion requirement, inhibition by amphomycin are suggestive that both reactions are catalyzed by one and the same enzyme. In experiments studying the glycosyl donor specificity in the assembly of lipid-linked oligosaccharide intermediates involved in N-glycosylation of proteins, it could be demonstrated that retinylphosphate mannose can replace dolichylphosphate mannose in the final steps of mannosylation.

O-glycosylation in Saccharomyces cerevisiae is initiated at the endoplasmic reticulum.

The first mannose of O-linked oligomannose chains in S. cerevisiae is transferred to Ser/Thr residues via dolichylphosphate mannose. Only this reaction (and not the subsequent reactions requiring GDP-Man) proceeds at the endoplasmic reticulum.

Glycoprotein biosynthesis in Saccharomyces cerevisiae: ngd29, an N-glycosylation mutant allelic to och1 having a defect in the initiation of outer chain formation.

Outer chain glycosylation in Saccharomyces cerevisiae leads to heterogeneous and immunogenic asparagine-linked saccharide chains containing more than 50 mannose residues on secreted glycoproteins. Using a [3H]mannose suicide selection procedure a collection of N-glycosylation defective mutants (designated ngd) was isolated. One mutant, ngd29, was found to have a defect in the initiation of the outer chain and displayed a temperature growth sensitivity at 37 degrees C allowing the isolation of the corresponding gene by complementation. Cloning, sequencing and disruption of NGD29 showed that it is a non lethal gene and identical to OCH1. It complemented both the glycosylation and growth defect. Membranes isolated from an ngd29 disruptant or an ngd29mnn1 double mutant were no longer able, in contrast to membranes from wild type cells, to transfer mannose from GDPmannose to Man8GlcNAc2, the in vivo acceptor for building up the outer chain. Heterologous expression of glucose oxidase from Aspergillus niger in an ngd29mnn1 double mutant produced a secreted uniform glycoprotein with exclusively Man8GlcNAc2 structure that in wild type yeast is heavily hyperglycosylated. The data indicate that this mutant strain is a suitable host for the expression of recombinant glycoproteins from different origin in S. cerevisiae to obtain mammalian oligomannosidic type N-linked carbohydrate chains.

Development and evaluation of a new ELISA for the detection and quantification of antierythropoietin antibodies in human sera.

Assays for the analysis of antierythropoietin antibodies (anti-EPO Abs) currently suffer from a high degree of nonspecificity or are cumbersome and time consuming to perform. They are therefore not well suited for the analysis of large numbers of human sera samples, a task that has become increasingly important due to an increase in the number of patients developing anti-EPO Abs. The objective of this study was to develop and validate a sensitive and specific ELISA for the determination of anti-EPO Abs that would suit these purposes. In this new double antigen bridging ELISA, anti-EPO Abs bind via one site to recombinant human erythropoietin (rhEPO)-biotin immobilized to streptavidin-coated microtiter plates (MTPs) and by a second site to rhEPO labelled with digoxigenin (DIG). The amount of bound antibody is determined using an anti-DIG antibody coupled to peroxidase. A rabbit polyclonal anti-EPO Ab purified by immunoadsorption is used as reference antibody preparation. The dynamic range of this ELISA was 1-75 ng/ml per assay calibrated with the reference antibody preparation. The assay was specific for anti-EPO Abs and did not react with other immunoglobulins (Ig) present in human serum. The lower limit of detection (LLD) of the assay was 0.5 ng/ml, and the lower limit of quantitation (LLQ) was 1.0 ng/ml. Anti-EPO Abs could be detected in the sera of pure red cell aplasia (PRCA) patients. In contrast to previous reports, no anti-EPO Abs could be detected in the sera of patients with systemic lupus erythematosus (SLE), rheumatoid arthritis (RA), Sjogren's syndrome (SS), or in the sera of dialysis patients.

Glycopeptide profiling of human urinary erythropoietin by matrix-assisted laser desorption/ionization mass spectrometry.

