Abstract
Charcot-Marie-Tooth (CMT) neuropathies comprise a group of monogenic disorders affecting the peripheral nervous system. CMT is characterized by a clinically and genetically heterogeneous group of neuropathies, involving all types of Mendelian inheritance patterns. Over 1,000 different mutations have been discovered in 80 disease-associated genes. Genetic research of CMT has pioneered the discovery of genomic disorders and aided in understanding the effects of copy number variation and the mechanisms of genomic rearrangements. CMT genetic study also unraveled common pathomechanisms for peripheral nerve degeneration, elucidated gene networks, and initiated the development of therapeutic approaches. The reference genome, which became available thanks to the Human Genome Project, and the development of next generation sequencing tools, considerably accelerated gene and mutation discoveries. In fact, the first clinical whole genome sequence was reported in a patient with CMT. Here we review the history of CMT gene discoveries, starting with technologies from the early days in human genetics through the high-throughput application of modern DNA analyses. We highlight the most relevant examples of CMT genes and mutation mechanisms, some of which provide promising treatment strategies. Finally, we propose future initiatives to accelerate diagnosis of CMT patients through new ways of sharing large datasets and genetic variants, and at ever diminishing costs.
Highlights
Charcot-Marie-Tooth (CMT) disease was so named to acknowledge J.M
Depending on the severity of motor or sensory deficiency, other CMT variants were grouped into predominantly distal hereditary motor neuropathies and hereditary sensory and autonomic neuropathies (HSAN) [4,5]
The Duffy-blood group marker did not segregate in several other large CMT families which were grouped within the CMT1A subtype of hereditary motor and sensory neuropathies (HMSN) [21,22,23]
Summary
Charcot-Marie-Tooth (CMT) disease was so named to acknowledge J.M. Charcot, P. CMT disease-associated genes are expressed in different cellular compartments of the developing and myelinating Schwann cells and/or the neuronal axons [15] Some of these genes have been shown to function in the nucleus as transcription factors (EGR2, SOX10, DNMT1), others in vesicle transport (RAB7A), in the Golgi (FAM134B), endoplasmic reticulum (SPTLC1, REEP1, ATL1), or the mitochondria (MFN2, GDAP1). As not all discoveries can be discussed, we provide a comprehensive table listing all currently known disease-causing genes for CMT, as well as the original technologies used to find the associated genes and mutations (Supplementary Table S1). CMT Genetics as a Pioneer for Genomic Mechanisms and Emerging Genome Technologies
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