Cardiac Ion Channels




Abstract


Ion channels are pore-forming membrane proteins that regulate the flow of ions passively down their electrochemical gradient across the membrane. Ion channels are present on all membranes of cells (plasma membrane) and are intracellular. There are more than 300 types of ion channels in a living cell.


Ion channels are distinguished by two important characteristics: ion permeation selectivity and gating kinetics. Ion channels can be classified by the strongest permeant ion (sodium [Na + ], potassium [K + ], calcium [Ca 2+ ], and chloride [Cl ]), but some channels are less selective or are not selective, as in gap junctional channels. Size, valency, and hydration energy are important determinants of selectivity.


Gating is the mechanism of opening and closing of ion channels and represents time-dependent transitions among distinct conforma­tional states of the channel protein resulting from molecular move­ments, most commonly in response to variations in voltage gradient across the plasma membrane (termed voltage-dependent gating ) and, less commonly, in response to specific ligand molecules bind­ing to the extracellular or intracellular side of the channel (ligand-dependent gating) or in response to mechanical stress such as stretch, pressure, shear, or displacement (mechanosensitive gating).


The transition from the resting (closed) state to the open state is called activation . Once opened, channels undergo conforma­tional transition in a time-dependent manner to a stable noncon­ducting (inactivated) state. Inactivated channels are incapable of reopening and must undergo recovery or reactivation process back to the resting state to regain their ability to open.




Keywords

cardiac ion channels, channel gating, cardiac action potential, channelopathies, gap junctions

 






  • Outline



  • Sodium Channels, 16




    • Structure and Physiology, 16



    • Function, 18



    • Regulation, 18



    • Pharmacology, 18



    • Inherited Channelopathies, 19



    • Acquired Diseases, 22




  • Potassium Channels, 22




    • Structure and Physiology, 22



    • Function, 24



    • Transient Outward Potassium Current, 24



    • Ultrarapidly Activating Delayed Outward Rectifying Current, 27



    • Rapidly Activating Delayed Outward Rectifying Current, 27



    • Slowly Activating Delayed Outward Rectifying Current, 29



    • Inward Rectifying Current, 31



    • Acetylcholine-Activated Potassium Current, 32



    • Adenosine Triphosphate–Sensitive Potassium Current, 33



    • Two-Pore Potassium Channels, 36



    • Small-Conductance Calcium-Activated Potassium Channels, 36




  • Calcium Channels, 37




    • Structure and Physiology, 37



    • The α1 Subunit, 38



    • The β Subunit, 38



    • The α2δ Subunit, 38



    • The γ Subunit, 39



    • Cardiac L-Type Calcium Current, 39



    • T-Type Calcium Current, 41




  • Cardiac Pacemaker Current, 42




    • Structure and Physiology, 42



    • Function, 42



    • Regulation, 43



    • Pharmacology, 43



    • Inherited Channelopathies, 43



    • Acquired Diseases, 43




  • Sarcoplasmic Reticulum Calcium Release Channels (Ryanodine Receptor 2), 43




    • Structure and Physiology, 43



    • Function, 44



    • Regulation, 45



    • Pharmacology, 45



    • Inherited Channelopathies, 46



    • Acquired Diseases, 46




  • Cardiac Gap Junctions, 46




    • Structure and Physiology, 46



    • Function, 47



    • Regulation, 48



    • Pharmacology, 48



    • Inherited Channelopathies, 48



    • Acquired Diseases, 48



Ion channels are pore-forming membrane proteins that regulate the flow of ions passively down their electrochemical gradient across the membrane. Ion channels are present on all membranes of cells (plasma membrane) and intracellular organelles (nucleus, mitochondria, endoplasmic reticulum). There are more than 300 types of ion channels in a living cell. The channels are not randomly distributed in the membrane but tend to cluster at the intercalated disc in association with modulatory subunits.


Ion channels are distinguished by two important characteristics: ion permeation selectivity and gating kinetics. Ion channels can be classified by the strongest permeant ion (sodium [Na + ], potassium [K + ], calcium [Ca 2+ ], and chloride [Cl ]), but some channels are less selective or are not selective, as in gap junctional channels. Size, valency, and hydration energy are important determinants of selectivity. Na + channels have a selectivity ratio for Na + to K + of 12 : 1. Voltage-gated K + and Na + channels exhibit more than 10-fold discrimination against other monovalent and divalent cations, and voltage-gated Ca 2+ channels exhibit more than 1000-fold discrimination against Na + and K + ions and are impermeable to anions. Ions move through the channel pore at a very high rate (more than 10 6 ions/s).


