Breast Neoplasms: Cartun RW

Yaziji H, Taylor CR, Goldstein NS, Dabbs DJ, Hammond EH, Hewlett B, Floyd AD, Barry TS, Martin AW, Badve S, Baehner F, Cartun RW, Eisen RN, Swanson PE, Hewitt SM, Vyberg M, Hicks DG, Anonymous00020. · Vitro Molecular Laboratories, Miami, FL daggerKeck School of Medicine, University of Southern California, Los Angeles, USA. · Appl Immunohistochem Mol Morphol. · Pubmed #18931614 No free full text.

Abstract: Estrogen receptor (ER) status in breast cancer is currently the most important predictive biomarker that determines breast cancer prognosis after treatment with endocrine therapy. Although immunohistochemistry has been widely viewed as the gold standard methodology for ER testing in breast cancer, lack of standardized procedures, and lack of regulatory adherence to testing guidelines has resulted in high rates of "false-negative" results worldwide. Standardized testing is only possible after all aspects of ER testing--preanalytical, analytical, and postanalytical, have been closely controlled. A meeting of the "ad-hoc committee" of expert pathologists, technologists, and scientists, representing academic centers, reference laboratories, and various agencies, issued standardization testing recommendations, aimed at optimization of clinical ER testing environment, as a step toward improved standardized testing.

Anderson WF, Luo S, Chatterjee N, Rosenberg PS, Matsuno RK, Goodman MT, Hernandez BY, Reichman M, Dolled-Filhart MP, O'Regan RM, Garcia-Closas M, Perou CM, Jatoi I, Cartun RW, Sherman ME. · NIH/NCI/DCEG, EPS Room 8036, 6120 Executive Blvd, Bethesda, MD 20852, USA. · Breast Cancer Res Treat. · Pubmed #18256926 No free full text.

Abstract: BACKGROUND: In 2001, the National Cancer Institute's Surveillance, Epidemiology, and End Results (SEER) program established Residual Tissue Repositories (RTR) in the Hawaii, Iowa, and Los Angeles Tumor Registries to collect discarded tissue blocks from pathologic laboratories within their catchment areas. To validate the utility of the RTR for supplementing SEER's central database, we assessed human epidermal growth factor receptor-2 (HER2) and estrogen receptor expression (ER) in a demonstration project. MATERIALS: Using a prepared set of tissue microarrays (TMAs) residing in the Hawaii Tumor Registry (HTR), we performed standard immunohistochemistry. Breast cancers in the TMA were diagnosed in 1995, followed through 2006, and linked to SEER's main database. RESULTS: The TMA included 354 cases, representing 51% of 687 breast cancers in the HTR (1995). The HTR and TMA cases were similar with respect to patient demographics and tumor characteristics. Seventy-six percent (76%, 268 of 354) of TMA cases were HER2+ and/or ER+, i.e., 28 HER2+ER-, 12 HER2+ER+, and 228 HER2-ER+. There were 67 HER2-ER- cases and 19 were unclassified. Age distributions at diagnosis were bimodal with dominant early-onset modes for HER2+ER- tumors and dominant late-onset modes for HER2-ER+ breast cancers. Epidemiologic patterns for concordant HER2+ER+ (double-positive) and HER2-ER- (double-negative) were intermediate to discordant HER2+ER- and HER2-ER+. CONCLUSION: Results showed contrasting incidence patterns for HER2+ (HER2+ER-) and ER+ (HER2-ER+) breast cancers, diagnosed in 1995. Though sample sizes were small, this demonstration project validates the potential utility of the RTR for supplementing the SEER program.

