Huppke P, Wegener E, Gilley J, Angeletti C, Kurth I , et al.
Experimental neurology •
We identified a homozygous missense mutation in the gene encoding NAD synthesizing enzyme NMNAT2 in two siblings with childhood onset polyneuropathy with erythromelalgia. No additional homozygotes for this rare allele, which leads to amino acid substitution T94M, were present among the unaffected relatives tested or in the 60,000 exomes of the ExAC database. For axons to survive, axonal NMNAT2 activity has to be maintained above a threshold level but the T94M mutation confers a partial loss of function both in the ability of NMNAT2 to support axon survival and in its enzymatic properties. Electrophysiological tests and histological analysis of sural nerve biopsies in the patients were consistent with loss of distal sensory and motor axons. Thus, it is likely that NMNAT2 mutation causes this pain and axon loss phenotype making this the first disorder associated with mutation of a key regulator of Wallerian-like axon degeneration in humans. This supports indications from numerous animal studies that the Wallerian degeneration pathway is important in human disease and raises important questions about which other human phenotypes could be linked to this gene.
Cheng X, Dib-Hajj SD, Tyrrell L, Te Morsche RH, Drenth JP , et al.
Brain : a journal of neurology •
Gain-of-function missense mutations of voltage-gated sodium channel Na(V)1.7 have been linked to the painful disorder inherited erythromelalgia. These mutations hyperpolarize activation, slow deactivation and enhance currents evoked by slow ramp stimuli (ramp currents). A correlation has recently been suggested between the age of onset of inherited erythromelalgia and the extent of hyperpolarizing shifts in mutant Na(V)1.7 channel activation; mutations causing large activation shifts have been linked to early age of onset inherited erythromelalgia, while mutations causing small activation shifts have been linked to age of onset within the second decade of life. Here, we report a family with inherited erythromelalgia with an in-frame deletion of a single residue--leucine 955 (Del-L955) in DII/S6. The proband did not show symptoms until the age of 15 years, and her affected mother only experienced mild symptoms during adolescence, which disappeared at the age of 38 years. Del-L955 shows no effect on Na(V)1.7 current density and fast inactivation, but causes an approximately -24 mV shift in activation, together with increases in amplitude of persistent currents and ramp currents. The mutation also produces an approximately -40 mV shift in slow inactivation, which reduces channel availability. Comparison of the effects of the Del-L955 mutation on dorsal root ganglion neuron hyperexcitability with those produced by another inherited erythromelalgia mutation (L858F) that does not enhance slow inactivation suggests that a delayed age of onset and milder symptoms in association with a large shift of channel activation, enhanced persistent and enhanced ramp currents may be related to the approximately -40 mV shift in slow inactivation for Del-L955, the largest shift thus far demonstrated in mutant Na(V)1.7 channels. Our results suggest that despite the pivotal role of activation shift in inherited erythromelalgia development, slow inactivation may regulate clinical phenotype by altering channel availability.
Choi JS, Cheng X, Foster E, Leffler A, Tyrrell L , et al.
Brain : a journal of neurology •
The Na(v)1.7 sodium channel is preferentially expressed in nocioceptive dorsal root ganglion and sympathetic ganglion neurons. Gain-of-function mutations in Na(v)1.7 produce the nocioceptor hyperexcitability underlying inherited erythromelalgia, characterized in most kindreds by early-age onset of severe pain. Here we describe a mutation (Na(v)1.7-G616R) in a pedigree with adult-onset of pain in some family members. The mutation shifts the voltage-dependence of channel fast-inactivation in a depolarizing direction in the adult-long, but not in the neonatal-short splicing isoform of Na(v)1.7 in dorsal root ganglion neurons. Altered inactivation does not depend on the age of the dorsal root ganglion neurons in which the mutant is expressed. Expression of the mutant adult-long, but not the mutant neonatal-short, isoform of Na(v)1.7 renders dorsal root ganglion neurons hyperexcitable, reducing the current threshold for generation of action potentials, increasing spontaneous activity and increasing the frequency of firing in response to graded suprathreshold stimuli. This study shows that a change in relative expression of splice isoforms can contribute to time-dependent manifestation of the functional phenotype of a sodium channelopathy.