Gating is the mechanism of opening and closing of ion channels and represents time-dependent transitions among distinct conformational states of the channel protein resulting from molecular movements, most commonly in response to variations in voltage gradient across the plasma membrane (termed voltage-dependent gating) and, less commonly, in response to specific ligand molecules binding to the extracellular or intracellular side of the channel (ligand-dependent gating) or in response to mechanical stress such as stretch, pressure, shear, or displacement (mechanosensitive gating).


Importantly, channel opening and closing are not instantaneous but usually take time. The transition from the resting (closed) state to the open state is called activation. Once opened, channels do not remain in the open state, but instead they undergo conformational transition in a time-dependent manner to a stable nonconducting (inactivated) state. Inactivated channels are incapable of reopening and must undergo recovery or reactivation process back to the resting state to regain their ability to open. Inactivation curves of the various voltage-gated ion channel types differ in their slopes and midpoints of inactivation and can overlap, in which case a steady-state or noninactivating current flows.


Ion channels differ with respect to the number of subunits of which they are composed and other aspects of structure. Many ion channels function as part of macromolecular complexes in which many components are assembled at specific sites within the membrane. For most ion channels, the pore-forming subunit is called the α subunit, whereas the auxiliary subunits are denoted β, γ, and so on. Most ion channels have a single pore; however, some have two.


It is important to note that although cardiomyocytes generally last the entire human lifetime, the half-lives of ion channels at the membrane are on the order of hours. The life cycle of cardiac ion channels encompasses many processes, starting from DNA transcription to translation into proteins, protein modification, protein oligomerization, channel transport to specific subdomains of the cell membrane (a process known as forward trafficking), and finally internalization for degradation or recycling (i.e., retrograde trafficking). Given the quick turnover of channels, the intracellular forward trafficking of channels constitutes a key regulatory step in controlling the current density of specific channels and offers targets for therapeutic manipulation of channel function in the treatment of heart disease. In addition, genetic channelopathies can result not only from mutations affecting channel structure and function but also from mutations leading to perturbation of any of the molecular processes involved in channel trafficking.




Sodium Channels


Structure and Physiology


The cardiac Na + channel complex is composed of a primary α and multiple ancillary β subunits. The approximately 2000-amino-acid α subunit contains the channel’s ion-conducting pore and controls channel selectivity for Na + ions and voltage-dependent gating machinery. This subunit contains all the drug and toxin interaction sites identified to date.


Nine genes encode the α subunit of the Na + channel in humans (Na v 1.1 through Na v 1.9). Na v 1.5 is the principal cardiac isoform. Na v 1.8 and Na v 1.9 are primarily expressed peripheral sensory neurons, Na v 1.4 in skeletal muscle, and Na v 1.6 in the central nervous system.


Na v 1.5, encoded by the SCN5A gene, consists of four internally homologous domains (I to IV) that are connected to each other by cytoplasmic linkers ( Fig. 2.1 ). Each domain consists of six membrane-spanning segments (S1 to S6), connected to each other by alternating intracellular and extracellular peptide loops. The four domains are arranged in a fourfold circular symmetry to form the channel. The extracellular loops between S5 and S6 (termed the P segments) have a unique primary structure in each domain ( Fig. 2.2 ). The P segments curve back into the membrane to form an ion-conducting central pore whose structural constituents determine the selectivity and conductance properties of the Na + channel.




Fig. 2.1


The Sodium Channel Macromolecular Complex.

See text for discussion.

(From Boussy T, Paparella G, de Asmundis C, et al. Genetic basis of ventricular arrhythmias. Heart Fail Clin . 2010;6:249–266.)



Fig. 2.2


Transmembrane Organization of Sodium Channel Subunits.

