Editorial Ion channels and neurological disease: DNA based ... - NCBI

J Neurol Neurosurg Psychiatry 1998;65:427–431

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Editorial

Ion channels and neurological disease: DNA based diagnosis is now possible, and ion channels may be important in common paroxysmal disorders Ion channels are large transmembrane proteins which are essential for the normal function of all eukaryotic cells.1 They are especially important in excitable cells because they determine the membrane potential, both at rest and during firing, and also play a critical part in neurotransmitter release. Ion channels may be broadly classified into voltage gated and ligand gated, although many voltage gated channels are also aVected by intracellular messengers.1 It is well recognised that autoimmune attack of the nicotinic acetylcholine receptor underlies acquired myasthenia gravis. Research over the past few years has, however, established that genetic defects in both ligand and voltage gated ion channels also cause some inherited neurological disorders.2–5 Collectively, these immunological and genetic conditions have become known as the Table 1

neurological channelopathies. The genetic channelopathies are listed in tables 1 and 2. The genetic advances have increased our understanding of the molecular pathogenesis of several relatively rare muscle and CNS diseases. The immediate benefits of this are an improved classification of these disorders and the availability of DNA based diagnosis. However, an important principle has also emerged: permanent ion channel dysfunction can cause a paroxysmal neurological disturbance. By extrapolation, ion channel defects are strong candidates for other paroxysmal disorders. Some of the recently established genetic channelopathies represent rare forms of more common disorders such as migraine and epilepsy. This has led to the suggestion that the genetic susceptibility known to exist in these common disorders

Genetic voltage gated channelopathies

Ion channel Skeletal muscle disorders: Skeletal muscle sodium channel

Skeletal muscle DHP sensitive calcium channel Skeletal muscle ryanodine calcium channel Skeletal muscle chloride channel CNS disorders: Brain and nerve potassium channel Brain (P/Q-type) calcium channel

Disorder

Inheritance

Gene

Chromosome

HyperPP PMC PAM ?NormoPP HypoPP MH MH Central core disease Myotonia congenita Thomsen’s disease Becker’s myotonia

Dominant Dominant Dominant Dominant Dominant Dominant Dominant Dominant

SCN4A

17q23-2 9 10 11 12 13

CACLN1A3

1q31-32 14 15 27

RYR1

19q13.123 24

Dominant Recessive

CLCN1

7q35 20 21

Episodic ataxia type I with myokymia Episodic ataxia type II FHM SCA6

Dominant Dominant

KCNA1 CACNL1A4

12p45 19p1328

Standard gene nomenclature is used for abbreviations. HyperPP=Hyperkalaemic periodic paralysis; HypoPP=hypokalaemic periodic paralysis; NormoPP=normokalaemic periodic paralysis; PMC=paramyotonia congenita; PAM=potassium aggravated myotonia; MH=malignant hyperthermia; FHM=familial hemiplegic migraine; SCA6=spinocerebellar ataxia type 6.

Table 2

Genetic ligand gated channelopathies

Ion channel

Disorder

Inheritance

Gene

Chromosome

Neuromuscular disorder: Nicotinic acetylcholine receptor

Congenital myasthenia

Dominant and recessive

CHRNA CHRNG CHRND CHRNB CHRNE

2q7

GLRA-1 CHRNA4

5q6 20q13.2-13.356 57

CNS disorder: Glycine receptor Neuronal nicotinic receptor

Hyperekplexia ADNFLE

Dominant Dominant

Standard gene nomenclature is used for abbreviations. ADNFLE=Autosomal dominant nocturnal frontal lobe epilepsy.

17p7

Hanna, Wood, Kullmann

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may be mediated through variations in ion channel function. In this article we review some of the many recently established genetic neurological channelopathies in which DNA based diagnosis is becoming available. We do not discuss the congenital myasthenic syndromes or hyperekplexia.6 7 Also, we speculate on possible future channelopathies and discuss some of the evidence that ion channel dysfunction may be important in common neurological disorders.

