Early onset Charcot‐Marie‐Tooth neuropathy type 2A and severe developmental delay: expanding the clinical phenotype of MFN2‐related neuropathy

Charcot‐Marie‐Tooth (CMT) syndromes are a group of clinically heterogeneous disorders of the peripheral nervous system. Mutations of mitofusin 2 (MFN2) have been recognized to be associated with CMT type 2A (CMT2A). CMT2A is primarily an axonal disorder resulting in motor and sensory neuropathy. We report a male child with psychomotor delay, dysmorphic features, and weakness of lower limbs associated with electrophysiological features of severe, sensory‐motor, axonal neuropathy. The patient was diagnosed with early onset CMT2A and severe psychomotor retardation associated with c.310C>T mutation (p.R104W) in MFN2 gene. CMT2A should be considered in patients with both axonal sensory‐motor neuropathy and developmental delay.     

Late‐onset hereditary sensory and autonomic neuropathy expands the phenotypic spectrum of MFN2‐related diseases

Mutations in the Mitofusin 2 (MFN2) gene have been identified in patients with autosomal dominant axonal motor and sensory neuropathy or Charcot–Marie‐Tooth 2A (CMT2A). Here we describe clinical and pathological changes in an adult patient with sporadic hereditary sensory and autonomic neuropathy (HSAN) due to an MFN2 mutation. The patient was a 53‐year‐old man who had sensory involvement and anhidrosis in all limbs without motor features. The electrophysiological assessment documented severe axonal sensory neuropathy. The sural nerve biopsy confirmed the electrophysiological findings, revealing severe loss of myelinated and unmyelinated fibers with regeneration clusters. Genetic analysis revealed the previously identified mutation c.776 G > A in MFN2. Our report expands the phenotypic spectrum of MFN2‐related diseases. Sequencing of MFN2 should be considered in all patients presenting with late‐onset HSAN.     

Mutational mechanisms in MFN2‐related neuropathy: compound heterozygosity for recessive and semidominant mutations

Mitofusin‐2 (MFN2) mutations are the most common cause of autosomal dominant axonal Charcot‐Marie‐Tooth disease (CMT, type 2A), sometimes complicated by additional features such as optic atrophy (CMT6) and upper motor neuron involvement (CMT5). Several pathogenic mutations are reported, mainly acting in a dominant fashion, although few sequence variants behaved as recessive or semidominant in rare homozygous or compound heterozygous patients. We describe a 49‐year‐old woman with CMT5 associated with compound heterozygosity for two MFN2 variants, one already reported missense mutation (c.748C>T, p.R250W) and a novel nonsense sequence change (c.1426C>T, p.R476*). Her mother, carrying the p.R250W variant, had very late‐onset minimal axonal neuropathy, whilst the father harboring the nonsense sequence change had neither clinical nor electrophysiological neuropathy. The missense mutation is likely pathogenic according to in silico analyses and a previous report, while the nonsense variant is predicted to behave as a null allele. The p.R250W variant behaves as semidominant by causing only a mild, almost subclinical, neuropathy when heterozygous; the nonsense mutation in the father was phenotypically silent, suggesting that haploinsufficiency for MFN2 is not disease causative, but was deleterious in the daughter who had only one active mutated MFN2 allele.     

A cryptic splicing mutation in the INF2 gene causing Charcot‐Marie‐Tooth disease with minimal glomerular dysfunction

Heterozygous mutations in the inverted formin‐2 (INF2) gene provoke focal segmental glomerulosclerosis (FSGS) and intermediate Charcot‐Marie‐Tooth (CMT) disease with FSGS. Here, we report four patients from a three‐generation family with a new cryptic splicing INF2 mutation causing autosomal dominant intermediate CMT with minimal glomerular dysfunction. Three males and one female with a mean age of 51 years (26‐87) presented with a slowly progressive sensorimotor polyneuropathy, pes cavus, and kyphoscoliosis. Mean age at CMT disease onset was 11.5 years (3‐17), and electrophysiological studies showed demyelinating and axonal features consistent with intermediate CMT. Plasma albumin and creatinine were normal in all four cases, and urine protein was normal in one case and mildly raised in three patients (mean: 0.32 g/L [0.18‐0.44], N < 0.14). Genetic analysis found a c.271C > G (p. Arg91Gly) variation in INF2 exon 2, and in vitro splicing assays showed the deletion of the last 120 nucleotides of INF2 exon 2 leading to a 40 amino acids in‐frame deletion (p. Arg91_p. Gln130del). This report expands the genetic spectrum of INF2‐associated disorders and demonstrates that INF2 mutations may provoke isolated CMT with no clinically relevant kidney involvement. Consequently, INF2 mutation analysis should not be restricted to individuals with coincident neuropathy and renal disease.     