The primary structures of the subunits of the voltage-gated ion channels are illustrated as transmembrane folding diagrams. Cylinders represent probable α-helical segments: S1 to S3, blue; S4, green; S5, orange; S6, purple; outer pore loop, shaded orange area. Bold lines represent the polypeptide chains of each subunit, with length approximately proportional to the number of amino acid residues in the brain sodium channel subtypes. The extracellular domains of the β1 and β2 subunits are shown as immunoglobulin-like folds. ψ shows sites of probable N -linked glycosylation. P represents sites of demonstrated protein phosphorylation by protein kinase A (red circles) and protein kinase C (red diamonds) ; h in the blue circle signifies an inactivation particle in the inactivation gate loop; the empty blue circles represent sites implicated in forming the inactivation gate receptor. The structure of the extracellular domain of the β subunits is illustrated as an immunoglobulin-like fold based on amino acid sequence homology to the myelin P0 protein. Sites of binding of α and β scorpion toxins (α-ScTx, β-ScTx) and a site of interaction between α and β1 subunits also are shown. H 3 N and NH 3 , Ammonia.

(From Caterall WA, Maier SK. Voltage-gated sodium channels and electrical excitability of the heart. In Zipes DP, Jalife J, eds. Cardiac Electrophysiology: From Cell to Bedside . 5th ed. Philadelphia: Saunders; 2009:9–17.)


Four auxiliary β subunits (Na v β1 to Na v β4, encoded by the genes SCN1B to SCN4B , respectively) have been identified; each is a glycoprotein with a single membrane-spanning segment. The β subunits modulate density, kinetics, voltage dependence of activation and inactivation, as well as surface expression of the Na + channel.


Na + channels are the typical example of voltage-gated ion channels. Na + channels switch among three functional states: deactivated (closed), activated (open), and inactivated (closed), depending on the membrane potential (E m ). These channel states control Na + ion permeability through the channel into the cardiomyocyte. Na + channel activation allows Na + ion influx into the cell, and inactivation blocks the entry of Na + ions.


On excitation of the cardiomyocyte by electrical stimuli from adjacent cells, its resting E m (approximately −85 mV) depolarizes. The positively charged S4 segment of each domain of the α subunit functions as the sensor of the transmembrane voltage; these segments are believed to undergo rapid structural conformational changes in response to membrane depolarization, thus leading to channel opening (activation) from its resting (closed) state and enabling a large and rapid influx of Na + (inward Na + current, I Na ) during the rapid upstroke (phase 0) of the action potential in atrial, ventricular, and Purkinje cardiomyocytes.


Normally, activation of Na + channels is transient; fast inactivation (closing of the pore) starts simultaneously with activation, but because inactivation is slightly slower than activation, the channels remain transiently open to conduct I Na during phase 0 of the action potential before it closes. Each Na + channel opens very briefly (less than 1 millisecond) during phase 0 of the action potential; collectively, activation of the channels lasts a few milliseconds and is followed by fast inactivation.


Na + channel inactivation comprises different conformational states, including fast, intermediate, and slow inactivation. Fast inactivation is at least partly mediated by rapid occlusion of the inner mouth of the pore by the cytoplasmic interdomain linker between domains III and IV of the α subunit, which has a triplet of hydrophobic residues that likely functions as a hinged “latch” that limits or restricts Na + ions from passing through the pore. The carboxyl terminus (C-terminus) also plays an important role in the control of Na + channel inactivation and stabilizing the channels in the inactivated state by interacting with the loop linking domains III and IV. Of note, although most Na + channels open before inactivating, some actually inactivate without ever opening (a process known as closed-state inactivation).


Once inactivated, Na + channels do not conduct any more current and cannot be reactivated (reopened) until after recovery from inactivation. The recovery of the Na + channel to reopen is voltage dependent. Channel inactivation is removed when the E m of the cell repolarizes during phase 4 of the action potential. The recovery of channels from inactivation is also time dependent; Na + channels typically activate within 0.2 to 0.3 milliseconds and inactivate completely within 2 to 5 milliseconds.