DNA based diagnosis of periodic paralyses is now obviating the need for time consuming and potentially hazardous provocative testing.10 In addition to avoiding precipitating factors, drugs which can be eVective in both types of periodic paralysis include acetazolamide and thiazide diuretic drugs.10 A recent placebo controlled trial suggests that dichlorphenamide (a more potent carbonic anhydrase inhibitor than acetazolamide) is specifically eVective in HypoPP.17 Salbutamol can be useful in HyperPP.16 Some patients are, however, resistant to all treatments. MYOTONIA CONGENITA AND THE POTASSIUM AGGRAVATED

Skeletal muscle channelopathies Conventionally, the periodic paralyses would be classified separately from the myotonias. An important result of the genetic progress in this field has been to show that different mutations of the same channel can cause diseases that blur this distinction. THE PERIODIC PARALYSES AND PARAMYOTONIA CONGENITA

The periodic paralyses are disorders of muscle fibre membrane excitability, which are classified on the basis of the serum potassium at or close to the onset of the attack into hyperkalaemic, normokalaemic, or hypokalaemic. During an attack, often precipitated by exercise followed by rest, the muscle fibre membrane enters a partially depolarised inexcitable state.8–10 Before molecular genetic advances, electrophysiological work had demonstrated that muscle fibres from patients with hyperkalaemic periodic paralysis (HyperPP) show defective inactivation of sodium channels.10 When the subunit of the voltage gated sodium channel gene in skeletal muscle was cloned, it was confirmed that mutations in this gene (SCN4A) are the cause of most cases of HyperPP.11–13 DiVerent mutations in the same channel are also associated with paramyotonia congenita (either alone or in combination with HyperPP), and with a group of disorders which have become known as the potassium aggravated myotonias.10 (Patients with paramyotonia, as opposed to myotonia, experience a worsening of stiVness with exercise.) Expression studies have confirmed that all sodium channel mutations investigated result in impaired fast inactivation of the channel. This is an abnormal gain of function, which is consistent with the dominant mode of inheritance seen in these disorders. HyperPP mutations give rise to a small residual current that fails to inactivate at positive membrane potentials8 Impaired membrane repolarisation causes extracellular potassium accumulation, especially in the T tubules, which further depolarises the muscle fibre membrane. This instability may explain both the episodic nature of HyperPP and the associated hyperkalaemia. Mutations seen in paramyotonia congenita alter the rate and voltage dependence of inactivation, resulting in the characteristic repetitive discharges. Available evidence suggests that normokalaemic periodic paralysis is also a sodium channel disorder.10 Although muscle fibre membrane inexcitability also characterises attacks of hypokalaemic periodic paralysis (HypoPP), there was no consensus on a candidate channel before genetic studies.10 A genomewide linkage search led to the discovery that three mutations in a muscle voltage gated calcium channel (CACNL1A3) are responsible for most cases of HypoPP.14 15 This is perhaps surprising, as this calcium channel is not known to have a role in determining muscle fibre membrane excitability. Expression studies have shown that the three known CACNL1A3 mutations alter channel function, but the pathogenesis of the attacks remains unclear.10 Both of the common forms of periodic paralysis may be associated with a disabling vacuolar myopathy which seems to be mutation specific.10 16

MYOTONIAS

Myotonia congenita is characterised by generalised symptomatic myotonia from a young age. This is generally milder in the rare dominant form (Thomsen’s disease) than in the much more common recessive form (Becker’s generalised myotonia).18 Electrophysiological experiments on skeletal muscle preparations from patients (and on the myotonic goat model of the disease) established that the resting chloride conductance of the muscle fibre membranes is reduced.10 19 As the chloride conductance plays a major part in determining the resting membrane potential, a decrease in this conductance lowers the threshold for depolarisation and therefore predisposes to myotonia. When the human skeletal muscle chloride channel CLCN1 was cloned, both forms of myotonia congenita were found to be due to diVerent mutations in this gene20 21 Expression studies have shown that both dominant and recessive mutations result in decreased chloride currents. By contrast with sodium and calcium channels, the functional chloride channel is a homodimer, possibly explaining why the disease can be either dominant or recessive. The recessive mutations result in loss of function. The dominant mutations, on the other hand, may result in haploid insufficiency (50% of the normal gene product is not enough for normal chloride conductance), or have a dominant negative eVect, in which mutant and wild-type subunits dimerise to result in abnormal or non-functional channels.10 The diagnosis is usually straightforward on clinical grounds. Although DNA based diagnosis is available, it is very time consuming as over 30 point mutations have been described.10 Treatment with antimyotonic drugs is often needed, of which mexilitene is the drug of choice. Cloning of the muscle sodium channel has also led to a better understanding of another previously poorly defined group of myotonic disorders. It is now clear that diseases in this group, which has been named “atypical” myotonia congenita, and which includes acetazolamide responsive myotonia, are also due to mutations in the sodium channel SCN4A. A prominent feature of the myotonia in this group is its marked exacerbation after potassium ingestion, which is not a feature of the chloride channel disorders. They are now known as the “potassium aggravated myotonias”.9 MALIGNANT HYPERTHERMIA AND CENTRAL CORE DISEASE

