Endogenous Myoglobin in Breast Cancer is Hypoxia-inducible by Alternative Transcription and Functions to Impair Mitochondrial Activity: a Role in Tumor Suppression?

Overview

Journal J Biol Chem

Specialty Biochemistry

Date 2011 Sep 21

PMID 21930697

Citations 25

Authors

Glen Kristiansen

Junmin Hu

Daniela Wichmann

Daniel P Stiehl

Michael Rose

Josefine Gerhardt

Annette Bohnert

Anette ten Haaf

Holger Moch

James Raleigh

Mahesh A Varia

Patrick Subarsky

Francesca M Scandurra

Erich Gnaiger

Eva Gleixner

Anne Bicker

Max Gassmann

Thomas Hankeln

Edgar Dahl

Thomas A Gorr

Affiliations

Soon will be listed here.

Abstract

Recently, immunohistochemical analysis of myoglobin (MB) in human breast cancer specimens has revealed a surprisingly widespread expression of MB in this nonmuscle context. The positive correlation with hypoxia-inducible factor 2α (HIF-2α) and carbonic anhydrase IX suggested that oxygen regulates myoglobin expression in breast carcinomas. Here, we report that MB mRNA and protein levels are robustly induced by prolonged hypoxia in breast cancer cell lines, in part via HIF-1/2-dependent transactivation. The hypoxia-induced MB mRNA originated from a novel alternative transcription start site 6 kb upstream of the ATG codon. MB regulation in normal and tumor tissue may thus be fundamentally different. Functionally, the knockdown of MB in MDA-MB468 breast cancer cells resulted in an unexpected increase of O(2) uptake and elevated activities of mitochondrial enzymes during hypoxia. Silencing of MB transcription attenuated proliferation rates and motility capacities of hypoxic cancer cells and, surprisingly, also fully oxygenated breast cancer cells. Endogenous MB in cancer cells is apparently involved in controlling oxidative cell energy metabolism, contrary to earlier findings on mouse heart, where the targeted disruption of the Mb gene did not effect myocardial energetics and O(2) consumption. This control function of MB seemingly impacts mitochondria and influences cell proliferation and motility, but it does so in ways not directly related to the facilitated diffusion or storage of O(2). Hypothetically, the mitochondrion-impairing role of MB in hypoxic cancer cells is part of a novel tumor-suppressive function.

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