Research Updates

• Gene Therapy Offers Hope for Congenital MD
• With Aggressive Care, Nemaline Myopathy Often Has Good Prognosis
• SMA Drug Search Gains Ground
• Drug Helps Preserve Bone for Corticosteroid Users
• Multicenter Study to Test Albuterol, Oxandrolone in FSH Dystrophy
• Newly Found Genes for Muscle Atrophy May Be Clues in ALS, SMA, CMT
• Coenzyme Q10 May Help in Friedreich's Ataxia, Mitochondrial Disease

Gene Therapy Offers Hope for Congenital MD

A group of European scientists has shown that an innovative gene therapy strategy holds promise for treating congenital muscular dystrophy (CMD) — a group of muscular dystrophies that manifest at birth and cause a variable degree of muscle weakness and wasting.

The most common form of CMD (called merosin-deficient CMD) is caused by flaws in the laminin alpha2 gene, which encodes a protein that's part of a larger protein complex called laminin. Laminin (sometimes called merosin) normally serves as a linchpin in a protein scaffold that surrounds and supports muscle cells, and when it's defective, the scaffold and the affected muscle fall apart.

This type of CMD ranges in severity from mild to extreme. In the most severe cases, affected individuals never gain the ability to walk, and die before age 30.

Theoretically, scientists could treat the disease by supplying an intact laminin alpha2 gene. But the European scientists, led by Markus Ruegg at the University of Basel in Switzerland, have shown that it might be more effective to supply the gene for agrin, a protein that has similar functions to laminin alpha2.

In healthy muscle, laminin alpha2 provides a link between proteins outside the muscle cell and proteins on the inside, but in CMD, that link is destroyed. With gene therapy or a drug treatment, miniagrin could be used to reconnect the proteins.

In the Sept. 20 issue of Nature, the group reported that a miniaturized version of the agrin protein (called miniagrin) could substitute for laminin alpha2 and thus largely prevent CMD in laminin alpha2-deficient mice.

The mice were genetically engineered to overproduce miniagrin. One day, people with CMD might be treated with virally delivered miniagrin or a drug that boosts the body's natural production of agrin, the group suggests.

These approaches would avoid potential immune reactions caused by giving the laminin alpha2 protein to someone whose body has never seen it, they say.

The new study builds on previous MDA-supported research into gene therapy for Duchenne muscular dystrophy, which is caused by a deficiency of the dystrophin protein. Dystrophin-deficient mice are rescued from DMD when they're given extra genes for one of two functionally similar proteins, utrophin or integrin.

MDA grantee Stephen Kaufman, who led the integrin studies at the University of Illinois in Urbana, said the new study "adds to the potential for using complementary genes to provide a remedy for the defective genes that cause muscular dystrophy." Much work still needs to be done to develop this complementary gene approach, he added.

With Aggressive Care, Nemaline Myopathy Often Has Good Prognosis

In the largest study of its kind to date, an MDA-funded research team has shown that nemaline myopathy (NM) often follows a favorable course with time, stabilizing in most cases and even improving in some.

NM causes muscle weakness and hypotonia (poor muscle tone), and is associated with nemaline bodies, abnormal clumps of threadlike material that crowd inside affected muscle cells. Despite those hallmark features, the disease exists in many forms, ranging from severe congenital-onset (near birth) cases to relatively mild adult-onset ones. It has been linked to mutations in several genes.

Most studies on NM have examined just a handful of people, and with so many variations, researchers have struggled to develop a clear picture of the disease.

In the new study, MDA grantee Alan Beggs of Children's Hospital and Harvard Medical School in Boston collaborated with researchers from the United States and Australia to get a snapshot of the disease in 143 people. The study was published in the September issue of Annals of Neurology.

In congenital-onset NM, there were often complications during pregnancy and delivery, nearly all infants were hypotonic at birth, and some had significant respiratory weakness. Many of them had feeding difficulties that required gastrostomy (insertion of a feeding tube into the stomach). But despite those dire beginnings, the majority of those babies survived, and some gained enough strength to walk within the first few years of life.

In the most severe cases, respiratory failure at delivery led to death during infancy. Infants who required respiratory support later in the first year of life survived and remained ventilator-dependent. Other infants with respiratory weakness and frequent respiratory infections improved with time; some went on to require nighttime ventilation.

