How Antioxidants Can Accelerate Cancers And Why They Don't Protect Against Them, Cold Spring Harbor Laboratory Scientists Reveal

Scientists Propose How Antioxidants Can Accelerate Cancers And Why They Don’t Protect Against Them

Cold Spring Harbor, NY – For decades, health-conscious people around the globe have taken antioxidant supplements and eaten foods rich in antioxidants, figuring this was one of the paths to good health and a long life.

Yet clinical trials of antioxidant supplements have repeatedly dashed the hopes of consumers who take them hoping to reduce their cancer risk. Virtually all such trials have failed to show any protective effect against cancer. In fact, in several trials, antioxidant supplementation has been linked with increased rates of certain cancers. In one trial, smokers taking extra beta carotene had higher, not lower, rates of lung cancer.

In a brief paper appearing today in The New England Journal of Medicine, David Tuveson, M.D., Ph.D., Cold Spring Harbor Laboratory Professor and Director of Research for the Lustgarten Foundation, and Navdeep S. Chandel, Ph.D., of the Feinberg School of Medicine at Northwestern University, propose why antioxidant supplements might not be working to reduce cancer development, and why they may actually do more harm than good.

Their insights are based on recent advances in the understanding of the system in our cells that establishes a natural balance between oxidizing and anti-oxidizing compounds. These compounds are involved in so-called redox (reduction and oxidation) reactions essential to cellular chemistry.

Oxidants like hydrogen peroxide are essential in small quantities and are manufactured within cells. There is no dispute that oxidants are toxic in large amounts, and cells naturally generate their own anti-oxidants to neutralize them. It has seemed logical to many, therefore, to boost intake of antioxidants to counter the effects of hydrogen peroxide and other similarly toxic “reactive oxygen species,” or ROS, as they are called by scientists. All the more because it is known that cancer cells generate higher levels of ROS to help feed their abnormal growth.

Drs. Tuveson and Chandel propose that taking antioxidant pills or eating vast quantities of foods rich in antioxidants may be failing to show a beneficial effect against cancer because they do not act at the critical site in cells where tumor-promoting ROS are produced – at cellular energy factories called mitochondria. Rather, supplements and dietary antioxidants tend to accumulate at scattered distant sites in the cell, “leaving tumor-promoting ROS relatively unperturbed,” the researchers say.

Quantities of both ROS and natural antioxidants are higher in cancer cells – the paradoxically higher levels of antioxidants being a natural defense by cancer cells to keep their higher levels of oxidants in check, so growth can continue. In fact, say Tuveson and Chandel, therapies that raise the levels of oxidants in cells may be beneficial, whereas those that act as antioxidants may further stimulate the cancer cells. Interestingly, radiation therapy kills cancer cells by dramatically raising levels of oxidants. The same is true of chemotherapeutic drugs – they kill tumor cells via oxidation.

Paradoxically, then, the authors suggest that “genetic or pharmacologic inhibition of antioxidant proteins” – a concept tested successfully in rodent models of lung and pancreatic cancers -- may be a useful therapeutic approach in humans. The key challenge, they say, is to identify antioxidant proteins and pathways in cells that are used only by cancer cells and not by healthy cells. Impeding antioxidant production in healthy cells will upset the delicate redox balance upon which normal cellular function depends.

The authors propose new research to profile antioxidant pathways in tumor and adjacent normal cells, to identify possible therapeutic targets.

“The Promise and Perils of Antioxidants for Cancer Patients” appears in The England Journal of Medicine on July 10, 2014. The authors are: Navdeep S. Cahndel, Ph.D., and David A. Tuveson, M.D., Ph.D. The paper can be obtained at: http://www.nejm.org/

About Cold Spring Harbor Laboratory

Celebrating its 125th Anniversary in 2015, Cold Spring Harbor Laboratory (CSHL) has shaped contemporary biomedical research and education with programs in cancer, neuroscience, plant biology and quantitative biology. CSHL is ranked number one in the world by Thomson Reuters for the impact of its research in molecular biology and genetics, and has been home to eight Nobel Prize winners. Today, CSHL's multidisciplinary scientific community is more than 600 researchers and technicians strong and its Meetings & Courses program hosts more than 12,000 scientists from around the world each year to its Long Island campus and its China center. A 501 (c) (3) not-for-profit organization, CSHL is independ.ently ranked in the top 1% of charities by Charity Navigator. For more information, visit www.cshl.edu.

About the Lustgarten Foundation

The Foundation's mission is to advance the scientific and medical research related to the diagnosis, treatment, cure and prevention of pancreatic cancer by: Increasing funding and support of research into the biological mechanisms and clinical strategies related to the prevention, diagnosis, and treatment of pancreatic cancer; facilitating and enhancing the dialogue among members of the medical and scientific communities about basic and clinical research efforts that relate to pancreatic cancer;and Heightening public awareness of pancreatic cancer diagnosis, treatment, and prevention and providing informational support for pancreatic cancer patients, their families, and friends. www.lustgarten.org

Public Affairs
pubaff@cshl.edu
516-367-8455

Hey, check out all the research scientist jobs. Post your resume today!