Publications by authors named "Michael Sanguinetti"
The opening and closing of voltage-dependent potassium channels is dependent on a tight coupling between movement of the voltage sensing S4 segments and the activation gate. A specific interaction between intracellular amino- and carboxyl-termini is required for the characteristically slow rate of channel closure (deactivation) of hERG1 channels. Compounds that increase hERG1 channel currents represent a novel approach for prevention of arrhythmia associated with prolonged ventricular repolarization.
View Article and Find Full Text PDFArticle Synopsis
- KCNQ1 (K7.1) K channels are found in various organs like the heart and pancreas and are linked to conditions like long QT syndrome, arrhythmias, diabetes, and some cancers.
- Mutations in the KCNQ1 gene lead to different arrhythmias and the gene's interactions contribute to the formation of specialized potassium channels through partnerships with accessory β-subunits.
- Recent studies, including cryo-EM structures, have enhanced our understanding of how KCNQ1 interacts with calmodulin and other subunits, affecting the function and regulation of these channels.
Cardiomyocytes express a surprisingly large number of potassium channel types. The primary physiological functions of the currents conducted by these channels are to maintain the resting membrane potential and mediate action potential repolarization under basal conditions and in response to changes in the concentrations of intracellular sodium, calcium, and ATP/ADP. Here, we review the diversity and functional roles of cardiac potassium channels under normal conditions and how heritable mutations in the genes encoding these channels can lead to distinct arrhythmias.
View Article and Find Full Text PDFOutward current conducted by human ----related gene type 1 (hERG1) K channels is important for action potential repolarization in the human ventricle. Rapid, voltage-dependent inactivation greatly reduces outward currents conducted by hERG1 channels and involves conformational changes in the ion selectivity filter (SF). Recently, compounds have been found that activate hERG1 channel function by modulating gating mechanisms such as reducing inactivation.
View Article and Find Full Text PDFLife threatening ventricular arrhythmias leading to sudden cardiac death are a major cause of morbidity and mortality. In the absence of structural heart disease, these arrhythmias, especially in the younger population, are often an outcome of genetic defects in specialized membrane proteins called ion channels. In the heart, exceptionally well-orchestrated activity of a diversity of ion channels mediates the cardiac action potential.
View Article and Find Full Text PDFArticle Synopsis
- The long QT syndrome (LQTS) is a life-threatening heart condition characterized by prolonged QT intervals, leading to severe arrhythmias, and identifying genetic variants is crucial for patient care, although many variants are of uncertain significance (VUS).
- This study explores the use of genome editing on patient-specific induced pluripotent stem cells (iPSCs) to determine the pathogenicity of VUS in cardiac channelopathy.
- Results showed that iPSC-derived cardiomyocytes with the VUS exhibited abnormal electrical activity and a higher risk of arrhythmia, but gene editing successfully corrected the cellular abnormalities, supporting the potential of this approach in clarifying genetic variant implications.
Article Synopsis
- The human hERG1 channels are crucial for repolarizing action potentials in the heart, and ginsenoside Rg3 impacts their function by slowing deactivation and changing activation potentials.
- Rg3 rapidly binds to hERG1, indicating it affects channel gating from an extracellular site, which was investigated through mutagenesis of specific amino acid residues.
- Mutations in certain regions of hERG1, particularly in the S1, S2, and S4 segments, demonstrated varying levels of interaction with Rg3, suggesting that Rg3 stabilizes hERG1 in an activated state to enhance current magnitude and modify its voltage-dependent gating.
Article Synopsis
- This paper summarizes insights from the fourth UC Davis symposium on cardiac K channels, highlighting expert discussions on their function and regulation.
- The 2016 theme centered on 'K Channels and Regulation,' emphasizing the complexities of how these channels impact cardiac repolarization and are influenced by various physiological and pharmacological conditions.
- The findings suggest that a thorough understanding of K channel mechanisms is crucial for developing new therapeutic targets in cardiac health and treating arrhythmias.
Article Synopsis
- This White Paper is the second from the UC Davis Cardiovascular Symposium focused on understanding cardiac excitation-contraction coupling and arrhythmias, held on March 3-4, 2016.
- The symposium's theme was 'K channels and regulation', aiming to identify knowledge gaps, understand heart diseases, explore novel therapeutic targets, and advance systems biology approaches for diagnosing and treating arrhythmias.
- It features contributions from multiple experts discussing the roles of cardiac K channels in health and disease, integrating insights from both experimental and computational studies.
Key Points: Intracellular Na -activated Slo2 potassium channels are in a closed state under normal physiological conditions, although their mechanisms of ion permeation gating are not well understood. A cryo-electron microscopy structure of Slo2.2 suggests that the ion permeation pathway of these channels is closed by a single constriction of the inner pore formed by the criss-crossing of the cytoplasmic ends of the S6 segments (the S6 bundle crossing) at a conserved Met residue.
View Article and Find Full Text PDFArticle Synopsis
- Ginsenoside 20(S)-Rg3 (Rg3) affects hERG1 channels by activating them at lower voltages and slowing their deactivation, but it's unclear if this effect extends to other channels in the ether-à-go-go family.
- Researchers compared Rg3's impact on hERG1 with other channels (EAG1, ERG3, ELK1) using oocytes from frogs, finding that Rg3 significantly shifted activation potentials for all channels studied, with varying degrees of efficacy.