Malignant hyperthermia is a rare but serious disorder, generally coming to light when otherwise healthy people undergo general anaesthesia.22 Exposure to triggering agents, including halogenated volatile anaesthetics and depolarising muscle relaxants, results in hyperthermia, muscle rigidity, and rhabdomyolysis. Without rapid intervention with supportive measures and dantrolene this is often fatal.22 Malignant hyperthermia is now known to be a disorder of regulation of skeletal muscle calcium. The triggering substances lead to an increased myoplasmic calcium concentration because of excessive release from the sarcoplasmic reticulum. Extrapolation from genetic studies on the porcine model of malignant hyperthermia

Neurological channelopathies

(porcine stress syndrome)23 led to the discovery that mutations in the human ryanodine receptor gene cause malignant hyperthermia in some families.23 24 The ryanodine receptor is a voltage gated ion channel located in the membrane of the sarcoplasmic reticulum, and which releases calcium ions, thereby contributing to excitationcontraction coupling. Depolarisation normally leads to brief activation of the ryanodine receptor via an interaction with the skeletal muscle calcium channel (CACLN1A3). Ryanodine receptor gene mutation analysis can now be used to identify those at risk of malignant hyperthermia in families with a known mutation in this gene. This should reduce the need for the invasive in vitro contracture test.25 26 In some patients susceptible to malignant hyperthermia central cores are seen in muscle biopsies, and conversely patients with central core disease, a congenital myopathy, are at risk for developing malignant hyperthermia. These findings have recently been explained by the discovery that central core disease and malignant hyperthermia may both be caused by mutations in the ryanodine receptor gene.24 Malignant hyperthermia is, however, genetically heterogeneous. Interestingly, a family has been identified, in which a point mutation in the calcium channel CACLN1A3 segregates with the disease.27 This is the channel that triggers the ryanodine receptor to open, implying that defective interactions between the two proteins can cause the malignant hyperthermia phenotype. HypoPP and some cases of malignant hyperthermia may thus be regarded as allelic disorders. CNS channelopathies CALCIUM CHANNELOPATHIES: EPISODIC ATAXIA TYPE 2, FAMILIAL HEMIPLEGIC MIGRAINE, AND SPINOCEREBELLAR ATAXIA TYPE 6

Perhaps the most remarkable recent discovery in the field of channelopathies is that three diVerent autosomal dominant disorders are associated with mutations in the same gene, CACNL1A4, coding for the á1A subunit of the brain P/Q-type voltage gated calcium channel.28 29 Episodic ataxia type 2 (EA2), familial hemiplegic migraine in some families, and (SCA6) are allelic disorders caused by diVerent mutations in this gene.28 29 The channel is widely expressed in the brain, with particularly high levels in cerebellar Purkinje cells. Spinocerebellar ataxia type 6 is the commonest genetic adult onset pure dominant cerebellar ataxia. Onset is usually in the fifth decade and the syndrome progresses slowly, with some patients becoming wheelchair bound after 20 years. The pathological features include marked cerebellar atrophy with loss of Purkinje and granule cells as well as cells in the dentate nucleus and inferior olive. It is another example of a genetic disease in which the mutation is an abnormally expanded trinucleotide repeat sequence (CAG).30 The CAG repeat is translated into a polyglutamine tract located in the C terminal region of the calcium channel á1A subunit. This repeat is much smaller and seems to be more stable than the other disease causing CAG repeats described to date.29 It is not known if the disease mechanism relates to altered calcium channel function, or involves abnormal protein deposition as has been suggested in other CAG repeat diseases.31 Episodic ataxia type 2 is characterised by episodes of midline cerebellar disturbance with nystagmus, vertigo, ataxia, and dysarthria. Headache with nausea, leading to a diagnosis of basilar migraine, occurs in 50% of families. Attacks may last for hours to days and are typically precipitated by stress, exercise, and fatigue. Between attacks there may be progressive cerebellar dysfunction with nystagmus, and imaging often shows cerebellar

