Grant - Summer 2019 - ALS - Davide Trotti, PhD

Davide Trotti, PhD, professor of Neuroscience at Thomas Jefferson University in Philadelphia, was awarded an MDA research grant totaling $300,000 over three years to investigate the mechanism by which the toxic mutations in C9ORF72-amyotrophic lateral sclerosis (ALS) contribute to the degradation of the neuromuscular junction (NMJ).

ALS is a progressive neuromuscular disease that destroys muscle-controlling nerve cells called motor neurons. Normally, nerve cells communicate with muscle cells by sending electrical signals across the NMJ. Neuromuscular junction disorders result from the destruction, malfunction, or absence of one or more key proteins involved in the transmission of signals between muscles and nerves. Frequently, disruption of this communication happens early in the course of ALS.

In 2011, researchers found that a mutation in the C9ORF72 gene where one segment is repeated too many times — otherwise known as a repeat expansion — is the most common cause of familial (inherited) ALS and is also found in sporadic (not inherited) cases. Although mutations in C9ORF72 represent the most common cause of ALS, little is known about the mechanisms by which these mutations impair neuromuscular communication at the NMJ.

In previous MDA-funded work, Dr. Trotti studied how the accumulation of protein clumps in patients with C9ORF72-ALS may contribute to motor neuron death. Using rodent and C9ORF72-ALS patient induced pluripotent stem cell models, Dr. Trotti will identify the NMJ pathogenic changes caused by C9ORF72-related toxic dipeptide proteins that lead to this loss of motor neuron-muscle connectivity in C9ORF72-ALS.

Grantee: ALS - Davide Trotti, PhD

Grant type: Research Grant

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Grant - Summer 2019 - DMD - Courtney Young, PhD

“This work will further advance pre-clinical development of our gene editing therapy for Duchenne. Assessing the immune response will allow for safety to be assessed and strategies to re-dose the therapy to be developed, which would greatly increase the efficacy and applicability of the therapy.”

Courtney Young, PhD, CEO of MyoGene Bio LLC in Los Angeles, was awarded an MDA research grant totaling $299,592 over three years to assess the immune response to repeated dosing of adeno-associated virus-dependent gene-replacement therapy in Duchenne muscular dystrophy (DMD).

DMD is caused by a mutation in the dystrophin gene on the X chromosome that results in little or no production of the protein dystrophin. Currently, gene-replacement and gene-editing (for example, the CRISPR gene-editing system) therapies rely on the adeno-associated virus (AAV) to deliver the replacement gene or gene-editing program to a patient’s cells. However, the virus can trigger an immune response in the body, so patients either have pre-existing immunity or will develop it after the first dose — ultimately preventing repeated dosing of the therapy.

At MyoGene Bio, Dr. Young and team have developed a gene-editing therapy using CRISPR/Cas9 aimed at allowing the production of dystrophin, and they have demonstrated the therapy can restore dystrophin in human cells and in mice. To safely enable repeated exposure to AAV, Dr. Young, who is an MDA early-in-career investigator, will develop an immunosuppressive protocol using humanized DMD mice to characterize the adaptive immune response to single and repeated exposures of AAV-CRISPR. Importantly, this work can inform practices not just in DMD but also across a wide array of diseases utilizing AAV-based gene therapy and gene editing.

Grantee: DMD - Courtney Young, PhD

Grant type: Research Grant

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Grant - Summer 2019 - DMD - Changwon Kho, PhD

“Given the high burden of cardiomyopathy in DMD patients, it is vital to identify the pathophysiological mechanisms in place in an effort to develop ways to effectively improve cardiac dysfunction and prevent muscular damage.”

Changwon Kho, PhD, assistant professor of Cardiology at the Icahn School of Medicine at Mount Sinai in New York, was awarded an MDA research grant totaling $300,000 over three years to study the SUMO1 protein as a therapeutic target for Duchenne muscular dystrophy (DMD).

DMD is caused by a mutation in the dystrophin gene on the X chromosome that results in little or no production of dystrophin, a protein that is essential for keeping muscle cells intact. Patients with DMD typically have cardiac complications, and heart failure is the major cause of death in DMD. It was recently discovered that the small ubiquitin-like modifier type 1 protein (SUMO1) pathway is defective in dystrophic hearts with established cardiomyopathy. In preliminary studies, Dr. Kho demonstrated that increasing activity of SUMO1, a naturally occurring protein, can restore calcium balance and cardiac function in DMD mice.

