A new study from The Ottawa Hospital and the University of Ottawa is poised to completely change our understanding of Duchenne muscular dystrophy and pave the way for far more effective treatments.
The study is the first to show that Duchenne muscular dystrophy directly affects muscle stem cells.
“For nearly 20 years, we’ve thought that the muscle weakness observed in patients with Duchenne muscular dystrophy is primarily due to problems in their muscle fibers, but our research shows that it is also due to intrinsic defects in the function of their muscle stem cells,” said Dr. Michael Rudnicki, senior author of the study. “This completely changes our understanding of Duchenne muscular dystrophy and could eventually lead to far more effective treatments.”
Dr. Rudnicki is the Director of the Regenerative Medicine Program at The Ottawa Hospital and a professor at the University of Ottawa. He also holds the Canada Research Chair in Molecular Genetics.
Duchenne muscular dystrophy is the most common form of muscular dystrophy, affecting approximately 1 in 3,600 boys. It is caused by genetic mutations that result in the loss of the dystrophin protein, leading to progressive muscle weakness and death by the second or third decade of life.
Muscle stem cells are responsible for muscle repair after normal injuries and exercise. In response to muscle damage, these stem cells divide to generate precursor cells that become the fibers that make up our muscles.
For many years, dystrophin was thought to be a simple structural protein only found in muscle fibers. In the current study, Dr. Rudnicki and his team discovered that muscle stem cells also express the dystrophin protein, and without this protein, they produce 10-fold fewer muscle precursor cells, which in-turn generate fewer functional muscle fibers. They also discovered that dystrophin is a key member of the molecular machinery that enables muscle stem cells sense their orientation in the surrounding tissue.
“Muscle stem cells that lack dystrophin cannot tell which way is up and which way is down,” said Dr. Rudnicki. “This is crucial because muscle stem cells need to sense their environment to decide whether to produce more stem cells or to form new muscle fibers. Without this information, muscle stem cells cannot divide properly and cannot properly repair damaged muscle.”
This research was conducted in mouse cells, but it is expected that the findings will hold in humans, as the dystrophin protein is almost identical in all animals.
Current treatments for Duchenne muscular dystrophy are limited to steroids and physical therapy that slow disease progression and lessen symptoms. Experimental approaches such as gene therapy are also being investigated, but Dr. Rudnicki’s research suggests that these approaches will have to be modified so that they target muscle stem cells as well as muscle fibers.
“We’re already looking at approaches to correct this problem in muscle stem cells,” said Dr. Rudnicki. “I’m not sure if we will ever cure Duchenne muscular dystrophy, but I’m very hopeful that someday in the future, we will have new therapies that correct the ability of muscle stem cells to repair the muscles of afflicted patients and turn this devastating, lethal disease into a chronic but manageable condition.”
The discovery is being hailed by experts in the field, including Dr. Ronald Worton, who co-discovered the gene for Duchenne muscular dystrophy in 1987 and served as Vice-President of Research at The Ottawa Hospital from 1996 to 2007.
“When we discovered the gene for Duchenne muscular dystrophy, there was great hope that we would be able to develop a new treatment fairly quickly,” said Dr. Worton, who is now retired. “This has been much more difficult than we initially thought, but Dr. Rudnicki’s research is a major breakthrough that should renew hope for researchers, patients, and families.”
Illustration: A normal mouse muscle fiber (top left) is contrasted with a muscle fiber from a mouse model of Duchenne muscular dystrophy (bottom right). In normal mice, stem cells (pink) express dystrophin (green) and are able to easily generate new muscle fibers, but in the disease model, there is no dystrophin and the stem cells lose their sense of direction and have trouble generating new muscle fibers. Reproduced with permission of Will Wang. –Will Wang.
Ottawa Hospital Research Institute News Release (11/16/15)
Science Daily (11/16/15)
Abstract (Nature Medicine; (11/16/15))