Possible Therapy for Tamoxifen-Resistant Breast Cancer Identified
Article ID: 595563
Released: 30-Oct-2012 11:45 AM EDT
Source Newsroom: Ohio State University Center for Clinical and Translational Science
Discovery of molecular “back door” in cancer cells could translate into chemotherapy-sparing option
Newswise — COLUMBUS, Ohio – A study by researchers at the Ohio State University Comprehensive Cancer Center – Arthur G. James Cancer Hospital and Richard J. Solove Research Institute (OSUCCC – James) has discovered how tamoxifen-resistant breast-cancer cells grow and proliferate. It also suggests that an experimental agent might offer a novel targeted therapy for tamoxifen-resistant breast cancer.
Like a second door that opens after the first door closes, a signaling pathway called hedgehog (Hhg) can promote the growth of breast-cancer cells after tamoxifen shuts down the pathway activated by the hormone estrogen. A second signaling pathway, called PI3K/AKT, is also involved.
Activation of the Hhg pathway renders tamoxifen treatment ineffective and enables the tumor to resume its growth and progression. As part of the study, the researchers analyzed over 300 human tumors and found that the tumors with an activated Hhg pathway had a worse prognosis.
Finally, the researchers showed that an experimental drug called vismodegib, which blocks the Hhg pathway, inhibits the growth of tamoxifen-resistant human breast tumors in an animal model. The drug is in clinical trials testing for other types of cancer.
Currently, chemotherapy is used to treat hormone-resistant breast cancers, but this is associated with significant side effects. This study has identified targeted therapies that could be an alternative to chemotherapy for these resistant tumors.
“Our findings suggest that we can target this pathway in patients with estrogen-receptor breast cancers who have failed tamoxifen therapy,” says first author Dr. Bhuvaneswari Ramaswamy, a medical oncologist specializing in breast cancer at the OSUCCC – James and OSU College of Medicine.
In 2008, Ramaswamy was awarded pilot funding from the Ohio State Center for Clinical and Translational Science (CCTS) and the Center for Women’s Health to compare the microRNA of tissue from tumors treated with tamoxifen with those that have not been treated. The data from this early study provided critical information on how microRNA, a regulator of genetic expression, reflects a tumor’s response to tamoxifen. The research team used these findings to help focus their current phase of research, which was just published in the journal Cancer Research.
“We describe a link between the hedgehog signaling pathway, which promotes tamoxifen resistance, and the PI3K/AKT pathway,” says principal investigator Sarmila Majumder, research assistant professor in molecular and cellular biochemistry at the OSUCCC – James. “Targeting the hedgehog pathway alone or in combination with the PI3K/AKT pathway could be a novel therapeutic option for treating tamoxifen-resistant breast cancer.”
Ramaswamy, an assistant professor of internal medicine at Ohio State, emphasizes that novel options are needed for these patients.
“A combined targeted therapy using both hedgehog and PI3K inhibitors could lead to a novel treatment for endocrine-resistant tumors in the future without use of chemotherapy,” she says. “And these agents we have identified are all in clinical development for other kinds of cancer.”
Approximately 230,000 new cases of breast cancer are expected in the United States in 2012, and almost 40,000 Americans will die from the disease. More than two-thirds of breast cancer cases show high levels of the estrogen receptor (ER). Doctors use the drug tamoxifen to treat these ER-positive tumors, and Ramaswamy notes that the drug has improved the disease-free survival of people with ER-positive breast cancer by 50 percent.
“But 30 to 40 percent of patients taking tamoxifen become resistant to it after about five years,” she says. Currently, there are very limited options for these patients and most end up receiving chemotherapy.
Key findings for this study include:
• Tamoxifen-resistant breast cancer depends on the Hhg pathway for cell growth;
• The PI3K/AKT pathway protects key Hhg signaling proteins from degradation, which promotes activation of the Hhg pathway.
• Analysis of 315 invasive breast cancers showed that high levels of the protein GLI1, an important Hhg marker, was correlated with poorer disease-free survival and overall survival.
“Our next step is to organize a clinical trial to evaluate vismodegib in patients with tamoxifen-resistant breast cancer,” Ramaswamy says.
Funding from the NIH/National Cancer Institute (grants CA137567 and CA133250) and a Pelotonia Idea grant supported this research. Other Ohio State researchers involved in this study were Yuanzhi Lu, Kun-yu Teng, Gerard Nuovo, Xiaobai Li and Charles L. Shapiro.
About The Ohio State University Center for Clinical and Translational Science
Dedicated to turning the scientific discoveries of today into the life-changing health innovations of tomorrow, The Ohio State University Center for Clinical and Translational Science (OSU CCTS) is a collaboration of experts including scientists and clinicians from seven OSU Health Science Colleges, OSU Medical Center and Nationwide Children’s Hospital. Funded by a multi-year Clinical and Translational Science Award (CTSA) from the National Institutes of Health, OSU CCTS provides financial, organizational and educational support to biomedical researchers as well as opportunities for community members to participate in credible and valuable research. The CCTS is led by Rebecca Jackson, M.D., Director of the CCTS and associate dean of research at Ohio State. For more information, visit http://ccts.osu.edu.
About the Clinical and Translational Science Awards
Launched in 2006 by the NIH, and currently residing in the newly created National Center for the Advancement of Translational Sciences (NCATS), the Clinical and Translational Science Awards (CTSA) program created academic homes for clinical and translational science at research institutions across the country. The CTSA’s primary goals are to speed the time it takes for basic science to turn into useable therapeutics that directly improve human health, and to train the next generation of clinicians and translational researchers.
The Ohio State University Comprehensive Cancer Center
Arthur G. James Cancer Hospital and Richard J. Solove Research Institute strives to create a cancer-free world by integrating scientific research with excellence in education and patient-centered care, a strategy that leads to better methods of prevention, detection and treatment. Ohio State is one of only 41 National Cancer Institute (NCI)-designated Comprehensive Cancer Centers and one of only seven centers funded by the NCI to conduct both phase I and phase II clinical trials. The NCI recently rated Ohio State’s cancer program as “exceptional,” the highest rating given by NCI survey teams. As the cancer program’s 210-bed adult patient-care component, The James is a “Top Hospital” as named by the Leapfrog Group and one of the top cancer hospitals in the nation as ranked by U.S.News & World Report.
The Ohio State University Center for Clinical and Translational Science (CCTS) is funded by the National Institutes of Health (NIH) Clinical and Translational Science Award (CTSA) program (grants 8UL1TR000090-05, 8KL2TR000112-05, and 8TL1TR000091-05) The CTSA program is led by the NIH’s National Center for Advancing Translational Sciences (NCATS). The content of this release is solely the responsibility of the CCTS and does not necessarily represent the official views of the NIH.