MFN2 deletion of exons 7 and 8: founder mutation in the UK population

Mitofusin 2 (MFN2) mutations are the most common cause of axonal Charcot‐Marie‐Tooth disease (CMT2). The majority are inherited in an autosomal dominant manner but recessive and semi‐dominant kindreds have also been described. We previously reported a deletion of exons 7 and 8 resulting in nonsense‐mediated decay, segregating with disease when present in trans with another pathogenic MFN2 mutation. Detailed clinical and electrophysiological data on a series of five affected patients from four kindreds and, when available, their parents and relatives were collected. MFN2 Sanger sequencing, multiplex ligation probe amplification, and haplotype analysis were performed. A severe early‐onset CMT phenotype was seen in all cases: progressive distal weakness, wasting, and sensory loss from infancy or early childhood. Optic atrophy (four of five) and wheelchair dependency in childhood were common (four of five). All were compound heterozygous for a deletion of exons 7 and 8 in MFN2 with another previously reported pathogenic mutation (Phe216Ser, Thr362Met, and Arg707Trp). Carrier parents and relatives were unaffected (age range: 24–82 years). Haplotype analysis confirmed that the deletion had a common founder in all families.     

Guillain‐BarrÉ syndrome subtype diagnosis: A prospective multicentric European study

Introduction: There is uncertainty as to whether the Guillain‐Barré syndrome (GBS) subtypes, acute inflammatory demyelinating polyradiculoneuropathy (AIDP) and acute motor axonal neuropathy (AMAN), can be diagnosed electrophysiologically. Methods: We prospectively included 58 GBS patients. Electrodiagnostic testing (EDX) was performed at means of 5 and 33 days after disease onset. Two traditional and one recent criteria sets were used to classify studies as demyelinating or axonal. Results were correlated with anti‐ganglioside antibodies and reversible conduction failure (RCF). Results: No classification shifts were observed, but more patients were classified as axonal with recent criteria. RCF and anti‐ganglioside antibodies were present in both subtypes, more frequently in the axonal subtype. Discussion: Serial EDX has no effect on GBS subtype proportions. The absence of exclusive correlation with RCF and anti‐ganglioside antibodies may challenge the concept of demyelinating and axonal GBS subtypes based upon electrophysiological criteria. Frequent RCF indicates that nodal/paranodal alterations may represent the main pathophysiology. Muscle Nerve 58 : 23–28, 2018.     

Clinical and genetic diversities of Charcot‐Marie‐Tooth disease with MFN2 mutations in a large case study

Charcot‐Marie‐Tooth disease (CMT) constitutes a heterogeneous group affecting motor and sensory neurons in the peripheral nervous system. MFN2 mutations are the most common cause of axonal CMT. We describe the clinical and mutational spectra of CMT patients harboring MFN2 mutations in Japan. We analyzed 1,334 unrelated patients with clinically suspected CMT referred by neurological and neuropediatric departments throughout Japan. We conducted mutation screening using a DNA microarray, targeted resequencing, and whole‐exome sequencing. We identified pathogenic or likely pathogenic MFN2 variants from 79 CMT patients, comprising 44 heterozygous and 1 compound heterozygous variants. A total of 15 novel variants were detected. An autosomal dominant family history was determined in 43 cases, and the remaining 36 cases were reported as sporadic with no family history. The mean onset age of CMT in these patients was 12 ± 14 (range 0–59) years. We observed neuropathic symptoms in all patients. Some had optic atrophy, vocal cord paralysis, or spasticity. We detected a compound heterozygous MFN2 mutation in a patient with a severe phenotype and the co‐occurrence of MFN2 and PMP22 mutations in a patient with an uncommon phenotype. MFN2 is the most frequent causative gene of CMT2 in Japan. We present 15 novel variants and broad clinical and mutational spectra of Japanese MFN2‐related CMT patients. Regardless of the onset age and inheritance pattern, MFN2 gene analysis should be performed. Combinations of causative genes should be considered to explain the phenotypic diversity.     