Following recovery, Na + channels enter a closed state that represents a nonconducting conformation, which allows the channels to be activated again during the next action potential. The fraction of channels available for opening varies from almost 100% at a membrane potential of −90 mV and 50% at an E m of −75 mV to almost 0% at +40 mV. Consequently, highly polarized (−80 to −90 mV) cell membranes can be depolarized rapidly by stimuli because more Na + channels reopen, whereas partially depolarized cells with potentials close to threshold −70 mV generate a much slower upstroke because of the inactivation of a proportion of Na + channels. Given that Na + channels are major determinants of conduction velocity, this velocity generally slows at a reduced E m .


Na + channel activation, inactivation, and recovery from inactivation occur within a few milliseconds. At the end of phase 1 of the action potential, more than 99% of Na + channels transit from an open (activated) state to an inactivated state. However, very few Na + channels are not inactivated and may reactivate (reopen) during phase 3 of the action potential. The small current produced by these channels (less than 1% of the peak I Na ) is called the “window current” because it arises when the sarcolemma reaches a potential that is depolarized sufficiently to reactivate some channels, but not enough to cause complete inactivation. The voltage range for the window current is very restricted and narrow in healthy hearts, thus granting it a small role during the cardiac action potential.


In addition to these rapid gating transitions, Na + channels are also susceptible to slower inactivating processes (slow inactivation) if the membrane remains depolarized for a longer time. These slower events can contribute to the availability of active channels under various physiological conditions. Whereas fast-inactivated Na + channels recover rapidly (within 10 milliseconds) during the hyperpolarized interval between stimuli, slow inactivation requires much longer recovery times (ranging from hundreds of milliseconds to many seconds). The molecular movements leading to slow inactivation are less well understood. The P segments seem to play a key role in slow inactivation.


Some Na + channels occasionally show alternative gating modes consisting of isolated brief openings occurring after variable and prolonged latencies and bursts of openings, during which the channel opens repetitively for hundreds of milliseconds. The isolated brief openings are the result of occasional failure of inactivation. Prolonged opening or reopening of some Na + channels during phases 2 and 3 can result in a small late Na + current (I NaL ). Despite its minor contribution in healthy hearts, I NaL can potentially play an important role in diseased hearts.


Function


Na + channels play a pivotal role in the initiation, propagation, and maintenance of the normal cardiac rhythm. The I Na determines excitability and conduction in atrial, His-Purkinje system (HPS), and ventricular myocardium. On membrane depolarization, the voltage-gated Na + channels respond within a millisecond by opening, thus leading to the very rapid depolarization of the cardiac cell membrane (phase 0 of the action potential), reflected by the fast (within tenths of a microsecond) subsequent opening of Na + channels triggering the excitation-contraction coupling. Na + entry during phase 0 of the action potential also modulates intracellular Na + levels and, through Na + -Ca 2+ exchange, intracellular Ca 2+ concentration and cell contraction.


Na + channel also plays a crucial role in the propagation of action potentials throughout the atrium, HPS, and ventricles. The opening of Na + channels in the atria underlies the P wave on the electrocardiogram (ECG), and in the ventricles I Na underlies the QRS complex and enables a synchronous ventricular contraction. Because the upstroke of the electrical potential primarily determines the speed of conduction between adjacent cells, Na + channels are present in abundance in tissues where speed is of importance. Cardiac Purkinje cells contain up to 1 million Na + channels, a finding that illustrates the importance of rapid conductance in the heart.


Na + channels also make a contribution in the plateau phase (phase 2) and help determine the duration of the action potential. After phase 0 of the action potential, I Na decreases to less than 1% of its peak value over the next several milliseconds because of voltage-dependent inactivation. This persistent or “late” inward I Na (I NaL ), along with the L-type Ca 2+ current (I CaL ), helps maintain the action potential plateau.


Furthermore, inactivation of the Na + channel is very important, as it prevents cells from being prematurely reexcited. With repolarization, the Na + channel normally recovers rapidly from inactivation (within 10 milliseconds) and is ready to open again. Hence Na + channels help determine the frequency of action potential firing. To a lesser extent, cardiac Na + channels are also present in the sinus node and the atrioventricular node (AVN), where they contribute to pacemaker activity.


