Tanja R. E. Stadie

A highly immunogenic peptide motif within the tandem repeat domain of MUC1 mucin is assumed to be exposed during development of breast cancer due to altered O-glycosylation. To elucidate the structural aspects of these changes, we have isolated and analysed the integrated or secretory MUC1 glycoforms from carcinoma cell lines or solid tumors and from human milk. The buoyant densities measured in CsCl gradients for MUC1 glycoforms from cancer cells revealed heterogeneity of the physicochemical species and a significant reduction of their carbohydrate contents compared to MUC1 from skim milk. Immunoreactivity patterns of MUC1 glycoforms from tumor or T47D cells exhibited a lack of fucosylated Lewis blood-group-related antigens and the appearance of core-type antigen sialyl(NeuGl)-TF, Gal beta 1-3(NeuGl alpha 2-6)GalNAc. Structural chemistry of MUC1 oligosaccharides demonstrated that the cancer-associated glycoforms carry mainly sialylated trisaccharides NeuAc alpha 2-3Gal Beta 1-3GalNAc or NeuAc alpha 2-6(Gal beta l-3)GalNAc, exhibit a concomitant decrease in the ratio of GlcNAc/GalNAc, a reduction or disappearance of L-fucose, and a partial substitution of N-acetylneuraminic acid by the N-glycolylated variant. On comparison to the secretory MUC1 in human milk, the glycoforms on human milk fat globule membranes showed apparently identical patterns of O-linked oligosaccharides with a preponderance of neutral polylactosamino-glycans. During serum-free cultivation of T47D cells over 4 weeks, the expression of secretory MUC1 glycoforms was inconsistent based on the decreasing contents of sialic acid and on the concomitant increase of immunodetectable TF antigen.

A synthetic peptide [TAP25, (T1aAPPAHGVT9S10APDT14RPAPGS20)T1bAPPA5b] corresponding to one repeat (T1a-S20) and five overlapping amino acids (T1b-A5b) of the MUC1 core protein served as an acceptor substrate for in vitro glycosylation. TAP25 was glycosylated using the detergent-solubilized UDP-GalNAc:polypeptide N-acetylgalactosaminyltransferases from the breast carcinoma cell line T47D, the colon carcinoma cell line HT29 and from human premature skim milk. The glycosylated peptides were isolated by ultrafiltration, purified by reverse-phase HPLC and further analysed by liquid secondary ion mass spectrometry (LSIMS). Three different glycosylation species, mono-, di- and triglycosylated peptides were identified. Automated Edman sequencing and LSIMS of proteolytic fragments independently revealed the sites of GalNAc incorporation and confirmed that the threonine residues Thr9 and Thr1b are the preferred sites of glycosylation independent of the enzyme source, while Thr14 remained non-glycosylated even with the enzyme preparation from milk. In addition, evidence was obtained that at least 20% of the glycosylated peptides exhibited GalNAc incorporation at Ser20. On the basis of kinetic studies a preferred sequence of GalNAc addition to the three acceptor sites has been concluded (Thr9-->Thr1b-->Ser20). Although Thr14 within the PDTRP motif of the tandem repeats remained non-glycosylated, the introduction of GalNAc into adjacent positions significantly decreased the immunoreactivity of antibodies SM-3, HMFG-1 and HMFG-2 defining overlapping epitopes of this motif. It is assumed that glycosylation at Thr9, Thr1b and Ser20 distorts the peptide conformation of the binding epitope.

mAb BW835 (IgG1) has been generated to breast cancer cell lines by alternating injections of MCF-7 or SW-613 cells and has been demonstrated to be of value in the serodiagnosis of mammary carcinoma. BW835 defines a carbohydrate epitope on integrated or secreted MUC1 glycoforms from carcinoma cells and human milk. To identify BW835-reactive glycopeptides on MUC1, proteolytic fragments of the mucin obtained by digestion with the Gly-C-specific endopeptidase IV from papaya corresponding to low molecular mass fragments (< 10 kilodaltons) of the tandem repeat domain were screened. A glycosylated fragment (glycopeptide 17) containing the mAb HMFG-2-defined epitope was highly reactive to BW835 antibody, while nonglycosylated tandem repeat peptide TAP25 or its in vitro-glycosylated N-acetylgalactosamine (GalNAc) derivatives were unreactive. Glycopeptide 17 bound to peanut agglutinin and to a Thomsen-Friedenreich antigen (TF alpha)-specific mAb (A78-G/A7). Binding of BW835 to glycopeptide 17 or to MUC1 was competitively inhibited by peanut agglutinin and by the synthetic glycopeptides TF alpha Ser or TF alpha Thr but not by their beta-anomers. Evidence for site specificity of binding by BW835 to glycopeptide 17 was revealed by demonstrating nonreactivity of the antibody to other TF alpha-expressing glycoproteins with peptide moieties lacking MUC1-specific motifs at putative glycosylation sites. The epitope of BW835 was localized to threonine within the VTSA-peptide motif by site-specific enzymatic beta-galactosylation of the synthetic tandem repeat peptide TAP25-GalNAc1 TAPPAHGVT(-O-alpha GalNAc)SAPDTRPAPGSTAPPA. This is the first report on a TF alpha-specific mAb that shows a strict peptide sequence dependency of binding.