A new roadmap for repairing the damage of multiple sclerosis

Dozens of drug candidates identified that share a common mechanism to stimulate regeneration of the brain’s myelinating cells

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IMAGE: FORMATION OF OLIGODENDROCYTES.

CREDIT: CASE WESTERN RESERVE SCHOOL OF MEDICINE

Research published today in the journal Nature provides new understanding about how drugs can repair damaged brain cells that cause disability in patients with multiple sclerosis. Led by researchers at Case Western Reserve University School of Medicine, the study suggests new drug targets and potent early-stage drug candidates could lead to regenerative medicines for multiple sclerosis and other debilitating neurological diseases.

Multiple sclerosis, a chronic and progressive disease affecting millions worldwide, is characterized by damage to the protective sheath that surrounds nerve cells. Without this insulating layer, called myelin, nerve cells in the brain and spinal cord struggle to transmit electrical impulses. As a result, multiple sclerosis patients suffer progressive loss of motor skills, vision and balance.

The new study describes how drugs work to replenish myelin destroyed by multiple sclerosis. While the brain is known to have some capacity to regenerate new myelin during the early stages of multiple sclerosis, this innate repair process is overwhelmed as the disease progresses.

“Many labs, including at Case Western Reserve, had identified drug candidates that kickstart the formation of new myelin, but exactly how each of these molecules affected brain cell function wasn’t clear,” said Drew Adams, PhD, the Thomas F. Peterson, Jr. Professor of Novel Therapeutics and assistant professor of genetics and genome sciences at Case Western Reserve University School of Medicine. “We were shocked to find that almost all of these previously identified molecules share the ability to inhibit specific enzymes that help to make cholesterol. This insight reorients drug discovery efforts onto these novel, druggable targets.”

This study builds on prior work by co-author Paul Tesar, PhD, the Dr. Donald and Ruth Weber Goodman Professor of Innovative Therapeutics and associate professor of genetics and genome sciences at Case Western Reserve University School of Medicine. In work reported in 2015 in Nature, Tesar identified a drug typically used to treat athlete’s foot, called miconazole, as a potent enhancer of new myelin.

In the current study, teams led by Adams and Tesar demonstrated that miconazole enhanced myelin formation by inhibiting an enzyme used by brain stem cells to produce cholesterol. Subsequent experiments identified more than 20 new drugs that enhance myelin formation by inhibiting closely-related cholesterol-producing enzymes. Surprisingly, drugs identified previously by labs across the world as enhancing new myelin also inhibited these same enzymes. “The idea that almost all drug candidates that promote myelin repair inhibit the same enzyme targets represents a bold new paradigm for the field and may redirect the course of ongoing drug discovery efforts,” said Tesar.

Normally, cellular pathways are crisscrossed, complex diagrams. But cholesterol biosynthesis is linear, said Adams, who is also a Mount Sinai Scholar. “There is only one way in, and one way out. So when you block enzymes in the cholesterol pathway, the metabolites simply accumulate.” In the Adams laboratory, lead authors Zita Hubler and Dharmaraja Allimuthu, PhD, could detect distinct cholesterol intermediaries as they accumulated, allowing them to pinpoint which enzymes were being blocked by which drugs.

Notably, several drugs accelerated myelin repair in mouse models of multiple sclerosis. Mouse experiments were performed in collaboration with Robert H. Miller, PhD, the Vivian Gill Distinguished Research Professor and professor of anatomy and cell biology at the George Washington University School of Medicine and Health Sciences.

To measure the formation of human myelin in the laboratory, the team used a new three-dimensional nerve cell culture model that closely mimics human brain tissue. Here too, the drug candidates promoted human myelin formation by blocking cholesterol pathway enzymes. A study describing this innovative model, developed in Tesar’s laboratory, was also published today in Nature Methods.

“Together these studies provide new drug targets, new drug candidates, and new cholesterol pathway biomarkers to propel the development of medicines that can replenish lost myelin in patients with multiple sclerosis and related diseases,” said Adams. While clinical candidates based on this work are not expected to enter clinical trials until 2019, say the authors, the new understanding of myelin repair provides a promising new path toward novel, regenerative multiple sclerosis treatments.

