Cancer

July 18, 2012

VU study finds stress fuels breast cancer metastasis to bone

Stress can promote breast cancer cell colonization of bone, Vanderbilt Center for Bone Biology investigators have discovered.

Florent Elefteriou, Ph.D., right, Preston Campbell and colleagues are investigating the role of stress in priming the bone environment for breast cancer cell metastasis. (photo by John Russell)

Stress can promote breast cancer cell colonization of bone, Vanderbilt Center for Bone Biology investigators have discovered.

The studies, reported July 17 in PLoS Biology, demonstrate in mice that activation of the sympathetic nervous system – the “fight-or-flight” response to stress – primes the bone environment for breast cancer cell metastasis. The researchers were able to prevent breast cancer cell lesions in bone using propranolol, a cardiovascular medicine that inhibits sympathetic nervous system signals.

Metastasis – the spread of cancer cells to distant organs, including bone – is more likely to kill patients than a primary breast tumor, said Florent Elefteriou, Ph.D., director of the Vanderbilt Center for Bone Biology.

“Preventing metastasis is really the goal we want to achieve,” he said.

Elefteriou and his colleagues knew from their previous studies that the sympathetic nervous system stimulated bone remodeling, and that it used some of the same signaling molecules that have been implicated in breast cancer metastasis to bone.

“We came to the hypothesis that sympathetic activation might remodel the bone environment and make it more favorable for cancer cells to metastasize there,” Elefteriou said.

Evidence from the clinic supported this notion. Breast cancer patients who suffered from stress or depression following their primary treatment had shorter survival times. Both stress and depression activate the sympathetic nervous system.

Human breast cancer cells with a fluorescent green “tag” that are injected into the bloodstream of mice metastasize to the mouse skeleton (a femur is shown). Chronic stress increases the number of bone lesions. (image courtesy of Preston Campbell and Florent Elefteriou)

To explore this possible link, the researchers studied cancer cell metastasis in mice. They followed fluorescently “tagged” human breast cancer cells that were injected into the mouse heart to model the stage of metastasis when breast cancer cells leave the primary site and move through the circulation.

They found that treating the mice with a drug that mimics sympathetic nervous system activation caused more cancer lesions in bone. Using physical restraint to stress the mice and activate the sympathetic nervous system also caused more cancer lesions in bone. Treating the restrained mice with propranolol, one of a family of blood pressure medicines called “beta-blockers,” reduced the number of bone lesions.

The investigators demonstrated that sympathetic nervous system activation increases bone levels of a signaling molecule called RANKL, which is known to promote the formation of osteoclasts – bone cells that break down bone tissue. RANKL has also been implicated in cell migration, and Elefteriou and colleagues were able to show that breast cancer cell migration to the bone depends on RANKL.

The findings suggest that beta-blockers or drugs that interfere with RANKL signaling, such as denosumab, may be useful in preventing breast cancer cell metastasis to bone. Propranolol and other beta-blockers are inexpensive, well characterized, and safe in most patients. They may be a good choice for long-term treatment if future studies in patients with breast cancer confirm their ability to block cancer cell metastasis to bone, Elefteriou said.

“If something as simple as a beta blocker could prevent cancer metastasis to bone, this would impact the treatment of millions of patients worldwide,” he said.

Efforts to reduce stress and depression in patients with cancer may have unappreciated benefits in terms of metastasis prevention, he added.

Graduate student Preston Campbell is the first author of the PLoS Biology paper. Other authors include Matthew Karolak, Yun Ma, Ph.D., Daniel Perrien, Ph.D., Kathryn Masood-Campbell, Niki Penner, Steve Munoz, Andries Zijlstra, Ph.D., Xiangli Yang, Ph.D., and Julie Sterling, Ph.D. Elefteriou is associate professor of Medicine, Pharmacology and Cancer Biology.

The research was supported by grants from the National Cancer Institute (CA040035), the National Center for Advancing Translational Sciences (RR024975), and the National Institute of General Medical Sciences (GM007628) of the National Institutes of Health.