News Release

'Bridge' protein spurs deadliest stages of breast cancer

New role for protein yields promising lead for metastasis prevention

Peer-Reviewed Publication

Sanford-Burnham Prebys

A protein known for its ability to "bridge" interactions between other cellular proteins may spur metastasis in breast cancer, the disease’s deadliest stage, a study from Burnham Institute for Medical Research has found.

Led by professor Gen-Sheng Feng, Ph.D., and colleagues at Burnham and Royal Victoria Hospital in Montreal, Quebec, the study ranks among the first to more precisely define the cancer role for the protein known as Gab-2. These results, to be published in the journal Oncogene, have been made available to the worldwide medical research community by priority posting online at the journal’s website.

The protein has been of keen research interest for its role in breast cancer, but whether it controlled metastasis or initial tumor growth was unknown. Gab-2 is one of a group of proteins known as "scaffold" or "bridge" proteins, which provide a molecular intermediary to help cell signal proteins interact.

"Although Gab-2 is highly expressed in breast cancer, it is not essential for the development of cancer," said Feng. "We found that Gab-2 is, however, essential for metastasis, or the spread of cancer. Breast cancer victims can survive before metastasis, but their chances decrease significantly when the cancer cells have spread. If we can understand precisely how Gab-2 functions in metastasis, then we might be able use this knowledge to design treatments that would block the deadly metastasis."

Feng, who studies molecular signaling in embryonic stem cells and examines signaling pathways that are involved in obesity and diabetes, has studied the roles played by Gab-2 and its chemical cousin Gab-1, in various disorders. His fundamental analyses of cell signaling for Gab-2 led him to study the protein in cancer cells.

Feng and his colleagues began by examining Gab-2’s role in a pathway influenced by the cancer-causing oncogene Neu, which is implicated in nearly 30 percent of human breast cancers and associated with poor survival rates. While scientists have known that the Neu pathway drives cancer development and metastasis (and can be treated with the drug Herceptin with a certain degree of success), the molecular mechanisms that lead to breast cancer development and metastasis are not fully understood.

Feng worked with mice a special strain of mice which lacks the gene for Gab-2. The Gab-2 mutant mice were bred with two types of mice; one with an active gene that induced metastatic breast cancer tumors and another that grew breast cancer cells with low potential for metastasis.

The mutant mice showed minor effects from the initial growth of breast cancer cells, Feng and his team found, indicating that Gab-2 has little effect on inducing cancer cell growth. However, in the mice pre-disposed to metastatic breast caner, the lack of Gab-2 potently reduced metastasis rates, indicating that Gab-2 was necessary for metastasis, if not for initial tumor growth.

Since Gab-2 is a scaffold molecule and is possibly part of many signaling pathways, Feng’s group wanted to determine how it influences cancer cell growth. They studied pathways known as Akt and Erk, well-known parts of the Neu oncogene pathway, in the mice lacking Gab-2 and found that while levels of Akt signals were unaffected by Gab-2’s absence, Erk signals were significantly reduced.

"It appears that Akt and Erk pathways have distinctive roles in mammary tumors; initiation and growth for Akt and metastasis for Erk," said Feng. "We suspect that Gab-2 might promote mammary cell metastasis through Erk activation. This is a novel mechanism for breast cancer metastasis which makes Gab-2 a possible new target for the design of therapies for metastatic breast cancer."

Feng and his team are now looking at the other molecules that assist the scaffold protein Gab-2’s effects on breast cancer metastasis.

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Feng’s colleagues in the study include Yuehai Ke, Dongmei Wu, Frederic Princen, Thanh Nguyen, Yuhong Pang, Jacqueline Lesperance and Robert Oshima of Burnham, and William Muller of Royal Victoria Hospital, Montreal, Quebec, Canada.

This research was supported by grants from the National Cancer Institute and from the National Heart, Lung, and Blood Institute of the National Institutes of Health, and a postdoctoral fellowship from the California Breast Cancer Research Program.

About Burnham Institute for Medical Research. Burnham Institute for Medical Research conducts world-class collaborative research dedicated to finding cures for human disease, improving quality of life, and thus creating a legacy for its employees, partners, donors, and community. The La Jolla, California campus was established as a nonprofit, public benefit corporation in 1976 and is now home to three major centers: a National Cancer Institute-designated Cancer Center, the Del E. Webb Center for Neurosciences and Aging, and the Infectious and Inflammatory Disease Center. Burnham today employs over 750 people and ranks consistently among the world’s top 20 research institutes. In 2006, Burnham established a presence at the University of California, Santa Barbara, led by Dr. Erkki Ruoslahti, Distinguished Professor. Burnham is also establishing a campus at Lake Nona in Orlando, Florida that will focus on diabetes and obesity research and will expand the Institute’s drug discovery capabilities. For additional information about Burnham and to learn about ways to support its research, visit www.burnham.org.


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