Some Cancer Therapies May Provide a New Way to Treat High Blood Pressure
WASHINGTON (November 20, 2017) — Drugs designed to halt cancer growth may offer a new way to control high blood pressure (hypertension), say Georgetown University Medical Center investigators. The finding could offer a real advance in hypertension treatment because although a number of high blood pressure drugs are now available, they work by different mechanisms that are not suited for all patients.
The study, published in the journal Hypertension, found that fibroblast growth factors, or FGFs, involved in increasing blood vessel growth so that cancer can grow, also have a systemic effect on blood pressure. The study suggests that just as oncologists use FGF inhibitors to control cancer, clinicians may be able to use FGF inhibitors to regulate blood pressure and control disease associated with hypertension.
“It’s rare that a single class of drugs can be used for such different conditions, but that is what our study strongly suggests,” says the study’s senior investigator, Anton Wellstein, MD, PhD, professor of oncology and pharmacology at Georgetown University School of Medicine and a researcher at Georgetown Lombardi Comprehensive Cancer Center.
Wellstein and his collaborators previously found that the FGF pathway, when switched on, drives growth of blood vessels that feed a growing tumor (angiogenesis). The development of FGF inhibitors is based in part on their ability to inhibit angiogenesis. The current study took a deeper dive into the pathway and found that a protein, FGFBP1, modulates FGF. The gene that produces FGFBP1 to regulate FGF is known as FGF binding protein 1.
Wellstein had learned from a publication by a group in the United Kingdom that a population in Eastern Europe that had hypertension also had a variation of the FGFBP1 gene. Due to this gene variation in these individuals, FGFBP1 was over-expressed in kidney tissue, the major control hubs for blood pressure.
He decided to test the link between FGFBP1 and hypertension in a mouse model his laboratory at Georgetown had created that revealed the link between FGF and cancer. In these mice, FGFBP1 can be switched on or off.
Wellstein partnered with Christopher S. Wilcox, MD, PhD, professor of medicine at Georgetown and the George E. Schreiner Chair of Nephrology, and when investigators switched on FGFBP1 in mice, their blood pressure shot up. “It actually went up [30 mm Hg] from a normal blood pressure to pretty bad hypertension,” says Wellstein. “It was amazing.”
He adds that he turned the gene on “just to a level you see in people in the Eastern European group who have hypertension.” Wellstein also clarified that when a cancer switches on overproduction of the FGF pathway, in order to stimulate blood vessel production, that has only a local tumor effect, not a systemic one. Most patients using cancer treatment have normal blood pressure, he says.
Further research revealed that hypertension regulation by FGFBP1 occurred in the resistance vessels — the end portion of vessels in different tissues that control the flow to that tissue. The aberrant FGFBP1 gene increased the vessel response to a hormone (angiotensin II) that constricts the blood vessels, making blood pressure rise.
“FGF can control how sensitive the blood pressure regulation by angiotensin II is,” says Wellstein. “That tells us that if a person has hypertension, it is possible to target FGF signaling because it contributes to maintenance of high blood pressure by altering sensitivity to a major vasoconstrictive hormone, angiotensin II,” he says.
Investigators then used an FGF inhibitor in mice with a switched on FGFBP1 gene, and found the drug effectively lowered the sensitivity to angiotensin II in several vascular beds.
“Of course, we can’t say that this tactic will work in humans with hypertension, but it will be straightforward to test this rather surprising possibility to target a new mechanism of blood pressure control,” says Wellstein.
Study co-authors include, from Georgetown University Medical Center: Elena Tassi, PhD; En Yin Lai, MD, PhD; Lingli Li, MD, PhD; Glenn Solis; Yifan Chen, PhD; Will Kiamietzman, MSc; Anna T. Riegel, PhD; and William J. Welch, PhD; and Patricio E. Ray, MD, from Children’s National Medical Center in Washington, D.C.
Georgetown University has filed a provisional patent application related to some of the findings in this paper with Wellstein named as an inventor (updated Nov. 26).
The research was supported by National Institutes of Health grants P01 HL068686, R01s CA71508, DK36079, DK49870, HL102497, P30 CA51008, and the George E. Schreiner Chair of Nephrology and the National Nature Science Foundation of China.
About Georgetown Lombardi Comprehensive Cancer Center (new window)
Georgetown Lombardi Comprehensive Cancer Center is designated by the National Cancer Institute as a comprehensive cancer center — the only cancer center of its kind in the Washington, D.C. area. A part of Georgetown University Medical Center and MedStar Georgetown University Hospital, Georgetown Lombardi seeks to improve the diagnosis, treatment, and prevention of cancer through innovative basic and clinical research, patient care, community education and outreach, and the training of cancer specialists of the future. Connect with Georgetown Lombardi on Facebook (new window) (Facebook.com/GeorgetownLombardi (new window)) and Twitter (new window) (@LombardiCancer (new window)).
About Georgetown University Medical Center (new window)
Georgetown University Medical Center (GUMC) is an internationally recognized academic medical center with a three-part mission of research, teaching and patient care (through MedStar Health). GUMC’s mission is carried out with a strong emphasis on public service and a dedication to the Catholic, Jesuit principle of cura personalis — or “care of the whole person.” The Medical Center includes the School of Medicine and the School of Nursing & Health Studies, both nationally ranked; Georgetown Lombardi Comprehensive Cancer Center, designated as a comprehensive cancer center by the National Cancer Institute; and the Biomedical Graduate Research Organization, which accounts for the majority of externally funded research at GUMC including a Clinical and Translational Science Award from the National Institutes of Health. Connect with GUMC on Facebook (new window) (Facebook.com/GUMCUpdate (new window)), Twitter (new window) (@gumedcenter (new window)) and Instagram (new window) (@gumedcenter (new window)).