Deglycosylation of mucin from LS174T colon cancer cells by hydrogen fluoride treatment

Characterization of the immunologic responses to human in vivo acquired enamel pellicle as a novel means to investigate its composition

Human acquired enamel pellicle is formed by molecules selectively adsorbed onto tooth surfaces. The present work describes the use of monoclonal antibody (mAb) technology as a novel approach to identify micro amounts of components present in pellicle. MAbs were obtained with reactivities against statherin, histatin, mucous glycoprotein 1(MGI), albumin, amylase and human immunoglobulins (Igs), indicating that these are pellicle components, which was further confirmed by immunoblotting. No mAbs against proline-rich proteins (PRPs), lysozyme, mucous glycoprotein 2 (MG2), carbonic anhydrase, lactoferrin or peroxidase were obtained, suggesting that these components are absent, present in low amounts, or exhibit low antigenicity. Further characterization of the binding epitopes of some of th e obtained anti-MGO, anti-statherin and anti-histatin mAbs were carried out and the biological relevance is discussed. The results open up the possibility that immunization with human pellicle and mAbs production can be employed to identify hitherto unknown constituents of pellicle.

Characterization of the rabbit homolog of human MUC1 glycoprotein isolated from bladder by affinity chromatography on immobilized jacalin

The urinary bladder is lined by transitional epithelium, the glycocalyx on the luminal surface has interesting properties and is implicated in protective functions. Glycoconjugates are major components of the glycocalyx, but their biochemical nature is not well understood. Previous studies on rabbit bladder indicated the presence of significant levels of sialoglycoproteins compared to glycosaminoglycans in the epithelium. In this study, rabbit explant cultures were radiolabeled by precursor sugars or amino acids and a major lectin-reactive glycoprotein of rabbit bladder mucosa was isolated by affinity chromatography on jacalin-agarose. The radiolabeled glycoprotein was purified to homogeneity by a second cycle on the lectin column, followed by gel filtration and density gradient centrifugation. The average molecular mass of the glycoprotein was estimated to be 245 kDa and 210 kDa by gel filtration and SDS-PAGE, respectively. Its buoyant density was 1.40 g/ml, suggesting a carbohydrate content of approximately 50%. The percent distribution of glucosamine-derived tritium label in sialic acid, galactosamine, and glucosamine was 30, 52, and 18, respectively. The glycoprotein consisted entirely of small sialylated and neutral oligosaccharides O-glycosidically linked to serine and threonine residues. The same glycoprotein could be immunoprecipitated with an antibody against the carboxy terminal 17 amino acid peptide of human MUC1 mucin glycoprotein. This suggests that this mucin glycoprotein is the rabbit homolog of MUC1 glycoprotein, which has been previously established to be a component of human bladder urothelium and has been purified from human urine and biochemically characterized.

Purification and characterization of the MUC1 mucin-type glycoprotein, epitectin, from human urine: structures of the major oligosaccharide alditols

The MUC1 glycoprotein, epitectin, a component of the human bladder epithelium, was purified from human urine. Sedimentation equilibrium analysis and gel filtration using polysaccharide or protein standards revealed a polydisperse preparation with molecular weights ranging from about 0.9 to 1.3 x 10(6). This suggests that in the native state epitectin exists as aggregates of three or four monomer units of 350-400 kDa. Epitectin was found to have significant affinity to hexyl-, octyl- or phenyl agarose indicating that hydrophobic interactions and possibly carbohydrate-carbohydrate interactions may be responsible for the self-association. Chemical and enzymic deglycosylation of [125I]-labeled urine epitectin and metabolically labeled H.Ep.2 epitectin resulted in extremely polydisperse products. The buoyant densities of epitectin purified from urine and H.Ep.2 cells were found to be 1.39-1.40 g ml(-1), suggesting that the total carbohydrate content of these preparations is not significantly different. The O-linked saccharides of epitectin were fractionated by HPLC and analyzed by permethylation and FAB-MS. The neutral saccharides from both sources contain three common structures, namely Gal1 --> 3GalNAc, GlcNAc1 --> 6 (Gal1 --> 3) GalNAc and Gal1 --> 4GlcNAc --> 6 (Gal1 --> 3)GalNAc. The sialic acid of urine epitectin consisted entirely of N-acetylneuraminic acid. The two sources of epitectin, in vitro labeled on sialic acid, were found to have the same sialyl oligosaccharides but in different proportions. Metabolic labeling and N-glycanase susceptibility experiments firmly established the presence of N-linked saccharides in epitectin as minor components. The remarkable similarities in the total carbohydrate content, the carbohydrate composition and structures of saccharides between epitectin from urine, a non-malignant source, and H.Ep.2 cells is surprising in view of the prevailing view that MUC1 glycoproteins of cancer cells are underglycosylated compared to those produced by non-malignant cells.

