Effects of rabbit gastrointestinal mucins and dextran on hydrochloride diffusion in vitro

We compared a viscous fingering formation of hydrochloric acid (HCl) in rabbit corpus, antral and duodenal mucins and with dextran under neutral and acidic conditions with respect to relative viscosity, molecular mass, and carbohydrate composition. The effect of desialyzation of duodenal mucin on the viscous fingering formation of HCl was also examined. HCl (0.1 N) was injected into 1% solutions of mucins and dextran and a subsequent viscous fingering formation was assessed based on an influx volume rate of HCl. A low influx volume rate indicates a high ability of the solutions to produce viscous fingers. The influx volume rate of HCl was lowest in duodenal mucin followed bl corpus mucin, antral mucin, and dextran at pH 7. The influx volume rate of HCl was inversely correlated with the relative viscosity of the solution. Maximum molecular masses were large in the order of corpus, antral, and duodenal mucins, and they were larger than dextran T2000. Rabbit gastrointestinal mucins were very polydisperse system. Duodenal mucin contains more sialic acid than gastric mucins; the influx volume rate of HCl increased in desialylated duodenal mucin. It is suggested that the higher ability of gastric mucins to prevent HCl diffusion than dextran were due to the differences in the molecular mass. The ability of duodenal mucin to prevent HCl diffusion was probably attributed to its high sialic acid content, which may reflect a physiological role of duodenal mucin in the duodenum that has to deal with HCl influx from the stomach.     

Purification and characterization of a membrane-bound and a secreted mucin-type glycoprotein carrying the carcinoma-associated sialyl-Lea epitope on distinct core proteins.

Two mucin-type glycoproteins detected by the monoclonal antibody C50, which reacts with the carcinoma-associated sialyl-Lewis a and sialyl-lactotetraose epitopes, were found in secreted and solubilized materials from the colon carcinoma cell line COLO 205. The larger glycoprotein (H-CanAg; heavy cancer antigen) was predominantly found in extracts of cells grown in vitro or as nude mice xenografts whereas the smaller species (L-CanAg; light cancer antigen) was the major component in spent culture medium and serum from grafted mice. Using detergent in the extraction buffer doubled the yield of H-CanAg, suggesting that this glycoprotein is membrane bound whereas the yield of L-CanAg was relatively unaffected. The two glycoproteins were purified from xenograft extracts and spent culture medium using perchloric acid precipitation, monoclonal antibody affinity purification, ion exchange chromatography, and gel filtration. Both glycoproteins were unaffected by reduction and alkylation in guanidine HCl. Using sodium dodecyl sulfate-polyacrylamide gel electrophoresis, relative molecular masses were estimated to be 600-800 kDa for H-CanAg and 150-300 kDa for L-CanAg. Carbohydrate analysis revealed that the CanAg glycoproteins were highly glycosylated (81-89% carbohydrate by weight), carrying carbohydrate chains with average lengths of 13-18 sugars which were rich in fucose and sialic acid (2-3 residues/chain for each sugar). L-CanAg isolated from spent medium was glycosylated to a higher degree than its counterpart from xenograft extract. Immunochemical studies of the intact glycoproteins showed that both H-CanAg and L-CanAg expressed the monoclonal antibody-defined, sialic acid-containing carbohydrate epitopes CA203 and CA242 as well as the Lewis a blood group antigen whereas only H-CanAg appeared to carry the sialyl-Lewis x epitope. The amino acid compositions were typical of mucins, containing high amounts of serine, threonine (more than 25% together), and proline (11-18%). Significant differences in amino acid composition between H-CanAg and L-CanAg were found. A rabbit antiserum against the cytoplasmic C-terminal part of the MUC1 gene product, core protein of the carcinoma-associated polymorphic epithelial mucin (PEM) and DU-PAN-2, reacted with H-CanAg. After deglycosylation with trifluoromethanesulfonic acid, H-CanAg but not L-CanAg was recognized by the monoclonal antibodies SM-3 and HMFG-2, directed to the tandem repeat of the PEM apoprotein. However, these antibodies which react with PEM from mammary carcinomas without prior deglycosylation were unable to recognize intact H-CanAg, probably as a consequence of a more extensive glycosylation of this glycoprotein.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and characterization of goblet-cell mucin of high Mr from the small intestine of sheep.

