Isolation and characterization of glycoproteins from canine tracheal mucus

Self-association of mucin

Aggregation phenomena in aqueous solutions of purified human tracheobronchial mucin have been studied by rheological methods, steady-state fluorescence, quasielastic light scattering, and spin probe techniques. At temperatures below 30 degrees C and concentrations above 15 mg/mL and in the absence of chaotropic agents, mucin solutions are viscoelastic gels. A gel-sol transition is observed at temperatures above 30 degrees C that is manifested by the diminishing storage modulus and a loss tangent above unity throughout the studied frequency range of the oscillatory shear. No decline in the mucin molecular weight is observed by size-exclusion chromatography above 30 degrees C in the absence of redox agents or proteolytic enzymes. Aggregation of hydrophobic protein segments of the mucin chains at 37 degrees C is indicated by QELS experiments. The decreasing polarity of the microenvironment of pyrene solubilized into mucin solutions at temperatures above 30 degrees C, concomitant with the gel-sol transition, shows the hydrophobicity of the formed aggregates. ESR spectra of the fatty acid spin probe, 16-doxylstearic acid indicate that the aggregate-aqueous interface becomes more developed at elevated temperatures.

Evidence for secretion of high molecular weight mucins by canine tracheal epithelial cells in primary culture: effects of select secretagogues in mucin secretion

The purpose of this investigation was to provide evidence for the secretion of high molecular weight mucins, CTM-A and CTM-B, in primary culture of canine tracheal epithelial (CTE) cells. The cells were isolated from tracheas of mongrel dogs by pronase treatment. Primary cultures of the epithelial cells were established using ICN collagen inserts in Dulbecco's modified Eagle's/F12 medium supplemented with growth factors and could be maintained for up to 23 days. The evidence for the mucin secretion in culture medium and their localization in the cells was established by a) positive immunocytochemical staining using specific antibodies developed against purified native as well as deglycosylated CTM-A and CTM-B; b) incorporation of labeled amino acids, followed by electrophoresis and autoradiography detection of glycoconjugates purified from the culture medium; c) comparison of the amino acid compositions of mucin purified from canine tracheal pouch secretions and that purified from the culture medium; and d) Western blot analyses using specific polyclonal antibodies directed against deglycosylated CTM-A and CTM-B. Immunoaffinity purified secreted labeled glycoconjugates were resistant to hyaluronidase treatment. The effects of cyclic AMP (1 x 10(-5) M), dibutyryl cyclic AMP (1 x 10(-5) M), 8-bromocyclic AMP (1 x 10(-5) M), and prostaglandin E1 (1 x 10(-6) M) on mucin secretion by CTE cells were also investigated. Secretion of mucins by CTE cells in culture was considerably more enhanced by 8-bromocyclic AMP than that observed for other secretagogues used in this study.

Mucin-like glycoprotein secreted by cultured hamster tracheal epithelial cells. Biochemical and immunological characterization

We isolated mucin-like glycoproteins from the conditioned medium of primary hamster tracheal epithelial (HTE) cell culture and characterized them biochemically and immunologically. These glycoproteins were purified on Sepharose CL-4B after Streptomyces hyaluronidase treatment and then by CsCl-density-gradient centrifugation in the presence of 4 M-guanidinium chloride. The purified glycoproteins were resistant to digestion by chondroitin AC lyase, heparinase, heparitinase and endo-N-acetylglucosaminidases A, D and H, but susceptible to endo-beta-galactosidase and keratanase. SDS/PAGE demonstrated no contamination by low-molecular-mass proteins. The purified glycoproteins showed a peak buoyant density of 1.56 g/ml in CsCl-density-gradient centrifugation, and contained 10% peptide and 90% carbohydrate by weight. Carbohydrates in these glycoproteins contained N-acetylglucosamine, N-acetylgalactosamine, galactose, fucose, sialic acid and a trace amount of mannose, but no uronic acid. Serine and threonine together accounted for 27% of the total amino acid residues. In addition, the mucin-like glycoproteins exhibited blood-group A and B activities, and very strong inhibitory activity for influenza A virus haemagglutination. With the use of the purified glycoprotein as an antigen, six monoclonal antibodies that stained mucus granules in hamster tracheal epithelium were obtained. We characterized the antibody produced by one of the clones, HM D46. We conclude that HTE cells cultured in the serum-free medium secrete a glycoprotein with physicochemical properties similar to those known in various airways mucins.