- The study highlights Rg3's potential as a basis for developing targeted treatments for cardiovascular and neural disorders by better understanding its mechanisms.
Molecular Basis of Cardiac Delayed Rectifier Potassium Channel Function and Pharmacology.
Card Electrophysiol Clin
June 2016
Human cardiomyocytes express 3 distinct types of delayed rectifier potassium channels. Human ether-a-go-go-related gene (hERG) channels conduct the rapidly activating current IKr; KCNQ1/KCNE1 channels conduct the slowly activating current IKs; and Kv1.5 channels conduct an ultrarapid activating current IKur.
View Article and Find Full Text PDFUnder normal physiological conditions, Slo2.1K(+) channels are in a closed state unless activated by an elevation in [Na(+)]i. Fenamates such as niflumic acid also activate Slo2.
View Article and Find Full Text PDFArticle Synopsis
- Slo2 potassium channels are usually inactive but can be activated by high levels of sodium (Na+) in situations like ischemia.
- Researchers found Na+ coordination motifs in the Slo2.1 subunit and created mutations to study their effects on channel activation.
- Among the mutations, the D757R variant showed no response to Na+, indicating that a single aspartate residue is crucial for Slo2.1 channel sensitivity to intracellular Na+, but overall, Na+ is a weaker activator compared to certain drugs like niflumic acid.
Article Synopsis
- Compounds can activate hERG1 channels through various mechanisms, such as slowing deactivation or increasing open probability.
- The first known hERG1 activator, RPR260243 (RPR), slows down the channel's deactivation in a voltage-dependent manner.
- Research shows that the differences in sensitivity to RPR between hERG1 and rERG2 channels are mainly due to specific residues in their C-terminus regions, emphasizing the importance of the C-linker in channel behavior.
Article Synopsis
- hERG1 potassium channels are crucial for cardiac repolarization; blocking them with certain drugs can prolong the QT interval and increase the risk of arrhythmias.
- Research shows that specific mutations (S620T or S631A) in hERG1 can disrupt inactivation gating, affecting drug sensitivity differently.
- The study concludes that the potency of drug binding is influenced by the presence of mutations, but this is not directly linked to their effects on channel inactivation, suggesting an allosteric mechanism at play.
Article Synopsis
- The activation of hERG1 K(+) channels is crucial for heart cell repolarization during action potentials, and the compound RPR-260243 (RPR) influences this process by slowing down channel deactivation and reducing inactivation.
- RPR binds to a specific pocket between hERG1 subunits, and investigating how many RPR molecules bind to the channel can help develop better anti-arrhythmia drugs for conditions with prolonged heart repolarization.
- The study reveals that the extent to which RPR slows deactivation is linked to the number of functional (wild-type) subunits in the channel structure, indicating that drug binding and channel function are related through different mechanisms.
Article Synopsis
- The Slo2.1 K(+) channels typically have a low open probability under normal conditions but can increase in activity due to elevated sodium and chloride levels from ischemia or rapid cell pacing.
- Initial research suggested that physiological levels of intracellular ATP inhibit these channels, but recent studies show this is not the case.
- Experiments involving different ATP concentrations and mutant channels confirm that changes in intracellular ATP do not affect the activity of Slo2.1 channels, leading to the conclusion that they are not inhibited by ATP.
At depolarized membrane potentials, the conductance of some voltage-gated K(+) channels is reduced by C-type inactivation. This gating process is voltage independent in Kv1 and involves a conformational change in the selectivity filter that is mediated by cooperative subunit interactions. C-type inactivation in hERG1 K(+) channels is voltage-dependent, much faster in onset and greatly attenuates currents at positive potentials.
View Article and Find Full Text PDFArticle Synopsis
- During repolarization in heart cells, hERG1 K(+) channels transition from an inactivated state to a closed state, which is crucial for ending the action potential plateau.
- The N-terminal domain of the hERG1 subunit is essential for the slow deactivation of these channels, as its absence speeds up deactivation significantly.
- Research on various mutations shows that even one mutant subunit in a channel can lead to rapid deactivation, indicating that all four subunits must work together for proper slow deactivation of hERG1 channels.
Type 1 human ether-a-go-go-related gene (hERG1) potassium channels are a key determinant of normal repolarization of cardiac action potentials. Loss of function mutations in hERG1 channels cause inherited long QT syndrome and increased risk of cardiac arrhythmia and sudden death. Many common medications that block hERG1 channels as an unintended side effect also increase arrhythmic risk.
View Article and Find Full Text PDFVoltage-gated K(+) channels are tetramers formed by coassembly of four identical or highly related subunits. All four subunits contribute to formation of the selectivity filter, the narrowest region of the channel pore which determines K(+) selective conductance. In some K(+) channels, the selectivity filter can undergo a conformational change to reduce K(+) flux by a mechanism called C-type inactivation.
View Article and Find Full Text PDFArticle Synopsis
- The activation gate of Slo2.1, a weakly voltage-dependent potassium channel, is primarily regulated by the selectivity filter rather than the S6 bundle crossing, which is common in other voltage-gated channels.
- Experiments using mutations in the S6 segment and other parts of the channel revealed that specific residues are crucial for proper channel function and trafficking to the cell surface.
- The study suggests that the inner pore remains open due to interactions among the S5, S6, and pore helix segments, highlighting a unique mechanism for Slo2.1 activation compared to other ion channels.