Mechanisms of disease and clinical features of mutations of the gene for mitofusin 2: an important cause of hereditary peripheral neuropathy with striking clinical variability in children and adults

Mitofusin 2, a large transmembrane GTPase located in the outer mitochondrial membrane, promotes membrane fusion and is involved in the maintenance of the morphology of axonal mitochondria. Mutations of the gene encoding mitofusin 2 (MFN2) have recently been identified as the cause of approximately one‐third of dominantly inherited cases of the axonal degenerative forms of Charcot–Marie–Tooth disease (CMT type 2A) and of rarer variants. The latter include a severe, early‐onset axonal neuropathy, which may occur in autosomal dominant or recessive forms, as well as some instances associated with pyramidal tract involvement (CMT type 5), with optic atrophy (CMT type 6), and, occasionally, with alterations of cerebral white matter. All individuals with a dominantly or recessively inherited or otherwise unexplained, chronic progressive axonal degenerative polyneuropathy should be tested for mutations of MFN2.     

Mitochondrial trifunctional protein deficiency: A rare cause of adult‐onset rhabdomyolysis

Introduction: Mitochondrial trifunctional protein deficiency is a rare autosomal recessive disorder of mitochondrial fatty acid β‐oxidation that may be due to mutations in 2 different nuclear genes, HADHA and HADHB. Perturbation of this multienzyme complex compromises the oxidation of long‐chain fatty acids, which leads to multiorgan dysfunction. Childhood‐ or adolescent‐onset recurrent rhabdomyolysis is a common muscular manifestation and is preceded frequently by clinically overt peripheral neuropathy. Methods: In this report we describe a patient with late adult‐onset recurrent rhabdomyolysis. Results: Despite normal sensory examination, nerve conduction studies showed a mild axonal peripheral neuropathy. The acylcarnitine profile showed elevated long‐chain and 3‐hydroxy long‐chain acylcarnitine species. HADHA sequencing revealed known compound heterozygous mutations c.180+3A>G (p.Thr37SerfsX6) and c.1528G>C (p.Glu510Gln). During a 10‐month follow‐up period, he had no further episodes of rhabdomyolysis after appropriate dietary modifications. Conclusions: Mitochondrial trifunctional protein deficiency should be considered in patients with adult‐onset recurrent rhabdomyolysis, especially in those with either clinically overt or subclinical peripheral neuropathy. Muscle Nerve 48 : 989–991, 2013     

Characterization of the mitofusin 2 R94W mutation in a knock‐in mouse model

Charcot‐Marie‐Tooth disease (CMT) comprises a group of heterogeneous peripheral axonopathies affecting 1 in 2,500 individuals. As mutations in several genes cause axonal degeneration in CMT type 2, mutations in mitofusin 2 (MFN2) account for approximately 90% of the most severe cases, making it the most common cause of inherited peripheral axonal degeneration. MFN2 is an integral mitochondrial outer membrane protein that plays a major role in mitochondrial fusion and motility; yet the mechanism by which dominant mutations in this protein lead to neurodegeneration is still not fully understood. Furthermore, future pre‐clinical drug trials will be in need of validated rodent models. We have generated a Mfn2 knock‐in mouse model expressing Mfn2^R94W, which was originally identified in CMT patients. We have performed behavioral, morphological, and biochemical studies to investigate the consequences of this mutation. Homozygous inheritance leads to premature death at P1, as well as mitochondrial dysfunction, including increased mitochondrial fragmentation in mouse embryonic fibroblasts and decreased ATP levels in newborn brains. Mfn2^R94W heterozygous mice show histopathology and age‐dependent open‐field test abnormalities, which support a mild peripheral neuropathy. Although behavior does not mimic the severity of the human disease phenotype, this mouse can provide useful tissues for studying molecular pathways associated with MFN2 point mutations.     