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atrophy.32 This disorder is usually very responsive to acetazolamide, although the precise therapeutic mechanism remains uncertain. An MRS study has shown a disturbance of cerebellar pH in patients with EA2 oV treatment.33 Initially, splice site and frame shift mutations were described in the CACLN1A4 gene in patients with EA2, implying that truncation of the protein may be important in pathogenesis.28 However, recently the SCA6 CAG repeat has also been described in patients with EA2.34 One family has, moreover, been reported in which a missense mutation in CACNL1A4 is associated with a severe progressive cerebellar ataxia in one member, whereas other members had episodic ataxia and vertigo, more suggestive of EA2.35 The genetic distinction between SCA6 and EA2 is thus far from clearcut. In families with familial hemiplegic migraine patients experience headache preceded by an aura, which includes a hemiparesis lasting hours to days. The onset is usually in childhood, and interictal nystagmus, ataxia, and dysarthria may occur.36 Four missense mutations in CACNL1A4 have been identified.28 Up to 50% of families with familial hemiplegic migraine linked to CACNL1A4 exhibit mild cerebellar ataxia and have cerebellar atrophy on imaging. A recent genotype-phenotype correlation study indicates that the presence of cerebellar atrophy may be mutation specific.37 The same study also identified a CACLN1A4 mutation in a case of “non-hemiplegic” migraine indicating that such mutations may associate with commoner forms of migraine.37 Interestingly, a missense mutation in the orthologous mouse gene produces the tottering (tg) phenotype which exhibits absence seizures, motor seizures and ataxia.38 The frame shift and splice site mutations in EA2 are similar to the gene defects in another mouse model, the leaner mouse (tgla) which is allelic to the tg mouse but more severely aVected, exhibiting absence seizures, severe ataxia and premature death.38 Abnormalities on EEG are reported in patients with familial hemiplegic migraine and EA2 which, in the light of the findings in the mouse models, raises the question whether CACLN1A4 is relevant to epilepsy in humans.39 40 Recently families with familial hemiplegic migraine not linked to CACNL1A4 have been shown to be linked to 1q31 at or near a diVerent (R type) voltage gated channel á1E subunit gene.41 42 The molecular pathogenesis of disease associated with frame shift and splice site mutations of CACNL1A4, and the CAG repeat, has yet to be studied. The four known missense mutations associated with familial hemiplegic migraine have, however, been expressed. Three of the mutations were associated with altered inactivation gating, suggesting that neuronal instability plays a part in migraine attacks.43 EPISODIC ATAXIA TYPE 1

The most diverse group of human voltage and ligand gated ion channels are the potassium channels, reflecting their early evolutionary origin.44 Point mutations in the human potassium channel gene KCNA1 cause the dominant disorder episodic ataxia type I (EA1).45 This channel is expressed widely, but especially in the cerebellum and in peripheral nerve.46 Patients experience brief attacks of cerebellar ataxia lasting up to minutes, which are not usually accompanied by abnormal eye signs as in EA2. There is no interictal cerebellar dysfunction, and brain imaging is normal. Stress, emotion, or sudden movement may precipitate attacks. Interictally there are continuous spontaneous repetitive discharges on EMG sometimes termed neuromyotonia, although this is not always clinically obvious.45 47 The therapeutic response in EA1 is less consistent than in EA2. Many families respond to carbamazepine, and others have a favourable response to acetazolamide, although

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some cases are resistant to both treatments.48 49 Several point mutations are now described, and expression studies indicate that they impair channel function both by reducing the amplitude of the potassium current and by altering its voltage dependent kinetics. These changes would be predicted to increase neuronal excitability, which is the basis of the neuromyotonia and presumably the attacks of ataxia.50 Homozygous deletion of the orthologous gene in the mouse has recently been described to cause severe epilepsy, raising the question whether KCNA1 mutations are involved in human epilepsy. In support of this, there is evidence for an overrepresentation of epilepsy in cases of EA1.51 52 Recently, mutations in two novel potassium channel genes have been shown to associate with benign familial neonatal convulsions, providing more direct evidence that potassium channel dysfunction may cause epilepsy in humans.53 54 AUTOSOMAL DOMINANT NOCTURNAL FRONTAL LOBE EPILEPSY