The carboxyl-terminal sequence of the human secretory mucin, MUC6. Analysis Of the primary amino acid sequence

The distribution of MUC6 suggests that its primary function is protection of vulnerable epithelial surfaces from damaging effects of constant exposure to a wide range of endogenous caustic or proteolytic agents. A combination of genomic, cDNA. and 3' rapid amplification of cDNA ends techniques was used to isolate the carboxyl-terminal end of MUC6. The 3' nontandem repeat region contained 1083 base pairs of coding sequence (361 amino acids) followed by 632 base pairs of 3'-untranslated region. The coding sequence consists of two distinct regions; region 1 contained the initial 270 amino acids (62% Ser-Thr-Pro with no Cys residues), and region 2 contained the COOH-terminal 91 amino acids (22% Ser-Thr-Pro with 12% Cys). Although region 1 had no homology to any sequences in GenBank, region 2 had approximately 25% amino acid homology to the COOH-terminal regions of human mucins MUC2, -5, and -5B and von Willebrand factor. The shortness of region 2 would leave little of the peptide backbone exposed to a potentially hostile environment. Antibody studies suggest that MUC6 in its native form exists as a disulfide-bonded multimer. The conservation of the 11 cysteine positions in region 2 suggests the importance of this short region to mucin polymerization.

Inhibition of mucin synthesis by benzyl-alpha-GalNAc in KATO III gastric cancer and Caco-2 colon cancer cells

Previous studies from our laboratory have shown that benzyl-alpha-GalNAc inhibits the glycosylation of mucin in colon cancer cells. In this study, we determined whether benzyl-alpha-GalNAc inhibits mucin glycosylation in KATO III gastric cancer cells. We also examined its effects on expression of mucin antigens, and compared the mucins made by KATO III with those of a colonic cancer cell line, Caco-2. Results of these experiments suggest that benzyl-alpha-GalNAc (2 mM) inhibited [3H]glucosamine labelling of mucins by 82% in KATO III and by 70% in Caco-2. For both cell lines, the mucin secreted in the presence of benzyl-alpha-GalNAc was less acidic. Both cell lines secreted benzyl-oligosaccharides, but those from KATO III (8-9 sugars) were larger than those from Caco-2 (6-7 sugars). In mucins purified from the medium of treated cells, peripheral carbohydrate antigens (sialyl Lex in KATO III and terminal fucose in Caco-2) were decreased (compared with control), while core carbohydrate antigens (T antigen in both cell lines and sialyl Tn in Caco-2) were increased. Western blots of cell homogenates showed differences between KATO III and Caco-2 in MUC 1 apomucin protein antigens, in sialyl Lex and in sialyl Tn antigens. We conclude that benzyl-alpha-GalNAc does inhibit the glycosylation of mucin in KATO III gastric cancer cells as in human colon cancer cells, but that alterations in mucin antigens occur in a cell line-specific manner.

Expression cloning of gastric mucin complementary DNA and localization of mucin gene expression

BACKGROUND & AIMS

Secretory mucins play an important role in gastric cytoprotection and are derived from a heterogeneous family of genes. The aim of this study was to determine the specific type and location of mucin gene expression in the human stomach.

METHODS

Expression cloning was performed by screening a human gastric complementary DNA expression library with antisera against deglycosylated gastric mucin. RNA analysis and immunohistochemistry were used to quantify and localize mucin gene expression.

RESULTS

Sequencing of positive clones revealed two clones containing tandem repeats. The first contained a 169-amino acid repeat and was named MUC6 (as previously described). The second contained the same 8-amino acid repeat consensus sequence (APTTSTTS) as complementary DNAs previously isolated from a tracheobronchial complementary DNA library and was labeled MUC5 (or MUC5AC). RNA analysis indicated that the gastric epithelium contains high levels of MUC5 and MUC6 messenger RNA with little or no MUC2, MUC3, and MUC4 messenger RNA. Immunohistochemical analysis showed that surface mucous cells of the cardia, fundus, and antrum expressed MUC5 peptide. In contrast, MUC6 peptide expression was limited to mucous neck cells of the fundus, antral-type glands of the antrum and cardia, and Brunner's glands of the duodenum.

