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Familial Hemiplegic Migraine (familial + hemiplegic_migraine)
Selected AbstractsFamilial Hemiplegic Migraine: Permanent Attack-Related Neurologic DeficitsHEADACHE, Issue 8 2007David Dodick MD Hemiplegic migraine (HM) is characterized by motor weakness and at least one other aura symptom or sign that is fully reversible within 24 hours. While prolonged neurological impairment lasting weeks has been observed, persistent attack-related neurological deficits have not been described. This case illustrates the potential for permanent neurological deficits to occur as a sequelae of HM in the absence of infarction, and highlights potentially important pathophysiological and treatment implications. [source] Novel mutations in the Na+, K+ -ATPase pump gene ATP1A2 associated with familial hemiplegic migraine and benign familial infantile convulsionsANNALS OF NEUROLOGY, Issue 3 2003Kaate R. J. Vanmolkot Msc Familial hemiplegic migraine (FHM) is a rare, severe, autosomal dominant subtype of migraine with aura. Up to 75% of FHM families have a mutation in the P/Q-type calcium channel Cav2.1 subunit CACNA1A gene on chromosome 19p13. Some CACNA1A mutations also may cause epilepsy. Here, we describe novel missense mutations in the ATP1A2 Na+,K+ -ATPase pump gene on chromosome 1q23 in two families with FHM. The M731T mutation was found in a family with pure FHM. The R689Q mutation was identified in a family in which FHM and benign familial infantile convulsions partially cosegregate. In this family, all available affected family members with FHM, benign familial infantile convulsions, or both, carry the ATP1A2 mutation. Like FHM linked to 19p13, FHM linked to 1q23 also involves dysfunction of ion transportation and epilepsy is part of its phenotypic spectrum. [source] Ataxic mutant mice with defects in Ca2+ channel ,1A subunit gene: morphological and functional abnormalities in cerebellar cortical neuronsCONGENITAL ANOMALIES, Issue 2 2000Kazuhiko Sawada ABSTRACT This review summarizes recent studies in the morphological and functional abnormalities of cerebella in three ataxic mutant mice, i.e. tottering mouse, leaner mouse, and rolling mouse Nagoya (RMN). These mutants carry mutations in the Ca2+ channel ,1A subunit gene, and become useful models for human neurological diseases such as episodic ataxia type-2, familial hemiplegic migraine, and spinocerebellar ataxia type-6. All three mutants exhibited altered morphology of the Purkinje cells, ectopic synaptic contacts between granule cell axons (parallel fibers) and Purkinje cell dendritic spines and abnormal expression of tyrosine hydroxylase in Purkinje cells. In leaner mice, Purkinje cell loss was observed in alternating sagittal compartments of the cerebellar cortex corresponding to the Zebrin II-negative zones. The mutated Ca2+ channel ,1A subunit was highly expressed in granule and Purkinje cells, and the P-type Ca2+ currents in Purkinje cells were selectively reduced in the mutant mice. Therefore, we concluded that altered Ca2+ currents through the mutated Ca2+ channel ,1A subunit might be involved in the functional and morphological abnormalities in granule and Purkinje cells, and might result in expressions of behavioral phenotypes including ataxia. Increased levels of corticotropin-releasing factor and cholecystokinin in some climbing and mossy fibers were observed in RMN. These neuropeptides modulated the excitability of granule and Purkinje cells, indicating the possible expression of ataxic symptoms. [source] Monogenic migraine syndromes highlight novel drug targetsDRUG DEVELOPMENT RESEARCH, Issue 7 2007J. Jay Gargus Abstract In the post-genomic era, the paradigm for drug discovery has changed, as every gene may become a potential target. Genetic diseases provide a special window into gene target selection. This approach is being applied to migraine making use of the genes and mutations causing familial hemiplegic migraine (FHM). FHM is caused by missense mutations in CACNA1A, altering a neuronal P/Q Ca2+ channel, in ATP1A2, altering ,2 Na,K-ATPase, and