Painful neuropathies: the emerging role of sodium channelopathies

Pain is a frequent debilitating feature reported in peripheral neuropathies with involvement of small nerve (Aδ and C) fibers. Voltage‐gated sodium channels are responsible for the generation and conduction of action potentials in the peripheral nociceptive neuronal pathway where Na_V1.7, Na_V1.8, and Na_V1.9 sodium channels (encoded by SCN9A, SCN10A, and SCN11A) are preferentially expressed. The human genetic pain conditions inherited erythromelalgia and paroxysmal extreme pain disorder were the first to be linked to gain‐of‐function SCN9A mutations. Recent studies have expanded this spectrum with gain‐of‐function SCN9A mutations in patients with small fiber neuropathy and in a new syndrome of pain, dysautonomia, and small hands and small feet (acromesomelia). In addition, painful neuropathies have been recently linked to SCN10A mutations. Patch‐clamp studies have shown that the effect of SCN9A mutations is dependent upon the cell‐type background. The functional effects of a mutation in dorsal root ganglion (DRG) neurons and sympathetic neuron cells may differ per mutation, reflecting the pattern of expression of autonomic symptoms in patients with painful neuropathies who carry the mutation in question. Peripheral neuropathies may not always be length‐dependent, as demonstrated in patients with initial facial and scalp pain symptoms with SCN9A mutations showing hyperexcitability in both trigeminal ganglion and DRG neurons. There is some evidence suggesting that gain‐of‐function SCN9A mutations can lead to degeneration of peripheral axons. This review will focus on the emerging role of sodium channelopathies in painful peripheral neuropathies, which could serve as a basis for novel therapeutic strategies.     

SCN1A/NaV1.1 channelopathies: Mechanisms in expression systems,animal models,and human iPSC models

Pathogenic SCN1A/Na_V1.1 mutations cause well‐defined epilepsies, including genetic epilepsy with febrile seizures plus (GEFS+) and the severe epileptic encephalopathy Dravet syndrome. In addition, they cause a severe form of migraine with aura, familial hemiplegic migraine. Moreover, SCN1A/Na_V1.1 variants have been inferred as risk factors in other types of epilepsy. We review here the advancements obtained studying pathologic mechanisms of SCN1A/Na_V1.1 mutations with experimental systems. We present results gained with in vitro expression systems, gene‐targeted animal models, and the induced pluripotent stem cell (iPSC) technology, highlighting advantages, limits, and pitfalls for each of these systems. Overall, the results obtained in the last two decades confirm that the initial pathologic mechanism of epileptogenic SCN1A/Na_V1.1 mutations is loss‐of‐function of Na_V1.1 leading to hypoexcitability of at least some types of γ‐aminobutyric acid (GABA)ergic neurons (including cortical and hippocampal parvalbumin‐positive and somatostatin‐positive ones). Conversely, more limited results point to Na_V1.1 gain‐of‐function for familial hemiplegic migraine (FHM) mutations. Behind these relatively simple pathologic mechanisms, an unexpected complexity has been observed, in part generated by technical issues in experimental studies and in part related to intrinsically complex pathophysiologic responses and remodeling, which yet remain to be fully disentangled.     

An SCN2A mutation in a family with infantile seizures from Madagascar reveals an increased subthreshold Na+ current

Missense mutations in SCN2A, encoding the brain sodium channel Na_V1.2, have been described in benign familial neonatal‐infantile seizures (BFNIS), a self‐limiting disorder, whereas several SCN2A de novo nonsense mutations have been found in patients with more severe phenotypes including epileptic encephalopathy. We report a family with BFNIS originating from Madagascar. Onset extended from 3 to 9 months of age. Interictal EEGs were normal. In two patients, ictal electroencephalography (EEG) studies showed partial seizure patterns with secondary generalization in one. Seizures remitted before 18 months of age, with or without medication. Intellectual development was normal. A novel missense mutation of SCN2A, c.4766A>G/p.Tyr1589Cys, was found in a highly conserved region of Na_V1.2 (D4/S2‐S3). Functional studies using heterologous expression in tsA201 cells and whole‐cell patch clamping revealed a depolarizing shift of steady‐state inactivation, increased persistent Na⁺ current, a slowing of fast inactivation and an acceleration of its recovery, thus a gain‐of‐function. Using an action potential waveform in a voltage‐clamp experiment we indicated an increased inward Na⁺ current at subthreshold voltages, which can explain a neuronal hyperexcitability. Our results suggest that this mutation induces neuronal hyperexcitability, resulting in infantile epilepsy with favorable outcome.     