(ADNFLE) This dominant disorder is characterised by clusters of nocturnal frontal lobe seizures, each typically lasting less than 1 minute.55 They usually occur while falling asleep or just before waking. Most patients respond well to carbamazepine. Linkage to chromosome 20q13.2 was established in 1995, followed soon after by the discovery of a point mutation in the á4 subunit of the neuronal nicotinic acetylcholine receptor.56 A second mutation has recently been described.57 The neuronal acetylcholine receptor is a pentameric protein composed of varying combinations of subunits. It is mainly located presynaptically, and influences the release of other neurotransmitters.58 Expression studies of the two known mutations show a loss of channel function, which is thought to be the basis of the epilepsy in these cases.57 It remains to be seen whether other neuronal nicotinic receptor subunits are important in commoner forms of epilepsy. Conclusions It is now established that genetic defects of both ligand and voltage gated ion channels can cause diverse neurological disease. To date, these are all relatively rare disorders. The detailed clinical, genetic, and biophysical analysis of neurological channelopathies over the past few years allows common themes to be identified. From a genetic viewpoint it is clear that both dominant and recessive modes of inheritance occur, and in some instances diVerent mutations in the same ion channel gene may exhibit diVerent inheritance. The mutations in CACLN1A4 indicate that diVerent mutations in the same ion channel gene may result in quite diVerent phenotypes, and also suggest that the relation between genotype and phenotype is not always simple. Another interesting finding is that either genetic or immunological insults to the same or closely related ion channels may produce neurological disease. For example, potassium channel antibodies may produce neuromyotonia, which also occurs in association with mutations in the KCNA1 gene.45 47 Some congenital syndromes that mimick acquired myasthenia gravis are also caused by mutations of the peripheral nicotinic receptor.7 This raises the possibility that immunological counterparts may be found for other genetic channelopathies. Ion channel dysfunction is often susceptible to external factors such as stress and changes in pH, ion concentration, and temperature, and many respond to acetazolamide. The natural history of these disorders is variable. Mutations may produce paroxysmal disorders with normal interictal tissue function (for example, EA1), paroxysmal disorders with progressive tissue dysfunction (for example,

Hanna, Wood, Kullmann

EA2), or progressive tissue dysfunction alone, without clear episodic symptoms (for example, SCA6). It is likely that other neurological channelopathies will be identified. Strong CNS candidate diseases include paroxysmal movement disorders such as paroxysmal dystonic choreoathetosis and familial geniospasm.59 60 Of the skeletal muscle diseases, the myotonic Schwartz-Jampel syndrome is another candidate.61 It is perhaps surprising that genetic channelopathies aVecting peripheral nerve have not been described (other than EA1, which includes neuromyotonia in the phenotype).62 Most intriguing is the possibility that ion channels may be important in common neurological diseases such as migraine and epilepsy. The clinical overlap between some of the calcium channel phenotypes and migraine is striking. One study supports the possibility that CACLN1A4 may be important in commoner forms of migraine, although this requires confirmation.63 The mouse models mentioned above also make CACLN1A4 a good candidate for the genetic susceptibility known to exist in absence epilepsy.38 Ligand gated channels are also strong candidates for commoner forms of primary epilepsy. These include postsynaptic receptors mediating fast excitatory or inhibitory transmission, as well as presynaptic receptors such as nicotinic and kainate receptors, which modulate the release of GABA.64 65 An allelic association has indeed been reported between a kainate receptor subunit and juvenile absence epilepsy.66 It remains to be seen if ion channel dysfunction is important in these common disorders. If it is, a new chapter in pharmacogenetic research with the aim of tailoring therapies to specific genotypes and modes of ion channel dysfunction is likely to follow. Further information about neurological channelopathy DNA based diagnosis is available from the DNA-laboratory, National Hospital, Queen Square, London, UK. Financial support from the Brain Research Trust and the Medical Research Council is gratefully acknowledged.