"The important point is that some apparently severe cases at birth later do well, so aggressive postnatal management and supportive care are warranted," Beggs said.

Few people with childhood- and adult-onset NM experienced noticeable respiratory weakness, none required gastrotomy, and only one child lost the ability to walk. However, a significant number showed abnormal respiratory function in laboratory tests, and a few died from respiratory disease.

Beggs emphasized that these findings should sound a warning for all people with NM to watch for respiratory complications, especially at night.

"Formal sleep studies on all patients are important to establish who may be at risk [for nighttime respiratory problems]. Abnormal findings should be followed up every few years, during significant changes in health, and prior to surgery," he said.

SMA Drug Search Gains Ground

Scientists have reported progress toward developing a drug treatment for spinal muscular atrophy (SMA) — a life-threatening disease that kills muscle-controlling nerve cells (motor neurons) in the spinal cord.

Nearly all cases of SMA are caused by flaws in the SMN1 gene, which encodes a protein called survival motor neuron (SMN). Everyone has a "backup" SMN gene called SMN2, but it produces very low levels of active SMN protein — not enough to fully substitute for SMN1.

Two genes — SMN1 and SMN2 — produce the essential SMN protein, but SMN2 makes a shortened version predominantly. Hence, a deficiency of SMN1 causes SMA. Researchers hope to treat SMA using a drug to boost the level of full-length protein from SMN2.

The key difference between SMN1 and SMN2 lies in the way cells handle RNA (the intermediate between genes and proteins). Two years ago, MDA grantees Christian Lorson of Arizona State University in Tempe and Elliot Androphy of New England Medical Center in Boston showed that an essential piece of SMN2 RNA is normally removed, creating a shortened (and mostly nonfunctional) SMN protein.

Still, people with SMA who happen to have extra copies of the SMN2 gene develop a less severe form of the disease (SMA type 2 or 3), and in mice, a genetically engineered boost of SMN2 can eliminate the disease.

Inspired by those observations, the San Diego-based biotechnology company Aurora Biosciences is screening millions of chemicals to find drugs that might jump-start SMN2 (see Quest, vol. 8, no. 4, "Fast-Track Pharmacy: Fishing for Drugs"). In the meantime, Lorson, Androphy and two other research teams have reported some promising "hits" in smaller screens.

In their MDA-funded screen, Lorson, Androphy and their team attached the SMN2 gene to the gene for jellyfish green fluorescent protein (GFP), and injected the fused SMN2-GFP gene into cells in a petri dish. That allowed them to use a simple color change — from no color to bright green — to identify chemicals that stimulated the cells to make full-length SMN2. In the November issue of Gene Therapy, they report that the mineral sodium vanadate turned the cells green, and also increased the level of full-length SMN2 in cells derived from SMA patients.

The other two groups conducted similar screens, starting with cells from SMA patients.

One group found that the antibiotic and anti-cancer drug aclarubicin increased the amount of full-length SMN2. The group, led by Arthur Burghes of Ohio State University in Columbus, presented its findings at the American Society of Human Genetics meeting held in San Diego in October. With support from MDA, Burghes created the mouse model of SMA in the late 1990s.

The other group found similar results with sodium butyrate — a drug that's been used to treat certain kinds of anemia. When tested on mice, the drug appeared to lessen the severity of SMA, and improved survival in those with mild disease signs similar to SMA types 2 and 3. The group, led by Hung Li of Kaohsiung Medical University in Taiwan, published its findings in the Aug. 14 issue of the Proceedings of the National Academy of Sciences.

Despite the promising results, it's doubtful that any of the chemicals can be used to treat SMA. Sodium vanadate is toxic, Lorson said. And although aclarubicin and sodium butyrate have been used to treat other diseases, it's unclear whether they'll have beneficial effects on SMA. They, too, may turn out to be toxic at the doses needed.

At this point, Burghes said, "I would say absolutely do not take aclarubicin. In my view, butyrate has not been tested rigorously enough in animals and there is no evidence it works in humans [with SMA]."

Still, these small screens offer an encouraging look ahead at Aurora's large screen. "These are great 'proof of principle' experiments in the sense that now we know there are chemicals that can modulate the RNA processing of SMN2," Lorson said.