Induction of sodium channel Nax (SCN7A) expression in rat and human hippocampus in temporal lobe epilepsy

Purpose: In a recent large‐scale gene‐expression study in a rat model of temporal lobe epilepsy (TLE) a persistent up‐regulation in the expression of the SCN7A gene was revealed. The SCN7A gene encodes an atypical sodium channel (Na_x), which is involved in osmoregulation via a sensing mechanism for the extracellular sodium concentration. Herein we investigated the expression and cellular distribution of SCN7A mRNA and protein in normal and epileptic rat and human hippocampus. Methods: SCN7A/Na_x expression analysis was performed by polymerase chain reaction (PCR), immunocytochemistry, and western blot analysis. Results: Increased expression of SCN7A/Na_x mRNA/protein was observed during epileptogenesis and in the chronic epileptic phase in the post–status epilepticus (SE) model of TLE. The up‐regulation was confirmed in human hippocampal tissue resected from pharmacoresistant patients with hippocampal sclerosis (HS). In both epileptic rat and human hippocampus, increased Na_x expression was observed in neurons and reactive astrocytes compared to control tissue. Conclusions: The increased and persistent expression of SCN7A/Na_x in the epileptic rat and human hippocampus supports the possible involvement of this channel in the complex reorganization occurring within the hippocampus during the epileptogenic process in TLE. Further studies are needed for a complete understanding of the functional role of SCN7A in epilepsy.     

A sodium channel mutation linked to epilepsy increases ramp and persistent current of Nav1.3 and induces hyperexcitability in hippocampal neurons

Voltage-gated sodium channelopathies underlie many excitability disorders. Genes SCN1A, SCN2A and SCN9A, which encode pore-forming α-subunits Na_V1.1, Na_V1.2 and Na_V1.7, are clustered on human chromosome 2, and mutations in these genes have been shown to underlie epilepsy, migraine, and somatic pain disorders. SCN3A, the gene which encodes Na_V1.3, is part of this cluster, but until recently was not associated with any mutation. A charge-neutralizing mutation, K345Q, in the Na_V1.3 DI/S5-6 linker has recently been identified in a patient with cryptogenic partial epilepsy. Pathogenicity of the Na_V1.3/K354Q mutation has been inferred from the conservation of this residue in all sodium channels and its absence from control alleles, but functional analysis has been limited to the corresponding substitution in the cardiac muscle sodium channel Na_V1.5. Since identical mutations may produce different effects within different sodium channel isoforms, we assessed the K354Q mutation within its native Na_V1.3 channel and studied the effect of the mutant Na_V1.3/K354Q channels on hippocampal neuron excitability. We show here that the K354Q mutation enhances the persistent and ramp currents of Na_V1.3, reduces current threshold and produces spontaneous firing and paroxysmal depolarizing shift-like complexes in hippocampal neurons. Our data provide a pathophysiological basis for the pathogenicity of the first epilepsy-linked mutation within Na_V1.3 channels and hippocampal neurons.     