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Adams, Tesar, and Miller collaborated with researchers from Ludwig-Maximilians University of Munich, Germany; Rice University; Leiden University Medical Center, Netherlands; and the Case Western Reserve University School of Medicine Department of Pediatrics for the study.

Hubler, et. al. “Accumulation of 8,9-unsaturated sterols drives oligodendrocyte formation and remyelination.” Nature.

This research was supported by grants from the National Institutes of Health, Conrad N. Hilton Foundation, and Mt. Sinai Health Care Foundation. Philanthropic support was generously provided by the Peterson, Fakhouri, Long, Goodman, Geller, Judge, and Weidenthal families.

For more information about the Adams and Tesar laboratories, please visit: genetics.case.eduand tesarlab.case.edu.

For more information about Case Western Reserve University School of Medicine, please visit: case.edu/medicine.

Multiple sclerosis — Helping cells to help themselves

 

These are mouse myelin repair cells (oligodendrocytes) in a petri dish. These cells produce myelin (green), which they then use to repair the myelin sheaths around nerve cells. Blue staining depicts nuclei. Copyright: Staroßom/Charité

Diseases such as multiple sclerosis are characterized by damage to the ‘myelin sheath’, a protective covering wrapped around nerve cells akin to insulation around an electrical wire. Researchers from Charité – Universitätsmedizin Berlin have discovered how the body initiates repair mechanisms which will limit the extent of any damage to this sheath. Their findings, which provide a basis for the development of new drugs to treat multiple sclerosis, have been published in the eminent journal Nature Communications*.

Multiple sclerosis is the most common autoimmune disease of the central nervous system. Estimates suggest that more than 200,000 people are affected by the disease in Germany alone. People with multiple sclerosis experience vision and sensory problems, as well as impaired coordination or even paralysis. These symptoms are caused by the disruption of nerve impulses in either the brain or the spinal cord. This disruption occurs when the body’s immune system attacks the myelin sheath, which is wrapped around the body’s nerve fibers and provides electrical insulation. When the myelin sheath is no longer intact, communication between nerve cells is impaired. Researchers across the globe are searching for new ways to repair the myelin sheath and, in doing so, are looking to reduce neurological symptoms in people with multiple sclerosis. Researchers from Charité have now moved a decisive step closer to this goal.

Charité’s research team decided to take a closer look at the body’s innate ability to heal itself, knowing that, under certain conditions, the central nervous system is capable of repairing damage to the myelin sheath. Specific molecular signals enable stem cells to differentiate into myelin repair cells (oligodendrocytes), which reside in a small stem-cell niche in the brain. Once they leave this niche, these repair cells migrate to where myelin damage has occurred in order to restore the affected nerve cells’ electrical insulation. Until now, very little had been known about the molecular signals responsible for initiating this myelin regeneration mechanism. “We have found that the Chi3l3 protein plays a central role in the body’s capacity to produce new myelin-forming oligodendrocytes,” says the study’s first author, Dr. Sarah-Christin Staroßom of Charité’s Institute for Medical Immunology. A researcher at the NeuroCure Cluster of Excellence and the Experimental and Clinical Research Center (ECRC), Dr. Staroßom explains the protein’s role as follows: “The Chi3l3 protein initiates the differentiation of neural stem cells into myelin repair cells, which restore the electrical insulation around damaged nerve cells.”

Using a mouse model, the research team were able to show that a reduction in Chi3l3 levels in the brain significantly impairs the body’s capacity for oligodendrocyte production, while a Chi3l3 infusion leads to an increase in the production of myelin repair cells. The same reaction was observed during an in vitro experiment using human cells. “We hope to use this knowledge to develop a new generation of drugs that can be used in the treatment of multiple sclerosis,” explains Dr. Staroßom. “As a next step, we will study in greater detail whether Chi3l3 or related proteins can be used to reduce the neurological symptoms of patients with multiple sclerosis.”