Scientists discover genetic switch that increases muscle blood supply
HOUSTON - (March 1, 2011) - Many people suffer from a devastating condition known as critical limb ischemia (CLI) that can lead to muscle wasting and even amputation. The disease is linked to the blockage of blood flow to the skeletal muscle and current treatment options include rehabilitative exercise and surgical bypass of blood vessels. New preclinical research suggests there may be a way to restore blood supply in skeletal muscle without traditional intervention.
Scientists at The University of Texas Health Science Center at Houston (UTHealth) and the Salk Institute for Biological Studies announced in the March 2 print issue of the journal Cell Metabolism that they have identified a genetic switch that can increase the number of blood vessels in the skeletal muscle of non-exercising mice.
Skeletal muscle is composed of two types of fibers: slow twitch fibers that inherently have a dense supply of blood vessels and fast twitch fibers that have fewer blood vessels. The researchers used a gene switch known as estrogen-related receptor gamma (ERR gamma) that when activated in fast twitch fibers of mice by genetic engineering, converts these fibers into slow twitch fibers.
“This consequently resulted in a striking increase in muscle blood supply as measured by imaging and angiography,” said Vihang Narkar, Ph.D., lead investigator and assistant professor of molecular medicine at the UTHealth Medical School. “These genetically-transformed muscles also acquire other characteristics of slow muscles, such as improved metabolic capacity and fatigue resistance that can be additionally beneficial in resolving muscle vascular disease.”
Narkar, whose UTHealth laboratory is in the Center for Diabetes and Obesity Research at the Brown Foundation Institute of Molecular Medicine for the Prevention of Human Diseases, said, “The identification of the estrogen-related receptor gamma vascular switch will open potential therapeutic avenues for treating CLI and other cardiovascular diseases linked to defective blood supply.”
Colin Barker, M.D., assistant professor of cardiology at the UTHealth Medical School, said new research is needed to help people with peripheral artery disease, particularly those with the most severe form - critical limb ischemia. “Poor circulation in the legs can lead to muscle wasting, infections, severe pain and amputation,” he said. “Dr. Narkar’s work potentially has many useful applications. It is very much in the translational medicine arena.”
“Understanding the gene network that specifies high vascular supply to muscle gives us a new and very powerful tool to promote improved muscle performance and the promise of fitness, especially for those who cannot work out,” says Ronald M. Evans, Ph.D., senior author, Howard Hughes Medical Institute Investigator and professor in the Salk’s Institute’s Gene Expression Laboratory. “This is good news for people with heart disease, frailty, peripheral vascular disease and more generally those who have a variety of medical problems where exercise could be helpful but is not possible to achieve.”
In 2010, an estimated 2.8 to 3.5 million U.S. citizens suffered from critical limb ischemia, according to a report by THE SAGE GROUP, an independent research and consulting company specializing in peripheral artery disease. CLI risk factors include diabetes, obesity and smoking.
“Exercise is an important part of any intervention strategy to prevent or treat diabetes mellitus and obesity,” said Perry Bickel, M.D., associate professor of medicine at the UTHealth Medical School and director of the UTHealth Center for Diabetes and Obesity Research. “Results by Drs. Narkar and Evans support the notion that in the future we may be able to design drugs that produce the benefits of exercise in order to counteract the damage that diabetes and obesity cause to the body, such as blockages of blood vessels.”
Narkar and Evans collaborated on a highly-publicized study published in the journal Cell in 2008 in which they used two investigational exercise mimetic drugs – GW1516 and AICAR – to increase the endurance of non-exercising mice. These drugs target different genetic switches, namely PPAR delta and AMPK.
UTHealth research assistant Sabina Lorca also contributed to the study. Contributors from the Salk Institute include: Weiwei Fan, Ph.D.; Michael Downes, Ph.D.; Ruth T. Yu., Ph.D.; Johan W. Jonker, Ph.D.; William A. Alaynick, Ph.D.; Ester Banayo; and Malith S. Karunasiri.
The study, titled “Exercise and PGC1-alpha-Independent Synchronization of Type I Muscle Metabolism and Vasculature by ERR gamma,” was supported by funding from the Howard Hughes Medical Institute, the Larry L. Hillblom Foundation, the Nuclear Receptor Signaling Atlas, The Leona M. and Harry B. Helmsley Charitable Trust and the National Institutes of Health (NIH) to Evans. Grants from the NIH and the Muscular Dystrophy Association to Narkar also supported this study.
About The University of Texas Health Science Center at Houston (UTHealth)
The University of Texas Health Science Center at Houston (UTHealth), the most comprehensive academic health system in The University of Texas System and the U.S. Gulf Coast region, is home to schools of biomedical informatics, biomedical sciences, dentistry, medicine, nursing and public health. It also includes a psychiatric hospital, multiple institutes and centers, a growing network of clinics and outreach programs in education and care throughout the region. The university’s primary teaching hospitals include Memorial Hermann-Texas Medical Center, Children’s Memorial Hermann Hospital and Lyndon B. Johnson General Hospital. Founded in 1972, its faculty, staff and students are committed to delivering innovative solutions that create the best hope for a healthier future.
About the Salk Institute for Biological Studies:
The Salk Institute for Biological Studies is one of the world's preeminent basic research institutions, where internationally renowned faculty probe fundamental life science questions in a unique, collaborative, and creative environment. Focused both on discovery and on mentoring future generations of researchers, Salk scientists make groundbreaking contributions to our understanding of cancer, aging, Alzheimer's, diabetes and infectious diseases by studying neuroscience, genetics, cell and plant biology and related disciplines. Faculty achievements have been recognized with numerous honors, including Nobel Prizes and memberships in the National Academy of Sciences. Founded in 1960 by polio vaccine pioneer Jonas Salk, M.D., the Institute is an independent nonprofit organization and architectural landmark.
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