Crude soluble mucus from sheep small intestine was freed of nearly all the nucleic acid contaminants by precipitation with protamine sulphate and treatment with nucleases. After removal of non-covalently bound proteins by equilibrium density-gradient centrifugation in CsCl, a high-Mr glycoprotein was isolated by repeated h.p.l.c. from the partially purified mucin. The high degree of purity of the high-Mr mucin was borne out by (a) the observation of a single boundary on analytical ultracentrifugation in the presence of 5M-guanidinium chloride and (b) the observation of apparent monodispersity on sedimentation-equilibrium analysis. The Mr of the highly purified mucin, determined by sedimentation equilibrium, was 5.0 (+/- 0.1) X 10(6) and was concentration-independent. Finally, only goblet cells and the mucus blanket lining the intestinal epithelial cells were immunofluorescent when guinea-pig anti-(highly purified mucin) serum was used in an indirect immunofluorescence assay. The above antiserum reacted with apparently equal strength with goblet cells and with free mucin in abomasum, caecum and colon. The chemical composition of the glycoprotein was 66% carbohydrate and 34% protein, 45% of the latter being composed of valine and threonine. The glycoprotein migrated anodally on immunoelectrophoresis and contained 7.1% (w/w) sulphate. Neutral hexoses accounted for nearly half of the total carbohydrate content, followed by galactosamine and glucosamine. Whereas fucose and sialic acid were present in only small amounts, uronic acid was not detectable in the highly purified mucus glycoprotein.     

Hydrogen ion diffusion in dog gastric mucus glycoprotein: effect of associated lipids and covalently bound fatty acids

The effect of neutral lipids, glycolipids and phospholipids associated with dog gastric mucus glycoprotein, and that of covalently bound fatty acids on the ability of glycoprotein to retard the diffusion of hydrogen ion was investigated. Purified mucus glycoprotein in its native form, placed between equimolar (0.155M) solutions of HCl and NaCl in a specially designed two-compartment chamber, caused a 90% reduction in permeability to hydrogen ion when compared with a layer of NaCl. Extraction of associated lipids lead to a 68% increase in permeability of the glycoprotein to hydrogen ion, while removal of the covalently bound fatty acids increased further the diffusion rate by 6%. Reassociation of the delipidated glycoprotein with its neutral lipids reduced the permeability to hydrogen ion by 34%, an 11% reduction was obtained with glycolipids, and 23% with phospholipids. Since neutral lipids account for 47% of the glycoprotein lipids, glycolipids 41.1% and phospholipids 11.9%, the quantitative decrease in permeability of the delipidated glycoprotein following its reassociation with phospholipids is 2.7 times greater than that of neutral lipids and 7.3 times greater than that of glycolipids.     

Degradation of pig gastric and colonic mucins by bacteria isolated from the pig colon

Mucin degradation was studied with one Clostridium (RS42) and two Bacteroides (RS2 and RS13) strains isolated from the pig colon mucosa. Mucins from pig colon and stomach were prepared in their subunit forms for use as growth substrates, and the loss of the individual sugars from the mucins was measured after bacterial growth. Colonic mucin was more resistant to degradation than gastric mucin. The strains differed in their competence in degrading the mucins. Carbohydrate plus sulfate removal from gastric mucin varied from 63 to 76% for RS2, 37 to 46% for RS13, and 37 to 53% for RS42. All three strains removed more fucose (67 to 87%) and less sulfate (22 to 63%) than the average carbohydrate plus sulfate loss. Under the same conditions of growth, a mixed pig fecal culture removed 78% of sulfate and 96% of each sugar. Of the two major glycoprotein types present in the subunit pig gastric mucin preparation (R. A. Stanley, S. P. Lee, and A. M. Roberton, Biochim. Biophys. Acta 760:262-269, 1983), the less highly sulfated mucin was more susceptible to RS42 degradation. The degradation of gastric mucin by RS2 was not affected by glucose or high sulfate concentrations in the growth medium. The results show that the three strains of colon bacteria are capable of significant hydrolysis of mucin carbohydrate and that the extent of degradation seen with pure cultures is determined in part by the subunit glycoprotein type(s) present in the mucin.     