Clincial and pathological study of distal motor neuropathy with N88S mutation in BSCL2

Seipinopathy is an autosomal dominant inherited distal motor neuropathy caused by Berardinelli‐Seip congenital lipodystrophy 2 (BSCL2) gene mutations. We describe a Chinese family with seipinopathy in which nine patients from four successive generations were involved. The onset of age was from 13 to 40 years. Among them six were distal hereditary motor neuropathy type II with predominant weakness of lower extremities, while one of them was accompanied by pyramidal signs. The other three women were distal hereditary motor neuropathy type V with predominant atrophy of hands. Electrophysiological results in one patient demonstrated reduction of amplitude of compound muscle action potentials. Sural nerve biopsy showed loss of large myelinated fibers and fiber regeneration. Gene analysis revealed a heterozygous 263A→G mutation in BSCL2 gene resulting in amino acid substitutions in N88S. This report suggests that a different type of distal hereditary motor neuropathy could exist within one family carrying N88S mutations. The axonal degeneration of sensory nerves appeared also in the disease.     

SCN2A channelopathies: Mechanisms and models

Variants in the SCN2A gene, encoding the voltage‐gated sodium channel Na_V1.2, cause a variety of neuropsychiatric syndromes with different severity ranging from self‐limiting epilepsies with early onset to developmental and epileptic encephalopathy with early or late onset and intellectual disability (ID), as well as ID or autism without seizures. Functional analysis of channel defects demonstrated a genotype‐phenotype correlation and suggested effective treatment options for one group of affected patients carrying gain‐of‐function variants. Here, we sum up the functional mechanisms underlying different phenotypes of patients with SCN2A channelopathies and present currently available models that can help in understanding SCN2A‐related disorders.     

Phenotype variability and histopathological findings in patients with a novel DNM2 mutation

Mutations of Dynamin 2 (DNM2) are responsible for several forms of neuromuscular disorder such as centronuclear myopathy, Charcot–Marie–Tooth disease (CMT) dominant intermediate type B, CMT 2M, and lethal congenital contracture syndrome 5. We describe a young man manifesting as length‐dependent sensorimotor neuropathy with hypertrophic cardiomyopathy, but his mother only had very mild symptoms of peripheral neuropathy. The electrophysiological data meet the criteria of intermediate CMT. The main pathological findings of sural nerve biopsy reveal a severe loss of large myelinating fibers and some clusters of regenerative fibers in fascicles, which are consistent with an axonal neuropathy. However, myopathological changes show a chronic myopathy‐like pattern characterized by great variations of fiber size, increased connective tissue, rimmed vacuoles and predominance of type 2 fibers. A novel DNM2 mutation (p.G359D) in the middle domain is identified, which is highly evolutionarily conserved. DNM2‐related CMT disease is phenotypically heterogeneous in age at onset, clinical features and electrophysiological changes. The histopathological findings indicate the coexistence of typical axonal neuropathy and chronic myopathy in DNM2‐related neuromuscular diseases.     

A novel INF2 mutation in a Korean family with autosomal dominant intermediate Charcot‐Marie‐Tooth disease and focal segmental glomerulosclerosis

Mutations in the inverted formin‐2 (INF2) gene were recently identified in patients with autosomal dominant intermediate Charcot‐Marie‐Tooth (DI‐CMT) disease and focal segmental glomerulosclerosis (FSGS). Here, we identified a novel p.L132P INF2 mutation in a Korean family with DI‐CMT and FSGS by whole‐exome sequencing. This mutation was cosegregated with affected individuals in the family and was not found in the 300 controls. The two affected members exhibited juvenile onset sensorimotor polyneuropathy and FSGS. Nerve conduction studies showed an intermediate range of motor nerve conduction velocities. We report a novel INF2 mutation in a family with DI‐CMT and FSGS as the first case in Koreans. The INF2 mutation appears to be a major cause of CMT with FSGS.     

