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Molecular biology of K+ channels and their role in cardiac arrhythmias1  Martin Tristani-Firouzi, MD, Jun Chen, MD, John S Mitcheson, PhD, Michael C Sanguinetti,

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Presentation on theme: "Molecular biology of K+ channels and their role in cardiac arrhythmias1  Martin Tristani-Firouzi, MD, Jun Chen, MD, John S Mitcheson, PhD, Michael C Sanguinetti,"— Presentation transcript:

1 Molecular biology of K+ channels and their role in cardiac arrhythmias1 
Martin Tristani-Firouzi, MD, Jun Chen, MD, John S Mitcheson, PhD, Michael C Sanguinetti, PhD  The American Journal of Medicine  Volume 110, Issue 1, Pages (January 2001) DOI: /S (00)

2 Figure 1 K+ currents responsible for repolarization of a typical ventricular action potential. Ventricular action potential (top). Phase 0, rapid upstroke; phase 1, initial repolarization; phase 2, plateau; phase 3, terminal repolarization; phase 4, diastolic membrane potential. The rapid repolarization of phase 1 is the result of the contribution of the rapidly activating transient outward (Ito), the ultra-rapid delayed rectifier (IKur), and the leak (Ileak) currents (middle and bottom). During the plateau phase, the rapid (IKr) and slow (IKs) delayed rectifier K+ currents as well as IKur and Ileak counter the depolarizing influence of L-type calcium current (not shown). IKr and the inward rectifier K+ current (IK1) provide repolarizing current during the terminal phase of the action potential [modified from (71). Reprinted with permission from the American Heart Association]. The American Journal of Medicine  , 50-59DOI: ( /S (00) )

3 Figure 2 Proposed topology of K+ channel subunits. A. Schematic representation of a voltage-gated K+ channel alpha subunit composed of six membrane-spanning alpha helices (S1 to S6). The fourth membrane-spanning unit (S4) contains positively charged residues at approximately every third position and is the voltage sensor. The residues between S5 and S6 (shown in orange) form the ion selective pore. Auxiliary beta subunits (shown in green) modify the gating properties and protein trafficking of the pore-forming alpha subunits. Kvbeta subunits are cytoplasmic proteins that bind to the N-terminus. MinK, a component of the IKs channel, is a membrane-spanning beta subunit. B. K+ channel alpha subunits coassemble to form a tetrameric channel composed of four identical subunits (homotetramer) or nonidentical subunits (heterotetramer). C. Inward rectifier K+ channels are formed by subunits containing two membrane-spanning alpha helices, separated by a pore domain. Like the six transmembrane voltage-gating ion channel, four subunits coassemble to form the inward rectifier K+ channel. TWIK channels are a unique class of channels formed by subunits containing four membrane-spanning domains and two pore loops. The American Journal of Medicine  , 50-59DOI: ( /S (00) )

4 Figure 3 The role of K+ channels in mediating phase 3 repolarization of the cardiac action potential. A. Yellow arrows represent K+ efflux through the rapid (IKr) and slow (IKs) delayed rectifier K+ channels. Outward movement of positively charged K+ hyperpolarizes the cell membrane and terminates the action potential. The surface electrocardiogram is depicted below. The QRS corresponds to the rapid upstroke of the action potential. The T wave represents the change in membrane potential associated with repolarization. B. Mutations in the genes encoding subunits of the IKr and IKs channels reduce the amount of repolarizing current available during the terminal phase of the cardiac action potential. Decreased repolarizing current prolongs the action potential, which is reflected on the surface electrocardiogram as prolongation of the QT interval. The American Journal of Medicine  , 50-59DOI: ( /S (00) )

5 Figure 4 Drug trapping within the K+ channel vestibule. Class III antiarrhythmic agents traverse the lipid bilayer as neutral molecules and equilibrate in the cytosol as positively charged molecules (top left). In the resting state, the activation gate (blue) of the K+ channel (green) remains closed. Upon depolarization, the activation gate opens and the drug enters the vestibule to block the channel (top right). The channel then enters a long-lasting closed state (inactivation), which increases the affinity of drug binding (bottom right). Upon repolarization, the activation gate closes (deactivation) and traps the drug within the channel vestibule (bottom left). On subsequent depolarizations, the channel is not available to conduct K+ because the drug remains bound. The American Journal of Medicine  , 50-59DOI: ( /S (00) )

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