Degradation of pig gastric and colonic mucins by bacteria isolated from the pig colon.

Mucin degradation was studied with one Clostridium (RS42) and two Bacteroides (RS2 and RS13) strains isolated from the pig colon mucosa. Mucins from pig colon and stomach were prepared in their subunit forms for use as growth substrates, and the loss of the individual sugars from the mucins was measured after bacterial growth. Colonic mucin was more resistant to degradation than gastric mucin. The strains differed in their competence in degrading the mucins. Carbohydrate plus sulfate removal from gastric mucin varied from 63 to 76% for RS2, 37 to 46% for RS13, and 37 to 53% for RS42. All three strains removed more fucose (67 to 87%) and less sulfate (22 to 63%) than the average carbohydrate plus sulfate loss. Under the same conditions of growth, a mixed pig fecal culture removed 78% of sulfate and 96% of each sugar. Of the two major glycoprotein types present in the subunit pig gastric mucin preparation (R. A. Stanley, S. P. Lee, and A. M. Roberton, Biochim. Biophys. Acta 760:262-269, 1983), the less highly sulfated mucin was more susceptible to RS42 degradation. The degradation of gastric mucin by RS2 was not affected by glucose or high sulfate concentrations in the growth medium. The results show that the three strains of colon bacteria are capable of significant hydrolysis of mucin carbohydrate and that the extent of degradation seen with pure cultures is determined in part by the subunit glycoprotein type(s) present in the mucin.     

Identification of the mucin core protein by cell-free translation of messenger RNA from bovine submaxillary glands

Bovine submaxillary mucin was purified and subjected to chemical deglycosylation by treatment at 20 degrees C with either anhydrous hydrogen fluoride or trifluoromethane sulfonic acid. Virtually all of the sialic acid, galactose, fucose, and over 90% of the N-acetylhexosamines were removed by these treatments. The amino acid compositions of the deglycosylated and native mucins were similar indicating that chemical deglycosylation did not cause significant degradation of the protein. Antiserum specific for the deglycosylated bovine submaxillary mucin was produced by immunization of rabbits with the deglycosylated mucin. RNA was isolated from bovine submaxillary glands by extraction with guanidine hydrochloride and further fractionated by chromatography on oligo(dT)-cellulose to yield poly(A)+ mRNA. The poly(A)+ mRNA was translated in a rabbit reticulocyte cell-free translation system using [35S]methionine, [3H]leucine, [3H]threonine, [3H]proline, or [3H]serine as radiolabel and the translation products were analyzed by gel electrophoresis and fluorography before and after immunoprecipitation with the antiserum. A labeled product of molecular weight 60,000 was present in the immunoprecipitates obtained in the absence but not in the presence of the unlabeled competitor deglycosylated mucin. It is concluded that the primary translation product of the bovine submaxillary gland gene is a 60,000-dalton protein and that the monomer subunit of the mucin is about 170,000. Thus, in the native state the mucin consists of several self-associating subunits.     

Effect of sucralfate on the viscosity and retardation of hydrogen ion diffusion by gastric mucus glycoprotein

The effect of an antiulcer drug (sucralfate) on the viscosity and the ability of pig gastric mucus glycoprotein to retard the diffusion of hydrogen ions was investigated. Preincubation with sucralfate produced a marked enhancement in the glycoprotein viscosity. This enhancement was concentration-dependent and at 1.0 X 10(-3) M sucralfate a 60% increase in viscosity was attained. Permeability measurements revealed that sucralfate caused a substantial improvement in the ability of the glycoprotein to retard the diffusion of hydrogen ions. At 1.0 X 10(-3) M sucralfate, permeability decreased by 25% and a 43% reduction was obtained with 1.0 X 10(-3) M sucralfate. It is suggested that sucralfate, by increasing the viscosity of the glycoprotein and by improving its ability to retard the diffusion of hydrogen ions, strengthens the integrity of gastric mucus.     

A novel approach for chemically deglycosylating O-linked glycoproteins. The deglycosylation of submaxillary and respiratory mucins.

