Document Type
Article
Publication Date
5-23-2011
Abstract
The functional role of oxidative stress in cancer pathogenesis has long been a hotly debated topic. A study published this month in BMC Cancer by Goh et al., directly addresses this issue by using a molecular genetic approach, via an established mouse animal model of human breast cancer. More specifically, alleviation of mitochondrial oxidative stress, via transgenic over-expression of catalase (an anti-oxidant enzyme) targeted to mitochondria, was sufficient to lower tumor grade (from high-to-low) and to dramatically reduce metastatic tumor burden by >12-fold. Here, we discuss these new findings and place them in the context of several other recent studies showing that oxidative stress directly contributes to tumor progression and metastasis. These results have important clinical and translational significance, as most current chemo-therapeutic agents and radiation therapy increase oxidative stress, and, therefore, could help drive tumor recurrence and metastasis. Similarly, chemo- and radiation-therapy both increase the risk for developing a secondary malignancy, such as leukemia and/or lymphoma. To effectively reduce mitochondrial oxidative stress, medical oncologists should now re-consider the use of powerful anti-oxidants as a key component of patient therapy and cancer prevention. Please see related research article: http://www.biomedcentral.com/1471-2407/11/191.
Recommended Citation
Sotgia, Federica; Martinez-Outschoorn, Ubaldo E; and Lisanti, Michael P, "Mitochondrial oxidative stress drives tumor progression and metastasis: should we use antioxidants as a key component of cancer treatment and prevention?" (2011). Department of Stem Cell Biology and Regenerative Medicine Faculty Papers & Presentations. Paper 2.
https://jdc.jefferson.edu/stem_regenerativefp/2
PubMed ID
21605374
Comments
This article has been peer reviewed and is published in BMC Medicine 2011, 9:62. The published version is available at DOI: 10.1186/1741-7015-9-62. ©BioMed Central Ltd.