Translation of messenger RNA from canine tracheal epithelial cells: identification of mucin core protein

A high-molecular-weight mucin (Mr approximately 11.0 x 10(6)) was purified from canine tracheal pouch secretions. The mucin was deglycosylated by treatment with trifluoromethane sulfonic acid for 8 h at 8 degrees C and subsequently with alpha-N-acetylgalactosaminidase. These treatments almost completely removed the carbohydrate moieties. The amino acid compositions of the deglycosylated and native mucins were similar, indicating that the deglycosylation procedure used did not cause notable degradation of the protein core. Antiserum specific for deglycosylated canine tracheal mucin was produced by immunization of rabbit with the antigen. RNA was isolated from fresh canine tracheal epithelial cells by extraction with guanidine isothiocyanate/hydrochloride and further fractionated by chromatography on oligo(dT)-cellulose to yield poly(A)+ RNA. The poly(A)+ RNA was translated in a rabbit reticulocyte cell-free translation system using [35S]methionine and [3H]leucine as radiolabels. The translation products were analyzed by gel electrophoresis and fluorography before and after immunoprecipitation with the antiserum to deglycosylated mucin. A labeled product of molecular weight 72,000 was present in the immunoprecipitate. When canine liver poly(A)+ RNA was used as control, no radioactivity above background was detected in the immunoprecipitate. It is concluded that the primary translation product of the canine tracheal epithelial cells is a 72,000-D protein and the monomer subunit of the mucin is about 167,000 D. Thus, in the native state, the canine tracheal mucin consists of several associating subunits.

Macromolecular properties and polymeric structure of canine tracheal mucins

Two high-Mr mucus glycoproteins (mucins), CTM-A and CTM-B, were highly purified from canine tracheal pouch secretions, and their macromolecular properties as well as polymeric structure were investigated. On SDS/composite-gel electrophoresis, a diffuse band was observed for each mucin. Polyacrylamide-gel electrophoresis using 6% gels also showed the absence of low-Mr contaminants in the mucins. Comparison of chemical and amino acid compositions revealed significant differences between the two mucins. Using a static-laser-light-scattering technique, CTM-A and CTM-B were found to have weight-average Mr values of about 11.0 x 10(6) and 1.4 x 10(6) respectively. Both mucins showed concentration-dependent aggregation in buffer containing 6 M-guanidine hydrochloride. Under similar experimental conditions, reduced-alkylated CTM-A had an Mr of 5.48 x 10(6) and showed no concentration-dependent aggregation. Hydrophobic properties of the mucins, investigated by the fluorescent probe technique using mansylphenylalanine as the probe, showed the presence of a large number of low-affinity (KD approx. 10(5) M) binding sites. These sites appeared to be located on the non-glycosylated regions of the protein core, since Pronase digestion of the mucins almost completely eliminated probe binding. Reduction of disulphide bonds of CTM-A and CTM-B did not significantly alter the probe-binding properties. Also, addition of increasing NaCl concentrations (0.03-1.0 M) to the buffer caused only a small change in the hydrophobic properties of native and reduced-alkylated mucins. CTM-A was deglycosylated, without notable in the hydrophobic properties of native and reduced-alkylated mucins. CTM-A was deglycosylated, without notable degradation, using a combination of chemical and enzymic methods. On SDS/PAGE the protein core was estimated to have an Mr of approx. 60,000. On the basis of the protein and carbohydrate contents of the major mucin CTM-A, the mucin monomer was calculated to have an Mr of approx. 140,000. The high Mr (11 x 10(6] observed by physical methods is therefore due to self-association of the mucin monomer subunits.