CONCLUSIONS

MUC5 and MUC6 represent major secretory mucins in the stomach and are localized to distinct cell types.

The human MUC2 mucin apoprotein appears to dimerize before O-glycosylation and shares epitopes with the 'insoluble' mucin of rat small intestine

Rabbit antiserum against a synthetic peptide corresponding to a tandemly repeated amino acid sequence in the human intestinal mucin apoprotein MUC2 was used in immunoprecipitation to study the biosynthesis of MUC2 in the colon-carcinoma cell line LS 174T. Under non-reducing conditions, two bands were precipitated, the smaller with an apparent size of about 700 kDa on SDS/PAGE. When analysed by two-dimensional electrophoresis after reduction, the larger band migrated to the same position as the smaller band and was interpreted as a putative disulphide-bond-stabilized dimer. Pulse-chase experiments showed only the monomer after 5 min and the appearance of the putative dimer after 30 min. The MUC2 apoprotein was also precipitated by antisera against the HF-deglycosylated peptides of the two highly glycosylated domains of the 'insoluble' mucin complex of rat small intestine [Carlstedt, Herrmann, Karlsson, Sheehan, Fransson and Hansson (1993) J. Biol. Chem. 268, [18771-18781]. Endoprotease Lys-C cleavage of the immunopurified apoprotein gave a large fragment of about 250 kDa that was detected by both the antiserum against the MUC2 tandem repeat and one of the glycopeptide antisera. This supports the view that the 'insoluble' mucin of rat small intestine is encoded by the Muc2 gene, as recently indicated by a partial cDNA sequence [Hansson, Baeckström, Carlstedt and Klinga-Levan (1994) Biochem. Biophys. Res. Commun. 198, 181-190] and that parts of the apoprotein are conserved between the species. A lectin from the snail Helix pomatia that detects terminal alpha-GalNAc residues did not bind to the monomer or putative dimer, suggesting that O-glycosylation starts after dimerization. The results indicate that the biosynthetic pathway of the MUC2 mucin may be similar to that of the von Willebrand factor with which MUC2 shares sequence similarities at its C- and N-termini.

Localization of mucin (MUC2 and MUC3) messenger RNA and peptide expression in human normal intestine and colon cancer

BACKGROUND/AIMS

Several studies have reported Northern blot data showing that mucin is expressed in a tissue-specific manner. To determine whether expression is limited to specific cell types within these tissues requires histological analysis.

METHODS

Both immunocytochemistry and in situ hybridization were used to identify cell types expressing the MUC2 and MUC3 mucins in the human small intestine, colon, and colon carcinoma.

RESULTS

In the normal small intestine and colon, an antibody recognizing the MUC2 apomucin stained goblet cells. In contrast, an antibody recognizing the MUC3 apomucin stained both goblet and absorptive cells. Consistent with this, in situ hybridization showed MUC2 messenger RNA (mRNA) only in goblet cells and MUC3 mRNA in both goblet and absorptive cells. In several samples of moderately well-differentiated colon cancer, MUC2 and MUC3 showed distinct patterns of expression, but the expression level of each was reduced compared with levels in normal tissue; there was considerable tumor-to-tumor and cell-to-cell variability using both mucin antibodies and complementary DNA probes.

CONCLUSIONS

Individual mucin genes have distinct patterns of expression within mucin-producing tissues, suggesting that the various mucin gene products play distinct functional roles.

A novel human airway mucin cDNA encodes a protein with unique tandem-repeat organization

Highly specific affinity-purified polyclonal antibodies against deglycosylated human tracheobronchial mucin was used to select immunoreactive clones from a Uni-ZAP cDNA expression library prepared from normal human tracheal mRNA. The largest of three positive clones, designated pAM1, which reacted strongly with the polyclonal antibodies, was further characterized. Sequence analyses revealed a partial 941 bp cDNA that encoded a 313-amino-acid polypeptide. Bases 3-892 consisted of imperfect 41-nucleotide tandem repeats (CCAGGAGGGGACACCGGGTTCACGAGCTGCCCACGCCCTCT) that encoded a unique polypeptide with two types of consensus repeats, TSCPRPLQEGTRV and TSCPRPLQEGTPGSRAAHALSRRGHRVHELPTSSPGGDTGF. The overall composition of the deduced amino acid sequence matched that expected for a mucin protein core and is rich in serine, threonine, proline, glycine and alanine (approximately 51%). Northern blots probed with the mucin cDNA exhibited intense polydisperse hybridization bands with RNA isolated from normal human trachea and cystic-fibrosis bronchus. The data indicate that mucin encoded by clone pAM1 represents a unique type of peptide organization which has not been described in mucin cDNAs reported thus far.

