GDAP1 mutations differ in their effects on mitochondrial dynamics and apoptosis depending on the mode of inheritance

Mutations in the GDAP1 gene lead to recessively or dominantly inherited peripheral neuropathies (Charcot–Marie–Tooth disease; CMT). Here, we demonstrate that GDAP1 is a mitochondrial fission factor whose activity is dependent on the fission factors Drp1 and Fis1. Unlike other mitochondrial fission factors, GDAP1 overexpression or knockdown does not influence the susceptibility of cells to apoptotic stimuli. Recessively inherited CMT-associated forms of GDAP1 (rmGDAP1s) have reduced fission activity, whereas dominantly inherited forms (dmGDAP1s) interfere with mitochondrial fusion. Only the expression of dmGDAP1s increases the production of ROS, leads to uneven mitochondrial transmembrane potentials, and enhances the susceptibility to apoptotic stimuli. Taken together, our results indicate that wild-type GDAP1 promotes fission without increasing the risk of apoptosis. In CMT, recessive GDAP1 mutations are associated with reduced fission activity, while dominant mutations impair mitochondrial fusion and cause mitochondrial damage. Thus, different cellular mechanisms that disturb mitochondrial dynamics underlie the similar clinical manifestations caused by GDAP1 mutations, depending on the mode of inheritance.     

A new missense <Emphasis Type="Italic">GDAP1</Emphasis> mutation disturbing targeting to the mitochondrial membrane causes a severe form of AR-CMT2C disease

Charcot–Marie–Tooth disease (CMT) caused by mutations in the ganglioside-induced differentiation-associated protein 1 (GDAP1) gene is characterized by a spectrum of phenotypes. Recurrent nonsense mutations (Q163X and S194X) showing regional distribution segregate with an early onset, severe course of recessive CMT disease with early loss of ambulancy. Missense mutations in GDAP1 have been reported in sporadic CMT cases with variable course of disease, among them the recurrent L239F missense GDAP1 mutation occurring in the European population. Finally, some GDAP1 mutations are associated with a mild form of CMT inherited as an autosomal dominant trait. In this study, we characterize the CMT phenotype in one Polish family with recessive trait of inheritance at the clinical, electrophysiological, morphological, cellular, and genetic level associated with a new Gly327Asp mutation in the GDAP1 gene. In spite of the nature of Gly327Asp mutation (missense), the CMT phenotype associated with this variant may be characterized as an early onset, severe axonal neuropathy, with severe skeletal deformities. The mutation lies within the transmembrane domain of GDAP1 and interferes with the mitochondrial targeting of the protein, similar to the loss of the domain in the previously reported Q163X and S194X mutations. We conclude that the loss of mitochondrial targeting is associated with a severe course of disease. Our study shows that clinical outcome of CMT disease caused by mutations in the GDAP1 gene cannot be predicted solely on the basis of genetic results (missense/nonsense mutations).     

Genetic Study of Demyelinating form of Autosomal-Recessive Charcot–Marie–Tooth Diseases in a Turkish Family

Charcot–Marie–Tooth (CMT) disease is a clinically and genetically heterogeneous group of inherited peripheral motor and sensory neuropathies characterized by distal muscle weakness atrophy predominantly in the lower extremities, diminished or absent deep tendon reflexes, distal sensory loss and skeletal deformities. Mode of inheritance could be either autosomal dominant, autosomal recessive, or X-linked. The autosomal-recessive subgroup of CMT (AR-CMT) neuropathies is heterogeneous as well. To date, nine demyelinating loci have been implicated in CMT4 and seven genes have been identified. It has been screened in this study for the presence of mutations in the coding region of GDAP1 and genetic linkage analyses of CMT4B1, CMT4B2, CMT4C, CMT4D, CMT4E, and CMT4F loci were tested in a Turkish family presenting recessively inherited form of CMT disease characterized by severe motor weakness. We did not find any mutations in GDAP1 and genetic linkage excluded for the six demyelinating genes loci (CMT4B1, CMT4B2, CMT4C, CMT4D, CMT4E, and CMT4F). Our findings indicate that another locus may be associated with AR-CMT disease.     