With this current funding, Dr. Kho will validate SUMO1 as a target and then begin to test candidate SUMO1 activators in a mouse model of DMD heart disease, aiming to provide a critical foundation for targeting the SUMO1 pathway as a treatment for DMD.

Grantee: DMD - Changwon Kho, PhD

Grant type: Research Grant

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Grant - Summer 2019 - SMA - Ashlyn Spring, PhD

Ashlyn Spring, PhD, a postdoctoral fellow in Biological and Genome Sciences at the University of North Carolina at Chapel Hill, was awarded an MDA development grant totaling $210,000 over three years to study the relationship of immune system dysfunction in spinal muscular atrophy (SMA).

SMA is caused by a mutated or missing survival motor neuron 1 gene (SMN1) that prevents the body from making enough survival motor neuron protein (SMN), ultimately leading to the loss of motor neurons, muscle weakness, and paralysis seen in SMA. Previous findings suggest that the immune system is also dysfunctional in patients with SMA, making them more susceptible to infection. However, while major strides have been made in developing and approving therapies to treat the genetic mutations behind SMA, little is known about how the immune system dysfunction affects other tissues.

In this project, Dr. Spring, a first-time MDA grantee, will use fly, mouse, and human cell line models of SMA to investigate how the immune system’s response to infections is impacted in the disease. This work will lead to an understanding of why SMN1 mutations change immune system function as well as help identify targets for new therapeutics to improve treatment of SMA in the future.

https://doi.org/10.55762/pc.gr.87333

Grantee: SMA - Ashlyn Spring, PhD

Grant type: Development Grant

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Grant - Summer 2019 - MM - Antonio Barrientos, PhD

“Better understanding of the cellular and mitochondrial processes leading to COX assembly is expected to have a significant impact on health and neuromuscular disease. Our project will test therapeutic interventions involving copper delivery to mitochondria, which could be extremely useful to patients.”

Antonio Barrientos, PhD, professor of Neurology and Biochemistry and Molecular Biology at the University of Miami Miller School of Medicine, was awarded an MDA research grant totaling $300,000 over three years to study the relationship between genetic mutations and copper delivery to mitochondrial cells in the pathology of mitochondrial myopathies.

Mitochondria produce much of the energy that cells require to function, and an important component of that process is an enzyme called cytochrome c oxidase (COX). Without a properly assembled COX complex, cellular energy production is severely compromised; this affects the brain, muscles, and other organs with high energy demands. Previously, MDA awarded Dr. Barrientos funding to study the underlying molecular mechanisms of COX deficiency in some forms of mitochondrial myopathy as well as defects in mitochondrial protein complex assembly, which are a frequent cause of inherited mitochondrial myopathies.

The mitochondrial protein COX1, which is one of the proteins that make up the COX protein complex, requires copper in order to function and produce cellular energy. In this proposal, Dr. Barrientos will use patient-derived cells to study the proteins that help deliver copper to mitochondria, how their function is disrupted by mutations causing mitochondrial myopathies, and why this dysfunction is specific to certain tissues. Additionally, he will test various therapeutic strategies to enhance copper delivery.

https://doi.org/10.55762/pc.gr.87334

Grantee: MM - Antonio Barrientos, PhD

Grant type: Research Grant

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Grant - Additional Grants 2019 - DM – Locana

"DM is caused by expression of dysfunctional, repetitive RNA in diseased tissues, where application of Locana’s core RNA-targeting technology has been shown to have potential for single-dose therapeutic benefit and could provide a long-lasting approach for patients."

Locana, a leading RNA-targeting gene therapy company based on the work of one of its founders Gene Yeo, PhD, MBA, professor of Cellular and Molecular Medicine at the University of California, San Diego, was awarded MDA Venture Philanthropy (MVP) funding totaling $550,000 over two years to advance Locana’s development program for myotonic dystrophy (DM), the most common form of adult-onset muscular dystrophy. MVP funding is awarded to researchers developing therapeutics for neuromuscular diseases to help lower the barriers and bridge the high-risk stages of drug development.

Myotonic dystrophy is a genetic neuromuscular disease that affects multiple muscles and systems, including skeletal muscle, cardiac muscle, the gastrointestinal tract, and the central nervous system. In both types of DM, DM1 and DM2, genetic mutations in the form of large repeat expansions of DNA lead to the development of clumps of RNA that become toxic to healthy cells. (RNA is the molecular step between DNA and protein.) 

