Your search keyword '"Kiper, Aytug K."' showing total 4 results

1. Cloxyquin activates hTRESK by allosteric modulation of the selectivity filter.

Author

Schreiber, Julian Alexander, Derksen, Anastasia, Goerges, Gunnar, Schütte, Sven, Sörgel, Jasmin, Kiper, Aytug K., Strutz-Seebohm, Nathalie, Ruck, Tobias, Meuth, Sven G., Decher, Niels, and Seebohm, Guiscard

Subjects

ALLOSTERIC regulation, MEMBRANE potential, ION channels, BINDING sites, SPINAL cord, DRUG therapy

Abstract

The TWIK-related spinal cord K+ channel (TRESK, K2P18.1) is a K2P channel contributing to the maintenance of membrane potentials in various cells. Recently, physiological TRESK function was identified as a key player in T-cell differentiation rendering the channel a new pharmacological target for treatment of autoimmune diseases. The channel activator cloxyquin represents a promising lead compound for the development of a new class of immunomodulators. Identification of cloxyquin binding site and characterization of the molecular activation mechanism can foster the future drug development. Here, we identify the cloxyquin binding site at the M2/M4 interface by mutational scan and analyze the molecular mechanism of action by protein modeling as well as in silico and in vitro electrophysiology using different permeating ion species (K+ / Rb+). In combination with kinetic analyses of channel inactivation, our results suggest that cloxyquin allosterically stabilizes the inner selectivity filter facilitating the conduction process subsequently activating hTRESK. Here, the binding site of the drug cloxyquin to the TWIK-related spinal cord K+ channel (TRESK) channel is determined and it is reported that Cloxyquin activates the ion channel by allosteric stabilization of the inner selectivity filter facilitating the ion conduction process. [ABSTRACT FROM AUTHOR]

Published

2023

2. A New Strategy for Multitarget Drug Discovery/Repositioning Through the Identification of Similar 3D Amino Acid Patterns Among Proteins Structures: The Case of Tafluprost and its Effects on Cardiac Ion Channels.

Author

Valdés-Jiménez, Alejandro, Jiménez-González, Daniel, Kiper, Aytug K., Rinné, Susanne, Decher, Niels, González, Wendy, Reyes-Parada, Miguel, and Núñez-Vivanco, Gabriel

Subjects

ION channels, PROTEIN structure, QUATERNARY structure, AMINO acids, BINDING sites, GEOGRAPHICAL discoveries

Abstract

The identification of similar three-dimensional (3D) amino acid patterns among different proteins might be helpful to explain the polypharmacological profile of many currently used drugs. Also, it would be a reasonable first step for the design of novel multitarget compounds. Most of the current computational tools employed for this aim are limited to the comparisons among known binding sites, and do not consider several additional important 3D patterns such as allosteric sites or other conserved motifs. In the present work, we introduce Geomfinder2.0, which is a new and improved version of our previously described algorithm for the deep exploration and discovery of similar and druggable 3D patterns. As compared with the original version, substantial improvements that have been incorporated to our software allow: (i) to compare quaternary structures, (ii) to deal with a list of pairs of structures, (iii) to know how druggable is the zone where similar 3D patterns are detected and (iv) to significantly reduce the execution time. Thus, the new algorithm achieves up to 353x speedup as compared to the previous sequential version, allowing the exploration of a significant number of quaternary structures in a reasonable time. In order to illustrate the potential of the updated Geomfinder version, we show a case of use in which similar 3D patterns were detected in the cardiac ions channels NaV1.5 and TASK-1. These channels are quite different in terms of structure, sequence and function and both have been regarded as important targets for drugs aimed at treating atrial fibrillation. Finally, we describe the in vitro effects of tafluprost (a drug currently used to treat glaucoma, which was identified as a novel putative ligand of NaV1.5 and TASK-1) upon both ion channels' activity and discuss its possible repositioning as a novel antiarrhythmic drug. [ABSTRACT FROM AUTHOR]

Published

2022

3. Molecular Pharmacology of K2P Potassium Channels.

Author

Decher, Niels, Rinné, Susanne, Bedoya, Mauricio, Gonzalez, Wendy, and Kiper, Aytug K.