Sh3tc2 deficiency affects neuregulin‐1/ErbB signaling

Mutations in SH3TC2 trigger autosomal recessive demyelinating Charcot‐Marie‐Tooth type 4C (CMT4C) neuropathy. Sh3tc2 is specifically expressed in Schwann cells and is necessary for proper myelination of peripheral axons. In line with the early onset of neuropathy observed in patients with CMT4C, our analyses of the murine model of CMT4C revealed that the myelinating properties of Sh3tc2‐deficient Schwann cells are affected at an early stage. This early phenotype is associated with changes in the canonical Nrg1/ErbB pathway involved in control of myelination. We demonstrated that Sh3tc2 interacts with ErbB2 and plays a role in the regulation of ErbB2 intracellular trafficking from the plasma membrane upon Nrg1 activation. Interestingly, both the loss of Sh3tc2 function in mice and the pathological mutations present in CMT4C patients affect ErbB2 internalization, potentially altering its downstream intracellular signaling pathways. Altogether, our results indicate that the molecular mechanism for the axonal size sensing is disturbed in Sh3tc2‐deficient myelinating Schwann cells, thus providing a novel insight into the pathophysiology of CMT4C neuropathy.     

Neuroaxonal dystrophy in PLA2G6 knockout mice

The PLA2G6 gene encodes group VIA calcium‐independent phospholipase A₂ (iPLA₂β), which belongs to the PLA₂ superfamily that hydrolyses the sn‐2 ester bond in phospholipids. In the nervous system, iPLA₂β is essential for remodeling membrane phospholipids in axons and synapses. Mutated PLA2G6 causes PLA2G6‐associated neurodegeneration (PLAN) including infantile neuroaxonal dystrophy (INAD) and adult‐onset dystonia‐parkinsonism (PARK14), which have unique clinical phenotypes. In the PLA2G6 knockout (KO) mouse, which is an excellent PLAN model, specific membrane degeneration takes place in neurons and their axons, and this is followed by axonal spheroid formation. These pathological findings are similar to those in PLAN. This review details the evidence that membrane degeneration of mitochondria and axon terminals is a precursor to spheroid formation in this disease model. From a young age before the onset, many mitochondria with damaged inner membranes appear in PLA2G6 KO mouse neurons. These injured mitochondria move anterogradely within the axons, increasing in the distal axons. As membrane degeneration progresses, the collapse of the double membrane of mitochondria accompanies axonal injury near impaired mitochondria. At the axon terminals, the membranes of the presynapses expand irregularly from a young age. Over time, the presynaptic membrane ruptures, causing axon terminal degeneration. Although these processes occur in different degenerating membranes, both contain tubulovesicular structures, which are a specific ultrastructural marker of INAD. This indicates that two unique types of membrane degeneration underlie PLAN pathology. We have shown a new pathological mechanism whereby axons degenerate due to defective maintenance and rupture of both the inner mitochondrial and presynaptic membranes. This degeneration mechanism could possibly clarify the pathologies of PLAN, Parkinson disease and neurodegeneration with iron accumulation (NBIA), which are assumed to be due to the primary degeneration of axons.     

Clinical spectrum of AIFM1‐associated disease in an Irish family,from mild neuropathy to severe cerebellar ataxia with colour blindness