Diagnostic moléculaire des formes axonales de la maladie de Charcot-Marie-Tooth

Charcot-Marie-Tooth (CMT) disease is the most common cause of inherited peripheral neuropathies with a frequency estimated at 1/2500. Electroneuromyographic examination distinguishes a myelinic form (CMT1) and an axonal form of the disease (CMT2). Significant genetic heterogeneity is found in CMT, with 15 genes or loci for CMT2. To date, a molecular diagnosis has not been established for most CMT2 patients and the distribution of identified mutations is wide spreading over nearly all genes. Simple guidelines for daily practice are difficult to establish from compilation of mutation reports or consultation of databases; little simplification can be expected from future findings. We present our results of molecular diagnosis for 251 CMT2 index cases characterized by their mode of inheritance (217 dominant and 34 recessive cases), and a motor conduction velocity in median nerve equal to or above to 38 m/s. For each case, at least one of the genes known to date for CMT2 (MFN2, RAB7, GARS, NF-L, HSPB1, GDAP1, MPZ, HSPB8, GJB1, DNM2, YARS, LMNA, and MED25) was studied. Around 22% of diagnoses were established and efficiency was comparable for dominant or recessive cases. For dominant cases, the first objective was to search for mutations of proteins connexin32, mitofusin2 and P0. For recessive cases, GDAP1 provided the key to molecular diagnosis; lamin A/C mutations were only found for patients with an ethnic background from North Africa. Heat shock proteins HSPB1 and HSPB8 were implicated in a significant proportion of “spinal” (or pure motor) CMT2. NF-L or RAB7 mutations were rare. We did not identify any deleterious mutations in GARS, DNM2, YARS orMED2. We propose a simple decision tree for molecular diagnosis of CMT2.     

Mitochondrial complex I deficiency in GDAP1-related autosomal dominant Charcot-Marie-Tooth disease (CMT2K)

Mutations in GDAP1, an outer mitochondrial membrane protein responsible for recessive Charcot-Marie-Tooth disease (CMT4A), have also been associated with CMT2K, a dominant form of the disease. The three CMT2K patients we studied carried a novel dominant GDAP1 mutation, C240Y (c.719G > A). Mitochondrial respiratory chain complex I activity in fibroblasts from CMT2K patients was 40% lower than in controls, whereas the tubular mitochondria were 33% larger in diameter and the mitochondrial mass was 20% greater. Thus, besides the regulatory role GDAP1 plays in mitochondrial network dynamics, it may also be involved in energy production and in the control of mitochondrial volume. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Julien Cassereau and Arnaud Chevrollier contributed equally to this work.     

Revue de la littérature récente sur les neuropathies héréditaires

The recent literature included interesting reports on the pathogenic mechanisms of hereditary neuropathies. The axonal traffic and its abnormalities in some forms of Charcot-Marie-Tooth (CMT) disease were particularly reviewed by Bucci et al. Many genes related to CMT disease code for proteins that are involved directly or not in intracellular traffic. KIF1B controls vesicle motility on microtubules. MTMR2, MTMR13 and FIG4 regulate the metabolism of phosphoinositide at the level of endosomes. The HSPs are involved in the proteasomal degradation. GDAP1 and MFN2 regulate the mitochondrial fission and fusion respectively and the mitochondial transport within the axon. Pareyson et al. reported a review on peripheral neuropathies in mitochondrial disorders. They used the term of “mitochondrial CMT” for the forms of CMT with abnormal mitochondrial dynamic or structure. Among the new entities, we can draw the attention to a proximal form of hereditary motor and sensory neuropathy with autosomal dominant inheritance, which is characterized by motor deficit with cramps and fasciculations predominating in proximal muscles. Distal sensory deficit can be present. The gene TFG on chromosome 3 has been recently identified to be responsible for this form. Another rare form of axonal autosomal recessive neuropathy due to HNT1 gene mutation is characterized by the presence of hands myotonia that appears later than neuropathy but constitute an interesting clinical hallmark to orientate the diagnosis of this form. In terms of differential diagnosis, CMT4J due to FIG4 mutation can present with a rapidly progressive and asymmetric weakness that resembles CIDP. Bouhy et al. made an interesting review on the therapeutic trials, animal models and the future therapeutic strategies to be developed in CMT disease.     