A homozygous mutation of voltage‐gated sodium channel βI gene SCN1B in a patient with Dravet syndrome

Dravet syndrome is a severe form of epileptic encephalopathy characterized by early onset epileptic seizures followed by ataxia and cognitive decline. Approximately 80% of patients with Dravet syndrome have been associated with heterozygous mutations in SCN1A gene encoding voltage‐gated sodium channel (VGSC) α_I subunit, whereas a homozygous mutation (p.Arg125Cys) of SCN1B gene encoding VGSC β_I subunit was recently described in a patient with Dravet syndrome. To further examine the involvement of homozygous SCN1B mutations in the etiology of Dravet syndrome, we performed mutational analyses on SCN1B in 286 patients with epileptic disorders, including 67 patients with Dravet syndrome who have been negative for SCN1A and SCN2A mutations. In the cohort, we found one additional homozygous mutation (p.Ile106Phe) in a patient with Dravet syndrome. The identified homozygous SCN1B mutations indicate that SCN1B is an etiologic candidate underlying Dravet syndrome.     

SCN1A‐related phenotypes: Epilepsy and beyond

SCN1A, encoding the alpha 1 subunit of the sodium channel, is associated with several epilepsy syndromes and a range of other diseases. SCN1A represents the archetypal channelopathy associated with a wide phenotypic spectrum of epilepsies ranging from genetic epilepsy with febrile seizures plus (GEFS+), to developmental and epileptic encephalopathies (DEEs). SCN1A disorders also result in other diseases such as hemiplegic migraine and autism spectrum disorder (ASD). Dravet syndrome (DS) is the prototypic DEE with an early onset of febrile status epilepticus, hemiclonic or generalized tonic‐clonic seizures, and later onset of additional seizure types. Electroencephalography (EEG) and magnetic resonance imaging (MRI) are normal at onset. Development is normal in the first year of life but plateaus rapidly, with most patients ultimately having intellectual disability. Epilepsy is drug‐resistant and necessitates polytherapy. Most pathogenic variants occur de novo in the affected child, but they are inherited from mosaic affected or unaffected parents in rare cases. The molecular finding of haploinsufficiency is consistent with a loss‐of‐function defect in cells and animal models. Although seizures are the most commonly reported symptom in DS, many additional issues critically affect patients’ cognitive and behavioral functioning. Hemiplegic migraine (HM) is a rare form of migraine with aura, characterized by the emergence of hemiparesis as part of the aura phase. All SCN1A mutations reported in sporadic/familial HM3 are missense mutations. Most of the experimental results show that they cause a gain of function of Na_V1.1 as opposed to the loss of function of the epileptogenic Na_V1.1 mutations. SCN1A and SCN2A pathogenic variants have been identified in genetic studies of cohorts of patients with ASD. In addition, ASD features are often reported in patients with Dravet syndrome and other DEEs.     

Dravet syndrome: Seizure control and gait in adults with different SCN1A mutations

Purpose: Dravet syndrome (DS) is an aggressive epileptic encephalopathy. Pharmacoresistant seizures of several types plague most patients with DS throughout their lives. Gait difficulties are a common, but inconsistent finding. The majority of cases are caused by mutations in the SCN1A gene, but little information is available about how particular mutations influence the adult phenotype. The purpose of this study is to correlate different types of SCN1A mutations and (1) seizure control, (2) occurrence of convulsive status epilepticus (cSE), and (3) the presence of crouch gait in adult patients. Methods: In a cohort of 10 adult patients with DS caused by SCN1A mutations, we investigated seizure frequency, history of cSE, and gait. All patients were identified in the epilepsy clinic between 2009 and 2011. SCN1A mutations were divided into four different groups based on location or effect of the mutation. Retrospective chart review and recent physical examination were completed in all cases. Key Findings: All patients had a pathogenic mutation in the SCN1A gene. Four SCN1A mutations have not been described previously. Greater than 90% seizure reduction was observed (compared to childhood frequency) in six of seven patients with missense mutations in the pore‐forming region (PFR) of the Na_v1.1 protein (group A) and nonsense mutations (group B). One patient with a splice‐site mutation (group C) and another with a mutation outside the PFR (group D) became free of all types of seizures. cSE after the age of 19 years was observed in only one patient. Crouch gait, without spasticity, is identified as an element of the adult DS phenotype. However, only one half of our adult DS cohort demonstrated crouch gait. This feature was observed in five of seven patients from groups A and B. Significance: This study shows that seizure control improves and cSE become less frequent in DS as patients age, independent of their SCN1A mutation type. Complete seizure freedom was seen in two patients (groups C and D). Finally, this study shows that in DS, crouch gait can be observed in up to 50% of adults with SCN1A mutation. Although no definite statistical correlations could be made due to the small number of patients, it is interesting to note that crouch gait was observed only in those patients with nonsense mutations or mutations in the PFR. Future studies with larger cohorts will be required to formally assess an association of gait abnormalities with particular SCN1A mutations.     