Physicochemical characterization of a minor mucin component from cystic fibrosis tracheobronchial secretions

A minor mucin glycoprotein component (HTM-2) was purified from the tracheobronchial secretions of two cystic fibrosis patients using a protocol established in our laboratory. The secretions were solubilized in 0.1 M Tris-HCl buffer (pH 7.5) containing 0.22 M potassium thiocyanate and fractionated on a Bio-Gel A-5m column, followed by digestion with DNAase, rechromatography on the same column and chromatography on hydroxyapatite which resolved the major mucin (HTM-1) from the minor mucin component (HTM-2). The mucin component HTM-2 was further purified using Superose 6 chromatography. SDS-composite gel (2% polyacrylamide + 0.5% agarose) and 6% polyacrylamide gel electrophoresis showed that the purified HTM-2 was totally free of low-molecular-weight contaminants. Equilibrium density sedimentation centrifugation of purified HTM-2 using CsCl gradients also showed the absence of proteoglycans and other low-molecular-weight proteins. Comparison of carbohydrate and amino acid compositions of the two mucin components indicated that HTM-2 was quite different from the major mucin, HTM-1, reported earlier from our laboratory (Biochemistry, 24, 7334, 1985). This suggested that HTM-2 has a different polypeptide core and is perhaps a different gene product. The effects of 6 M guanidine-HCl and different concentrations of NaCl on the molecular size of HTM-2 and its ability to form aggregates was also investigated using the technique of static light scattering. In buffer containing 6 M guanidine-HCl, HTM-2 had a weight-average molecular weight of approximately 4.5 x 10(6). However, in the presence of buffer containing 0.03, 0.10 or 0.15 M NaCl, the molecular weight of HTM-2 was estimated to be approximately 11 x 10(6). These data suggest aggregation of HTM-2 in the presence of a range of NaCl concentrations. In contrast to HTM-1, which is a more anionic glycoprotein, the apparent molecular size of HTM-2 did not decrease at the higher NaCl concentration.

Polymeric structure of human respiratory mucin: studies on two protein components released upon reduction of disulfide bonds

A major mucus glycoprotein (mucin) was purified from the tracheobronchial secretions of an asthmatic patient. Upon SDS-composite gel electrophoresis, the purified native (non-reduced) mucin gave a single band. SDS-gel electrophoresis on 6% polyacrylamide gels showed the absence of low molecular mass protein contaminants. However, SDS-PAGE (6% gels) of the reduced mucin showed the presence of a major high molecular mass mucin component and two low molecular mass components of 118 and 70 kDa, respectively. The 118 and 70 kDa components were purified by preparative electroelution of the reduced mucin. These components were also separated from the reduced mucin by gel-permeation chromatography on a Superose 6 column. Chemical compositional analyses showed that the 118 kDa component was a glycoprotein while the 70 kDa component was non-glycosylated. The effect of disulfide bond reduction on mucin structure and the hydrophobic probe binding properties of native and reduced mucin were studied using the fluorescent probe technique. Mansylphenylalanine was used as the fluorescent probe. The native mucin showed the presence of a large number of low-affinity (KD approximately 10(-5) M) binding sites for the probe. On the other hand, reduced-alkylated mucin containing the 118 and 70 kDa components showed the presence of additional high-affinity (KD approximately 10(-6) M) binding sites as well as low-affinity binding sites for the probe. Reduced alkylated mucin devoid of the 118 and 70 kDa components showed the presence of only low-affinity binding sites. These observations suggest that the availability of high-affinity probe binding sites upon reduction of mucin disulfide bonds may be either due to binding of the probe to the released component(s) and/or due to noncovalent interaction of the released component(s) with the mucin causing a conformational change in the mucin structure. Thus, the 118 and 70 kDa components appear to be an integral part of the total polymeric structure of the human respiratory mucin.