GDAP1 mutations are frequent among Brazilian patients with autosomal recessive axonal Charcot-Marie-Tooth disease

Mutations in ganglioside-induced differentiation-associated-protein 1 (GDAP1) are associated with several subtypes of Charcot-Marie-Tooth (CMT) disease, including autosomal recessive and demyelinating (CMT4A); autosomal recessive and axonal (AR-CMT2K); autosomal dominant and axonal (CMT2K); and an intermediate and recessive form (CMTRIA). To date, at least 103 mutations in this gene have been described, but the relative frequency of GDAP1 mutations in the Brazilian CMT population is unknown. In this study, we investigated the frequency of GDAP1 mutations in a cohort of 100 unrelated Brazilian CMT patients. We identified five variants in unrelated axonal CMT patients, among which two were novel and probably pathogenic (N64S, P119T) one was novel and was classified as VUS (K207L) and two were known pathogenic variants (R125* and Q163*). The prevalence rate of GDAP1 among the axonal CMT cases was 7,14% (5/70), all of them of recessive inheritance, thus suggesting that the prevalence was higher than what is observed in most countries. All patients exhibited severe early-onset CMT that was rapidly progressive. Additionally, this study widens the mutational spectrum of GDAP1-related CMT through identification of two novel likely pathogenic variants.     

Autosomal recessive Charcot‐Marie‐Tooth disease: from genes to phenotypes

The prevalence of Charcot‐Marie‐Tooth (CMT) disease or hereditary motor and sensory neuropathy (HMSN) varies in different populations. While in some countries of Western Europe, the United States and Japan the dominant form of HMSN is the most frequent, in other countries such as those of the Mediterranean Basin, the autosomal recessive form (AR‐CMT) is more common. Autosomal recessive CMT cases are generally characterized by earlier onset, usually before the age of 2 or 3 years, and rapid clinical progression that results in severe polyneuropathy and more marked distal limb deformities such as pes equino‐varus, claw‐like hands, and often major spinal deformities. Recent clinical, morphological and molecular investigations of CMT families with autosomal recessive inheritance allowed the identification of many genes such as GDAP1, MTMR2, SBF2, NDRG1, EGR2, SH3TC2, PRX, FGD4, and FIG4, implicated in demyelinating forms (ARCMT1 or CMT4), and LMNA, MED25, HINT1, GDAP1, LRSAM1, NEFL, HSPB1 and MFN2 in axonal forms (ARCMT2). However, many patients remain without genetic diagnosis to date, prompting investigations into ARCMT families in order to help discover new genes and common pathways. This review summarizes recent advances regarding the genotypes and corresponding phenotypes of AR‐CMT.     

Autosomal recessive axonal form of Charcot-Marie-Tooth Disease caused by compound heterozygous 3'-splice site and Ser130Cys mutation in the GDAP1 gene

A recessive demyelinating subtype of Charcot-Marie-Tooth disease called CMT4 is a heterogeneous group of disorders. A relatively frequent form of recessive CMT (CMT4 A) has been mapped to the chromosome 8 q21 and shown to be caused by mutations in the ganglioside-induced differentiation protein 1 (GDAP1) gene. Twenty mutations in the GDAP1 gene have been reported in patients suffering from the axonal and demyelinating forms of CMT disease. In this study we report two novel mutations in the GDAP1 gene in a patient suffering from CMT2 disease and whose parents were asymptomatic carriers of a Ser130Cys and 3'-splice site (311-1G > A) mutation, respectively.     