The site-specific glycan heterogeneity of human urinary erythropoietin was investigated by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). Owing to the small amount of protein available, a strategy combining optimal sensitivity and specificity was used. Erythropoietin was reduced, S-alkylated and digested with endoproteinase Lys C. The peptides were separated by reversed-phase high-performance liquid chromatography and the molecular masses of the peptides determined by MALDI-MS. The peptides were identified by comparing the experimental masses with the masses predicted from the cDNA derived amino acid sequence. Glycopeptides were identified from the mass spectra based on the peak pattern caused by the glycan heterogeneity. They were further characterized after treatment with neuraminidase and endoproteases. All N-glycosylation sites exhibited fucose-containing complex-type glycans. The N-glycosylation sites at Asn38 and Asn83 are mainly occupied by tetraantennary glycans, whereas Asn24 is occupied by a mixture of bi-, tri- and tetraantennary glycans. A molecular mass glycoprofile for each glycosylation site was established based on the relative peak intensities observed in the MALDI mass spectra of the desialylated glycopeptides.

Purification of GDP mannose:dolichyl-phosphate O-beta-D-mannosyltransferase from Saccharomyces cerevisiae.

The enzyme GDP mannose:dolichyl-phosphate O-beta-D-mannosyltransferase (GDP-Man:DolP mannosyltransferase) catalyzing the reaction: GDP-man + DolP in equilibrium DolP-Man + GDP has been purified from Saccharomyces cerevisiae to homogeneity. The purification was achieved using a combination of column chromatographic methods with preparative gel electrophoresis. The enzyme has an apparent molecular mass of 30 kDa on SDS/polyacrylamide gels. Enzymatic activity could be correlated directly with this band. Antibodies against the transferase were raised in rabbits. The immune serum obtained removed enzymatic activity from a detergent extract of yeast membranes and reacted specifically with the 30-kDa band on immunoblots. Experiments addressing the orientation of this enzyme in the endoplasmic reticulum membrane are presented by using selective trypsin and N-ethylmaleimide treatment.

Dolichyl phosphate-mediated mannosyl transfer through liposomal membranes.

A partially purified (up to 1000-fold) mannosyl transferase that catalyzed the reversible reaction GDP-Man + Dol-P in equilibrium Dol-P-Man + GDP was incorporated into liposomes consisting of soybean lecithin and dolichyl phosphate (Dol-P). The enzyme transferred the mannosyl moiety from external GDP-Man to liposome-associated Dol-P. However, when the liposomes were preloaded with GDP, mannosyl residues were also transferred to the inside, giving rise to internal GDP-Man by the reverse reaction. This transfer of an activated sugar through a membrane required the presence of Dol-P and the enzyme in the liposome. Mannosyl residues were not transferred to the inside when the liposomes were preloaded with ADP or GMP. Amphomycin completely inhibited the formation of Dol-P-Man as well as the transfer of mannose into the liposomes. The results are taken as evidence for the open postulated role of dolichols in sugar translocation through membranes. The data are discussed in relation to glycoprotein synthesis at the endoplasmic reticulum.

Interorganelle transfer and glycosylation of yeast invertase in vitro.

Core glycosylated proteins formed in the yeast endoplasmic reticulum (ER) are transported to the Golgi body, where oligosaccharides are elongated by addition of outer-chain carbohydrate. The transport process is blocked in a temperature-sensitive secretion mutant (sec18) of Saccharomyces cerevisiae, which accumulates core glycosylated invertase (product of SUC2; EC 3.2.1.26) in the ER. To approach the molecular mechanism of this transport process, we have devised a reaction in which core glycosylated invertase, accumulated in sec18 cells, is transferred to the Golgi body in vitro. For this purpose, membranes from sec18, SUC2 cells that are also defective in an outer chain alpha-1----3-mannosyltransferase (mnnl) are mixed with membranes from a strain that contains the transferase but is deficient in invertase (MNNl, delta SUC2). Transfer is detected by the acquisition of outer-chain alpha-1----3-linked mannose residues dependent on both donor and recipient membranes. The reaction is temperature and detergent sensitive and requires ATP, GDP-mannose, Mg2+, and Mn2+, and the product invertase remains associated with sedimentable membranes. Treatment of donor, but not acceptor, membranes with N-ethylmaleimide or trypsin inactivates transfer competence. These characteristics suggest that the ER, or a vesicle derived from the ER, contributes invertase to a chemically distinct compartment where mannosyl modification is executed.