Drug Helps Preserve Bone for Corticosteroid Users

The risk of fracturing bones, particularly the vertebrae in the spine, is high in patients taking corticosteroids, such as prednisone (Deltasone, Orasone) and prednisone-related medications. Corticosteroids, also known as glucocorticoids, are often prescribed for myasthenia gravis, Lambert-Eaton syndrome, dermatomyositis and polymyositis. They're also sometimes used in inclusion-body myositis and Duchenne muscular dystrophy.

A recent study conducted under the auspices of Procter & Gamble and Aventis Pharmaceuticals targeted 500 men and women ages 18 to 85 taking corticosteroids and found the drug Actonel to be effective in preserving bone. The study, released at a meeting of the American College of Gastro-enterology in October, found that Actonel (generic name risedronate) reduced the number of vertebral fractures in patients taking it by 70 percent compared to the fracture number in those taking a placebo. All study subjects were given calcium supplements, and some also received vitamin D.

The study estimates that up to 50 percent of those taking more than 7.5 milligrams a day of prednisone or the equivalent for a similar drug will experience bone fractures because of osteoporosis (see "Sticks and Stones Break Fragile Bones").

The study found that Actonel was generally well tolerated, but the drug can't be used by patients who can't stand or sit upright for at least 30 minutes. Severe irritation of the esophagus can result from lying down after taking Actonel. The drug also can't be taken by those with severe kidney impairment or certain types of bone disorders other than osteoporosis.

Multicenter Study to Test Albuterol, Oxandrolone in FSH Dystrophy

A new, multicenter study to test two medications in 160 people with facioscapulohumeral muscular dystrophy (FSHD) is recruiting participants.

John Kissel

The study follows the publication of the results of an earlier trial of albuterol (brand name Proventil and others), a beta-adrenergic agonist, which was found to increase muscle bulk and grip strength. The study, an MDA-supported, one-year trial of 90 people with FSHD, was published in the Oct. 23 issue of Neurology (also see Quest, vol. 7, no. 4, "Research Updates").

Oxandrolone (Oxandrin) is an anabolic (tissue-building) steroid, a synthetic compound resembling the male hormone testosterone. It's now used to treat involuntary weight loss associated with severe illness, protein breakdown associated with corticosteroid drugs and bone pain associated with osteoporosis.

The new trial is designed to test the hypothesis that albuterol taken on a precise dosing schedule (given one month on and one month off), alone or combined with oxandrolone, may cause increases in muscle strength, function or bulk in FSHD. The investigators will also measure various biochemical changes, if such should occur.

The study will take place at Ohio State University Medical Center in Columbus; the University of Rochester Medical Center in Rochester, N.Y.; Brigham and Women's Hospital/ Harvard University in Boston; the University of Texas Southwestern Medical Center in Dallas; the University of Kansas Medical Center in Kansas City; the University of Texas Health Science Center at San Antonio; Montreal (Quebec, Canada) Neurological Institute; and Kings Regional Neuroscience Center in London, England. Trial participants must be able to make regular visits to one of these centers.

"We hope that the design and large size of the study will answer definitively the question of whether anabolic agents represent viable treatment options in FSHD and other forms of muscular dystrophy," said neurologist John Kissel, co-director of the MDA clinic at OSU, who is on the study team.

For more information or to inquire about participation in the study, contact Karen Downing at OSU's Department of Neurology at (614) 293-6813 or downing.42@osu.edu.

Newly Found Genes for Muscle Atrophy May Be Clues in ALS, SMA, CMT

A team of scientists based at Regeneron Pharmaceuticals in Tarry-town, N.Y., has found two genes whose normal function appears to be to accelerate muscle atrophy — a process of muscle breakdown that occurs as a consequence of disuse, injury, aging, and certain neuromuscular diseases.

The findings might yield insights into treatments for amyotrophic lateral sclerosis (ALS), spinal muscular atrophy (SMA) and Charcot-Marie-Tooth disease (CMT), says Louis Kunkel, an MDA grantee and geneticist at Children's Hospital of Boston.