Partial epilepsy with antecedent febrile seizures and seizure aggravation by antiepileptic drugs: Associated with loss of function of Nav1.1

Purpose: Generalized epilepsy with febrile seizures plus (GEFS+) and severe myoclonic epilepsy in infancy (SMEI) are associated with sodium channel α‐subunit type‐1 gene (SCN1A) mutations. Febrile seizures and partial seizures occur in both GEFS+ and SMEI; sporadic onset and seizure aggravation by antiepileptic drugs (AEDs) are features of SMEI. We thus searched gene mutations in isolated cases of partial epilepsy with antecedent FS (PEFS+) that showed seizure aggravations by AEDs. Methods: Genomic DNA from four patients was screened for mutations in SCN1A, SCN2A, SCN1B, and GABRG2 using denaturing high‐performance liquid chromatography (dHPLC) and sequencing. Whole‐cell patch clamp analysis was used to characterize biophysical properties of two newly defined mutants of Na_v1.1 in tsA201 cells. Results: Two heterozygous de novo mutations of SCN1A (R946H and F1765L) were detected, which were proven to cause loss of function of Na_v1.1. When the functional defects of mutants reported previously are compared, it is found that all mutants from PEFS+ have features of loss of function, whereas GEFS+ shows mild dysfunction excluding loss of function, coincident with mild clinical manifestations. PEFS+ is similar to SMEI clinically with possible AED‐induced seizure aggravation and biophysiologically with features of loss of function, and different from SMEI by missense mutation without changes in hydrophobicity or polarity of the residues. Conclusions: Isolated milder PEFS+ may associate with SCN1A mutations and loss of function of Na_v1.1, which may be the basis of seizure aggravation by sodium channel–blocking AEDs. This study characterized phenotypes biologically, which may be helpful in understanding the pathophysiologic basis, and further in management of the disease.     

The therapeutic implication of a novel SCN2A mutation associated early-onset epileptic encephalopathy with Rett-like features

Epileptic encephalopathies are highly heterogeneous and phenotypical disorders with different underlying genetic defects. Mutations in the SCN2A gene cause different epilepsy syndromes, including epilepsy of infancy with migrating focal seizures, Ohtahara syndrome, and West syndrome. We utilized a targeted next generation sequencing (NGS) approach on a girl with early-onset seizures and Rett-like features, including autistic behavior, limited hand function with chorea, and profound intellectual disability, to identify novel missense mutation (c.1270G>A; p.V424M) in the SCN2A gene, which encodes the αII-subunit of the voltage-gated Na⁺ channel (Na_v1.2). The identified SCN2A mutation responsible for the development of the disease is confirmed to be de novo for the proband. Our findings broaden the clinical spectrum of SCN2A mutations, which resembles clinical phenotypes of SCN1A mutations by manifesting as fever sensitive seizures, and highlights that SCN2A mutations are an important cause of early-onset epileptic encephalopathies with movement disorders. In addition, the use of levetiracetam to treat SCN2A epileptic encephalopathy, when Na⁺ channel-blocking anticonvulsants are ineffective, is also recommended.     

