Your search keyword '"Potassium channels -- Genetic aspects"' showing total 6 results

1. A recombinant N-terminal domain fully restores deactivation gating in N-truncated and long QT syndrome mutant hERG potassium channels

Author

Gustina, Ahleah S. and Trudeau, Matthew C.

Subjects

Long QT syndrome -- Development and progression, Long QT syndrome -- Research, Long QT syndrome -- Genetic aspects, Potassium channels -- Physiological aspects, Potassium channels -- Genetic aspects, Gene mutations -- Physiological aspects, Science and technology

Abstract

Human ether a go-go related gene (hERG) potassium channels play a central role in cardiac repolarization where channel closing (deactivation) regulates current density during action potentials. Consequently, mutations in hERG that perturb deactivation are linked to long QT syndrome (LQTS), a catastrophic cardiac arrhythmia. Interactions between an N-terminal domain and the pore-forming 'core' of the channel were proposed to regulate deactivation, however, despite its central importance the mechanistic basis for deactivation is unclear. Here, to more directly examine the mechanism for regulation of deactivation, we genetically fused N-terminal domains to fluorescent proteins and tested channel function with electrophysiology and protein interactions with Forster resonance energy transfer (FRET) spectroscopy. Truncation of hERG N-terminal regions markedly sped deactivation, and here we report that reapplication of gene fragments encoding N-terminal residues 1-135 (the 'eag domain') was sufficient to restore regulation of deactivation. We show that fluorophore-tagged eag domains and N-truncated channels were in close proximity at the plasma membrane as determined with FRET. The eag domains with Y43A or R56Q (aLQTS locus) mutations showed less regulation of deactivation and less FRET, whereas eag domains restored regulation of deactivation gating to full-length Y43A or R56Q channels and showed FRET. This study demonstrates that direct, noncovalent interactions between the eag domain and the channel core were sufficient to regulate deactivation gating, that an LQTS mutation perturbed physical interactions between the eag domain and the channel, and that small molecules such as the eag domain represent a novel method for restoring function to channels with disease-causing mutations. eag domain | FRET | LQTS

Published

2009

2. Mutations in Kir2.1 cause the developmental and episodic electrical phenotypes of Andersen's syndrome

Author

Plaster, Nikki M., Tawil, Rabi, Tristani-Firouzi, Martin, Canun, Sonia, Bendahhou, Said, Tsunoda, Akiko, Donaldson, Matthew R., Iannaccone, Susan T., Brunt, Ewout, Barohn, Richard, Clark, John, Deymeer, Feza, George, Alfred L., Jr., Fish, Frank A., Hahn, Angelika, Nitu, Alexandru, Ozdemir, Coskun, Serdaroglu, Piraye, Subramony, S. H., Wolfe, Gil, Fu, Ying-Hui, and Ptacek, Louis J.

Subjects

Cell research -- Analysis, Gene mutations -- Physiological aspects, Phenotype -- Genetic aspects, Cardia -- Physiological aspects, Potassium channels -- Genetic aspects, Chromosomes -- Genetic aspects, Biological sciences

Abstract

Research has been conducted on the Andersen's syndrome characterized by cardiac arrhythmias and dysmorphic features. The mapping of the Andersen's locus to the chromosome near the inward rectifying potassium channel gene has been carried out and the results indicate that mutations in Kir2.1 affect the developmental signaling and cause Andersen's syndrome.

Published

2001

3. Voltage-dependent gating characteristics of the K+ channel KAT1 depend on the N and C termini

Author

Marten, Irene and Hoshi, Toshinori

Subjects

Potassium channels -- Genetic aspects, Telomeres -- Physiological aspects, Gene mutations -- Physiological aspects, Chromosome deletion -- Physiological aspects, Science and technology

Abstract

We studied how the C and N termini of the plant [K.sup.+] channel KAT1 influence the voltage-dependent gating behavior by generating C- and N-terminal deletion mutants. Functional expression was observed only when C-terminal deletions were downstream of the putative cyclic nucleotide binding site. Treatments of oocytes expressing KAT1 channels with anticytoskeletal agents indicated that intact microtubules are important for functional expression. C-terminal deletions altered the voltage sensitivity of the KAT1 channel with greater deletions resulting in smaller equivalent charge movements. In contrast, a deletion in the N terminus (A20-34) shifted the half-activation voltage by approximately -65 mV without markedly affecting the number of equivalent charges. The results reveal novel roles of the N and C termini in regulation of the voltage-dependent gating of KAT1.

Published

1997

4. Promoter analysis of Kv8.1 revealed the essential element for Kv8.1 expression

Author

Ebihara, M., Ohba, H., and Yoshikawa, T.

Subjects

Human genetics -- Research, Potassium channels -- Genetic aspects, Diseases -- Genetic aspects, Gene mutations -- Physiological aspects, Biological sciences

Published

2001

5. Splice variants of small conductance calcium-activated potassium channel gene KCNN3/ SKCa3 cause dominant-negative suppression of SKCa currents

Author

Tomita, H., Shakkottai, V., Wulff, H., Sun, G., Potkin, S.G., Bunney, W.E., Chandy, K.G., and Gargus, J.J.

Subjects

Gene mutations -- Physiological aspects, Human genetics -- Research, Potassium channels -- Genetic aspects, Biological sciences

Published

2001

6. A structural basis for drug-induced long QT syndrome

Author

Mitcheson, John S., Chen, Jun, Lin, Monica, Culberson, Chris, and Sanguinetti, Michael C.

Subjects

Gene mutations -- Physiological aspects, Potassium channels -- Genetic aspects, Human genetics -- Research, Science and technology

Abstract

Mutations in the HERG [K.sup.+] channel gene cause inherited long QT syndrome (LQT), a disorder of cardiac repolarization that predisposes affected individuals to lethal arrhythmias [Curran, M. E., Splawski, I., Timothy, K. W., Vincent, G. M., Green, E. D. & Keating, M. T. (1995) Cell 80, 795-804]. Acquired LQT is far more common and is most often caused by block of cardiac HERG [K.sup.+] channels by commonly used medications [Roden, D. M., Lazzara, R., Rosen, M., Schwartz, P. J., Towbin, J. & Vincent, G. M. (1996) Circulation 94, 1996-2012]. It is unclear why so many structurally diverse compounds block HERG channels, but this undesirable side effect now is recognized as a major hurdle in the development of new and safe drugs. Here we use alanine-scanning mutagenesis to determine the structural basis for high-affinity drug block of HERG channels by MK-499, a methanesulfonanilide antiarrhythmic drug. The binding site, corroborated with homology modeling, is comprised of amino acids located on the S6 transmembrane domain (G648, Y652, and F656) and pore helix (T623 and V625) of the HERG channel subunit that face the cavity of the channel. Other compounds that are structurally unrelated to MK-499, but cause LQT, also were studied. The antihistamine terfenadine and a gastrointestinal prokinetic drug, cisapride, interact with Y652 and F656, but not with V625. The aromatic residues of the S6 domain that interact with these drugs (Y652 and F656) are unique to eag/erg [K.sup.+] channels. Other voltage-gated [K.sup.+] (Kv) channels have Ile and Val (Ile) in the equivalent positions. These findings suggest a possible structural explanation for how so many commonly used medications block HERG but not other Kv channels and should facilitate the rational design of drugs devoid of HERG channel binding activity.

Published

2000