01/Nov/2012
Adding an angiogenesis inhibitor to treatment with a
HER2-inhibiting drug could improve outcomes for patients with
HER2-positive breast cancer who develop brain metastases. In
their report published online in PNAS Plus, Massachusetts
General Hospital (MGH) investigators report the first preclinical
study combining antiangiogenic and anti-HER2 drugs in an animal
model of brain metastatic breast cancer.
"We have shown dramatic improvement in survival by slowing the
growth of brain metastatic, HER2-amplified breast cancer," says
Rakesh Jain, PhD, director of the Steele Laboratory for
Tumor Biology at MGH, Cook Professor of Radiation Oncology
(Tumor Biology) at Harvard Medical School and senior author of the
study. "This is particularly important because patients with this
type of breast cancer have an increased risk of brain metastases,
which have not responded to current therapies."
A quarter of breast cancers are driven by overexpression of the
growth factor HER2, making them particularly aggressive.
Treatment with drugs that block the pathway controlled by HER2
– trastuzumab (Herceptin) and lapatinib (Tykerb)
– suppresses the growth of these tumors and extends patient
survival. But these patients are at increased risk of
developing brain metastases, which have resisted anti-HER2
treatment. Angiogenesis is also known to have an important
role in breast cancer, and although previous studies combining
chemotherapy with the antiangiogenesis drug bevacizumab (Avastin)
delayed disease progression, they have not extended overall
survival.
In addition to directly blocking the HER2-controlled growth
pathway, anti-HER2 drugs also contribute to suppression of
tumor-associated blood vessels. Previous studies in Jain's
lab suggested that the proangiogenic factor VEGF may overcome the
antiangiogenic effects of anti-HER2 drugs. This observation
led the researchers to investigate whether blocking the VEGF
pathway would improve the results of anti-HER2 treatment.
Their study used a new mouse model in which the proliferation of
HER2-amplified breast cancer cells implanted into brain tissue
could be monitored over time. The researchers first confirmed
that, as in human patients, treatment with a single anti-HER2 drug
suppressed tumor growth in breast tissue but not within the
brain.
While treatment with DC101, an antibody that blocks the VEGF
pathway in mice, improved survival compared with either anti-HER2
drug, combining DC101 with one anti-HER2 drugs produced even
greater survival improvement, including the death of tumor cells
through significant reduction in tumor-associated
angiogenesis. A triple combination of DC101 with both
anti-HER2 drugs had the most dramatic effects. Animals
receiving a single anti-HER2 drug along with DC101 lived more than
three times as long as control animals, while those receiving all
three drugs lived five times as long.
Jeffrey Engelman, MD, PhD, of the MGH Cancer Center,
co-corresponding author of the PNAS Plus report, notes that a
clinical trial now underway combining chemotherapy with bevacizumab
in breast cancer addsanti-HER2 treatment for those participants
whose tumors are HER2-amplified. The results of the current
MGH study suggest that investigating a triple combination may be
particularly beneficial. "With targeted therapies like
anti-HER2 drugs suppressing the growth of tumors outside the
central nervous system, brain metastasis is becoming a more common
cause of treatment failure."
Co-corresponding author Dai Fukumura, MD, PhD, of the Steele Lab
adds, "A clinical trial of this sort of triple combination will be
an important next step. And in the meantime, we will continue
to investigate the mechanisms of resistance to the effects of both
double and triple combinations." Fukumura is an associate
professor of Radiation Oncology and Engelman an associate professor
of Medicine at Harvard Medical School.
Co-lead authors of the PNAS Plus article are David Kodack, PhD,
Euiheon Chung and Hiroshi Yamashita of the Steele Lab.
Additional co-author are Joao Incio, MD, Annique Duyverman, Yuhui
Huang, PhD, Eleanor Ager, PhD, Walid Kamoun, Shom Goel, MBBS,
Matija Snuderl, MD, Alisha Lussiez, Lotte Hiddingh and Sidra
Mahmood, Steele Lab; Youngchul Song and April Eichler, MD,
MGH Cancer Center; Christian Farrar, PhD, MGH Martinos Center for
Biomedical Imaging, and Bakhos Tannous, PhD, MGH Neurology.
Support for the study includes grants from the National Cancer
Institute and a Breast Cancer Research Innovator Award from the
Department of Defense
Massachusetts General Hospital, founded in 1811, is the original
and largest teaching hospital of Harvard Medical School. The MGH
conducts the largest hospital-based research program in the United
States, with an annual research budget of more than $750 million
and major research centers in AIDS, cardiovascular research,
cancer, computational and integrative biology, cutaneous biology,
human genetics, medical imaging, neurodegenerative disorders,
regenerative medicine, reproductive biology, systems biology,
transplantation biology and photomedicine. In July 2012, MGH moved
into the number one spot on the 2012-13 U.S. News & World
Report list of "America's Best Hospitals."
Media Contacts: Sue McGreevey,
smcgreevey@partners.org, 617 724-2764