Evidence of hydrophobic domains in human respiratory mucins. Effect of sodium chloride on hydrophobic binding properties

Hydrophobic binding properties of purified human respiratory mucins were studied by the fluorescence probe technique using mansylphenylalanine (Mns-Phe) as the fluorescent probe. Mucins were purified from tracheobronchial secretions of cystic fibrosis (CF) and asthmatic patients, as well as from individuals with normal lungs, according to a protocol earlier established in our laboratory. Purified mucins were subjected to reduction-alkylation and Pronase digestion to study the effects of these treatments on the hydrophobic properties of the mucins. In addition, the effects of increased NaCl concentration on the hydrophobic properties of native and reduced-alkylated mucins were also investigated. Native mucins showed evidence of a large number of low-affinity (KD approximately 10(-5) M) binding sites for the hydrophobic ligand Mns-Phe and had between 40 and 50 binding sites/mg of mucin. Reduction of mucin using dithiothreitol in the presence of 6 M guanidine hydrochloride and subsequent alkylation with iodoacetamide apparently caused marked conformational changes in the mucin molecules as revealed by the presence of both high-affinity (KD approximately 10(-6) M) and low-affinity (KD approximately 10(-5) M) binding sites for the probe and an increase in the number of probe binding sites. Pronase digestion of the native and reduced-alkylated mucins almost completely eliminated binding of the fluorescent probe to the mucins, showing that the binding sites are on the nonglycosylated, Pronase-sensitive portion of the mucin molecules. Increasing NaCl concentrations (0.03-1.0 M) did not appreciably alter the native mucin-induced Mns-Phe fluorescence, while that of the reduced-alkylated mucin-induced Mns-Phe fluorescence was progressively increased.(ABSTRACT TRUNCATED AT 250 WORDS)

Physical properties of purified human respiratory mucus glycoproteins: effects of sodium chloride concentration on the aggregation properties and shape

The biophysical properties of purified native (nonreduced) mucus glycoproteins (mucins) isolated from lung mucus secretions of cystic fibrosis (CF) patients and subjects with normal lungs were studied using the technique of light scattering. The effects of different NaCl concentrations and 6 M guanidine hydrochloride on the molecular size of mucins, their ability to form aggregates, and their shape were investigated. Under the concentration range studied (0.05-3.5 mg/ml), in buffered 0.03 and 0.01 M NaCl, the CF mucins had higher molecular weights (12.2 x 10(6) to 17.1 x 10(6) and 9.5 x 10(6) to 10.4 x 10(6), respectively) than those observed in buffered 0.15 M NaCl (4.3 x 10(6) to 6.6 x 10(6]. These results were interpreted in terms of CF mucins self-aggregating in buffered 0.03 and 0.01 M NaCl. In contrast, in the both buffered 0.3 and 0.15 M NaCl, the normal respiratory mucins had molecular weights of 6.3 x 10(6) to 8.6 x 10(6), thus suggesting the absence of normal mucin aggregation in buffered 0.03 M NaCl. In the presence of 6 M guanidine HCl both CF and normal mucins had molecular weights of about 5 x 10(6) and showed more extended structure (i.e., larger radius of gyration) than in the presence of 0.03 or 0.15 M NaCl. Studies of the relationship of the light scattering intensity with scattering angle showed that, under the above experimental conditions studied, both CF and normal respiratory mucins were polydisperse flexible coil-shaped molecules. The increased aggregation of CF mucins observed at lower salt concentrations may alter the viscoelastic properties of CF lung mucus secretions.

Transition from normal to hypersecretory bronchial mucus in a canine model of bronchitis: changes in yield and composition

Density-gradient analysis was used to follow the transition from normal to hypersecretory bronchial mucus in a model of bronchitis induced in dogs by chronic exposure to SO2 gas. Aspirates of saline bronchial lavage were obtained by fiberoptic bronchoscopy from dogs before, during a 6- to 9-month exposure period to SO2 gas, and during a recovery period of similar duration. Prior to SO2 exposure, aspirates from all animals had a low yield of nondialyzable macromolecules (15 +/- 6 mg/aspirate) and similar composition. Specifically, epithelial glycoprotein of typical buoyant density was not detected; rather a glycoconjugate of higher buoyant density with features of both proteoglycan and glycoprotein was identified. Neutral lipids were predominant with lesser amounts of phospholipids; no glycolipids were detected. During the SO2 exposure period, aspirates from five of the eight dogs contained components similar in buoyant density to human bronchitic glycoprotein. Glycoprotein isolated from the canine aspirates was similar to glycoprotein isolated from human chronic bronchitic sputum, having the same carbohydrate composition and range of oligosaccharide size. Further, during and after SO2 exposure some aspirates contained appreciable amounts of glycolipids. These data demonstrate substantial similarities in composition between normal human and canine mucus and in mucus isolated from dogs with chronic airway inflammation induced by repeated irritant exposure and from human patients with chronic bronchitis.

