Therapy slows onset and progression of Lou Gehrig's disease, study finds

Posted: September 10, 2013 at 7:40 am

Public release date: 9-Sep-2013 [ | E-mail | Share ]

Contact: Gina Bericchia Gina.Bericchia@NationwideChildrens.org 614-355-0495 Nationwide Children's Hospital

Studies of a therapy designed to treat amyotrophic lateral sclerosis (ALS) suggest that the treatment dramatically slows onset and progression of the deadly disease, one of the most common neuromuscular disorders in the world. The researchers, led by teams from The Research Institute at Nationwide Children's Hospital and the Ludwig Institute at the University of California, San Diego, found a survival increase of up to 39 percent in animal models with a one-time treatment, a crucial step toward moving the therapy into human clinical trials.

The therapy reduces expression of a gene called SOD1, which in some cases of familial ALS has a mutation that weakens and kills nerve cells called motor neurons that control muscle movement. While many drug studies involve only one type of animal model, this effort included analysis in two different models treated before and after disease onset. The in-depth study could vault the drug into human clinical trials, said Brian Kaspar, PhD, a principal investigator in the Center for Gene Therapy at Nationwide Children's and a senior author on the research, which was published online Sept. 6 in Molecular Therapy.

"We designed these rigorous studies using two different models of the disease with the experimenters blinded to the treatment and in two separate laboratories," said Dr. Kaspar, who collaborated on the study with a team led by Don Cleveland, PhD, at the University of California, San Diego. "We were very pleased with the results, and found that the delivery approach was successful in a larger species, enabling us to initiate a clinical translational plan for this horrible disease."

There currently is no cure for ALS, also called Lou Gehrig's disease. The Centers for Disease Control and Prevention estimates there are about 5,000 new cases in the U.S. each year, mostly in people age 50 to 60. Although the exact cause of ALS is unknown, more than 170 mutations in the SOD1 gene have been found in many patients with familial ALS, which accounts for about 2 percent of all cases.

SOD1 provides instructions for making an enzyme called superoxide dismutase, which is found throughout the body and breaks down toxic molecules that can be damaging to cells. When mutated, the SOD1 gene yields a faulty version of the enzyme that is especially harmful to motor neurons. One of the mutations, which is found in about half of all familial ALS patients, is particularly devastating, with death usually coming within 18 months of diagnosis. SOD1 has also been implicated in other types of ALS, called sporadic ALS, which means the therapy could prove beneficial for larger numbers of patients suffering with this disease.

Earlier work by Dr. Kaspar and others found that they could halt production of the mutated enzyme by blocking SOD1 expression, which in turn, they suspected, would slow ALS progression. To test this hypothesis, the researchers would not only need to come up with an approach that would block the gene, but also figure out how to specifically target cells implicated in the disease, which include motor neurons and glial cells. What's more, the therapy would preferably be administered noninvasively instead of direct delivery via burr holes drilled into the skull.

Dr. Kaspar's team accomplished the second part of this challenge in 2009, when they discovered that adeno-associated virus serotype 9 (AAV9) could cross the blood-brain barrier, making it an ideal transport system for delivering genes and RNA interference strategies designed to treat disease.

In this new work, funded by the National Institutes of Health, the researchers blocked human SOD1, using a technology known as short hairpin RNA, or shRNA. These single strands of RNA are designed in the lab to seek out specific sequences found in the human SOD1 gene, latch onto them and block gene expression.

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Therapy slows onset and progression of Lou Gehrig's disease, study finds

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