Research News

New candidate drug slows protein synthesis to treat demyelinating disease

Protein synthesis.

After treatment with Sephin1, myelin in both cultures and nerves from an animal model of Charcot-Marie-Tooth disease demonstrates significant improvement. Cultures are shown above, with myelin in orange and neurofilament, a neuron component, in green. Nerves are shown below; myelin is the black ring around white axons. Images: Indrajit Das and Maurizio D’Antonio

By ELLEN GOLDBAUM

Published April 16, 2015 This content is archived.

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Lawrence Wrabetz.
“This study is an important first step toward developing a therapeutic strategy for these diseases with a drug that could potentially be used in clinical trials. ”
Lawrence Wrabetz, director
Hunter James Kelly Research Institute

In 2013, UB researchers published a paper showing how slowing down protein synthesis can improve myelin production and repair in some demyelinating diseases, such as Charcot-Marie-Tooth disease (CMT). The research held promise for other misfolded protein diseases, such as Alzheimer’s, Parkinson’s and amyotrophic lateral sclerosis (ALS). The drawback was that the small molecule that slowed protein synthesis had side effects that rendered it unsuitable for human use.

At the time, the researchers, led by Lawrence Wrabetz, director of UB’s Hunter James Kelly Research Institute, noted that if they could find a new version of the agent they used that was safe and effective, it could lead to new therapeutic strategies for CMT and perhaps other misfolded protein diseases as well.

Last week, Wrabetz and others co-authored a paper in the journal Science that reports just that. The lead author is Anne Bertolotti, program leader in the Medical Research Council Laboratory of Molecular Biology at Cambridge.

In preclinical trials in animals, the Science paper reports, a new candidate drug called Sephin1 can markedly improve CMT and familial ALS, two diseases of proteostasis (protein homeostasis, the process keeping protein production in balance in cells). While the diseases are otherwise unrelated, both can result from difficulties in protein folding. In the case of ALS, the misfolded proteins are toxic to neurons and kill them, whereas in CMT neuropathy, the misfolded proteins disturb the production of myelin, the crucial fatty material that normally wraps the axons of neurons, allowing them to signal effectively.

“Our 2013 study and others have found that in diseases caused by proteostasis, keeping protein production more stringently and persistently dialed down is good for limiting disease,” says Wrabetz, also professor of neurology and biochemistry in the School of Medicine and Biomedical Sciences. “Professor Bertolotti and her colleagues at Cambridge used medicinal chemistry to develop a candidate drug that regulates protein production, but without the toxic side effects.”

Basing the design of the preclinical trial on the same one they published in 2013, Wrabetz and his colleague, Maurizio D’Antonio at San Raffaele Scientific Institute in Milan, joined by Indrajit Das of Cambridge, treated juvenile animals with CMT with Sephin1. After five months of treatment, the results were unequivocally positive.

“Motor function in the animals returned to normal, the amount of myelin destruction was reduced by 70 percent and myelin thickness improved remarkably,” Wrabetz says.

There were equally positive results when Das treated the familial ALS model with Sephin1 at Cambridge.

Sephin1 regulates a key factor in protein synthesis, and does so through phosphorylation, or the addition of a phosphate group.

“The finding is important because proteostasis diseases are multiple and affect many people,” Wrabetz explains, noting these diseases include neurodegenerative conditions, such as Alzheimer’s and Parkinson’s, demyelinating diseases such as multiple sclerosis and certain types of cancers and some subtypes of diabetes.

“It’s important to emphasize that further studies are necessary to confirm that the effects in these two animal models will translate to patients with CMT and familial ALS, and then that this or similar candidate drugs could be useful in other diseases where proteostasis is a factor,” Wrabetz notes. “Nonetheless, this study is an important first step toward developing a therapeutic strategy for these diseases with a candidate drug that could potentially be used in clinical trials.”

Wrabetz and Laura Feltri, UB professor of biochemistry and neurology, also are interested in exploring the study’s relevance to leukodystrophies, the rare and severe developmental diseases of myelin in the brain and nerves. He notes that imbalances in proteostasis have been reported to contribute to some leukodystrophies.

Currently, they are exploring whether altered proteostasis is present in animal models of Krabbe leukodystrophy, the disease that afflicted Hunter James Kelly, for which the Hunter James Kelly Research Institute is named.

The institute conducts research on myelin and its related diseases with the goal of developing new ways of understanding and treating conditions such as Krabbe disease and other leukodystrophies. It was established in 1997 by Jim Kelly, Buffalo Bills Hall of Fame quarterback, and his wife, Jill, after their infant son Hunter was diagnosed with Krabbe leukodystrophy, an inherited fatal disorder. He died in 2005 at the age of 8.

Other co-authors on the Science paper are Indrajit Das, Agnieszka Krzyzosiak, Kim Schneider, Nicholas Barry and Anna Sigurdardottir.