Structure of canine tracheobronchial mucin glycoprotein

Canine tracheal mucin glycoprotein was isolated from beagle dogs fitted with tracheal pouches. Following exclusion chromatography on Sepharose CL-4B, noncovalently associated proteins were further resolved by dissociative density gradient centrifugation in CsBr-guanidinium chloride, and the mucin was then extracted with chloroform-methanol. The delipidated high-density product obtained had a nominal molecular weight of about 10(6) and an overall composition characteristic for a mucin glycoprotein, viz., a high content of serine and threonine, about 80% carbohydrate by weight, the absence of mannose or uronic acid, measurable ester sulfate, and a Pronase-resistant domain of molecular weight (1.75-3.0) X 10(5) which contains essentially all of the saccharide residues. Noncovalently bound lipid amounted to 6-10% by weight and was primarily cholesterol and cholesteryl esters. Cleavage of disulfide bonds by performic acid oxidation resulted in the release of a protein (Mr 65,000) not otherwise resolved by sodium dodecyl sulfate gel electrophoresis or the purification scheme.

Establishment and characterization of a cell line derived from bovine tracheal glands

Bovine tracheal submucosal gland cells have been isolated by enzymatic digestion and serially propagated in tissue culture for more than 12 mo. (40 passages). The cells exhibit an epithelioid appearance at confluence and contain alcian blue (pH 2.5)/periodic acid-Schiff-positive material within cytoplasmic granules. By electron microscopy numerous osmiophilic secretory granules are seen. Maximal growth is observed when the cells are grown on human placental collagen-coated culture vessels in medium supplemented with 20% fetal bovine serum. Scintillation spectrometry revealed that radiolabeled precursor (35SO4) was incorporated into high molecular weight molecules and released from cells. Isoproterenol (10(-6) to 10(-3) M) stimulated the release of 35SO4. The maximal response to isoproterenol was completely inhibited by the beta-adrenergic antagonist propranolol. It is concluded that the cultured cells retain features of tracheal gland cells and may serve as a useful model of synthesis and secretion of macromolecules by tracheal gland cells.

Lateral nasal gland secretion in the anaesthetized dog

The effects of pharmacological and nervous stimuli on the flow of secretion from the dog lateral nasal gland following catheterization are described. Drugs were injected close-arterially into the arterial supply to the nose, or intravenously. Cholinergic agonists (pilocarpine, methacholine), given intravenously (I.V.) or intra-arterially (I.A.), and stimulation of the vidian nerve produced a copious flow of secretion which was blocked by atropine. The adrenoceptor agonists phenylephrine (alpha) and salbutamol (beta 2), given I.V. or I.A., and stimulation of the vagosympathetic nerve produced a small but consistent flow of secretion. Histamine (50 micrograms), substance P (0.1 micrograms) and prostaglandin E1 (1-5 micrograms), injected I.A., produced small flows of secretion. Bradykinin (25 ng-50 micrograms), 5-hydroxytryptamine (100 ng-50 micrograms) and vasoactive intestinal peptide (VIP) (10 ng-50 micrograms) did not cause secretion. The total protein content, the composition of secretions as revealed by sodium dodecyl sulphate-polyacrylamide agarose gel electrophoresis, and changes in [Na] and [K] in relation to flow of secretion are described. Differences in ion and protein concentrations, and in protein composition, are described for vidian nerve-induced and vagosympathetically induced secretions. Electron microscopy revealed that the gland contains serous cells in the secretory region, and ducts morphologically similar to the intercalated, striated and excretory ducts of salivary glands.