In ALS and SMA, the death of muscle-controlling nerve cells (motor neurons) in the spinal cord causes severe atrophy of voluntary muscles throughout the body. In CMT, damage to the peripheral nerves that carry signals from the spinal cord to muscles causes a milder atrophy of muscles in the extremities.

In the new study, Sue Bodine and her colleagues at Regeneron induced atrophy of a leg muscle in rats by three separate methods: severing the nerve to the muscle (denervation), immobilizing the leg or preventing the leg from bearing weight. Then, they extracted genetic material from the atrophied muscles and looked for genes that weren't "turned on" in normal muscles.

In all three models of atrophy, they found two genes — MuRF1 and MAFbx — that were upregulated (activated).

To test the roles of MuRF1 and MAFbx in muscle atrophy, they deleted each of the genes in two different groups of mice. Both strains of mutant mice were resistant to the muscle atrophy caused by denervation. The researchers also were able to trigger signs of atrophy by delivering the MAFbx gene to muscle cells.

The results were published in the Oct. 26 issue of Science.

The MuRF1 and MAFbx genes both encode "ubiquitin ligases," a family of proteins that mark other proteins for destruction. Finding drugs that block the activity of MuRF1 and MAFbx might be an effective way to prevent muscle atrophy, Bodine and her group suggest.

Kunkel, who's using "gene chip" technology to search for genes that modify the course of muscular dystrophy, says that such drugs "might alleviate some of the symptoms and make the quality of life better for people with motor neuron diseases [like ALS and SMA] and peripheral nerve disorders [like CMT]." However, it's not yet known whether MuRF1 and MAFbx contribute to the muscle atrophy that occurs in those diseases, he says.

Coenzyme Q10 May Help in Friedreich's Ataxia, Mitochondrial Disease

Coenzyme Q10, a dietary supplement that's available over the counter, has "come of age" with respect to its ability to alleviate symptoms in people with Friedreich's ataxia, some other forms of ataxia that are apparently directly related to a lack of coenzyme Q10, and perhaps in some mitochondrial disorders of muscle, says Salvatore DiMauro, a neurologist and MDA grantee who specializes in mitochondrial diseases at Columbia-Presbyterian Medical Center in New York.

Coenzyme Q10 — or coQ10 — is part of the energy-producing machinery of the mitochondria (subunits in cells) and also acts as an antioxidant, combating dangerous free radicals that can destroy cell membranes and other structures.

Salvatore DiMauro

DiMauro attended the Fifth European Meeting on Mitochondrial Pathology in Venice, Italy, in September, and was particularly impressed with a presentation by Raffaele Lodi of the University of Bologna (Italy) and Oxford University (England). Lodi, DiMauro says, "presented a study using coQ10 that showed a remarkably good result in patients with Friedreich's ataxia that may connect with our own research." Lodi's studies, using nuclear magnetic resonance images of the brain and muscle, showed a decline in lactic acid [a metabolic byproduct that's undesirable in excess] and an improvement in ATP stores [a measure of stored molecular energy] in skeletal muscle and in the brain with coQ10.

DiMauro reports that clinical measures of functional improvement in Friedreich's ataxia were also found with coQ10 therapy.

He notes that he and other researchers have seen several patients with a genetic deficiency of coQ10 benefit from using the substance. Testing for such a deficiency is complex and requires a specialized medical center laboratory, he says.

Another group for which coQ10 supplementation might be helpful is those with mitochondrial disorders, DiMauro says. In particular, he says, patients with MELAS, MERRF and Kearns-Sayre mitochondrial disorders have been studied by Japanese researchers and found to have some (though not major) deficiencies in their coQ10 levels. "Whether that's enough to justify using coQ10, I'm not certain," DiMauro says, but he believes it's probably worth trying.

DiMauro's group prescribes 600 to 1,000 milligrams a day of coenzyme Q10 divided into three doses and recommends that people take the pills with meals. He also endorses using a liquid form of coQ10.

DiMauro recommends that people with neuromuscular disorders consult with their own doctors before taking a supplement, but he also says that coQ10, at least in the recommended doses, hasn't caused any problems. "The good thing is, so far there have been absolutely no side effects. It seems to be a totally harmless compound, even in patients who went up to three grams [3,000 milligrams] a day on their own," he says.