Gene Expression Profiling of Benign and Malignant Pheochromocytoma

Overview

Journal Ann N Y Acad Sci

Specialty Science

Date 2006 Nov 15

PMID 17102123

Citations 27

Authors

Frederieke M Brouwers

Abdel G Elkahloun

Peter J Munson

Graeme Eisenhofer

Jennifer Barb

W Marston Linehan

Jacques W M Lenders

Ronald de Krijger

Massimo Mannelli

Robert Udelsman

Idris T Ocal

Barry L Shulkin

Stefan R Bornstein

Jan Breza

Lucia Ksinantova

Karel Pacak

Affiliations

Soon will be listed here.

Abstract

There are currently no reliable diagnostic and prognostic markers or effective treatments for malignant pheochromocytoma. This study used oligonucleotide microarrays to examine gene expression profiles in pheochromocytomas from 90 patients, including 20 with malignant tumors, the latter including metastases and primary tumors from which metastases developed. Other subgroups of tumors included those defined by tissue norepinephrine compared to epinephrine contents (i.e., noradrenergic versus adrenergic phenotypes), adrenal versus extra-adrenal locations, and presence of germline mutations of genes predisposing to the tumor. Correcting for the confounding influence of noradrenergic versus adrenergic catecholamine phenotype by the analysis of variance revealed a larger and more accurate number of genes that discriminated benign from malignant pheochromocytomas than when the confounding influence of catecholamine phenotype was not considered. Seventy percent of these genes were underexpressed in malignant compared to benign tumors. Similarly, 89% of genes were underexpressed in malignant primary tumors compared to benign tumors, suggesting that malignant potential is largely characterized by a less-differentiated pattern of gene expression. The present database of differentially expressed genes provides a unique resource for mapping the pathways leading to malignancy and for establishing new targets for treatment and diagnostic and prognostic markers of malignant disease. The database may also be useful for examining mechanisms of tumorigenesis and genotype-phenotype relationships. Further progress on the basis of this database can be made from follow-up confirmatory studies, application of bioinformatics approaches for data mining and pathway analyses, testing in pheochromocytoma cell culture and animal model systems, and retrospective and prospective studies of diagnostic markers.

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