Subjects

POTASSIUM channels, MOLECULAR pharmacology, BINDING sites, TARGETED drug delivery, MOLECULAR dynamics

Abstract

Potassium channels of the tandem of two-pore-domain (K2P) family were among the last potassium channels cloned. However, recent progress in understanding their physiological relevance and molecular pharmacology revealed their therapeutic potential and thus these channels evolved as major drug targets against a large variety of diseases. However, after the initial cloning of the fifteen family members there was a lack of potent and/or selective modulators. By now a large variety of K2P channel modulators (activators and blockers) have been described, especially for TASK-1, TASK-3, TREK-1, TREK2, TRAAK and TRESK channels. Recently obtained crystal structures of K2P channels, alanine scanning approaches to map drug binding sites, in silico experiments with molecular dynamics simulations (MDs) combined with electrophysiological studies to reveal the mechanism of channel inhibition/activation, yielded a good understanding of the molecular pharmacology of these channels. Besides summarizing drugs that were identified to modulate K2P channels, the main focus of this article is on describing the differential binding sites and mechanisms of channel modulation that are utilized by the different K2P channel blockers and activators. [ABSTRACT FROM AUTHOR]

Published

2021

4. POPDC2 a novel susceptibility gene for conduction disorders.

Author

Rinné, Susanne, Ortiz-Bonnin, Beatriz, Stallmeyer, Birgit, Kiper, Aytug K., Fortmüller, Lisa, Schindler, Roland F.R., Herbort-Brand, Ursula, Kabir, Nashitha S., Dittmann, Sven, Friedrich, Corinna, Zumhagen, Sven, Gualandi, Francesca, Selvatici, Rita, Rapezzi, Claudio, Arbustini, Eloisa, Ferlini, Alessandra, Fabritz, Larissa, Schulze-Bahr, Eric, Brand, Thomas, and Decher, Niels

Subjects

*VENTRICULAR arrhythmia, *ATRIOVENTRICULAR node, *TWINS, *MYOCARDIUM, *GENETIC mutation, *SINOATRIAL node, *RECESSIVE genes

Abstract

Despite recent progress in the understanding of cardiac ion channel function and its role in inherited forms of ventricular arrhythmias, the molecular basis of cardiac conduction disorders often remains unresolved. We aimed to elucidate the genetic background of familial atrioventricular block (AVB) using a whole exome sequencing (WES) approach. In monozygotic twins with a third-degree AVB and in another, unrelated family with first-degree AVB, we identified a heterozygous nonsense mutation in the POPDC2 gene causing a premature stop at position 188 (POPDC2W188⁎), deleting parts of its cAMP binding-domain. Popeye-domain containing (POPDC) proteins are predominantly expressed in the skeletal muscle and the heart, with particularly high expression of POPDC2 in the sinoatrial node of the mouse. We now show by quantitative PCR experiments that in the human heart the POPDC-modulated two-pore domain potassium (K 2P) channel TREK-1 is preferentially expressed in the atrioventricular node. Co-expression studies in Xenopus oocytes revealed that POPDC2W188⁎ causes a loss-of-function with impaired TREK-1 modulation. Consistent with the high expression level of POPDC2 in the murine sinoatrial node, POPDC2W188⁎ knock-in mice displayed stress-induced sinus bradycardia and pauses, a phenotype that was previously also reported for POPDC2 and TREK-1 knock-out mice. We propose that the POPDC2W188⁎ loss-of-function mutation contributes to AVB pathogenesis by an aberrant modulation of TREK-1, highlighting that POPDC2 represents a novel arrhythmia gene for cardiac conduction disorders. [ABSTRACT FROM AUTHOR]

Published

2020