A sodium channel gene SCN9A polymorphism that increases nociceptor excitability

Sodium channel Na_V1.7, encoded by the SCN9A gene, is preferentially expressed in nociceptive primary sensory neurons, where it amplifies small depolarizations. In studies on a family with inherited erythromelalgia associated with Na_V1.7 gain‐of‐function mutation A863P, we identified a nonsynonymous single‐nucleotide polymorphism within SCN9A in the affected proband and several unaffected family members; this polymorphism (c. 3448C&T, Single Nucleotide Polymorphisms database rs6746030, which produces the amino acid substitution R1150W in human Na_V1.7 [hNa_V1.7]) is present in 1.1 to 12.7% of control chromosomes, depending on ethnicity. In this study, we examined the effect of the R1150W substitution on function of the hNa_V1.7 channel, and on the firing of dorsal root ganglion (DRG) neurons in which this channel is normally expressed. We show that this polymorphism depolarizes activation (7.9–11mV in different assays). Current‐clamp analysis shows that the 1150W allele depolarizes (6mV) resting membrane potential and increases (～2‐fold) the firing frequency in response to depolarization in DRG neurons in which it is present. Our results suggest that polymorphisms in the Na_V1.7 channel may influence susceptibility to pain. Ann Neurol 2009;66:862–866     

Exome sequencing identifies a de novo SCN2A mutation in a patient with intractable seizures,severe intellectual disability,optic atrophy,muscular hypotonia,and brain abnormalities

Epilepsy is a phenotypically and genetically highly heterogeneous disorder with >200 genes linked to inherited forms of the disease. To identify the underlying genetic cause in a patient with intractable seizures, optic atrophy, severe intellectual disability (ID), brain abnormalities, and muscular hypotonia, we performed exome sequencing in a 5‐year‐old girl and her unaffected parents. In the patient, we detected a novel, de novo missense mutation in the SCN2A (c.5645G>T; p.R1882L) gene encoding the α_II‐subunit of the voltage‐gated sodium channel Na_v1.2. A literature review revealed 33 different SCN2A mutations in 14 families with benign forms of epilepsy and in 21 cases with severe phenotypes. Although almost all benign mutations were inherited, the majority of severe mutations occurred de novo. Of interest, de novo SCN2A mutations have also been reported in five patients without seizures but with ID (n = 3) and/or autism (n = 3). In the present study, we successfully used exome sequencing to detect a de novo mutation in a genetically heterogeneous disorder with epilepsy and ID. Using this approach, we expand the phenotypic spectrum of SCN2A mutations. Our own and literature data indicate that SCN2A‐linked severe phenotypes are more likely to be caused by de novo mutations. A PowerPoint slide summarizing this article is available for download in the Supporting Information section here .     

Missense mutation of the sodium channel gene SCN2A causes Dravet syndrome

Mutations of the gene encoding the α2 subunit of the neuronal sodium channel, SCN2A, have been found in benign familial neonatal-infantile seizures (BFNIS). In Dravet syndrome, only one nonsense mutation of SCN2A was identified, while hundreds of mutations were found in the paralogue gene, SCN1A, which encodes the α1 subunit. This study examines whether SCN2A mutations are associated with Dravet syndrome. We screened for mutations of SCN1A, SCN2A and GABRG2 (the gene encoding γ2 subunit of the GABA_A receptor) in 59 patients with Dravet syndrome and found 29 SCN1A mutations and three missense SCN2A mutations. Among the three, one de novo SCN2A mutation (c.3935G>C: R1312T) identified in a patient was thought to affect an arginine residue in a voltage sensor of the channel and hence, to be pathogenic. This finding suggests that both nonsense mutations and missense SCN2A mutations cause Dravet syndrome.     

The incidence of SCN1A‐related Dravet syndrome in Denmark is 1:22,000: A population‐based study from 2004 to 2009

Dravet syndrome is a severe infantile‐onset epileptic encephalopathy associated with mutations in the sodium channel alpha‐1 subunit gene SCN1A. We aimed to describe the incidence of Dravet syndrome in the Danish population. Based on a 6‐year birth cohort from 2004 to 2009, we propose an incidence of 1:22,000, which is higher than what has been established earlier. We identified 17 cases with SCN1A mutation–positive Dravet syndrome. Fifteen patients were found, by conventional Sanger sequencing. Two additional patients with clinical Dravet syndrome, but without a detectable SCN1A mutation by Sanger sequencing, were diagnosed with a SCN1A mutation after using a targeted next‐generation sequencing gene panel.     