Yang XR, Pfeiffer RM, Garcia-Closas M, Rimm DL, Lissowska J, Brinton LA, Peplonska B, Hewitt SM, Cartun RW, Mandich D, Sasano H, Evans DB, Sutter TR, Sherman ME. · Genetic Epidemiology Branch, Division of Cancer Epidemiology & Genetics, National Cancer Institute, NIH, Bethesda, MD 20892-7236, USA. · Cancer Res. · Pubmed #17968031 links to  free full text

Abstract: The objective of this study was to evaluate the coexpression patterns of hormonal markers in breast cancer tissue and their relationship with pathologic characteristics and epidemiologic risk factors. We evaluated the expression of 17 markers by immunohistochemistry in 842 invasive breast carcinomas collected in a population-based case-control study conducted in Poland. Based on marker correlations, factor analysis identified four major coexpression patterns (factors): "nuclear receptor factor" [estrogen receptor (ER)-alpha, progesterone receptor, androgen receptor, cyclin D1, and aromatase], "estrogen metabolism/ER-beta factor" (ER-beta, peroxisome proliferator-activated receptor-gamma, steroid sulfatase, estrogen sulfonotransferase, and cytochrome P450 1B1), "HER2 factor" (human epidermal growth factor receptor 2, E-cadherin, cyclooxygenase-2, aromatase, steroid sulfatase), and "proliferation factor" (cytokeratin 5, cytokeratin 5/6, epidermal growth factor receptor, P53). Three of these factors corresponded to molecular subtypes previously defined by expression profiling; however, the estrogen metabolism/ER-beta factor seemed to be distinctive. High scores for this factor were associated with high tumor grade (P heterogeneity = 0.02), younger age at menarche (P heterogeneity = 0.04), lower current body mass index among premenopausal women (P heterogeneity = 0.01), and older age at menopause (P heterogeneity = 0.04). High scores for the proliferation factor were also associated with early menarche (P heterogeneity < 0.0001), and in contrast to the estrogen metabolism/ER-beta factor, higher current body mass index among premenopausal women (P heterogeneity = 0.03). Our analysis of hormonal pathway markers independently confirmed several previously defined molecular subtypes identified by gene expression profiling and augmented these findings by suggesting the existence of additional relationships related to ER-beta and enzymes involved in hormone metabolism.

Tsongalis GJ, Cartun RW, Ricci A. · Department of Pathology and Laboratory Medicine, Hartford Hospital, CT 06102, USA. · Clin Chem Lab Med. · Pubmed #11097337 No free full text.

Abstract: Pharmacogenomic analysis aspires to identify individuals with specific genetic characteristics in order to predict a positive response or reduce a negative response to a therapeutic modality. While the search continues for the many single nucleotide polymorphisms which will be used in such genetic analyses, other genetic alterations in specific cell types have proven useful in determining the potential for response to therapy. One such genetic alteration is amplification of entire gene sequences which results in overexpression of a gene product or protein. Amplification of the HER2 (neu, erbB-2) oncogene is found in up to 35% of human breast cancers and is associated with a poor prognosis. In addition, this genetic alteration may predict response to various therapeutic modalities. Assays are available to detect the HER2 protein receptor or copies of the HER2 gene sequence to determine eligibility for Herceptin treatment or adriamycin treatment in node positive patients, respectively. This model represents a somatic event used in the functional determination of a therapeutic strategy.

Johnson RC, Ricci A, Cartun RW, Ackroyd R, Tsongalis GJ. · Department of Pathology and Laboratory Medicine, Hartford Hospital, Connecticut, USA. · Cancer Invest. · Pubmed #10808369 No free full text.

Abstract: With the successful clinical trials of the engineered antibody Herceptin (in advanced-stage breast cancer) and adriamycin-based chemotherapy regimens (in the adjuvant setting), the need to detect p185HER2 overexpression or associated amplification of the coding gene HER2 in breast cancer patients is escalating. Twenty to 30% of breast carcinomas have overexpression of p185HER2. This condition correlates with poor patient prognosis and predicts response to chemotherapy in lymph node-positive patients. In this study we compare quantitation of p185HER2 in breast cancer at the gene and protein levels using differential polymerase chain reaction (PCR) and immunohistochemistry, respectively. To assign HER2 gene copy numbers, a calibration curve was constructed using normal breast epithelia and breast carcinoma cell lines having known dosages of amplified HER2. We found corresponding molecular and immunohistochemical results in 85% of the 13 paraffin-embedded breast carcinoma cases examined. Two cases were found to have minimum gene amplification but marked p185HER2 overexpression, suggesting an alternative mechanism to overexpression such as transcriptional activation. Although the differential PCR assay exhibits saturation approaching 20 HER2 gene copies, this may not be clinically significant because the immunohistochemical assay also appears to saturate in this gene copy number range.