MICHAEL G HANNA NICHOLAS W WOOD DIMITRI M KULLMANN Department of Clinical Neurology, Institute of Neurology, Queen Square, Lonon, UK Correspondence to: Dr M G Hanna, Muscle and Neurogenetics Sections, Institute of Neurology, Queen Square, London WC1N 3BG, UK. Telephone 0171 837 3611, extension 4231; email [email protected] 1 Hille B. Ion channels of excitable membranes. 2nd edition. Sunderland, MA: Sinauer, 1992. 2 Ackerman MJ, Clapham DE. Ion channels-basic science and clinical disease. N Engl J Med1997;336:1575–86 . 3 Bulman DE. Phenotypic variation and newcomers in ion channel disorders. Hum Mol Genet 1997;6:1679–85. 4 HoVman EP, Lehamnn-Horn F, Rudel R. Overexcited or inactive: ion channels in muscle disease. Cell 1995;80:681–6. 5 Greenberg DA. Calcium channels in neurological disease. Ann Neurol 1997; 42:275–82. 6 Shiang R, Ryan SG, Zhu Y, et al. Mutations in the á1A subunit of the inhibitory glycine receptor cause the dominant neurological disorder hyperekplexia. Nat Genet 1993;5:351–8. 7 Beeson D, Palace J, Vincent A. Congenital myasthenic syndromes. Curr Opin Neurol 1997;10:402–407. 8 Cannon SC. Sodium channel defects in myotonia and periodic paralysis. Ann Rev Neurosci 1996;19:141–64. 9 Rudel R, Lehmann-Horn F. Paramyotonia, potassium aggravated myotonias and periodic paralyses. Neuromusc Disord 1997;7:127–32. 10 Lehmann-Horn F, Rudel R. Molecular pathophysiology of voltage-gated ion channels. Rev Physiol Biochem Pharmacol 1996;128:195–268. 11 George AL Jr, Ledbetter DH, Kallen RG, et al. Assignment of a human skeletal muscle sodium channel a subunit gene (SCN4A) to 17q23.1–25.3 Genomics 1991;9:555–6. 12 Rojas CV, Wang J, Schwartz LS, et al. A met-val mutation in the skeletal muscle Na channel subunit in hyperkalaemic periodic paralysis. Nature 1991;354:387–9. 13 Ptacek LJ, George AL, Griggs RC, et al. Identification of a mutation in the gene causing hyperkalaemic periodic paralysis. Cell 1991;67:1021–7. 14 Fontaine B, Vale-SantosJM, Jurkatt-Rott K, et al. Mapping of hypokalaemic periodic paralysis (HypoPP) to chromosome 1q31-q32 by a genome-wide search in three European families. Nat Genet 1994;6:267–72. 15 Ptacek LJ, Tawil R, Griggs RC, et al. Dihydropyridine receptor mutations cause hypokalaemic periodic paralysis. Cell 1994;77:863–8. 16 Griggs RC, Tawil R, Brown RH, et al. Dichlorphenamide is eVective in the treatment of hypokalaemic periodic paralysis. Ann Neurol 1997;42:428.