A Subtle Alternative Splicing Event of the Na<Subscript>V</Subscript>1.8 Voltage-Gated Sodium Channel is Conserved in Human,Rat, and Mouse

The voltage-gated sodium channel subtype Na_V1.8 (SCN10A) is exclusively expressed in dorsal root ganglia (DRG) and plays a critical role in pain perception. We isolated mRNA from human, rat, and mouse DRGs and screened for alternatively spliced isoforms of the SCN10A mRNA using 454 sequencing. In all three species, we found an event of subtle alternative splicing at a NAGNAG tandem acceptor that results in isoforms including or lacking glutamine 1030 (Na_V1.8+Q and Na_V1.8-Q, respectively) within the cytoplasmic loop between domains II and III. The relative amount of Na_V1.8-Q mRNA in adult DRG was measured with 14.1 ± 0.1% in humans and 11.2 ± 0.2% in rats. This is in contrast to an abundance of 64.3 ± 0.3% in mouse DRG. Thus, the NAGNAG tandem acceptor in SCN10A is conserved among rodents and humans but its alternative usage apparently occurs with species-specific abundance. Analysis of human Na_V1.8+Q and -Q isoforms in whole-cell patch-clamp experiments after heterologous expression in the neuroblastoma cell line Neuro-2A revealed no obvious impact of the splicing event on channel function.     

A novel SCN1A mutation in a cytoplasmic loop in intractable juvenile myoclonic epilepsy without febrile seizures

Generalised (genetic) epilepsy with febrile seizures plus (GEFS+) is a familial epilepsy syndrome with various phenotypes. The majority of individuals with GEFS+ have generalised seizure types, in addition to febrile seizures (FS) or febrile seizures plus (FS+), defined as either continued FS after 6 years of age or afebrile seizures following FS. A 27‐year‐old man with no history of FS/FS+ experienced intractable generalised convulsive seizures. The patient's father had a history of similar seizures during puberty and the patient's siblings had only FS. No individual in the family had both generalised seizures and FS/FS+, although GEFS+ might be considered to be present in the family. Analysis of SCN1A, a sodium channel gene, revealed a novel mutation (c.3250A>T [S1084C]) in the cytoplasmic loop 2 of SCN1A in both the patient and his father. Most previously reported SCN1A mutations in GEFS+ patients are located in the conserved homologous domains of SCN1A, whereas mutations in the cytoplasmic loops are very rare. SCN1A gene analysis is not commonly performed in subjects with generalised seizures without FS. SCN1A mutation may be a clinically‐useful genetic marker in order to distinguish GEFS+ patients from those with classic idiopathic generalised epilepsy, even if they present an atypical clinical picture.     