Regulation


The regulatory proteins interacting with Na v 1.5 ( Fig. 2.3 ) can be classified as follows: (1) anchoring-adaptor proteins (e.g., ankyrin-G, syntrophin proteins, multicopy suppressor of gsp1 [MOG1]), which play roles only in trafficking and targeting the channel protein in specific membrane compartments; (2) enzymes interacting with and modifying the channel structure (posttranslational modifications), such as protein kinases or ubiquitin ligases; and (3) proteins modulating the biophysical properties of Na v 1.5 on binding (e.g., caveolin-3, calmodulin, glycerol 3-phosphate dehydrogenase 1–like [G3PD1L], telethonin, Plakophilin-2). Coexpression of Na v 1.5 with its β subunits induces acceleration in the recovery from inactivation and enhancement of I Na amplitude.




Fig. 2.3


Topology of Na V 1.5 and Its Interaction With Various Regulatory Proteins.

The pore-forming α subunit of Na V 1.5 consists of four homologous domains (DI to DIV), connected together by intracellular and extracellular loops. Several regulatory proteins for Na V 1.5 are identified and their sites of interaction have been mapped on the α subunit of the Na V 1.5 channel. Many of these interactions are shown to take place at the intracellular loops or the C-terminus of Na V 1.5. For a few proteins that have been shown to associate with Na V 1.5, the sites of interaction on the Na V 1.5 channel are still unknown. CaMKII , Ca 2+ -calmodulin-dependent kinase II; FGF13 , fibroblast growth factor 13; GPD1-L , glycerol-3-phosphate dehydrogenase 1-like; MOG1 , multicopy suppressor of gsp1.

(From Shy D, Gillet L, Abriel H. Cardiac sodium channel Na v 1.5 distribution in myocytes via interacting proteins: the multiple pool model. Biochim Biophys Acta . 2013;1833:886–894.)


The cardiac Na + channels are subject to phosphorylation and dephosphorylation by kinases or phosphatases. The intracellular linker between domains I and II contains eight consensus sites for cyclic adenosine monophosphate (cAMP)–dependent protein kinase A (PKA) phosphorylation. cAMP-dependent PKA and G protein stimulatory α subunit (Gsα) modulate the function of expressed cardiac Na + channels on β-adrenergic stimulation and enhance I Na .


In contrast, the activation of α-adrenergic stimulating protein kinase C (PKC) results in the attenuation of I Na . The effect of PKC is largely attributable to phosphorylation of a highly conserved serine in the linker between domains III and IV. PKC reduces the maximal conductance of the channels and alters gating. Na + channels exhibit a hyperpolarizing shift in the steady-state availability curve, suggesting an enhancement of inactivation from closed states.


All subunits of the Na + channel are modified by glycosylation. The β1 and β2 subunits are heavily glycosylated, with up to 40% of the mass being carbohydrate. In contrast, the α subunit is only 5% sugar by weight. Sialic acid is a prominent component of the N-linked carbohydrate of the Na + channel. The addition of such a highly charged carbohydrate has predictable effects on the voltage dependence of gating through alteration of the surface charge of the channel protein.


Pharmacology


Na + channels are the targets for the action of class I antiarrhythmic drugs. Na + channel blockers bind to a specific receptor within the channel’s pore. The binding blocks ion movement through the pore and stabilizes the inactivated state of Na + channels. Blockade of Na + channels tends to decreased tissue excitability and conduction velocity (by attenuating peak I Na ) and can shorten action potential duration (by attenuating late I Na ).


One important component in the action of antiarrhythmic drugs is a voltage-dependent change in the affinity of the drug-binding site (i.e., the channel is a modulated receptor). In addition, restricted access to binding sites can contribute to drug action, a phenomenon that has been called the guarded receptor model. Open and inactivated channels are more susceptible to block than resting channels, likely because of a difference in binding affinity or state-dependent access to the binding site. Consequently, binding of antiarrhythmic drugs occurs primarily during the action potential (known as use-dependent block), and the block dissipates after repolarization (i.e., in the interval between action potentials). When the time interval between depolarizations is insufficient for block to recover before the next depolarization occurs (secondary to either abbreviation of the interval between action potentials during fast heart rates or slow kinetics of the unbinding of the Na + channel blocker), block of Na + channels accumulates (resulting in an increased number of blocked channels and enhanced blockade). A drug with rapid kinetics produces less channel block with the subsequent depolarization than a drug with slower recovery. Use-dependent block is important for the action of antiarrhythmic drugs because it allows strong drug effects during fast heart rates associated with tachyarrhythmias but limits Na + channel block during normal heart rates. This property is known as use-dependence and is seen most frequently with the class IC agents, less frequently with the class IA drugs, and rarely with the class IB agents. Importantly, drug recovery kinetics can potentially be slowed by pathophysiological conditions such as membrane depolarization, ischemia, and acidosis.