A new approach for removing O-glycosidically linked carbohydrate side chains from glycoproteins is described. Periodate oxidation of the C3 and C4 carbons in peptide-linked N-acetylgalactosamine (GalNAc) residues generates a dialdehyde product which, under mild alkaline conditions, undergoes a beta-elimination which releases carbohydrate and leaves an intact peptide core. The pH and time dependence, and intermediates of the elimination, have been extensively followed by carbon-13 NMR spectroscopy and amino acid analysis using ovine submaxillary mucin (OSM) as the substrate. The deglycosylation of OSM is complete and provides apomucin in high yield with an amino acid composition identical to the starting material. Carboxymethylated OSM when deglycosylated by this method gives an apomucin with an apparent molecular weight of ca. 700 x 10(3). The molecular weight is the same as that calculated for the peptide core of the starting mucin, demonstrating the absence of peptide core cleavage. This contrasts with the use of trifluoromethanesulfonic acid (TFMSA), which generates apomucin products of lower molecular weights. Oligosaccharide side chains substituted at C3 of the peptide-linked GalNAc residue are resistant to the oxidation and elimination. Glycoproteins containing these more complex side chains can be deglycosylated by pretreatment with TFMSA under mild (0 degree C) conditions, which removes peripheral sugars (while leaving the peptide-linked GalNAc residue intact), followed by oxidation and beta-elimination. Studies on the deglycosylation of porcine submaxillary mucin and human tracheobronchial mucin indicate that this approach provides more efficient removal of carbohydrate and less peptide core degradation than a more vigorous (25 degrees C) treatment with TFMSA alone. 13C NMR spectroscopic studies and carbohydrate analysis of the deglycosylation intermediates of the human mucin indicate that certain sialic acid containing and N-acetylglucosamine-containing oligosaccharides have elevated resistance to TFMSA treatment at 0 degrees C. By the use of neuraminidase, repeated mild TFMSA treatments, and multiple oxidations and beta-eliminations, the human mucin can be nearly completely deglycosylated. It is expected that all mucins and most glycoproteins containing O-glycosidic linkages can be readily and nearly completely deglycosylated using this combined approach.     

Isolation and partial characterization of a soluble mucin in human pancreatic juice.

Morphological and histochemical abnormalities in pancreatic mucin occur in many pancreatic disorders. However, the composition of pancreatic mucin is poorly understood. Purified mucin was isolated from pure pancreatic juice by sequential chromatography on Sepharose CL-2B and CL-4B followed by CsCl density gradient ultracentrifugation. The mucin preparation consists of 24% protein and 73% carbohydrate. Reduction of the macromolecule (greater than 2 x 10(6)) by mercaptoethanol resulted in the formation of subunits of molecular weight 500,000 and released several small molecular weight proteins, including a glycoprotein of an average molecular weight of 116,000. Cellulose acetate electrophoresis separated the mucin into three species of different staining properties for periodic acid-Schiff reagent and Alcian blue, suggesting the presence of microheterogeneity with respect to sulphation and sialation. Threonine, serine, and proline composed 48% of the total amino acids, while the oligosaccharide moiety contained N-acetylglucosamine, N-acetylgalactosamine, fucose, galactose, sialic acid, and sulphate. We also detected the presence of C16:0 and C18:0 fatty acids which were probably noncovalently bound to the pancreatic mucin.     

Purification and chemical characterization of the major glycoprotein of avian myeloblastosis virus.

The major glycoprotein of avian myeloblastosis virus (AMV) has been purified to an apparent state of homogeneity by gel filtration on a Sepharose 4B column in the presence of 6 m guanidine hydrochloride followed by dialysis against distilled water and then extraction with chloroform-methanol. The AMV glycoprotein remains soluble in the aqueous phase whereas contaminating proteins precipitate, either upon dialysis against distilled water or after treatment with chloroform-methanol.Carbohydrate, represented by glucosamine, mannose, galactose, fucose, and sialic acid, constitutes 40% of the weight of AMV glycoprotein. Glucosamine is the major carbohydrate component whereas fucose and sialic acid are present in relatively low amount. Amino acid analysis indicates a relatively high content of aspartic and glutamic acid, serine, threonine, and glycine. Based on SDS-polyacrylamide gel electrophoresis, a molecular weight value of 77,500 ± 500 was determined for AMV glycoprotein.     