To elucidate the rate of missense mutations in the SCN9A gene (which encodes sodium channel Na(v)1.7) (OMIM 603415) among patients with primary erythermalgia and to examine the possibility that other sodium channels can cause the disease. Case series. Department of Medicine, Radboud University Nijmegen, the Netherlands. Six patients with sporadic and 9 with unique familial primary erythermalgia. Interventions Questionnaire to determine clinical profile and sequencing of all coding exons from SCN9A and those of SCN10A (OMIM 604427) and SCN11A (OMIM 604385) in 2 selected cases with a clear family history of the disease. Detection of SCN9A mutation. We identified 1 patient with an SCN9A mutation. This mutation (I848T) has been associated with primary erythermalgia. Sequencing of 2 other candidate genes did not show mutations in 2 patients with familial primary erythermalgia. The Na(v)1.7 voltage-gated sodium channels are related to syndromes of altered nociception. We detected a low SCN9A mutation rate in patients with primary erythermalgia, suggesting that pain syndromes in the skin may have a polygenic basis.
Hereditary erythermalgia is a painful and debilitating genetic disorder associated with mutations in voltage-gated sodium channel Nav1.7. We have previously reported a Canadian family segregating erythermalgia consistently with a dominant genetic etiology. Molecular analysis of the proband from the family detected two different missense mutations in Nav1.7. In the present study we have performed a long-term follow-up clinical study of disease progression in three affected family members. A more extensive molecular study has also been completed, analyzing the segregation of the two missense variants in the family. The two variants (P610T, L858F) segregate independently with respect to clinical presentation. Detailed genotype/phenotype correlation suggests that one of the two variants (L858F) is causal for erythermalgia. The second variant (P610T) may modify the phenotype in the proband. This is the second reported study of potential compound heterozygosity for coding polymorphisms in Nav1.7, the first being in a patient with paroxysmal extreme pain disorder.
The voltage-gated sodium-channel type IX alpha subunit, known as Na(v)1.7 and encoded by the gene SCN9A, is located in peripheral neurons and plays an important role in action potential production in these cells. Recent genetic studies have identified Na(v)1.7 dysfunction in three different human pain disorders. Gain-of-function missense mutations in Na(v)1.7 have been shown to cause primary erythermalgia and paroxysmal extreme pain disorder, while nonsense mutations in Na(v)1.7 result in loss of Na(v)1.7 function and a condition known as channelopathy-associated insensitivity to pain, a rare disorder in which affected individuals are unable to feel physical pain. This review highlights these recent developments and discusses the critical role of Na(v)1.7 in pain sensation in humans.
Primary erythermalgia is a rare autosomal dominant inherited disorder characterized by recurrent attacks of red, warm and painful burning extremities. The gene involved in primary erythermalgia, SCN9A, encodes for a voltage dependent sodium channel alpha subunit (NaV1.7). NaV1.7 is located in dorsal root ganglions and in nociceptive peripheral neurons. It has been hypothesized that mutations lead to a gain of function and hyperexcitability of peripheral sensory neurons contributing to symptoms in primary erythermalgia.
Drenth JP, te Morsche RH, Guillet G, Taieb A, Kirby RL , et al.
The Journal of investigative dermatology •
Primary erythermalgia is a rare disorder characterized by recurrent attacks of red, warm and painful hands, and/or feet. We previously localized the gene for primary erythermalgia to a 7.94 cM region on chromosome 2q. Recently, Yang et al identified two missense mutations of the sodium channel alpha subunit SCN9A in patients with erythermalgia. The presence of voltage-gated sodium channels in sensory neurons is thought to play a crucial role in several chronic painful neuropathies. We examined four different families and two sporadic cases and detected missense sequence variants in SCN9A to be present in primary erythermalgia patients. A total of five of six mutations were located in highly conserved regions. One family with autosomal dominantly inherited erythermalgia was double heterozygous for two separate SCN9A mutations. These data establish primary erythermalgia as a neuropathic disorder and offers hope for treatment of this incapacitating painful disorder.
Primary erythermalgia is a rare disorder characterized by recurrent attacks of red, warm, and painful hands and/or feet. The symptoms are generally refractory to treatment and persist throughout life. Five kindreds with multiple cases of primary erythermalgia were identified, and the largest was subjected to a genomewide search. We detected strong evidence for linkage of the primary erythermalgia locus to markers from chromosome 2q. The highest LOD score (Z) was obtained with D2S2330 (Z(max) = 6.51). Analysis of recombination events identified D2S2370 and D2S1776 as flanking markers, on chromosome 2q31-32. This defines a critical interval of 7.94 cM that harbors the primary erythermalgia gene. Affected members within the additional families also shared a common haplotype on chromosome 2q31-32, supporting our linkage results. Identification of the primary erythermalgia gene will allow a better clinical classification of this pleomorphic group of disorders.
