The isolation and characterization of complementary DNAs (cDNAs) which code for an epithelial antigen aberrantly expressed in human breast tumor tissue are described here. The only information regarding the primary structure of this potentially important antigen has been a 20-amino-acid repeat motif. We now report the complete amino acid sequences of different forms of the human epithelial tumor antigen as deduced from the nucleotide sequence of isolated non-repeat cDNAs. The diversity of protein forms is generated by a series of alternative splicing events that occur in the regions located upstream and downstream to a central tandem repeat array. Isolated cDNAs coding for the upstream region show that differential usage of alternative splice acceptor sites may generate two protein forms containing putative signal peptides of varying hydrophobicities. The complexity of possible antigen forms is further compounded by alternative splicing events occurring in the region 3' to the repeat array. The isolated cDNAs 3' to the tandem repeats indicate that whereas one mRNA transcript is colinear with the gene, and defines an open reading frame (ORF) containing 160 amino acids downstream to the repeat array, a second cDNA correlates with a mRNA that is generated by a series of splicing events. The deduced amino acid sequence of the spliced cDNA contains an ORF that is identical for 149 amino acids downstream to the repeat array with the amino acid sequence of the unspliced cDNA. At this point it diverges and continues for an additional 179 amino acids. The sequence contains a highly hydrophobic 28-amino-acid peptide, located towards the carboxyl terminus, that may correspond to a transmembrane region. The cDNAs and deduced amino acid sequences, presented here, define the complete amino acid sequences of the epithelial tumor antigen and demonstrate the existence of multiple protein forms that probably localize to different cellular and extracellular compartments.
A mechanism is described whereby one and the same gene can encode both a receptor protein as well as its specific ligand. Generation of this receptor-ligand partnership is effected by proteolytic cleavage within a specific module located in a membrane resident protein. It is postulated here that the "SEA" module, found in a number of heavily O-linked glycosylated membrane-associated proteins, serves as a site for proteolytic cleavage. The subunits generated by proteolytic cleavage of the SEA module reassociate, and can subsequently elicit a signaling cascade. We hypothesize that all membrane resident proteins containing such a "SEA" module will undergo cleavage, thereby generating a receptor-ligand alliance. This requires that the protein subunits resulting from the proteolytic cleavage reassociate with each other in a highly specific fashion. The same SEA module that serves as the site for proteolytic cleavage, probably also contains the binding sites for reassociation of the resultant two subunits. More than one type of module can function as a site for proteolytic cleavage; this can occur not only in one-pass membrane proteins but also in 7-transmembrane proteins and other membrane-associated proteins. The proposal presented here is likely to have significant practical consequences. It could well lead to the rational design and identification of molecules that, by binding to one of the cleaved partners, will act either as agonists or antagonists, alter signal transduction and, hence, cellular behavior.Keywords: SEA module; mucins; receptors; ligands; signaling; proteolytic cleavageInteractions between ligands and their membrane receptors affect all aspects of cell behavior, be they related to tissue patterning, cell differentiation, cell growth, or cell death.The engagement of a cell surface receptor by its specific ligand(s) initiates a signaling cascade that ultimately culminates in changed patterns of gene expression, thereby altering cellular characteristics. Activation of the membranelocated receptor can be induced by a soluble secreted ligand, a cell-surface-associated ligand resident on either the same cell or a neighboring cell or by an extracellular matrixembedded ligand. Whatever the location of the ligand, in almost all cases, the gene coding for the ligand is distinct
Background: The MUC1 gene encodes a mucin glycoprotein(s) which is basally expressed in most epithelial cells. In breast adenocarcinoma and a variety of epithelial tumors its transcription is dramatically upregulated. Of particular relevance to breast cancer, steroid hormones also stimulate the expression of the MUC1 gene. The MUC1 gene directs expression of several protein isoforms, which participate in many crucial cell processes. Although the MUC1 gene plays a critical role in cell physiology and pathology, little is known about its promoter organization and transcriptional regulation. The goal of this study was to provide insight into the structure and transcriptional activity of the MUC1 promoter.
Expression of the gene coding for a new breast tumor-associated antigen, H23, was compared to expression of genes coding for pS2, c-erbB2 and estrogen receptor (ER). Comparison involved mRNA expression in normal and malignant breast tissues as well as in non-breast tumors. Results obtained by RNA dot blot and Northern hybridizations showed that expression of the H23 antigen coding gene is a discriminatory marker in human breast cancer. It is expressed in 92% of breast tumors whereas 69%, 62% and 56% of breast tumors demonstrate significant mRNA levels of c-erbB2, ER and pS2, respectively. Non-malignant or normal breast tissue expresses much lower levels of the H23 antigen mRNA. From the comparative analysis presented here it is concluded that the gene coding for H23 antigen furnishes a most useful marker for human breast cancer.Gene expression; Breast tumor antigen H23; Breast tumor antigen pS2; Oncogene erbB2; Estrogen receptor; Breast cancer
A monoclonal antibody, H23, that specifically recognizes a breast‐tumor‐associated antigen, was used to isolate a cDNA insert that codes for the antigenic epitope. Nucleotide sequencing of this cDNA, as well as a longer 850‐bp cDNA insert, shows that they are composed of 60‐bp (G + C)‐rich tandem repeating units. The coding strand was determined and codes for a proline‐rich 20‐amino‐acid repeat motif. A comparison of the highly conserved repeat unit with the deduced flanking amino acid sequences demonstrates conservation of specific subregions of the repeat consensus within the flanking amino acids. Hybridization of the 60‐bp cDNA probe with RNAs extracted from a variety of primary and metastatic human tumors yields relatively high levels of hybrid with the breast carcinomas, as compared to lower hybrid levels with RNAs from other epithelial tumors. RNA extracted from breast tissue adjacent to the tumor or from benign breast tumors, demonstrates low or undetectable levels of hybridization. Probing Southern blots with the 60‐bp repeat shows that the tumor antigen is highly polymorphic and contains a variable number of tandem repeats (VNTRs). The VNTR nature of the gene was confirmed by probing Southern blots with unique genomic sequences that are physically linked to an isolated gene fragment that also contains the tandem repeat array. Mouse cells transfected with this gene fragement produce tumor antigen that is readily detected by H23 monoclonal antibodies. The allelic forms seen in 10 different primary human tumors demonstrate 100% concordance with the various mRNA species expressed. These studies are extended to the protein forms detected by immunoblot analyses that show both a correlation of the expressed tumor antigen species with the allelic forms as well as significantly increased expression in breast cancer tissue. The above studies unequivocally establish the over‐expression of a VNTR gene coding for an epithelial tumor antigen in human breast cancer tissue.
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