Yeast mannosyl transferases requiring dolichyl phosphate and dolichyl phosphate mannose as substrate. Partial purification and characterization of the solubilized enzyme.

The first mannosyl unit of manno-oligosaccharides of fungal mannoproteins is transferred in a dolichyl-phosphate-dependent reaction sequence to serine/threonine residues of the protein. The two membrane-bound enzymes catalyzing this transfer in the yeast Saccharomyces cerevisiae have been solubilized by detergents. The enzyme transferring mannose from guanosine diphosphate mannose to dolichyl phosphate has been purified 18-fold when based on membrane protein and 140-fold when based on total cell protein. The enzyme transferring mannose from dolichyl phosphate mannose to protein has been purified 48-fold and 380-fold, respectively. A HCl-treated cell-wall mannoprotein from yeast served as acceptor protein for the second enzyme. The solubilized enzyme catalyzing the formation of dolichyl diphosphate mannose has a Km for guanosine diphosphate mannose of 7 x 10(-6) M and is saturated with about 0.15 mM yeast dolichyl phosphate. The metal requirement, pH-optima, and the detergent concentration necessary for optimal activity have been determined for both solubilized enzymes.

Molecular cloning and heterologous expression of N-glycosidase F from Flavobacterium meningosepticum.

N-Glycosidase F (peptide-N4-(N-acetyl-beta-glycosaminyl)asparagine amidase; EC 3.5.1.52) catalyzes the cleavage of N-glycosidically linked carbohydrate chains between N-acetylglucosamine and asparagine. The structural gene was isolated by screening a Flavobacterium meningosepticum genomic DNA library in lambda gt10 with oligonucleotides, deduced from partial amino acid sequences of the protein. A clone with an open reading frame of 1062 bases was obtained. The amino acid sequence reveals a 42-residue-long leader peptide, which shows similarities to the endoglycosidase H-leader with respect to the cleavage site of the signal peptide, but is distinct from the ones known from other Gram-positive or -negative bacteria. The molecular weight of the native protein, derived from the DNA sequence, is in agreement with the molecular weight of the purified protein on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (35,000). Escherichia coli, transformed with a plasmid containing this DNA sequence, expresses N-glycosidase F activity. The enzyme with its natural Flavobacterium promoter and leader peptide is not secreted in E. coli but seems to be associated with cell membranes.

Reconstitution of rabbit muscle aldolase after dissociation and denaturation at alkaline pH.

Tetrameric rabbit muscle aldolase is dissociated to the inactive monomer at strongly alkaline pH (pH greater than or equal to 12). As shown by sedimentation velocity, fluorescence emission, and specific activity, the final profiles of dissociation, denaturation, and deactivation run parallel. Increasing incubation time proves the enzyme to be metastable in the pH range of deactivation. At 10 less than pH less than 12 "hysteresis" of the deactivation-reactivation reaction is observed. Short incubation at pH greater than or equal to 12 leads to high yields of reactivation (greater than or equal to 60%), while irreversibly denatured enzyme protein is the final product after long incubation. The kinetics of reconstitution under essentially irreversible conditions (pH 7.6) can be described by a sequential uni-bimolecular mechanism, assuming partial activity of the isolated subunits. The kinetic constants correspond to those observed for the reactivation after denaturation at acid pH or in 6M guanidine. HCl. Obviously the pH-dependent deactivation and reactivation of aldolase at alkaline pH obeys the general transconformation/association model which has been previously reported to hold for the reconstitution of numerous oligomeric enzymes after denaturation in various denaturants.

Synthesis and possible role of carbohydrate moieties of yeast glycoproteins.