Biosynthesis of two distinct types of mucin in HM3 human colon cancer cells

Mucins, high-M(r) glycoproteins with a large amount of O-glycosidically linked carbohydrate, protect the colonic epithelial surface and are altered in ulcerative colitis and colon cancer. At least two mucin genes, MUC2 and MUC3, are expressed at high levels in the human intestine. As an experimental model for studying the biosynthesis of human intestinal mucins, we used HM3 colon cancer cells. When mature mucins labelled with [3H]glucosamine or [3H]threonine were analysed by gel filtration, it was found that secreted mucins (M(r) > 10(8) were larger than soluble cellular mucins (M(r) approx. 5 x 10(6)). Only secreted mucin was sensitive to reduction. Both MUC2 and MUC3 proteins, identified by labelling with [3H]threonine or [35S]cysteine and immunoprecipitation with antibodies to synthetic mucin peptides, were already of large size (M(r) > 180,000) by the earliest labelling time (5 min). The MUC3 precursor was completely degraded by trypsin, but the MUC2 precursor had a trypsin-resistant fragment of M(r) approx. 240,000 containing threonine and cysteine. The trypsin-resistant MUC2 fragment contained N-linked carbohydrate, as indicated by a decrease in size as a result of peptidyl N-glycosidase digestion or tunicamycin treatment of HM3 cells. These results show that HM3 colon cancer cells produce at least two distinct human intestinal mucins. They also indicate that the mechanisms of biosynthesis of intestinal mucins differ from those of other mucin-like glycoproteins that have been studied.

Structural features of the low-molecular-mass human salivary mucin

The low-molecular-mass human salivary mucin has at least two isoforms, MG2a and MG2b, that differ primarily in their sialic acid and fucose content. In this study, we characterize further these isoforms, particularly their peptide moieties. Trypsin digests of MG2a and MG2b yielded high- and low-molecular-mass glycopeptides following gel filtration on Sephacryl S-300. The larger glycopeptides from MG2a and MG2b had similar amino acid compositions and identical N-terminal sequences, suggesting common structural features between their peptides. An oligonucleotide probe generated from the amino acid sequence of the smaller glycopeptide from MG2a was employed in Northern-blot analysis. This probe specifically hybridized to two mRNA species from human submandibular and sublingual glands. A cDNA clone selected from a human submandibular gland cDNA expression library with antibody generated against deglycosylated MG2a also hybridized to these two mRNA species. In both cases, the larger mRNA was polydisperse, and the hybridization signal was more intense in the sublingual gland. In addition, the N-terminal amino acid sequence of the larger glycopeptide was found to be part of one of the selected MG2 cDNA clones.

Human tracheobronchial mucin: purification and binding to Pseudomonas aeruginosa

Colonization of the respiratory tract with Pseudomonas aeruginosa is a serious problem in cystic fibrosis and seriously ill hospitalized patients. Human tracheobronchial mucin (HTBM), the major glycoprotein of human tracheobronchial secretions, is known to interact with this pathogen, which may then be cleared by mucociliary action. However, the mechanism of interaction is not known. To understand this process, pure HTBM was isolated from tracheobronchial secretions of a laryngectomee. Following initial fractionation on Sepharose CL-2B, the HTBM-containing fraction was subjected to reductive methylation and then gel filtration. Pure HTBM was employed in an overlay binding assay to identify the bacterial adhesin(s) and mucin receptors that participate in mucin-P. aeruginosa interactions. An approximately 16-kDa nonpilus protein component(s) of P. aeruginosa was found to be the adhesin(s) for HTBM. The mucin receptor for the 16-kDa component(s) was found in the peptide moiety. This study confirms that P. aeruginosa utilizes the nonpilus adhesin(s) to bind to HTBM. Identification of the specificity of the HTBM-P. aeruginosa interactions can lead to a better understanding of the predominance of P. aeruginosa colonization in individuals with cystic fibrosis.

