Researchers identify a new cause of inherited neuropathy
News Mar 24, 2016
Neurology researchers link mutations in myelin protein to Charcot-Marie-Tooth Disease -
Charcot-Marie-Tooth disease (CMT) is a family of inherited disorders of the peripheral nervous system, affecting approximately one in 2,500 Americans. Its most common iteration, CMT1, comes in many forms, most of which have to date been linked to a small set of causative genes. New research from the department of Neurology at the Perelman School of Medicine at the University of Pennsylvania (Penn) and the Children's Hospital of Philadelphia recently spanned the globe to uncover a new genetic cause of CMT1. Their findings are published online in the journal Brain.
Their findings expand the number of genes known to cause CMT1, further helping neurologists and patients find the genetic underpinnings of their neuropathy.
Charcot-Marie Tooth Disease is a progressive debilitating neurodegenerative disorder that strikes in the second or third decade of life. This disease results in numbness and weakness in the hands and feet. There are two categories of CMT: those caused by the loss of axons in the peripheral nerves (CMT2) and those characterized by a malfunction in the Schwann cells that make up the myelin sheath, the protective coating that surrounds the nerve fibers and allows them to conduct nerve signals at high speeds (CMT1).
Penn neurologists studied a father and son with CMT1 who were treated at the Hospital of the University of Pennsylvania and Children's Hospital of Philadelphia, respectively, and did not carry a mutation in any of the five genes known to cause CMT1. The father's parents did not have the disease, suggesting that a new random mutation occurred, not shared by either parent, which he then passed on to one of his three sons.
Through complex genetic sequencing of the father's 20,000 genes, the team was able to identify 49 mutations that could be the cause of the pair's CMT. One mutation, a change in the peripheral myelin protein 2 gene (PMP2), emerged as the most likely culprit. PMP2 encodes a protein that transports fatty acids, which are the building blocks of the myelin sheath and known to be one of the most abundant proteins in peripheral nervous system myelin. Further testing of the father's living siblings, parents and two other sons showed that he and his one affected son were the only family members to carry this mutation. This was strong evidence that mutations in PMP2 cause CMT1, slowing nerve conduction and resulting in weakness and numbness in the hands and feet.
"Next-generation sequencing technology has allowed us to find new causes of genetic diseases in much smaller families," explained the study's lead author, William Motley, MD, PhD, a resident physician in Medicine. "The fact that his parents did not have the disease allowed us to narrow the number of possible mutations, as so few arise between generations. We are fortunate to have these tools to help us provide genetic diagnoses to our patients, sometimes even in cases where the patients have no mutations in known causes of their disease. Traditional genetic techniques would never have allowed us to find the cause of this family's CMT."
To provide further evidence of an association between PMP2 mutation and CMT1, the Penn team reached out to an international consortium of CMT researchers to find patients with mutations in the same gene. Working with collaborators at the University of Antwerp, an additional 136 European families with CMT1 were screened for mutations in PMP2. These identified an Austrian family with several affected members who share a mutation in PMP2. Interestingly, the mutation was adjacent to the mutation in the family seen at Penn.
"This has been a highly fulfilling effort. We were able to track down the cause of this family's CMT, help another family, and find a new genetic cause of CMT in the process," said senior author, Steven S. Scherer, MD, PhD, the Ruth Wagner Van Meter and J. Ray Van Meter Professor of Neurology and Chief of the Neuromuscular division in the department of Neurology. "The participation of the family, the clinicians, and the scientists, from Penn and around the world, makes this success even sweeter."
Note: Material may have been edited for length and content. For further information, please contact the cited source.
Motley WW et al. De novo PMP2 mutations in families with type 1 Charcot–Marie–Tooth disease. Brain, Published Online March 23 2016. doi: 10.1093/brain/aww055
Inter-areal Balanced Amplification Enhances Signal Propagation in the BrainNews
Neuroscientists find that signal transmission in a large-scale model of the primate brain is robust under the condition in which area-to-area connections exhibit a “balance” between excitation and inhibition.READ MORE
Early Life Experiences Alter DNA Structure in the Adult BrainNews
Scientists report in the journal Science that the type of mothering a female mouse provides her pups actually changes their DNA.READ MORE
Worms Exhibit Fear and Respond to Anti-anxiety MedsNews
A team of investigators has uncovered new clues about the mechanisms of fear and anxiety through an unlikely creature: the tiny nematode worm.READ MORE
Comments | 0 ADD COMMENT
International Conference on Neuroimmunology, Neurological disorders and Neurogenetics
Sep 26 - Sep 27, 2018