Update on hereditary neuropathy]

Hereditary neuropathies are classified into several subtypes according to clinical, electrophysiologic and pathologic findings. Recent genetic studies have revealed their phenotypic and genetic diversities. In the primary peripheral demyelinating neuropathies (CMT1), at least 15 genes have been associated with the disorders; altered dosage or point mutation of PMP22, GJB1, MPZ, EGR2, MTMR2, NDRG1, PRX, SOX10, GDAP1 and MTMR13/SBF2. In the primary peripheral axonal neuropathies (CMT2), at least 10 genes have been associated with these disorders; NEFL, KIF1B, MFN2, GAN1, LMNA, RAB7, GARS, TDP1, APTX, and SETX. In addition, some mutations in GJB1, MPZ, GDAP1 and NEFL also present with clinical and electrophysiologic findings of CMT2. Patients with TDP1, APTX or SETX mutations share common clinical findings; autosomal recessive inheritance, cerebellar ataxia, and axonal neuropathy. These genes are suspected to be related to DNA/RNA repair and induce cell death especially in neuronal cells. In addition to the above diseases, we have reported a new type of NMSNP (MIM# * 604484) characterized by proximal dominant neurogenic atrophy, obvious sensory nerve involvement and the gene locus on 3q12.3. Here, we summarize the genetic bases of hereditary neuropathies and attempt to highlight significant genotype-phenotype correlations with a special interest in nonsense-mediated mRNA decay pathway.     

Phenotypical features of the p.R120W mutation in the GDAP1 gene causing autosomal dominant Charcot-Marie-Tooth disease

Mutations in the ganglioside-induced-differentiation-associated protein 1 gene (GDAP1) can cause Charcot-Marie-Tooth (CMT) disease with demyelinating (CMT4A) or axonal forms (CMT2K and ARCMT2K). Most of these mutations present a recessive inheritance, but few autosomal dominant GDAP1 mutations have also been reported. We performed a GDAP1 gene screening in a clinically well-characterized series of 81 index cases with axonal CMT neuropathy, identifying 17 patients belonging to 4 unrelated families in whom the heterozygous p.R120W was found to be the only disease-causing mutation. The main objective was to fully characterize the neuropathy caused by this mutation. The clinical picture included a mild-moderate phenotype with onset around adolescence, but great variability. Consistently, ankle dorsiflexion and plantar flexion were impaired to a similar degree. Nerve conduction studies revealed an axonal neuropathy. Muscle magnetic resonance imaging studies demonstrated selective involvement of intrinsic foot muscles in all patients and a uniform pattern of fatty infiltration in the calf, with distal and superficial posterior predominance. Pathological abnormalities included depletion of myelinated fibers, regenerative clusters and features of axonal degeneration with mitochondrial aggregates. Our findings highlight the relevance of dominantly transmitted p.R120W GDAP1 gene mutations which can cause an axonal CMT with a wide clinical profile.     

A novel Met116Thr mutation in the GDAP1 gene in a Polish family with the axonal recessive Charcot-Marie-Tooth type 4 disease

Mutations in the gene coding for ganglioside-induced differentiation-associated protein-1 (GDAP1), which maps to chromosome 8q21, have been described in families with autosomal recessive Charcot-Marie-Tooth disease (CMT4A). Interestingly, some mutations in the GDAP1 gene have been reported in the demyelinating form of CMT1 disease, whereas others were found in patients with the axonal type of CMT disease. So far, 23 mutations in the GDAP1 gene have been reported in patients of different ethnic origins. In this study we report a novel mutation Met116Thr in the GDAP1 gene identified in a three generation Polish family with axonal CMT4.     

