Key to lung cancer chemo resistance revealed



Shyam Biswal, Ph.D.
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Scientists at Johns Hopkins have discovered how taking the brakes off a "detox" gene causes chemotherapy resistance in a common form of lung cancer.

Products made by a gene called NRF2 normally protect cells from environmental pollutants like cigarette smoke and diesel exhaust by absorbing the materials and pumping them out of the cell. Another gene called KEAP1 encodes products that stop this cleansing process. But lung cancer cells sabotage the expression of these same genes to block assault from chemotherapy drugs.

"What we're seeing is that lung cancer cells recruit and distort NRF2 and KEAP1 expression to help tumor cells evade the toxic effects of chemotherapy," says Shyam Biswal, Ph.D., associate professor at the Johns Hopkins Bloomberg School of Public Health and Kimmel Cancer Center, who published results of cell culture studies in the October 3, 2006 issue of PLoS Medicine.

Past studies have shown that NRF2 detoxifies cells by directing proteins to absorb and pump out pollutants and chemicals. The NRF2 gene makes a "trigger" protein which starts the production of other proteins and enzymes that sweep the cell clear of toxins. To halt the detox process, proteins manufactured by KEAP1 bind to the NRF2 triggers tagging them for destruction. In cancer cells, NRF2 activity runs amok, sweeping away all cellular toxins, including chemotherapy agents.

Biswal says that blocking NRF2 activity could improve the effectiveness of standard chemotherapy drugs, particularly platinum-based compounds widely used for lung cancer.

In Biswal's study, half of 12 lung cancer cell lines and 10 of 54 tissue samples from non-small cell lung cancer patients had mutations in the KEAP1 gene rendering it inactive and unable to keep NRF2 activity in check. In addition, half of the tissue samples were missing one copy of the KEAP1 gene - cells usually have two copies of each gene. No missing genes or mutations were observed in normal lung tissues from the same patients.

NRF2 activity along with its cleansing proteins and enzymes were higher in tumor samples than normal cells, according to the researchers. Their cell culture tests also show that cancer cells with KEAP1 mutations are more resistant to chemotherapy drugs than normal lung cells.

Tumor samples with normal KEAP1 genes also show increased levels of NRF2 and its enzymes, suggesting other ways of dismantling KEAP1, such as splicing the gene to make a shortened, ineffective protein, he said.

The researchers plan to confirm their findings with a larger set of samples and then to screen for appropriate drugs. Funding for the study was provided by the National Cancer Institute Lung SPORE (Specialized Program of Research Excellence), National Heart Lung and Blood Institute, National Institute of Environmental Health Sciences Center, National Institute of Health, and the Flight Attendant Medical Research Institution.

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Note to reporters: A photo of Dr. Biswal is available at: http://www.hopkinsmedicine.org/Press_releases/2006/Images/ShyamBiswal2.jpg

Co-authors include Anju Singh, Vikas Misra, Rajesh K Thimmulappa, Hannah Lee, Stephen Ames, Mohammad O. Hoque, James G. Herman, Stephen B. Baylin, David Sidransky, Edward Gabrielson and Malcolm Brock from Johns Hopkins.

1Nuclear factor erythroid-2 related factor 2 (NRF2) 2Kelch-like ECH-associated protein 1 (KEAP1)

On the web:
www.hopkinskimmelcancercenter.org
www.jhsph.edu
www.plos.org


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