Researchers have developed a mouse model of brain-metastatic breast cancer and found the potential of stem-cell-based therapy to eliminate metastatic cells from the brain and prolong survival is strong.

The research team developed a mouse model that closely mimics what is seen in patients. They found that injecting into the carotid artery breast cancer cells that express markers allowing them to enter the brain - cells labeled with bioluminescent and fluorescent markers to enable tracking by imaging technologies - resulted in the formation of many metastatic tumors throughout the brain, mimicking what is seen in advanced breast cancer patients. Current therapeutic options for such patients are limited, particularly when there are many metastases. 

To devise a potential new therapy, the investigators engineered a population of neural stem cells to express a potent version of a gene called TRAIL, which codes for a molecule that activates cell-death-inducing receptors found only on the surface of cancer cells. Previous research by Shah and his colleagues had shown that two types of stem cells are naturally attracted toward tumors in the brain.

After first verifying in their model that stem cells injected to the brain would travel to multiple metastatic sites and not to tumor-free areas, the team implanted TRAIL-expressing stem cells into the brains of metastasis-bearing mice, which reduced the growth of tumors. Injecting the TRAIL-expressing stem cells into the carotid artery, a likely strategy for clinical application, led to significantly slower tumor growth and increased survival, compared with animals receiving unaltered stem cells or control injections.

The safe use of a stem-cell-based therapy against brain metastasis would require preventing the engineered cells from persisting within the brain, where they could affect normal tissue and possibly give rise to new tumors. To facilitate removal of the therapeutic stem cells from the brain at the conclusion of therapy, the researchers created cells that, in addition to TRAIL, express a viral gene called HSV-TK, which renders them susceptible to the effects of the antiviral drug ganciclovir.

Several tests in cultured cells indicated that ganciclovir would cause the death of HSV-TK-expressing stem cells, and testing in the mouse model confirmed that administration of the drug after successful treatment of brain metastases successfully eliminated therapeutic stem cells that also expressed HSV-TK.

 "Metastatic brain tumors - often from lung, breast or skin cancers - are the most commonly observed tumors within the brain and account for about 30 percent of advanced breast cancer metastases," says Khalid Shah, MS, PhD, an HSCI Principal Faculty member and director of the Molecular Neurotherapy and Imaging Laboratory in the MGH Departments of Radiology and Neurology, who led the study. "Our results are the first to provide insight into ways of targeting brain metastases with stem-cell-directed molecules that specifically induce the death of tumor cells and then eliminating the therapeutic stem cells." 

Published in Brain. In addition to Shah, who also is an associate professor at Harvard Medical School, authors of the Brain report are co-lead authors Wanlu Du, PhD, and Tugba Bagci-Onder, PhD, along with Jose-Luiz Figueiredo, MD, and Jordi Martinez-Quintanilla, PhD - all of the MGH Molecular Neurotherapy and Imaging Laboratory. The study was supported by National Institutes of Health grants CA138922 and NS071197 and a grant from the James McDonald Foundation.