The isolation and characterization of the high-molecular-weight glycoprotein from pig colonic mucus.

1. A high-molecular-weight glycoprotein constitutes over 80% by weight of the total glycoprotein from water-soluble pig colonic mucus. 2. It was isolated from from nucleic acid and non-covalently bound protein by nuclease digestion followed by equilibrium centrifugation in a CsCl gradient. 3. The glycoprotein has the following composition by weight: fucose 10.4%; glucosamine 23.9%; galactosamine 8.3%; sialic acid 9.9%; galactose 20.8%; sulphate 3.0%; protein 13.3%; moisture about 10%. 4. The native glycoprotein has the high mol.wt. of 15 X 10(6). 5. Reduction of the native glycoprotein with 2-mercaptoethanol results in a glycoprotein of mol.wt. 6 X 10(6). 6. Pronase digestion removes 29% of the protein (3% of the glycoprotein) but none of the carbohydrate. 7. The molecular weight of the Pronase-digested glycoprotein is 1.5 X 10(6), which is halved to 0.76 X 10(6) on reduction with 2-mercaptoethanol. 8. The contribution of non-covalent interactions, disulphide bridges and the non-glycosylated peptide core to the quaternary structure of the glycoprotein are discussed and compared with the known structure of pig gastric glycoportein.     

Sialic acid is an essential moiety of mucin as a hydroxyl radical scavenger

In this work, we examined the antioxidant role of mucin, a typical sialic acid containing high-molecular weight glycoprotein. The function of mucin as a hydroxyl radical (.OH) scavenger was characterized using bovine submaxillary gland mucin (BSM). Non-treated BSM effectively protected DNA from the attack of .OH; however, desialylated BSM lost this potential. Moreover, we estimated the scavenging effects of BSM against .OH generated by UV irradiation of hydrogen peroxide using ESR analysis. Our results indicate that BSM has .OH scavenging ability the and sialic acid in mucin is an essential moiety to scavenge .OH.     

The carbohydrate moiety of the activator protein for glucosylceramide beta-glucosidase

SAP-2 is a family of heat-stable, acidic glycoproteins which stimulate enzymatic hydrolysis of glucosylceramide. We studied the carbohydrate moieties of a ConA-binding form of SAP-2. The protein contained glucosamine, galactose, mannose, and fucose; galactosamine and sialic acid were not detectable. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and silver staining showed three bands of 6.5, 8.5, and 10 kDa. After deglycosylation with peptide N-glycosidase, SAP-2 eluted more slowly from the C4 column and showed a single band of 4 kDa. From carbohydrate analysis it was evident that deglycosylation had removed more than 90% of the sugars. These data indicate that SAP-2 possesses N-linked complex or hybrid type oligosaccharide chains. The specific activity of the deglycosylated protein in the glucosidase stimulation assay was unaffected.     

Determination of the carbohydrate composition of mammalian glycoproteins by capillary gas chromatography/mass spectrometry

A technique to determine the carbohydrate composition of glycoproteins using capillary gas chromatography/mass spectrometry (electron impact) with selected ion monitoring is described. This method entails hydrolysis with methanolic-HCl followed by formation of trimethylsilyl methylglycoside derivatives, extraction of the carbohydrate derivatives into hexane, and GC/MS analysis. For those carbohydrates that are present in animal glycoproteins including fucose, mannose, galactose, glucosamine, galactosamine, and N-acetylneuraminic acid (sialic acid), the sensitivity of this assay was approximately 1-3 pmol and the assay was linear over a 100-fold range. The carbohydrate compositions determined on small quantities (1-10 pmol) of various glycoproteins including human transferrin and alpha-1 acid glycoprotein, fetuin, and ovalbumin were identical to their reported carbohydrate content and compositions. Major advantages of this technique include the time required to complete the sample preparation and analysis (less than 8 h), the sensitivity and specificity of the assay, and the fact that all carbohydrate moieties, including sialic acid, can be quantitated in a single hydrolysate of a glycoprotein.     