Locana’s RNA-targeting platform technology aims to address a wide spectrum of human genetic diseases, including DM. Locana has advanced a powerful modular RNA targeting-effector approach that is distinct from DNA-targeting approaches (such as CRISPR/Cas9) and nucleic acid-based RNA targeting approaches (such as antisense oligonucleotides). Locana intends to build a portfolio of therapies that address the root cause of genetic diseases driven by dysfunctional RNA behavior.

Grantee: DM – Locana

Grant type: Venture Philanthropy Grant

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Grant - Additional Grants 2019 - FSHD – Adam Bittel, PT, DPT, PhD

"We are interested in both understanding how exercise affects skeletal muscle in FSHD and identifying the key cellular events contributing to those responses."

Adam Bittel, PT, DPT, PhD, a postdoctoral fellow at Children’s National Medical Center in Washington, DC, was awarded the 2019 SSSI-MDA Fellowship Award. The award, co-sponsored by Strength, Science & Stories of Inspiration (SSSI) and MDA, will provide a total of $40,000 over two years to support Dr. Bittel’s work investigating the cellular mechanisms underlying the effects of exercise in facioscapulohumeral muscular dystrophy (FSHD).

During his doctoral studies, Dr. Bittel explored how exercise influences multi-organ metabolism in metabolic syndromes as well as in Barth syndrome, a genetic disease affecting skeletal and cardiac muscle. While exercise is known to improve muscle health and metabolism in other forms of muscular dystrophy, there are very few studies assessing the effects of exercise in individuals with FSHD. Dr. Bittel is interested in understanding how exercise affects skeletal muscle in a mouse model of FSHD (the FLExDUX4 mouse) and in identifying important cellular events contributing to those responses.

https://doi.org/10.55762/pc.gr.87251

Grantee: FSHD – Adam Bittel, PT, DPT, PhD

Grant type: Development Grant

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Grant - Winter 2019 - ALS - Ze’ev Melamed, PhD

"I believe that my proposed study may open the door to a completely new and promising direction in ALS research. Implementation of cellular and genomics tools offers an innovative approach to uncover mechanisms through which stathmin-2 loss-of-function provokes ALS pathogenesis and if so, identify a feasible therapeutic approach."

Ze’ev Melamed, PhD, postdoctoral fellow at the Ludwig Institute for Cancer Research at the University of California, San Diego, was awarded an MDA development grant totaling $210,000 over three years to collaborate with Ionis Pharmaceuticals to determine how suppression of stathmin-2 protein, recently shown to be decreased in the motor neurons of sporadic amyotrophic lateral sclerosis (ALS) patients, drives motor neuron degeneration and whether reversal of stathmin-2 defects could have therapeutic potential for ALS.

One hallmark of most cases of ALS is the accumulation of the RNA-binding protein TDP-43 into aggregates (clumps) outside the nucleus of the cell, but it is still not understood how these defects contribute to disease. In previous work, Dr. Melamed used cell models to discover that TDP-43 regulates the maturation of the mRNA (DNA code creates RNA in the form of a messenger, or mRNA molecule) of stathmin-2, a microtubule-associated protein previously implicated in axonal growth and regeneration. In other words, he found that decreased levels of stathmin-2 mRNA is a consequence of TDP-43 pathology in ALS.

In this work, he will study how stathmin-2 affects the maintenance and repair of motor neurons, and how loss of stathmin-2 affects the ability of neurons to regenerate. He will also work with Ionis Pharmaceuticals to develop an antisense oligonucleotide designed to correct aberrant processing of stathmin-2 mRNA, possibly having the therapeutic effect of restoring levels of stathmin-2 in motor neurons of patients with ALS.

https://doi.org/10.55762/pc.gr.84539

Grantee: ALS - Ze’ev Melamed, PhD

Grant type: Development Grant

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Grant - Winter 2019 - DM - Tom Cooper, MD

"The overall goal of the work is to understand the molecular and physiological pathways leading from the disease-causing mutation to the molecular and cellular defects that cause cardiac conduction defects and arrhythmias."

Tom Cooper, MD, professor of Pathology and Immunology at Baylor College of Medicine, was awarded an MDA research grant totaling $325,571 over three years to study how the molecular defects that cause myotonic dystrophy type 1 (DM1) relate to the heart problems that are a prominent symptom of this disease (they affect at least half of individuals with DM1).