Isolation and characterization of tracheobronchial mucin from a laryngectomee

A tracheobronchial mucin was isolated from the tracheobronchial secretion of a laryngectomee. It was purified by gel filtration on Sepharose CL-6B in Tris-urea buffer and rechromatography of excluded materials through the same gel matrix. It was homogeneous in 0.7% agarose-2% polyacrylamide electrophoresis under nonreducing conditions. Comparable analysis with 2-mercaptoethanol revealed at least 3 subunits. Based upon recoverable weight, the mucin was composed of 75% carbohydrate, 21% protein, and 3% sulfate. Oligosaccharides obtained by alkaline beta-elimination indicated O-glycosyl linkage to the peptide component. Marked heterogeneity of the carbohydrate side-chains was reflected in the preparation of 20 distinct oligosaccharides ranging in size from 4 to 17 residues.

Monoclonal antibodies as probes for unique antigens in secretory cells of mixed exocrine organs

In the past, it has been difficult to identify the secretory product and control mechanisms associated with individual cell types making up mixed exocrine organs. This report establishes the feasibility of using immunological methods to characterize both the biochemical constituents and regulatory mechanisms associated with secretory cells in the trachea. Monoclonal antibodies directed against components of tracheal mucus were produced by immunizing mice with dialyzed, desiccated secretions harvested from tracheal organ culture. An immunofluorescence assay revealed that of the total 337 hybridomas screened, 100 produced antibodies recognizing goblet cell granules; 64, gland cell granules; and 3, antigen confined to the ciliated apical surface of the epithelium. The tracheal goblet cell antibody described in this report was strongly cross-reactive with intestinal goblet cells, as well as with a subpopulation of submandibular gland cells, but not with cells of Brunner's glands or the ciliated cell apical membrane. The serous cell antibody was not cross-reactive with goblet, Brunner's gland, or submandibular cells, or the ciliated cell apical membrane. The antibody directed against the apical membrane of ciliated cells did not cross-react with gland or goblet cells or the apical membrane of epithelial cells in the duodenum. Monoclonal antibodies, therefore, represent probes by which products unique to specific cells or parts of cells in the trachea can be distinguished. The antibodies, when used in enzyme immunoassays, can be used to quantitatively monitor secretion by individual cell types under a variety of physiological and pathological conditions. They also provide the means for purification and characterization of cell-specific products by immunoaffinity chromatography.

Regulation of the synthesis of mucin glycoproteins in swine trachea explants

Swine tracheal epithelium has been cultured as explants in a chemically defined medium for periods of up to 2 wk. The viability of the explants was shown by the preservation of the ultrastructural features of cells in the epithelial layer and by the active incorporation of radioactive glucosamine and sulfate into secreted mucin glycoproteins. The rate of secretion of mucin glycoprotein was about 0.035 mg per cm2 per d. After initial 24 h lag period was shown to be due to the equilibration of intracellular mucin glycoprotein pools with radioactive precursors. The rate of secretion of glycoprotein showed a linear dependence on the area of the explant, and maximal incorporation was observed at 200 microM glucosamine. A higher concentration of 35SO4, 1000 microM, was required for maximal incorporation of the precursor. Insulin at 0.1 to 1 microgram/ml increased the rate of secretion twofold, whereas 0.1 to 100 micrograms/ml of hydrocortisone and 0.1 to 100 micrograms/ml of epinephrine significantly decreased the rate of secretion. Vitamin A had little or no effect of normal trachea explants at low concentrations, and, at higher concentrations, 10(-5) M, it decreased the secretion of mucin glycoproteins. Vitamin A, at a concentration of 10(-9) M, increased the rate of synthesis of glycoprotein at least fourfold in trachea explants from vitamin A-deficient rats. Mucus secretions collected from the surface of swine trachea and from the culture medium of trachea explants were purified. The mucus was solubilized by reduction and carboxymethylation, and the high molecular weight mucin glycoproteins were purified by chromatography on Sepharose CL-6B columns under dissociating conditions in 2 M guanidine HCl. The mucin glycoproteins purified from swine trachea and from the culture medium of trachea explants were virtually indistinguishable. They showed the same properties when examined by gel electrophoresis and immunoprecipitation. The purified glycoproteins contained about 25% protein, and serine, threonine, and proline were the principal amino acids present. More than 80% of the carbohydride chains in both samples were released by treatment with alkaline borohydride. Nearly the same molar ratio of N-acetylgalactosamine, N-acetylglucosamine, galactose, fucose, sulfate, and sialic acid was found in both preparations.