Prostaglandin effect on the physical properties of gastric mucus glycoprotein and its susceptibility to pepsin

The effect of 16,16-dimethyl prostaglandin E2 (DMPGE2) on gastric mucus glycoprotein viscosity, permeability to hydrogen ion and degradation by pepsin was investigated. Preincubation with DMPGE2 produced a marked enhancement in the glycoprotein viscosity. The increase was concentration dependent and at 2.6 X 10(-5)M DMPGE2 reached a value of 178%. Permeability measurements revealed that 2.6 X 10(-7)M DMPGE2 increased the retardation ability of the glycoprotein to hydrogen ion by 10%, while 22% increase was obtained with 2.6 X 10(-4)M DMPGE2. The results of peptic activity assay showed that DMPGE2 had no inhibitory effect on the rate of glycoprotein proteolysis, and actually a small stimulatory influence was consistently observed. The results suggest that prostaglandins beneficially affect the physical properties of mucus glycoprotein which are considered to be essential for the protective function of gastric mucus.     

Subunit structure of deglycosylated human and swine trachea and Cowper's gland mucin glycoproteins

Summary The oligosaccharide chains in human and swine trachea and Cowper's gland mucin glycoproteins were completely removed in order to examine the subunit structure and properties of the polypeptide chains of these glycoproteins. The carbohydrate, which constitutes more than 70% of these glycoproteins, was removed by two treatments with trifluoromethanesulfonic acid for 3 h at 3° and periodate oxidation by a modified Smith degradation. All of the sialic acid, fucose, galactose, N-acetylglucosamine and N-acetylgalactosamine present in these glycoproteins was removed by these procedures.The deglycosylated polypeptide chains were purified and characterized. The size of the monomeric forms of all three polypeptide chains were very similar. Data obtained by gel filtration, release of amino acids during hydrolysis with carboxypeptidase B and gel electrophoresis in the presence of 0.1% dodecyl sulfate showed that a major fraction from each of the three mucin glycoproteins had a molecular size of about 67 kDa. All of the deglycosylated chains had a tendency to aggregate. Digestion with carboxypeptidases showed that human and swine trachea mucin glycoproteins had identical carboxyl terminal sequences, -Val-Ala-Phe-Tyr-Leu-Lys-Arg-COOH. Cowper's gland mucin glycoprotein had a similar carboxyl terminal sequence, -Val-Ala-Tyr-Leu-Phe-Arg-Arg-COOH. The yield of amino acids after long periods of hydrolysis with carboxypeptidases showed that at least 85% of the polypeptide chains in each of the deglycosylated preparations have these sequences. These results suggested that the polypeptide chains in these deglycosylated mucin glycoprotein preparations were relatively homogeneous.The deglycosylated polypeptide chains as well as the intact mucin glycoproteins had blocked amino terminii. The purified polypeptide chains were digested with trypsin-TCPK, and S. aureus V8 protease and the resulting peptides were isolated by gel electrophoresis in the presence of 0.1% dodecyl sulfate and by HPLC. Two partial amino acid sequences from swine trachea mucin glycoprotein, two partial sequences from human trachea mucin glycoprotein and three partial sequences from Cowper's gland mucin glycoprotein were determined. The partial amino acid sequences of the peptides isolated from swine trachea mucin glycoprotein showed more than 70% sequence homology to a repeating sequence present in porcine submaxillary mucin glycoprotein. Five to eight immunoprecipitable bands with sizes ranging from about 40 kDa to 46 kDa were seen when the polypeptide chains were digested with S. aureus V8 protease. All of the bands had blocked amino terminii and differed by a constant molecular weight of about 1.5 kDa. These data suggest that the polypeptides were formed by cleavage of glutamic acid residues present at regular intervals in the chains of all three mucin glycoproteins. These large immunoreactive peptides were formed by the removal of smaller peptides from the carboxyl terminal end of the deglycosylated mucin glycoprotein chains. Taken collectively, these findings indicate that the polypeptide chains in these mucin glycoproteins are very similar in subunit structure and that there is a high degree of homology between their polypeptide chains.     

