New Hope for Antibody to Treat Muscular Dystrophy

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Antibody reduces muscle scarring in animal model, expected to be tested for safety in humans

Elizabeth McNally, MD, PhD, director of the Center for Genetic Medicine and the Elizabeth J. Ward Professor of Genetic Medicine, was the senior author of the study.

Northwestern Medicine scientists have developed an antibody that they believe can be used to treat muscular dystrophy, findings that were published in Science Translational Medicine.

“We believe this can become a therapy for muscular dystrophy, including the many different forms of muscular dystrophy,” said senior study author Elizabeth McNally, MD, PhD, director of the Center for Genetic Medicine and the Elizabeth J. Ward Professor of Genetic Medicine. “Given the success with so many other antibodies in treating chronic human diseases like rheumatoid arthritis and psoriasis, we are very optimistic this antibody can translate into the human disease setting.”

The antibody targets the TGF-beta pathway, a pathway known to be important for regulating scarring (fibrosis). In muscular dystrophy, the muscles become scarred over time, and this antibody helps reduce scarring in the muscles. With this treatment the muscles also became stronger.

The study was conducted in an animal model of muscular dystrophy, and the scientists hope to develop the antibody to treat people, since the pathways are the same in the animal models as they are in people with muscular dystrophy.

About 300,000 people in the U.S. live with muscular dystrophy. There are currently only a small number of treatments for a tiny percentage of patients who have very specific gene mutations. Most patients with muscular dystrophy have no therapeutic options.

Alexis Demonbreun, PhD, assistant professor of Pharmacology, was the lead author of the study.

The target protein in this case binds the three major forms of TGF-beta, which makes it more effective than other approaches that target single forms of TGF-beta. Many scientists have tried to target TGF-beta to treat disease, but it has been difficult to do this successfully because of the multiple forms and their complicated pathway of action.

The team made an antibody to the protein that binds all three forms of TGF-beta and stabilizes these proteins so they cannot become active. Too much TGF-beta activity is a major contributor to scarring and muscle weakness in muscular dystrophy.

Alexis Demonbreun, PhD, the lead study author and an assistant professor of Pharmacology, selected antibodies to the hinge region of the target protein (called LTBP4), since this hinge is critically important to stabilizing and keeping TGF-beta from being overactive. The hinge is normally cleaved by enzymes to trigger release of TGF-beta. The antibody blocks the cleavage and the activation of the complex.

The next steps in the research are optimizing the antibody sequence to improve its activity and so that it can be produced in larger quantities. Once that is done, the full safety studies are required before launching a clinical trial.

Other Northwestern authors include David Barefield, PhD, adjunct assistant professor of Neuroscience; Mattia Quattrocelli, PhD; Katherine Fallon; Claire Oosterbaan; Lauren Vaught; Nina Reiser; Elena Bogdanovic; Matthew Velez; Isabella Salamone; Patrick G.T. Page; and Michele Hadhazy.

The work was supported by National Institutes of Health grants HL140938, AR052646, DK121875, AR073655, HL141698, and Parent Project Muscular Dystrophy, the Muscular Dystrophy Association, Department of Defense grant W81XWH-17-DMDRP-IIRA and a sponsored research agreement from Solid Biosciences to Northwestern University.