The pathways for protein N- and O-glycosylation in yeast cells are summarized. Evidence is presented that the terminal glucosyl residues of the dolichyl-PP-oligosaccharide intermediate are responsible for decreasing the Km for the peptide to be N-glycosylated. A liposomal model system is introduced that allows the study of a dolichyl phosphate (Dol-P) dependent transmembrane transport of mannosyl residues. The results obtained so far suggest that the mannosylation of Dol-P and the transmembrane translocation of Dol-P-Man are catalysed by the enzyme more or less simultaneously. However, only about 8-10% of the enzyme molecules incorporated into the liposomes seem to carry out the 'coupled' reaction. The glycosylation of carboxypeptidase Y is not required for this protein to reach the vacuole, its target organelle. In the presence of low concentrations of tunicamycin, however, yeast cells do stop growth. This does not seem to be due to the inhibition of secretion of glycoproteins like external invertase. It is postulated that protein glycosylation is crucial for a cell cycle event during the G1 phase.

Saccharomyces cerevisiae mating pheromones specifically inhibit the synthesis of proteins destined to be N-glycosylated.

alpha Factor specifically inhibits the synthesis of N-glycosylated proteins in Saccharomyces cerevisiae mating type a cells but not in alpha cells or in a/alpha diploids. a Factor has the same effect of alpha cells. The synthesis of O-glycosylated proteins is not inhibited. Although the mating pheromones act like a 'physiological tunicamycin', the mechanism of inhibition is different: not the glycosylation of proteins as such but rather the synthesis of those proteins destined to be N-glycosylated is inhibited. Thus none of a number of glycosylating enzymes tested in vitro is reduced in activity in alpha-factor-treated cells. The synthesis of the glycoprotein carboxypeptidase Y, on the other hand, is strongly inhibited by tunicamycin as well as by alpha factor; but only in the former case did carbohydrate-free protein accumulate in the cells. alpha Factor causes maximal inhibition of glycoprotein formation after as little as 30 min, long before all cells in the population are arrested in G1; moreover, release from this inhibition precedes the increase in budding index (resumption of cell division). It is postulated, therefore, that N-glycosylated proteins are required for the G1/S-phase transition in the yeast cell cycle. This is supported by previous reports that first cycle arrest in G1 occurs when (a) tunicamycin is added to growing cultures, and (b) a temperature-sensitive N-glycosylation mutant is shifted to its restrictive temperature.

Structural characterization of glycoprotein carbohydrate chains by using diagoxigenin-labeled lectins on blots.

The carbohydrate structures of blotted glycoproteins can be analyzed by probing them with lectins. Here we describe a method where lectins conjugated with digoxigenin are used in combination with an anti-digoxigenin antibody AP conjugate as a very sensitive detection system for this type of analysis. The specificity of the lectins used, and the sensitivity of the detection system, provide valuable conclusions on the glycan structures. Only small amounts of glycoproteins are required for the analysis. The binding specificity of a set of lectins is demonstrated with various glycoproteins of defined carbohydrate structure. The application of these labeled lectins in combination with specific glycosidases for the characterization of the carbohydrate chains of recombinant tissue plasminogen activator and erythropoietin is presented.

Primary structure of the heterosaccharide of the surface glycoprotein of Methanothermus fervidus.

The outer surface of the cells of the hyperthermophile Methanothermus fervidus is covered by crystalline glycoprotein subunits (S-layer). From the purified S-layer glycoprotein, a heterosaccharide was isolated. The heterosaccharide consists of D-3-O-methylmannose, D-mannose, and D-N-acetylgalactosamine in a molar ratio of 2:3:1 corresponding to a relative molecular mass of 1061.83 Da. 3-O-methylmannose could be partly replaced by 3-O-methylglucose. The primary structure of the glycan was revealed by methylation analysis, by plasma desorption mass spectrometry, and by high field NMR spectroscopy. The purified heterosaccharide is linked via N-acetylgalactosamine to an asparagine residue of the peptide moiety. The following structure is proposed for the heterosaccharide: alpha-D-3-O-MetManp-(1-->6)-alpha-D-3-O-MetManp-((1-->2)-alp ha-D-Manp)3-(1-->4) - D-GalNAc.