Sequential deglycosylation and utilization of the N-linked, complex-type glycans of human alpha1-acid glycoprotein mediates growth of Streptococcus oralis

Streptococcus oralis is the agent of a large number of infections in immunocompromised patients, but little is known regarding the mechanisms by which this fermentative organism proliferates in vivo. Glycoproteins are widespread within the circulation and host tissues, and could provide a source of fermentable carbohydrate for the growth of those pathogenic organisms with the capacity to release monosaccharides from glycans via the production of specific glycosidases. The ability of acute phase serum alpha1-acid glycoprotein to support growth of S.oralis in vitro has been examined as a model for growth of this organism on N-linked glycoproteins. Growth was accompanied by the production of a range of glycosidases (sialidase, N-acetyl-beta-D-glucosaminidase, and beta-D-galactosidase) as measured using the 4-methylumbelliferone-linked substrates. The residual glycoprotein glycans remaining during growth of this organism were released by treatment with hydrazine and their analysis by HPAEC-PAD and MALDI demonstrated extensive degradation of all glycan chains with only terminal N-acetylglucosamine residues attached to asparagines of the protein backbone remaining when growth was complete. Monosaccharides were released sequentially from the glycans by S.oralis glycosidases in the order sialic acid, galactose, fucose, nonterminal N-acetylglucosamine, and mannose due to the actions of exo-glycosidic activities, including mannosidases which have not previously been reported for S.oralis. All released monosaccharides were metabolized during growth with the exception of fucose which remained free in culture supernatants. Direct release of oligosaccharides was not observed, indicating the absence of endo-glycosidases in S.oralis. We propose that this mechanism of deglycosylation of host glycoproteins and the subsequent utilization of released monosaccharides is important in the survival and persistence of this and other pathogenic bacteria in vivo.     

Partial deglycosylation of blood-group-specific glycoproteins.

The time course for the partial deglycosylation of blood-group-specific glycoproteins from human ovarian-cyst fluids with 0.25 M-H2SO4/acetic acid and 6 M-HCl in methanol was studied. Either reagent readily removed about 80% of the carbohydrate from the glycoproteins to leave non-diffusible glycopeptides that contain N-acetylgalactosamine as the predominant sugar. Some changes in amino acid distribution were observed during the deglycosylation, which were attributed to an accelerated break-up of the nonglycosylated regions of the parent glycoprotein. The N-acetylgalactosaminyl-peptides isolated were judged to be polydisperse by gel filtration, and ion-exchange chromatography divided the glycopeptide population into several fractions with differing amino acid compositions. A Lumbricus terrestris hexosaminidase preparation was successful in removing almost all the remaining sugar from the glycopeptides, but caused further rupture of the peptide. When a per O-acetylated glycoprotein was treated with the H2SO4/acetic acid reagent the glycopeptide contained, in addition to N-acetylgalactosamine, about 50% of the sialic acid present in the parent glycoprotein, indicating that most of this sugar is located near the peptide end of the carbohydrate chains.     

Characterization and comparison of the major glycoprotein from three strains of Rous sarcoma virus.

The major glycoprotein g2 was purified from three strains of Rous sarcoma virus, representing subgroups A, B, and C. Carbohydrate analysis showed that glucosamine, mannose, galactose, fucose and sialic acid constitute 40% of the weight of the subgroup A glycoprotein and 15% of the subgroup B and C glycoproteins. The molar ratios of sugars were very similar and amino acid compositions were similar but not identical for the three glycoproteins. Glycosidase digestions of subgroup A and C glycoproteins suggested the presence of two types of oligosaccharide chains, the complex serum type, with terminal sequences sialic acidα-Galβ-GlcNAcβ- and the high mannose type with terminal α-linked mannosyl residues. After removal of 70% of the carbohydrate by glycosidases, subgroup A glycoprotein contained only glucosamine and mannose, in the molar ratio 2.0:1.3. The sequence of sugar release was consistent with oligosaccharide structures such as those which have been described for other glycoproteins. The plant lectins concanavalin A and wheat germ agglutinin were shown to interact strongly with the g2 glycoprotein from viruses of all three subgroups.