in SCN1A, altering a neuronal sodium channel. These genes provide insights into migraine pathogenesis that likely extend to other forms of migraine as well. Since the three FHM genes are only co-expressed in neurons, FHM is a neuronal, not a vascular, disease and because they all encode ion transport proteins, FHM is a neuronal channelopathy,meaning meta-stable neuronal hyperexcitability is the substrate of migraine, much as it is for genetic epilepsy syndromes. This similarity is reinforced, since different mutations of all three FHM genes can produce seizure syndromes. This has implications for drug discovery in that seizure medications already known to modulate the FHM channel mechanisms warrant more targeted development, and that drugs targeted to vascular headaches, such as the historically effective triptans, or experimental botulinum toxin, may well work by similar nonvascular mechanisms. Finally, in model neurogenetic systems such as Caenorhabditis elegans, the FHM genes also provide both a comprehensive means to discover all genes involved in their signaling pathway,genes potentially involved in common forms of the disease, and an in vivo whole animal means to screen rapidly for novel therapeutics. Drug Dev Res 68:432,440, 2007. © 2008 Wiley-Liss, Inc. [source] A Novel ATP1A2 Gene Mutation in an Irish Familial Hemiplegic Migraine KindredHEADACHE, Issue 1 2008Desiree M. Fernandez MRCP Objective., We studied a large Irish Caucasian pedigree with familial hemiplegic migraine (FHM) with the aim of finding the causative gene mutation. Background., FHM is a rare autosomal-dominant subtype of migraine with aura, which is linked to 4 loci on chromosomes 19p13, 1q23, 2q24, and 1q31. The mutations responsible for hemiplegic migraine have been described in the CACNA1A gene (chromosome 19p13), ATP1A2 gene (chromosome 1q23), and SCN1A gene (chromosome 2q24). Methods., We performed linkage analyses in this family for chromosome 1q23 and performed mutation analysis of the ATP1A2 gene. Results., Linkage to the FHM2 locus on chromosome 1 was demonstrated. Mutation screening of the ATP1A2 gene revealed a G to C substitution in exon 22 resulting in a novel protein variant, D999H, which co-segregates with FHM within this pedigree and is absent in 50 unaffected individuals. This residue is also highly conserved across species. Conclusions., We propose that D999H is a novel FHM ATP1A2 mutation. [source] Pseudomigraine With Lymphocytic Pleocytosis: A Calcium Channelopathy?HEADACHE, Issue 8 2003Clinical Description of 10 Cases, Genetic Analysis of the Familial Hemiplegic Migraine Gene CACNA1A Objective.,To report the clinical findings of 10 patients diagnosed with pseudomigraine with lymphocytic pleocytosis and the results of mutational analysis of the CACNA1A gene in 8 of these patients. Background.,Pseudomigraine with lymphocytic pleocytosis, also referred to as headache with neurologic deficits and cerebrospinal fluid lymphocytosis (HaNDL), is characterized by episodic transient neurologic dysfunction associated with moderate to severe headache and cerebrospinal fluid lymphocytic pleocytosis. Episodes are recurrent and the condition is self-limiting. The etiology of this sporadic condition remains unknown, but the episodic nature and its ability to be triggered by angiography is somewhat reminiscent of the phenotypic features of familial hemiplegic migraine, a condition caused by mutations in the CACNA1A gene. Design/Methods.,Utilizing retrospective chart review, we describe the clinical features of pseudomigraine with lymphocytic pleocytosis in 10 patients. Whole blood was taken from 8 patients (2 were lost to follow-up) and used for DNA testing. The CACNA1A gene was screened for mutations using heteroduplex analysis and direct DNA sequencing. Results.,Clinical features of pseudomigraine with lymphocytic pleocytosis included transient episodes of weakness, sensory and visual symptoms, aphasia, and confusion lasting minutes up to 4 hours. Sensory symptoms, typically affecting the face and arm, were the most common presentation. Localization of symptoms