Molecular Diagnosis Of Hereditary Peripheral Neuropathies

Hereditary peripheral neuropathies are clinically and genetically heterogeneous and include the most common motor and sensory forms (HMSN) as well as the rarer pure motor and pure sensory phenotypes. As a group, Charcot-Marie-Tooth (CMT) disease and related neuropathies (Déjérine-Sottas disease [DSD], congenital hypomyelinating neuropathy [CHN] and hereditary neuropathy with liability to pressure palsies [HNPP]) represent the most common inherited peripheral nerve diseases as well as one of the most common human inherited disorders with a prevalence of ∼20–40:100,000. During the last decade, advances in molecular genetics have greatly increased our understanding of these disorders and significantly changed the clinical approach to them by providing powerful molecular tools for diagnosis. The most common form is demyelinating CMT (CMT1). Based on genetic location and the gene involved, CMT1 is further subcategorized into autosomal dominant (AD) CMT1A (PMP22, 17p11.2) and CMT1B (MPZ, 1q21.2), and X-linked dominant CMTX (Cx32, Xq13.1). Approx. 3/4 of CMT1 patients belong to the CMT1A subgroup and carry a 1.5-Mb duplication on chr. 17p11.2 encompassing the myelin protein PMP22 gene. Given the high duplication rate in sporadic cases, the diagnosis of CMT1A should be considered even in the absence of a family history. Furthermore, the reciprocal deletion of the CMT1A 1.5-Mb tract is commonly (∼80%) observed in HNPP patients. Altogether, detection of these relatively common molecular abnormalities allows diagnosis in the vast majority of CMT1 or HNPP patients. Patients who do not have the CMT1A duplication should be screened initially for Cx32 mutations which are the next most frequent cause of CMT1 accounting for ∼10% of patients. Approx. 4% of cases belong to the CMT1B subgroup, harboring mutations in the myelin protein P₀ gene (MPZ). Mutations in the PMP22 gene can be found in a minority of CMT1 patients. Of the remaining cases, some have been demonstrated to carry mutations in the EGR2 gene. Interestingly, mutations in the PMP22, MPZ and EGR2 genes can also cause the more severe early-onset variants DSD and CHN. A number of loci have been linked to the rare autosomal recessive forms of CMT1. Very recently, mutations in the MTMR2 and NDRG1 genes have been associated with two distinct phenotypes, AR-CMT1 with myelin outfoldings (CMT4B) and HMSN-Lom, respectively. Approx. 20–30% of CMT patients exhibit the axonal type CMT2. For the majority of these patients, no molecular test is currently available. Although several loci have been associated with this form, only one disease gene, NF-L on chr. 8p21, has been thus far identified. However, Cx32 mutations should always be excluded in female patients diagnosed with CMT2. Finally, recent evidences have indicated that mutations in the MPZ gene can be found in ∼5% of AD-CMT2 families.     

Charcot‐Marie‐Tooth disease: frequency of genetic subtypes in a Southern Italy population

The objective of this study is to assess the genetic distribution of Charcot‐Marie‐Tooth (CMT) disease in Campania, a region of Southern Italy. We analyzed a cohort of 197 index cases and reported the type and frequency of mutations for the whole CMT population and for each electrophysiological group (CMT1, CMT2, and hereditary neuropathy with susceptibility to pressure palsies [HNPP]) and for familial and isolated CMT cases. Genetic diagnosis was achieved in 148 patients (75.1%) with a higher success rate in HNPP and CMT1 than CMT2. Only four genes (PMP22, GJB1, MPZ, and GDAP1) accounted for 92% of all genetically confirmed CMT cases. In CMT1, PMP22 duplication was the most common mutation while the second gene in order of frequency was MPZ in familial and SH3TC2 in isolated cases. In CMT2, GJB1 was the most frequent mutated gene and GJB1 with GDAP1 accounted for almost 3/4 of genetically defined CMT2 patients. The first gene in order of frequency was GJB1 in familial and GDAP1 in isolated cases. In HNPP, the majority of patients harbored the PMP22 gene deletion. The novelty of our data is the relatively high frequency of SH3TC2 and GDAP1 mutations in demyelinating and axonal forms, respectively. These epidemiological data can help in panel design for our patients' population.     

Impaired intracellular trafficking is a common disease mechanism of PMP22 point mutations in peripheral neuropathies

The most common forms of hereditary motor and sensory neuropathies (HMSN) or Charcot-Marie-Tooth disease (CMT) are associated with mutations affecting myelin genes in the peripheral nervous system. A minor subgroup of CMT type 1A (CMT1A) is caused by point mutations in the gene encoding the peripheral myelin protein 22 (PMP22). To study the mechanisms by which these mutations cause the CMT pathology, we transiently transfected COS7 and Schwann cells with wild-type and PMP22 expression constructs carrying six representative dominant or de novo point mutations and one putative recessive point mutation. All but one of the first group of mutant PMP22 proteins failed to be incorporated into the plasma membrane and were retained in intracellular compartments of transfected cells. Surprisingly, the recessive PMP22 mutation produced a protein that was also mildly impaired in trafficking. Thus, our results suggest a common disease mechanism underlying the pathology of CMT1A due to PMP22 point mutations.     

