G A Niehans

To determine the relative expression of distinct mucin genes in normal and neoplastic tissue, antibodies and cDNA probes that recognize the core tandem repeat sequences of membrane-bound (MUC1) and secreted (MUC2 and MUC3) mucins were used for immunohistochemical and RNA Northern and slot-blot analysis. MUC1 mRNA was detected in all epithelial tissues tested. MUC1 core peptide, recognized by monoclonal antibodies 139H2 and DF3, was highly expressed on apical membranes of bronchus, breast, salivary gland, pancreas, prostate, and uterus, and was sparsely expressed in gastric surface cells, gallbladder, small intestine, and colonic epithelium. In contrast, MUC2 and MUC3 gene expression was primarily restricted to the intestinal tract. MUC2 mRNA was highly expressed in normal jejunum, ileum, and colon, compared with very low levels in normal bronchus and gallbladder. MUC3 mRNA was highly expressed in normal jejunum, ileum, colon, and gallbladder. Immunohistochemical studies using antibodies against synthetic MUC2 (anti-MRP) and MUC3 (anti-M3P) peptides indicate that MUC2- and MUC3-producing cells in the gastrointestinal tract are distinct. Goblet cells of the small intestine and colon reacted strongly with anti-MRP, whereas M3P reactivity was restricted to columnar cells of small intestinal villi, surface colonic epithelium, and gallbladder. Mucin protein epitopes and mRNA levels were frequently altered in adenocarcinomas compared to corresponding normal tissues. Alterations included increased expression, aberrant expression, and, less frequently, loss of expression. Increased MUC1 immunoreactivity was observed in most adenocarcinomas of the breast, lung, stomach, pancreas, prostate, and ovary. In addition, with the exception of prostate cancer, focal aberrant expression of MUC2 and MUC3 epitopes was frequently observed. Increased MUC1, MUC2, and MUC3 epitopes were present in colon adenocarcinomas of all histological subtypes, with the greatest increase of MUC2 epitopes observed in colloid (mucinous) colon cancers. MUC2 or MUC3 mRNA levels were increased in colloid colon cancer compared with normal colon, however in well- and moderately well-differentiated colon cancers MUC1, 2 and 3 mRNA levels were decreased. Compared with corresponding normal tissue, MUC1 mRNA levels were increased in breast cancer and well-differentiated lung cancers, and MUC3 mRNA was increased in gastric adenocarcinomas. Normal stomach lacked both MUC2 and MUC3 immunoreactivity and mRNA, however, MUC2 and MUC3 proteins and mRNA were highly expressed in gastric intestinal metaplasia. In conclusion, mucin genes are independently regulated and their expression is organ- and cell type-specific. Furthermore, neoplastic transformation is associated with dys-regulated expression of both membrane-bound and secreted mucin core protein epitopes and may be due to altered mucin mRNA levels and/or altered mucin glycosylation.

To reach a clinically detectable size, neoplasms must be able to suppress or evade a host immune response. Activated T cells may enter apoptosis in the presence of Fas ligand (FasL) (1), and tissue expression of FasL has been shown to contribute to immune privilege in the eye and testis (2, 3). We have demonstrated that all human lung carcinoma cell lines tested (16 of 16) express a Mr 38,000 protein consistent with FasL by immunoblotting, whereas the majority of resected tumors (23 of 28) show positive staining for FasL by immunohistochemistry. DNA sequencing of reverse transcription-PCR products from lung cancer cells and resected lung tumors confirms the presence of human FasL mRNA in these neoplastic tissues. Furthermore, lung carcinoma cells are capable of killing a Fas-sensitive human T cell line (Jurkat) in coculture experiments; this killing was inhibited by a recombinant form of the soluble portion of the Fas receptor (FasFc). FasL expression by neoplastic cells represents a potential mechanism for peripheral deletion of tumor-reactive T-cell clones.