did not conform to vascular territories. Headache was typically throbbing and most often bilateral. Genetic analysis did not identify any mutations in the CACNA1A gene. Conclusions.,Similarities between familial hemiplegic migraine and pseudomigraine with lymphocytic pleocytosis include recurrent headache with reversible neurologic deficit, cerebrospinal fluid lymphocytic pleocytosis, and triggers such as angiography. Even so, heteroduplex analysis and DNA sequencing failed to identify any sporadic mutations or shared polymorphisms in the exons or the intron/exon boundaries of the CACNA1A gene. These results do not support a role of the CACNA1A gene in the etiology of pseudomigraine with lymphocytic pleocytosis. [source] Molecular determinants of inactivation in voltage-gated Ca2+ channelsTHE JOURNAL OF PHYSIOLOGY, Issue 2 2000Steffen Hering Evolution has created a large family of different classes of voltage-gated Ca2+ channels and a variety of additional splice variants with different inactivation properties. Inactivation controls the amount of Ca2+ entry during an action potential and is, therefore, believed to play an important role in tissue-specific Ca2+ signalling. Furthermore, mutations in a neuronal Ca2+ channel (Cav2.1) that are associated with the aetiology of neurological disorders such as familial hemiplegic migraine and ataxia cause significant changes in the process of channel inactivation. Ca2+ channels of a given subtype may inactivate by three different conformational changes: a fast and a slow voltage-dependent inactivation process and in some channel types by an additional Ca2+ -dependent inactivation mechanism. Inactivation kinetics of Ca2+ channels are determined by the intrinsic properties of their pore-forming ,1 -subunits and by interactions with other channel subunits. This review focuses on structural determinants of Ca2+ channel inactivation in different parts of Ca2+ channel ,1 -subunits, including pore-forming transmembrane segments and loops, intracellular domain linkers and the carboxyl terminus. Inactivation is also affected by the interaction of the ,1 -subunits with auxiliary ,-subunits and intracellular regulator proteins. The evidence shows that pore-forming S6 segments and conformational changes in extra- (pore loop) and intracellular linkers connected to pore-forming segments may play a principal role in the modulation of Ca2+ channel inactivation. Structural concepts of Ca2+ channel inactivation are discussed. [source] Apnoeic spells following general anaesthesia in a patient with familial hemiplegic migraineANAESTHESIA, Issue 9 2007J. Willson Summary Hemiplegic migraine is an unusual variant of migraine, characterised by a temporary hemiparesis or hemiplegia associated with headache. We report a patient with hemiplegic migraine who developed atypical migraine with apnoeic spells, aphasia and hemiparesis following general anaesthesia. We review the clinical features of hemiplegic migraine and the considerations for its anaesthetic management. [source] Novel mutations in the Na+, K+ -ATPase pump gene ATP1A2 associated with familial hemiplegic migraine and benign familial infantile convulsionsANNALS OF NEUROLOGY, Issue 3 2003Kaate R. J. Vanmolkot Msc Familial hemiplegic migraine (FHM) is a rare, severe, autosomal dominant subtype of migraine with aura. Up to 75% of FHM families have a mutation in the P/Q-type calcium channel Cav2.1 subunit CACNA1A gene on chromosome 19p13. Some CACNA1A mutations also may cause epilepsy. Here, we describe novel missense mutations in the ATP1A2 Na+,K+ -ATPase pump gene on chromosome 1q23 in two families with FHM. The M731T mutation was found in a family with pure FHM. The R689Q mutation was identified in a family in which FHM and benign familial infantile convulsions partially cosegregate. In this family, all available affected family members with FHM, benign familial infantile convulsions, or both, carry the ATP1A2 mutation. Like FHM linked to 19p13, FHM linked to 1q23 also involves dysfunction of ion transportation and epilepsy is part of its phenotypic spectrum. [source] |