Identifying genes and gene products that are important in tumor cells is a high priority goal of the National Cancer Institute. In order to determine whether a gene of interest is expressed in human malignancy, investigators must be able to evaluate actual tissue samples of human tumors. Unfortunately, access to large numbers of well-characterized human tissue samples is difficult, and there is a large expense for the preparation of glass slides from tumor in order to perform immunohistochemistry or in-situ hybridization. As a partial solution to this problem, pathologists began to combine multiple tissue samples in one tissue block, in order to reduce the histology costs and the time and effort involved to perform the special studies. This technique has been refined to the point where hundreds of tissue samples can be placed in a grid arrangement in a single paraffin tissue block. Investigators in the NHGRI (Kohenen, Kallioniemi and others) demonstrated the utility of large scale tissue microarrays in a seminal paper published in Science. Following a tissue microarray workshop hosted by NCI in Fall, 1999, a steering committee convened with the purpose of establishing a pathology-based tissue microarray core facility. The steering committee is composed of representatives from intramural and extramural NCI and from the NHGRI. This project is a direct outgrowth of the Extraordinary Opportunity to Define the Signatures of Cancer Cells identified in the 2001 Bypass Budget plan. The goals of the first year were to establish a core microarray production facility based on a similar facility in the NHGRI and to create the first mixed tumor microarrays for nationwide distribution. The principle product of the core is a mixed tumor block containing representative samples of the most common epithelial malignancies (breast, colon, lung, prostate, and ovary) as well as samples of melanoma, glioma and lymphoma. A selection of normal tissue and standard cell lines were also to be included to bring the total number of tissue spots to 500. Anonymized human tumor samples are obtained through the CHTN, and this organization will also handle distribution of arrays on glass slides to investigators in the intramural and extramural scientific community. Three sets of 5 multi-tumor arrays have been prepared in the first production year (FY2001), totaling nearly 3000 slides for distribution. The slides are being distributed from CHTN nearly as fast a they are produced. In addition to slide production, the core facility has been engaged in technology development, from the basic histology procedures to array use to large-scale imaging of arrays. In the second production year, the facility plans to hire a second histotechnician, acquire an automated arrayer and to continue production of multi-tumor arrays. Also in production are tissue arrays of the NCI 60 cell line collection (these are the 60 cell lines used by the NCI to perform anti-tumor drug testing) and collaborative projects for specialized tumor blocks for renal cell carcinoma (collaborator, M. Linehan), mesothelioma (collaborator, D. Schrump and D. Bartlett), and hepatocellular carcinoma (S. Thorgeirsson.
Evans, Andrew; Bates, Victoria; Troy, Helen et al. (2008) Glut-1 as a therapeutic target: increased chemoresistance and HIF-1-independent link with cell turnover is revealed through COMPARE analysis and metabolomic studies. Cancer Chemother Pharmacol 61:377-93 |
Molinolo, Alfredo A; Hewitt, Stephen M; Amornphimoltham, Panomwat et al. (2007) Dissecting the Akt/mammalian target of rapamycin signaling network: emerging results from the head and neck cancer tissue array initiative. Clin Cancer Res 13:4964-73 |
Goldstein, Neal S; Hewitt, Stephen M; Taylor, Clive R et al. (2007) Recommendations for improved standardization of immunohistochemistry. Appl Immunohistochem Mol Morphol 15:124-33 |
Yang, Sherry X; Hewitt, Stephen M; Steinberg, Seth M et al. (2007) Expression levels of eIF4E, VEGF, and cyclin D1, and correlation of eIF4E with VEGF and cyclin D1 in multi-tumor tissue microarray. Oncol Rep 17:281-7 |
Fukuoka, Junya; Dracheva, Tatiana; Shih, Joanna H et al. (2007) Desmoglein 3 as a prognostic factor in lung cancer. Hum Pathol 38:276-83 |
Gannot, Gallya; Tangrea, Michael A; Erickson, Heidi S et al. (2007) Layered peptide array for multiplex immunohistochemistry. J Mol Diagn 9:297-304 |
Takikita, Mikiko; Chung, Joon-Yong; Hewitt, Stephen M (2007) Tissue microarrays enabling high-throughput molecular pathology. Curr Opin Biotechnol 18:318-25 |
Chung, Joon-Yong; Braunschweig, Till; Tuttle, Kimberly et al. (2007) Tissue microarrays as a platform for proteomic investigation. J Mol Histol 38:123-8 |
Yang, Xiaohong R; Sherman, Mark E; Rimm, David L et al. (2007) Differences in risk factors for breast cancer molecular subtypes in a population-based study. Cancer Epidemiol Biomarkers Prev 16:439-43 |
Traicoff, June L; Chung, Joon-Yong; Braunschweig, Till et al. (2007) Expression of EIF3-p48/INT6, TID1 and Patched in cancer, a profiling of multiple tumor types and correlation of expression. J Biomed Sci 14:395-405 |
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