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17 Hanna MG, Stewart J, Schapira AHV et al. Salbutamol treatment in a patient with hyperkalaemic periodic paralysis due to a mutation in the skeletal muscle sodium channel gene (SCN4A). J Neurol Neurosurg Psychiatry 1998 (in press). 18 Hudson AJ, Ebers GC, Bulman DE. The skeletal muscle sodium and chloride channel diseases. Brain 1995;118:547–63. 19 Bryant SH. Cable properties of external intercostal muscle fibres from myotonic and nonmyotonic goats. J Physiol (Lond) 1969;204:539–50. 20 Koch MC, Steinmeyer K, Lorenz C, et al. The skeletal muscle chloride channel in dominant and recessive human myotonia. Science 1992;257: 797–800. 21 George AL, Crackower MA, Abdalla JA, et al. Molecular basis of Thomsen’s disease (autosomal dominant myotonia congenita). Nat Genet 1993;3:305– 10. 22 Hogan K. To fire the train: a second malignant hyperthermia gene. Am J Hum Genet 1997;60:11303–08. 23 Fujii J, Otsu K, Zorzato F, et al. Identification of a mutation in porcine ryanodine receptor associate with malignant hyperthermia. Science 1991;253:448–51. 24 Quane KA, Healy Keating KE, et al. Mutations in the ryanodine receptor gene in central core disease and malignant hyperthermia. Nat Genet 1993; 5:51–5. 25 Hopkins PM, Ellis FR, Halsall PJ, et al. An analysis of the predictive probability of the in vitro contracture test for determining susceptibility to malignant hyperthermia. Anesth Analg 1997;84:648–56. 26 Ellis FR, Harriman DGF. A new screening test for susceptibility to malignant hyperpyrexia. Br J Anaesth 1973;45:638. 27 Monnier N, Procaccio V, Stieglitz P, et al. Malignant-hyperthermia susceptibility is associated with a mutation of the á1-subunit of the human dihydropyridine-sensitive L-type voltage-dependent calcium-channel receptor in skeletal muscle. Am J Hum Genet 1997; 60:1316–25. 28 OphoV RA, Terwindt GM, Verouwe MN, et al. Familial hemiplegic migraine and episodic ataxia type-2 are caused by mutations in the calcium channel gene CACNL1A4. Cell 1996;87:543–52. 29 Zhuchenko O, Bailey J, Bonnen P et al. Autosomal dominant cerebellar ataxia (SCA6) associated with small polyglutamine expansions in the 1A-voltage-dependent calcium channel. Nat Genet 1997;15:62–8. 30 Zoghbi HY. The expanding world of ataxins. Nat Genet 14 237–40. 31 Skinner PJ, Koshy BT, Cummings CJ, et al. Ataxin-I with an expanded glutamine tract alters nuclear-matrix associated structures. Nature 1997;389:971–4. 32 Baloh WB, Yue Q, Furman JM, et al. Familial episodic ataxia: clinical heterogeneity in four families linked to chromosome 19p. Ann Neurol 1997; 41:8–16. 33 Bain PG, O’Brian MD, Keevil SF, et al. Familial periodic cerebellar ataxia: a problem of cerebellar intracellular pH homeostasis. Ann Neurol 1992;31: 147–54. 34 Jodice C, Mantuano E, Veneziano L, et al. Episodic ataxia type 2 (EA2) and spinocerebellar ataxia type6 (SCA6) due to CAG repeat expansion in the CACNA1A gene on chromosome 19p. Hum Mol Genet 1997;6:1973–8. 35 Yue Q, Jen JC, Nelson SF, et al. Progressive ataxia due to a missense mutation in a calcium channel gene. Am J Hum Genet 1997;61:1078–87. 36 Elliot MA, Peroutka SJ, Welch S, et al. Familial hemiplegic migraine, nystagmus and cerebellar atrophy. Ann Neurol 1996;39:100–6. 37 Terwindt GM, OphoV RA, Haan J, et al. Variable clinical expression of mutations in the P/Q-type calcium channel gene in familial hemiplegic migraine. Dutch Migraine Genetics Research Group. Neurology 1998;50: 1105–10 38 Fletcher CF, Lutz Y, O’Sullivan CM, et al. Absence epilepsy in tottering mutant mice is associated with calcium channel defects. Cell 1996;87:607– 17. 39 Bouchard JP, Roberge C, Van Gelder NM, et al. Familial periodic ataxia responsive to acetazolamide. Can J Neurol Sci 1984;11:550–3. 40 Neufeld NY, Nisipeanu P, Chistik V, et al. The electroencephalogram in acetazolamide responsive periodic ataxia. Mov Disord 1996;11:283–8. 41 Gardner K, Barmada MM, Ptacek LJ, et al. A new locus for hemiplegic migraine maps to chromosome 1q31. Neurology 1997;49:1231–8.