DM1 causes weakness of the voluntary muscles and an inability to relax muscles at will. As the disease progresses, many other organ systems are impacted, and the heart can weaken and develop an abnormal rhythm. The most lethal aspects of DM1 are the cardiac problems that develop with the disease.

DM1 occurs when a gene on chromosome 19 called DMPK contains an abnormally expanded section. The large repeat expansions form aggregates of toxic RNA that ultimately prevent proteins essential for healthy muscle function from being made properly. In previous MDA-funded work, Dr. Cooper created a mouse model on which he tested antisense oligonucleotides — short RNA-like molecules that bind to the excess RNA, blocking its interactions with other substances or causing it to be broken down — aimed at delivery to the heart muscle specifically.

In this work, Dr. Cooper hopes to better understand the pathogenic mechanisms compromising heart function in DM1 and to test the ability of different therapeutic approaches to reverse or rescue the cardiac complications in his DM1 mouse model.

https://doi.org/10.55762/pc.gr.84544

Grantee: DM - Tom Cooper, MD

Grant type: Research Grant

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Grant - Winter 2019 - ALS - Tania Gendron, PhD

"We hope that the biomarkers of cognitive impairment identified through this work will prove useful in the clinical assessment and care of patients, and in the design of clinical trials. Moreover, because biomarkers for cognitive dysfunction are likely to reflect biochemical changes that precede its clinical manifestation, they may permit the earlier diagnosis of such dysfunction — information important for the effective timing of potential medical interventions."

Tania Gendron, PhD, assistant professor of Neuroscience at the Mayo Clinic in Jacksonville, Fla., was awarded an MDA research grant totaling $285,000 over three years to identify biomarkers to predict cognitive impairment in amyotrophic lateral sclerosis (ALS), which could be useful in patient care as well as for stratification of clinical trials.

As many as half of all ALS patients will show signs of impaired cognition during the course of the disease. Recognizing symptoms of cognitive impairment is important considering the effect they have on disease progression (patients with ALS who also have cognitive impairment have a shorter survival time), quality of life, and disease management and treatment of symptoms. To date, there are no validated biomarkers for cognitive impairment in patients with ALS.

The goal of this project is to deliver a panel of biomarkers that can detect emerging cognitive impairment in ALS patients. Dr. Gendron will use mass spectrometry-based proteomics to identify protein biomarkers of cognitive impairment in patients’ spinal fluid, and then determine whether these biomarkers correlate with the severity of cognitive impairment and if they can be used to determine the rate of disease progression and survival.

If successful, identifying biomarkers for cognitive impairment in ALS patients would help to improve patient stratification in clinical trials, as well as provide insight into the discovery of drug targets for treating cognitive impairment in not only ALS but also a variety of other neurological diseases.

https://doi.org/10.55762/pc.gr.84549

Grantee: ALS - Tania Gendron, PhD

Grant type: Research Grant

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Grant - Winter 2019 - DMD - Steven Welc, PhD

"Identifying processes that regulate muscle fibrosis and inflammation are clinically important and could lead to novel strategies to treat DMD. Additionally, results from this research project could help to provide the foundation for the clinical use of Klotho to treat DMD."

Steven Welc, PhD, postdoctoral fellow in Physiology at the University of California, Los Angeles, was awarded an MDA development grant totaling $210,000 over three years to study the role of Klotho protein in reducing fibrosis in a mouse model of Duchenne muscular dystrophy (DMD).

Fibrosis occurs when excess fibrous connective tissue is created in an organ or tissue in an attempt to repair it. In DMD, lack of dystrophin causes muscles to deteriorate; this in turn causes the inflammatory response that promotes fibrosis, or the replacement of muscle fibers with connective tissue that leads to reduced function. In previous research, Dr. Welc discovered that the anti-inflammatory and anti-fibrotic Klotho protein was silenced in a mouse model of DMD, and there were decreased amounts of Klotho in the muscle cells of DMD patients. By restoring Klotho expression in a mouse model of DMD, he was able to modify inflammation and reduce fibrosis in muscle tissue.

In this work, Dr. Welc will test several possible mechanisms by which Klotho could reduce fibrosis in a mouse model of DMD. Specifically, he will examine the role of Klotho in regulating communication between macrophages and fibro-adipogenic progenitors (FAPs) by determining whether Klotho reduces proliferation and survival of FAPs, thereby reducing fibrosis in DMD mice.

https://doi.org/10.55762/pc.gr.84540

Grantee: DMD - Steven Welc, PhD

Grant type: Development Grant

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