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Query: UMLS:C0009952 (
febrile convulsions
)
1,215
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Benign familial neonatal convulsions (BFNC) is a rare dominantly inherited epileptic syndrome characterized by frequent brief seizures within the first days of life. The disease is caused by mutations in one of two recently identified voltage-gated potassium channel genes,
KCNQ2
or KCNQ3. Here, we describe a four-generation BFNC family carrying a novel mutation within the distal, unconserved C-terminal domain of
KCNQ2
, a 1-bp deletion, 2513delG, in codon 838 predicting substitution of the last seven and extension by another 56 amino acids. Three family members suffering from febrile but not from neonatal convulsions do not carry the mutation, confirming that
febrile convulsions
and BFNC are of different pathogenesis. Functional expression of the mutant channel in Xenopus oocytes revealed a reduction of the potassium current to 5% of the wild-type current, but the voltage sensitivity and kinetics were not significantly changed. To find out whether the loss of the last seven amino acids or the C-terminal extension because of 2513delG causes the phenotype, a second, artificial mutation was constructed yielding a stop codon at position 838. This truncation increased the potassium current by twofold compared with the wild type, indicating that the pathological extension produces the phenotype, and suggesting an important role of the distal, unconserved C-terminal domain of this channel. Our results indicate that BFNC is caused by a decreased potassium current impairing repolarization of the neuronal cell membrane, which results in hyperexcitability of the central nervous system.
...
PMID:A reduced K+ current due to a novel mutation in KCNQ2 causes neonatal convulsions. 1048 60
Mutations in the voltage-gated potassium channel genes
KCNQ2
and KCNQ3 have been found to cause benign familial neonatal convulsions. Recent studies provided evidence that
KCNQ2
and KCNQ3 contribute to the M-current, which regulates the subthreshold electrical excitability in the CNS.
Febrile convulsions
represent the majority of childhood seizures, and show a strong family history, suggesting a genetic predisposition. By performing an association study, we investigated whether
KCNQ2
gene polymorphisms can be used as markers of susceptibility to
febrile convulsions
. These data suggest that the
KCNQ2
gene might not be a useful marker for prediction of the susceptibility of
febrile convulsions
.
...
PMID:The voltage-gated potassium channel KCNQ2 in Taiwanese children with febrile convulsions. 1239 2
Of the five human KCNQ (Kv7) channels, KCNQ1 with auxiliary subunit KCNE1 mediates the native cardiac I(Ks) current with mutations causing short and long QT cardiac arrhythmias. KCNQ4 mutations cause deafness.
KCNQ2
/3 channels form the native M-current controlling excitability of most neurons, with mutations causing benign neonatal
febrile convulsions
. Drosophila contains a single KCNQ (dKCNQ) that appears to serve alone the functions of all the duplicated mammalian neuronal and cardiac KCNQ channels sharing roughly 50-60% amino acid identity therefore offering a route to investigate these channels. Current information about the functional properties of dKCNQ is lacking therefore we have investigated these properties here. Using whole cell patch clamp electrophysiology we compare the biophysical and pharmacological properties of dKCNQ with the mammalian neuronal and cardiac KCNQ channels expressed in HEK cells. We show that Drosophila KCNQ (dKCNQ) is a slowly activating and slowly-deactivating K(+) current open at sub-threshold potentials that has similar properties to neuronal
KCNQ2
/3 with some features of the cardiac KCNQ1/KCNE1 accompanied by conserved sensitivity to a number of clinically relevant KCNQ blockers (chromanol 293B, XE991, linopirdine) and opener (zinc pyrithione). We also investigate the molecular basis of the differential selectivity of KCNQ channels to the opener retigabine and show a single amino acid substitution (M217W) can confer sensitivity to dKCNQ. We show dKCNQ has similar electrophysiological and pharmacological properties as the mammalian KCNQ channels, allowing future study of physiological and pathological roles of KCNQ in Drosophila and whole organism screening for new modulators of KCNQ channelopathies.
...
PMID:Drosophila KCNQ channel displays evolutionarily conserved electrophysiology and pharmacology with mammalian KCNQ channels. 2191 66