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42 Ducros A, Joutel A, Vahedi K et al. Mapping of a second locus for familial hemiplegic migraine to 1q21-q23 and evidence of further heterogeneity. Ann Neurol 1997;42:885–9. 43 Kraus RL, Sinnegger MJ, Glossmann H, et al. Familial hemiplegic migraine mutations change á1A Ca2+ channel kinetics. J Biol Chem 1998;273:5586– 90. 44 Jan LY, Jan NY. Cloned potassium channels from eukaryotes and prokaryotes. Ann Rev Neurosci 1997;20:91–123. 45 Browne DL, Gancher ST, Nutt JG, et al. Episodic ataxia-myokymia syndrome is associated with a point mutation in the human potassium channel gene, KCNA1. Nat Genet 1994;8:136–40. 46 Beckh S, Pongs O. Members of the RCK potassium channel family are differentially expressed in the rat nervous system. EMBO J 1990;9:777–82. 47 Hart IK, Waters C, Vincent A, et al. Autoantibodies detected to expressed K+ channels are implicated in neuromyotonia. Ann Neurol 1997;41:238– 46. 48 Brunt ER, Van Weerden TW. Familial paroxysmal kinesigenic ataxia and continuous myokymia. Brain 1190;113:1361–82. 49 Hanna MG, Eunson L, Panayiotopoulos CP, et al. The first stop codon mutation in the human voltage gated potassium channel Kv1.1 associates with drug-resistant episodic ataxia type I [abstract]. J Neurol 1998 (in press). 50 Adelman JP, Bond CT, Pessia M, et al. Episodic ataxia results from voltagedependent potassium channels with altered functions. Neuron 1995;15: 1449–5. 51 Smart SL, Lopanstev V, Zhang SY, et al. Deletion of the Kv1.1 potassium channel causes epilepsy in mice. Neuron 1998;20:809–19. 52 Hanna MG, Zuberi SM, Eunson L, et al. A new mutation in the human voltage gated potassium channel (Kv1.1) associates with episodic ataxia type I and epilepsy [abstract]. J Neurol 1998(in press). 53 Biervert C, Schroeder BC, Kubisch C, et al. A potassium channel mutation in neonatal human epilepsy. Science 1998;279:403–6 54 Singh NA, Charlier C, StauVer D, et al. A novel potassium channel gene, KCNQ2, is mutated in an inherited epilepsy of newborns. Nat Genet 1998; 18:25–9. 55 ScheVer IE, Bhatia KP, Lopes-Cendes I, et al. Autosomal dominant frontal epilepsy misdiagnosed as sleep disorder. Lancet 1994;343:515–7. 56 Steinlein OK, Mulley JC, Propping P, et al. A missense mutation in the neuronal nicotinic acetylcholine receptor á4 subunit is associated with autosomal dominant nocturnal frontal lobe epilepsy. Nat Genet 1995;11: 201–2. 57 Steinlein OK, Magnusson A, Stoodt, et al. An insertion mutation of the CHRNA4 gene in a family with dominant nocturnal frontal lobe epilepsy. Hum Mol Genet 1997;6:943–7. 58 Sargent PB. The diversity of neuronal nicotinic acetylcholine receptors. A Rev Neurosci 1993;16:403–43. 59 Jarman PR, Wood NW, Davis MT, et al. Hereditary geniospasm: linkage to chromosome 9q13-q21 and evidence for genetic heterogeneity. Am J Hum Genet 1997;61:928–33. 60 Fink JK, Rainer S, Wilkowski J, et al. Paroxysmal dystonic choreoathetosis: tight linkage to chromosome 2q. Am J Hum Genet 1996;59:140–5. 61 Fontaine B, Nicole S, Topaluglu H. Recessive Scwartz Jampel syndrome (SJS): confirmation of linkage to chromosome 1p, evidence for genetic homogeneity and reduction of the SJS locus to a 3cM interval. Hum Genet 1996;98:380–5. 62 Gutmann L, Gutmann L. Axonal channelopathies: an evolving concept in the pathogenesis of peripheral nerve disorders. Neurology 1996;47:18–21. 63 May A, OphoV RA, Terwindt GM, et al. Familial hemiplegic migraine locus on chromosome 19p13 is involved in common froms of migraine with and without aura. Hum Genet 1995;8:136–140. 64 Lena C, Changeux JP. Role of Ca2+ ions in nicotinic facilitation of GABA release in mouse thalamus. J Neurosci 1997;17:576–85. 65 Lerma J. Kainate reveals its targets. Neuron 1997;19:1155–8. 66 Sander T, Hildmann T, Kretz R, et al. Allelic association of juvenile absence epilepsy ith a GluR5 kainate receptor gene (GRIK1) polymorphism. Am J Med Genet 1997;74:416–21.