In vitro labeling of the sialic acid moiety of glycoconjugates with carbon-14

Labeling of sialoglycoproteins with carbon-14 in vitro was performed by reacting the aldehyde groups, generated by mild periodate oxidation of the terminal sialyl groups, with 14C-labeled sodium cyanide to produce the labeled cyanohydrin derivatives (Kiliani reaction). Labeling with tritium was carried out by reduction of the aldehyde groups generated on the sialyl residues with 3H-labeled sodium borohydride following standard procedures. The behavior of both types of labeled specimens of fetuin and ovine submaxillary mucin, individually and in mixtures, was investigated by gel-filtration chromatography, gel electrophoresis, and cesium bromide gradient ultracentrifugation. The labeled sialyl residues were subjected to partial characterization: color yield with the resorcinol and thiobarbituric acid reagents, behavior on ion-exchange chromatography, and susceptibility to mild acid and enzymatic hydrolyses. In addition to these model glycoproteins, this procedure was also utilized to label the sialoglycoproteins present in human tracheobronchial secretions collected from normal subjects and patients with chronic bronchitis. The potential uses of this approach for comparative studies of normal and pathological sialoglycoconjugates available in minute amounts is described. The extension of this approach to the labeling of the galactosyl and N-acetylgalactosaminyl moieties of glycoconjugates following treatment with galactose oxidase is outlined.

Respiratory mucous secretions in patients with cystic fibrosis: relationship between levels of highly sulfated mucin component and severity of the disease

The tracheobronchial secretions from cystic fibrosis patients contained higher levels of protein, DNA and sialic acid than the tracheobronchial secretions from healthy donors. In contrast, the neutral hexose content in CF secretions was strikingly lower than in secretions from normal subjects. The levels of neutral hexose and sialic acid in the CF secretions were found to increase with increasing severity of the disease. The alterations in the levels of these chemical parameters in the secretions of patients with increased disease severity are as a result of increased levels of the mucin content of the secretions, especially of the highly sulfated mucin component. Since mucins are considered, to a large extent, responsible for the viscoelastic properties of the secretions, the enhanced levels of the highly sulfated mucin component in the secretions of the patients with increased disease severity, may contribute to altered rheological properties and hence decreased mucociliary transport of the secretions.

The mechanism of thermal degradation of a high-molecular-weight glycoprotein complex from bovine cervical mucus

Gel-like oestrus bovine cervical mucus can be brought to the point of dissolution by thermal treatment. The glycoprotein complex so produced was isolated on CsCl density gradients, and found to be of a size comparable with that of a complex purified from mucus that had been brought to the point of dissolution by mild mechanical stirring. The latter material (GP-S) had a mol.wt. of 15.9 X 10(6) and was used to study further the effect of thermal treatment. Time and temperature lead to a gradual breakdown of GP-S, which is characterized by a single activation energy of 93.3 kJ/mol (22.3 kcal/mol) over the temperature range of 21-99 degrees C. The process responsible is thermal hydrolysis of peptide bonds, particularly next to aspartic acid residues. This conclusion is consistent with the appearance of aspartic acid as a new N-terminal amino acid and the activation energy of the process. After thermal degradation there is an increase in the buoyant density of GP-S and a change in the amino acid composition. These findings were found to be consistent with the loss of the naked peptide region and the preponderance of aspartic acid residues in this region. Thermal degradation therefore does not involve dispersion of non-covalent bonds, and indeed GP-S is quite unaffected by media commonly used to disperse such bonds.