Novel GDAP1 Mutation in a Turkish Family with CMT2K (CMT2K with Novel GDAP1 Mutation)

Mutations in the ganglioside-induced differentiation-associated protein 1 gene (GDAP1) cause Charcot–Marie–Tooth type 2 (CMT2), a severe autosomal recessive form of neuropathy associated with axonal phenotypes. It has been screened in this study for the presence of mutations in the coding region of GDAP1, which maps to chromosome 8q21, in a family with CMT2. To date, 29 mutations in the GDAP1 have been reported in patients of different ethnic origins. Here, we report a novel missense mutation (c.836A>G), and two polymorphisms: a silent variant (c.102G>C), and a 5′-splice site mutation (IVS5+24C>T) in GDPA1 gene identified in a five generation Turkish family with autosomal recessive CMT2.     

A molecular basis for hereditary motor and sensory neuropathy disorders

Charcot-Marie-Tooth disease (CMT), or inherited peripheral neuropathies, is one of the most frequent genetically inherited neurologic disorders, with a prevalence of approximately one in 2500 people. CMT is usually inherited in an autosomal dominant fashion, although X-linked and recessive forms of CMT also exist. Over the past several years, considerable progress has been made toward understanding the genetic causes of many of the most frequent forms of CMT, particularly those caused by mutations in Schwann cell genes inducing the demyelinating forms of CMT, also known as CMT1. Because the genetic cause of these disorders is known, it is now possible to study how mutations in genes encoding myelin proteins cause neuropathy. Identifying these mechanisms will be important both for understanding demyelination and for developing future treatments for CMT.     

Dominantly inherited peripheral neuropathies

Since 1886, the year that Charcot and Marie and Tooth described a genetic "peroneal muscular atrophy syndrome," electrophysiological and histological studies of the peripheral nervous system have greatly aided the characterization of this syndrome, which falls among the hereditary sensory-motor neuropathies. Two principal forms of Charcot-Marie-Tooth (CMT) disease have been distinguished: CMT 1, corresponding to a demyelinating type, and CMT 2, corresponding to an axonal type. The modes of transmission of these types are variable, recessive or dominant, autosomal, or X-linked. Our discussion here is confined to the dominant forms. In recent years, advances in molecular biology have greatly modified the approach to CMT disease and related neuropathies (such as hereditary neuropathy with liability to pressure palsies). With increased knowledge of responsible gene mutations and several other loci identified by linkage studies, our understanding of the pathophysiology of these neuropathies is increasing; however, with greater understanding, the classification of these disorders is becoming more complex. In this review we present and discuss the currently characterized subtypes, with emphasis on their known histological aspects. While nerve biopsy has lost its diagnostic importance in certain forms of the disease, such as CMT 1A, CMT 1B, and X-linked CMT (CMT X), it remains important for better characterizing the lesions of CMT 2 and forms of genetic peroneal atrophy in which DNA study is unrevealing.     

Increased mitochondrial fusion in a autosomal recessive CMT2A family with mitochondrial GTPase mitofusin 2 mutations

Charcot‐Marie‐Tooth type 2A disease (CMT2A) is an inherited peripheral neuropathy mainly caused by mutations in the MFN2 gene coding for the mitochondrial fusion protein mitofusin 2. Although the disease is mainly inherited in a dominant fashion, few cases of early‐onset autosomal recessive CMT2A (AR‐CMT2A) have been reported in recent years. In this study, we characterized the structure of the mitochondrial network in cultured primary fibroblasts obtained from AR‐CMT2A family members. The patient‐derived cells showed an increase of the mitochondrial fusion with large connected networks and an increase of the mitochondrial volume. Interestingly, fibroblasts derived from the two asymptomatic parents showed similar changes to a lesser extent. These results support the hypothesis that AR‐CMT2A‐related MFN2 mutations acts through a semi‐dominant negative mechanism and suggest that other biological parameters might show mild alterations in asymptomatic heterozygote AR‐CMT2A patients. Such alterations could be useful biomarkers helping to distinguish MFN2 mutations from variants, a growing challenge with the advent of next generation sequencing into routine clinical practice.