Evidence for different human tracheobronchial mucin peptides deduced from nucleotide cDNA sequences

Highly glycosylated regions or glycopeptides were obtained by proteolysis of human tracheobronchial mucins. They were chemically deglycosylated and the resulting products were used to raise a rabbit antiserum. This antiserum specifically recognized the superanuclear region of respiratory and colonic goblet cells as areas around and below the nucleus of mucin-secreting cells in tracheobronchial mucous glands. A lambda gt11 cDNA library constructed from human tracheobronchial mucosa was screened with this antiserum. Ten positive clones were obtained from screening half of the library (about 10(6) recombinants). The antibodies were purified by absorption to each positive clone; some purified antibodies were specific for goblet cells and others recognized both goblet and mucous cells, indicating that there is differential cellular expression of mucin peptides. The total or partial amino acid sequences deduced from these cDNA clones could be classified into three groups. The first group contained repetitive sequences of eight amino acid residues, almost perfectly identical, and in different arrangements. The second type exhibited homology at their amino and carboxy-terminal ends. The last group had no distinctive feature except for a high content of hydroxy amino acids typical of mucins. Five different clones could correspond to the carboxy-terminal end of tracheobronchial apomucins. These results indicate that human tracheobronchial apomucins consist of a family of different proteins.

Differential mucin gene expression in human pancreatic and colon cancer cells

The purpose of this study was to determine the quantity and nature of the mucins synthesized and secreted by four different pancreatic cancer cell lines. Well- to moderately-differentiated SW1990 and CAPAN-2 human pancreatic cancer cells were found to produce more high-Mr glycoprotein (HMG) than less-differentiated MIA PaCa-2 and PANC-1 cells. Most of the labelled HMG was secreted within 24 h. The results of chemical and enzymic degradation, ion-exchange chromatography and density-gradient centrifugation indicated that the HMG in SW1990 and CAPAN-2 cells has the properties expected for mucins, whereas much of the HMG in MIA PaCa-2 and PANC-1 cells may not be mucin, but proteoglycan. These results are consistent with immunoblots and Northern blots showing the presence of apomucin and apomucin mRNA in SW1990 and CAPAN-2 cells, but not in MIA PaCa-2 and PANC-1 cells. The Western blots and Northern blots also show that SW1990 and CAPAN-2 cells, like breast cancer cells, have the mammary-type apomucin and mRNA coded by the MUC1 gene, but lack the intestinal type apomucin and mRNA coded by the MUC2 gene. In contrast, the colon cancer cell lines tested in culture express apomucin and mRNA coded by MUC2 but not by MUC1.

Multiple apomucin translation products from human respiratory mucosa mRNA

Poly(A)-rich RNA was purified from a pool of five human tracheobronchial mucosa. After in vitro translation in a reticulocyte lysate and immunoprecipitation of the translated products, using either a polyclonal antiserum or a monoclonal antibody to deglycosylated respiratory mucin peptides, the products were characterized by SDS/PAGE. The respiratory mucin precursors migrated as a very large smear from almost the top of the resolving polyacrylamide gel to an area corresponding to a molecular mass of about 100 kDa. After hybridization with mucin cDNA probe TH 29 described by Crepin et al. [Crepin, M., Porchet, N., Aubert, J. P. & Degand, P. (1990) Biorheology 27, 471-484] respiratory mucin mRNAs also appeared polydisperse. Although degradation or incomplete translation of high-molecular-mass mRNA cannot be entirely ruled out, these results suggest that human respiratory apomucins consist of a family of peptides which share some common epitopes. This possibility is in agreement with (a) the diversity of mucin precursors observed previously with pulse/chase experiments performed with explants of human respiratory mucosa and (b) the polydispersity of secreted respiratory mucins observed by electron microscopy.

Molecular cloning of cDNAs derived from a novel human intestinal mucin gene

A human small intestinal lambda gt11 cDNA library was screened with antibodies to deglycosylated small intestinal mucin. Four partial cDNA clones were isolated that define a novel human mucin gene. These include two partial cDNA clones, SIB 124 and SIB 139, that contain 51 nucleotide tandem repeats which encode a seventeen amino acid repetitive peptide with a consensus sequence of HSTPSFTSSITTTETTS. SIB 139 hybridized to messages produced by small intestine, colon, colonic tumors and also by high mucin variant LS174T colon cancer cells. The gene from which cDNAs SIB 124 and SIB 139 are derived (proposed name MUC 3) maps to chromosome 7, distinct from other known human mucin genes.