Structure and function of mucus

Discussing the available evidence a fairly strong case can be made for the existence of a basic glycoprotein unit, characterized by what may be a common protein backbone (Fig. 1). This is far less likely for the carbohydrate portion. The considerably more variability in the amount and composition of the carbohydrate coat and species and organ differences may arise because of this fact. Very large aggregates are built up from the basic unit using cross-links of disulfide bonds either intermolecularly, i.e. directly, or intramolecularly, i.e. indirectly via a possible lectin-like structure which forms its bond with some of the carbohydrate side chains. Structures of the order of 10-100 million molecular weight are to be expected which, being heavily entangled, give rise to the special rheological character of the mucus. In most instances mucus behaves rheologically like a gel. The concentration of glycoprotein in the mucus may be the most important parameter which determines the special rheological features required in a special functional context. A unified point of view, when discussing mucus structure and function, was taken. On the evidence available, it seems well justified to continue to do so.

Purification and composition of colonic epithelial mucin

Colonic mucin was purified from homogenized scrapings of rat colonic epithelial cells using gel filtration and ion-exchange chromatography. High molecular weight water-soluble mucin was separated from low molecular weight proteins by gel exclusion chromatography on Sepharose 4B, and was further separated into two major mucin fractions and several non-mucin fractions on DEAE-cellulose. Fraction IV, the major mucin, was a sulphated glycoprotein with 62% carbohydrate by weight, and high concentrations of serine and threonine. A more acidic mucin, fraction V, had similar composition. Approx. 85% of the sialic acid of fractions IV and V were removed after incubation with Clostridium perfringens neuraminidase. Blood group A but not group H activity was present in fractions III, IV, and V. Ultracentrifugation experiments showed that fraction IV migrated as a single peak, whereas fraction V contained two components. Our study indicates that colonic mucin consists of at least two closely related acidic high molecular weight glycoproteins which can be separated from non-mucin contaminants by ion-exchange chromatography.

Characterization of mucin isolated from rat tracheal transplants

Subcutaneous rat tracheal grafts yield several milligrams of secretions from which a homogeneous mucin fraction was isolated and purified. Histological evidence demonstrated that a normal mucociliary epithelium and mucous secretion were maintained for the 4-6 weeks of the experiment. The collected secretions were initially characterized by column chromatography on Sepharose CL-6B which separated the excluded high molecular weight mucins (unpurified mucin fraction) from most of the serum-type glycoproteins and proteins, including albumin. A reductive alkylation treatment of the unpurified mucin fraction followed by Sepharose CL-4B chromatography removed contaminating protein and most of the mannose-containing material from the mucin fraction. The void volume material from this column produced a single high molecular weight band upon sodium dodecyl sulfate agarose/acrylamide gel electrophoresis. The purified mucin fraction contained 16.5% protein and primarily galactose, N-acetylglucosamine, N-acetylgalactosamine, and sialic acid. This fraction also underwent beta-elimination in the presence of alkaline borohydride, demonstrating the presence of O-glycosidic linkages.

Hydrophobic interaction of fluorescent probes with fetuin, ovine submaxillary mucin, and canine tracheal mucins

The presence of hydrophobic sites in fetuin, ovine submaxillary mucin and two homogeneous canine tracheal mucins was established by fluorescence probe techniques. The interaction between the above-mentioned glycoproteins and two hydrophobic fluorescent compounds, sodium mansate and mansylphenylalanine, was accompanied by an enhancement in fluorescence and a shift of the fluorescence maxima to shorter wavelengths. The introduction of a phenylalanine residue to the mansyl group enhanced the binding affinity of the probe for the hydrophobic sites of these glycoproteins as evidenced by lower values for the dissociation constants. The high molecular weight (581 600) tracheal mucin, which had the highest carbohydrate content (80%) of all the glycoproteins investigated, exhibited the highest fluorescence enhancement and the largest number of binding sites for these fluorescent probes.