Mucins synthesized by malignant cells may contribute (via decreased cellular adhesion and immune recognition) to cancer invasion and metastases. Human mucins are derived from a heterogeneous family of genes, labeled MUC1-6. Our aim was to determine the pattern of mucin gene expression in normal, preneoplastic (intestinal metaplasia), and malignant gastric specimens. Probes and antibodies for specific mucin tandem repeat sequences were used for RNA and immunohistochemical analysis. Normal stomach mucosa was characterized by expression of MUC1, MUC5, and MUC6 mRNA and immunoreactive protein, without MUC2, MUC3, and MUC4 gene expression. In contrast, high levels of MUC2 and MUC3 mucin mRNA and immunoreactive protein were found in specimens with intestinal metaplasia. Gastric cancers exhibited markedly altered secretory mucin mRNA levels compared with adjacent normal mucosa, with decreased levels of MUC5 and MUC6 mRNA and increased levels of MUC3 and MUC4 mRNA. Overall, immunoreactive MUC1 mucin was detected in 72% of 33 gastric cancers, and secretory mucin core peptides were expressed in 34% (MUC2), 45% (MUC3), 19% (MUC5), and 57% (MUC6) of these specimens. Coexpression of multiple (three or more) mucin core proteins occurred in 15 of 25 (60%) advanced (stages III and IV) cancers compared with 1 of 8 (12.5%) early (stages I and II) cancers (P < 0.048). We conclude that human gastric epithelium has a unique mucin gene pattern, which becomes markedly altered in preneoplastic and neoplastic specimens. Increased mucin gene heterogeneity in gastric adenocarcinomas is associated with advanced cancer stage.

The retinoblastoma (RB) and cyclin-dependent kinase inhibitor 2/multiple tumor suppressor gene 1 (CDKN2/MTS1) tumor suppressor genes play important roles in the regulation of the cell cycle. The protein products of these two genes, pRB and p16INK4A ("p16"), respectively, inhibit progression from G1 to S phase. Moreover, p16 has been shown to exert its function through inhibition of CDK4-mediated phosphorylation of pRB. Both genes have been found to be mutated or deleted in a wide range of primary human tumors and tumor cell lines. However, the presence of CDKN2/MTS1 containing nonneoplastic elements in every tumor specimen may contribute to the apparent lower deletion detection rate in resected neoplasms compared to cell lines. We have developed an immunohistochemical assay that allows us to assess p16 expression in formalin-fixed, paraffin-embedded tissues. As controls, we used paraffin-embedded pellets of cell lines with well-defined p16 status (four positive and four negative lines), as well as routinely processed nude mouse xenografts of two p16-positive cell lines. p16-negative cells were characterized by the absence of nuclear staining, whereas cytoplasmic staining was variable. In neoplastic and normal tissues, the level of p16 generally appeared to be low. We tested 75 random human malignancies from 4 different anatomic sites for p16 expression and correlated the findings with the immunohistochemical presence or absence of pRB. Twenty % of tumors selectively lacked pRB, while 37% of neoplasms had undetectable p16. In 43% of all carcinomas, both pRB and p16 could be detected. Significant differences existed in the expression of both tumor suppressor genes between carcinomas from different sites. Breast cancers had the highest rate of p16 negativity (13 of 20). Our data show that: (a) immunohistochemistry may be a suitable modality to screen for RB and CDKN2/MTS1 abnormalities in paraffin-embedded tissues; (b) undetectable levels of p16 expression occur at a relatively high frequency; (c) p16 and pRB expression in common human malignancies is not mutually exclusive; (d) loss of function of both tumor suppressor genes appears to be a distinctly uncommon phenomenon; and (e) different types of carcinomas have variable rates of disturbance in the p16/pRB pathway.

BACKGROUND: Amplification and over-expression of the HER-2/neu oncogene (also known as c-erbB-2) occurs in 20%-30% of invasive breast carcinomas. The extent to which HER-2/neu expression changes over time in association with tumor progression or is heterogeneous at different metastatic sites has received only limited study. PURPOSE: Our purpose was to determine whether primary tumors differ from metastases in HER-2/neu protein content or whether metastases are heterogeneous in regard to HER-2/neu expression. METHODS: In a retrospective study, we examined tumor tissue obtained at autopsy from two to five metastatic organ sites in each of 30 patients who died with metastatic breast carcinoma. Using an immunoperoxidase technique, we stained archival formalin-fixed, paraffin-embedded tissue sections with a monoclonal antibody to the 185-kilodalton protein product (p185) of the HER-2/neu gene. RESULTS: The tissue from eight of 30 patients showed strong diffuse reactivity for p185 at all metastatic sites examined. Tissues from six patients showed faint staining and tissues from 15 were negative, again with a congruent staining pattern. A single case showed discordant staining, in that two of four metastases showed faint staining, whereas the other two showed strong immunoreactivity. In 14 cases, we were able to obtain paraffin blocks from the original biopsy or surgical resection of the primary breast lesion. For these 14 patients, the average length of time between initial diagnosis and death was 4 years (range, 2-9). There was good correlation between results from autopsy and original surgical tissues. CONCLUSIONS: Expression of HER-2/neu appears to be relatively stable over time and is generally congruent at different metastatic sites. IMPLICATIONS: The fact that p185 immunoreactivity is rarely heterogeneous is encouraging, both for the potential use of HER-2/neu-related proteins as serum tumor markers and for innovative therapies targeted at p185 expression.