SCN1A testing for epilepsy: Application in clinical practice

This report is a practical reference guide for genetic testing of SCN1A, the gene encoding the α1 subunit of neuronal voltage‐gated sodium channels (protein name: Na_v1.1). Mutations in this gene are frequently found in Dravet syndrome (DS), and are sometimes found in genetic epilepsy with febrile seizures plus (GEFS+), migrating partial seizures of infancy (MPSI), other infantile epileptic encephalopathies, and rarely in infantile spasms. Recommendations for testing: (1) Testing is particularly useful for people with suspected DS and sometimes in other early onset infantile epileptic encephalopathies such as MPSI because genetic confirmation of the clinical diagnosis may allow optimization of antiepileptic therapy with the potential to improve seizure control and developmental outcome. In addition, a molecular diagnosis may prevent the need for unnecessary investigations, as well as inform genetic counseling. (2) SCN1A testing should be considered in people with possible DS where the typical initial presentation is of a developmentally normal infant presenting with recurrent, febrile or afebrile prolonged, hemiclonic seizures or generalized status epilepticus. After age 2, the clinical diagnosis of DS becomes more obvious, with the classical evolution of other seizure types and developmental slowing. (3) In contrast to DS, the clinical utility of SCN1A testing for GEFS+ remains questionable. (4) The test is not recommended for children with phenotypes that are not clearly associated with SCN1A mutations such as those characterized by abnormal development or neurologic deficits apparent at birth or structural abnormalities of the brain. Interpreting test results: (1) Mutational testing of SCN1A involves both conventional DNA sequencing of the coding regions and analyses to detect genomic rearrangements within the relevant chromosomal region: 2q24. Interpretation of the test results must always be done in the context of the electroclinical syndrome and often requires the assistance of a medical geneticist, since many genomic variations are possible and it is essential to differentiate benign polymorphisms from pathogenic mutations. (2) Missense variants may have no apparent effect on the phenotype (benign polymorphisms) or may represent mutations underlying DS, MPSI, GEFS+, and related syndromes and can provide a challenge in interpretation. (3) Conventional methods do not detect variations in introns or promoter or regulatory regions; therefore, a negative test does not exclude a pathogenic role of SCN1A in a specific phenotype. (4) It is important to note that a negative test does not rule out the clinical diagnosis of DS or other conditions because genes other than SCN1A may be involved. Obtaining written informed consent and genetic counseling should be considered prior to molecular testing, depending on the clinical situation and local regulations.     

A novel mutation of α-galactosidase A gene causes Fabry disease mimicking primary erythromelalgia in a Chinese family

Purpose: Fabry disease is an X-linked genetic disorder caused by the mutations of α-galactosidase A (GLA, MIM 300644) gene presenting with various clinical symptoms including small-fiber peripheral neuropathy and limb burning pain. Here, we reported a Chinese pedigree with the initial diagnosis of primary erythromelalgia in an autosomal dominant (AD)-inherited pattern. Methods: Mutation analysis of SCN9A and GLA genes by direct sequencing and functional analysis of a novel mutation of GLA in cells were performed. Results: Our data did not show any pathological mutations in SCN9A gene; however, a novel missense mutation c.139T>C (p.W47R) of GLA was identified in a male proband as well as two female carriers in this family. Enzyme assay of α-galactosidase A activity showed deficient enzyme activity in male patients and female carriers, further confirming the diagnosis of Fabry disease. Finally, a functional analysis indicated that the replacement of the 47th amino acid tryptophan (W47) with arginine (W47R) or glycine (W47G) led to reduced activity of α-galactosidase A in 293T cells. Therefore, these findings demonstrated that the novel mutation p.W47R of GLA is the cause of Fabry disease. Conclusions: Because Fabry disease and primary erythromelalgia share similar symptoms, it is a good strategy for clinical physicians to perform genetic mutation screenings on both SCN9A and GLA genes in those patients with limb burning pain but without a clear inheritant pattern.     

An atypical case of SCN9A mutation presenting with global motor delay and a severe pain disorder

Introduction: Erythromelalgia due to heterozygous gain‐of‐function SCN9A mutations usually presents as a pure sensory–autonomic disorder characterized by recurrent episodes of burning pain and redness of the extremities. Methods: We describe a patient with an unusual phenotypic presentation of gross motor delay, childhood‐onset erythromelalgia, extreme visceral pain episodes, hypesthesia, and self‐mutilation. The investigation of the patient's motor delay included various biochemical analyses, a comparative genomic hybridization array (CGH), electromyogram (EMG), and muscle biopsy. Once erythromelalgia was suspected clinically, the SCN9A gene was sequenced. Results: The EMG, CGH, and biochemical tests were negative. The biopsy showed an axonal neuropathy and neurogenic atrophy. Sequencing of SCN9A revealed a heterozygous missense mutation in exon 7; p.I234T. Conclusions: This is a case of global motor delay and erythromelalgia associated with SCN9A. The motor delay may be attributed to the extreme pain episodes or to a developmental perturbation of proprioceptive inputs. Muscle Nerve 49 : 134–138, 2014