Mutations in apoptosis‐inducing factor mitochondrion‐associated‐1 (AIFM1) cause X‐linked peripheral neuropathy (Cowchock syndrome, CMT4X); however, more recently a cerebellar presentation has been described. We describe a large Irish family with seven affected males. They presented with a variable age of onset, 18 months to 39 years of age. All developed variably present sensorineural deafness, peripheral neuropathy, cerebellar ataxia, and pyramidal involvement. In addition, three had colour vision deficiency. Scale for the assessment and rating of ataxia ranged 2 to 23/40, while Charcot‐Marie‐Tooth neuropathy score 2 varied between 7 and 13/36. All individuals had normal cognitive assessment. Neurophysiology demonstrated length‐dependent large‐fibre sensorimotor axonal neuropathy, with particular involvement of superficial radial sensory responses. Brain imaging, performed in four, revealed varying extent of cerebellar atrophy, and white matter changes in one. Optical coherence tomography was abnormal in one, who had unrelated eye pathology. Four obligate female carriers were assessed clinically, two of them neurophysiologically; all were unaffected. Whole genome sequencing demonstrated a previously reported hemizygous AIFM1 mutation. Analysis for mutations in other genes associated with colour deficiency was negative. AIFM1‐associated phenotype in this family demonstrated significant variability. To our knowledge, this is the first report of AIFM1‐associated colour blindness. Superficial radial nerve was particularly affected neurophysiologically, which could represent a phenotypic marker towards this specific genetic diagnosis.     

Indian‐subcontinent NBIA: Unusual phenotypes,novel PANK2 mutations,and undetermined genetic forms

Neurodegeneration with brain iron accumulation (NBIA) is etiologically, clinically, and by imaging a heterogeneous group including NBIA types 1 [pantothenate kinase‐associated neurodegeneration (PKAN)] and 2 (PLA2G6‐associated neurodegeneration), neuroferritinopathy, and aceruloplasminaemia. Data on genetically defined Indian‐subcontinent NBIA cases are limited. We report 6 patients from the Indian‐subcontinent with a movement disorder and MRI basal ganglia iron deposition, compatible with diagnosis of an NBIA syndrome. All patients were screened for abnormalities in serum ceruloplasmin and ferritin levels and mutations in NBIA‐associated genes [pantothenate kinase 2 (PANK2), PLA2G6 and ferritin light chain (exon 4)]. We present clinical, imaging and genetic data correlating phenotype–genotype relations. Four patients carried PANK2 mutations, two of these were novel. The clinical phenotype was mainly dystonic with generalized dystonia and marked orobulbar features in the 4 adolescent‐onset cases. One of the four had a late‐onset (age 37) unilateral jerky postural tremor. His mutation, c.1379C>T, appears associated with a milder phenotype. Interestingly, he developed the eye‐of‐the‐tiger sign only 10 years after onset. Two of the six presented with adult‐onset levodopa (L ‐dopa)‐responsive asymmetric re‐emergent rest tremor, developing L ‐dopa‐induced dyskinesias, and good benefit to deep brain stimulation (in one), thus resembling Parkinson's disease (PD). Both had an eye‐of‐the‐tiger sign on MRI but were negative for known NBIA‐associated genes, suggesting the existence of further genetic or sporadic forms of NBIA syndromes. In conclusion, genetically determined NBIA cases from the Indian subcontinent suggest presence of unusual phenotypes of PANK2 and novel mutations. The phenotype of NBIA of unknown cause includes a PD‐like presentation. © 2010 Movement Disorder Society     

Sonography of the median nerve in CMT1A,CMT2A,CMTX, and HNPP

Introduction: In this study we compare the ultrasound features in the median nerve in patients with different types of Charcot–Marie–Tooth (CMT) disease and hereditary neuropathies with liability to pressure palsies (HNPP) as a typical entrapment neuropathy. Methods: Median nerve ultrasound and conduction studies were performed in patients with CMT1A (n = 12), MFN2‐associated CMT2A (n = 7), CMTX (n = 5), and HNPP (n = 5), and in controls (n = 28). Results: Median nerve cross‐sectional area (CSA) was significantly increased in CMT1A, whereas, in axonal CMT2A, fascicle diameter (FD) was enlarged. CSA correlated with nerve conduction slowing in CMT1A and with axonal loss, as shown by motor and sensory nerve amplitudes in both CMT1A and CMT2A. A relatively low wrist‐to‐forearm‐ratio (WFR <0.8) or a relatively high WFR (>1.8) appeared to be unlikely in MFN2 and Cx32 mutations of CMT2A and CMTX, respectively. Conclusion: Differences in CSA, FD, and WFR of the median nerve can be helpful in defining subtypes of hereditary neuropathies. Muscle Nerve 47:385‐395, 2013