Class I antiarrhythmic drugs are classified into three groups according to rates of drug binding to and dissociation from the channel receptor. Class IC drugs (flecainide and propafenone) block both the open and inactivated Na + channels (which is induced by membrane depolarization) and have the slowest kinetics of unbinding during diastole. The results are prolongation of conduction at normal heart rates and a further increase in the effect at more rapid rate (use-dependence).


The class IB agents (lidocaine, mexiletine, and tocainide) block both open and inactivated Na + channels and dissociate from the channel more rapidly than other class I drugs. As a consequence, class IB drugs exhibit minimal or no effects on the Na + channels in normal tissue but cause significant conduction slowing in depolarized tissue, especially at faster depolarization rates. Furthermore, class IB drugs are less effective in the atrium, where the action potential duration is so short that the Na + channel is in the inactivated state only briefly compared with the relatively long diastolic recovery times; thus accumulation of block is less likely to result from the rapid recovery of block.


Class IA drugs (quinidine, procainamide, and disopyramide) exhibit open state block, have intermediate effects on Na + channels, and generally only cause significant prolongation of conduction in cardiac tissue at rapid heart rates. Because the open state block is dominant and recovery from block is slow, these drugs are effective in both the atrium (where action potential duration is short) and the ventricle.


Importantly, class IA drugs also have moderate K + channel blocking activity (which tends to slow the rate of repolarization and prolong the action potential duration) and anticholinergic activity, and they tend to depress myocardial contractility. At slower heart rates, when use-dependent blockade of I Na is not significant, K + channel blockade becomes predominant (reverse use-dependence), leading to prolongation of the action potential duration and QT interval and increased automaticity. Flecainide and propafenone also have K + channel blocking activity and can increase the action potential duration in ventricular myocytes. Propafenone has significant β-adrenergic blocking activity.


The late I Na (I NaL ) also can be a target for blockade. Several drugs exhibit relative selectivity for block of I NaL over peak I Na , including mexiletine, flecainide, lidocaine, amiodarone, and ranolazine.


Inherited Channelopathies


Mutations in genes that encode various subunits of the cardiac Na + channel or proteins involved in regulation of the inward I Na have been linked to several types of electrical disorders ( Table 2.1 ). Depending on the mutation, the consequence is either a gain of channel function (with consequent prolongation of action potential duration because more positive ions accumulate in the cell) or an overall loss of channel function that influences the initial depolarizing phase of the action potential (with consequent decrease in cardiac excitability and electrical conduction velocity). It is noteworthy that a single mutation can cause different phenotypes or combinations thereof. The pathophysiology and clinical presentation of those channelopathies are discussed in detail in Chapter 31 .



TABLE 2.1

Inherited Cardiac Sodium Channelopathies














































































































































































Clinical Phenotype Gene Protein Functional Effect
Long QT Syndrome (LQTS)
LQT3 SCN5A Na v 1.5 ↑ late or sustained I Na
LQT9 CAV3 Caveolin-3 ↑ sustained I Na
LQT10 SCN4B Na v β4 ↑ sustained I Na
LQT12 SNTA1 α1-syntrophin ↑ sustained I Na
Brugada Syndrome (BrS)
BrS1 SCN5A Na v 1.5 ↓ I Na
BrS2 GPD1L G3PD1L ↓ I Na
BrS5 SCN1B Na v β1 ↓ I Na
BrS7 SCN3B Na v β3 ↓ I Na
BrS11 RANGRF MOG1, Na v 1.5 cofactor ↓ I Na
BrS12 SLAMP Sarcolemmal associated protein ↓ I Na
BrS14 SCN2B Na v β2 ↓ I Na
BrS15 PKP2 Plakophillin-2 ↓ I Na
BrS16 FGF12 Fibroblast growth factor homologous factor-1 ↓ I Na
BrS17 SCN10A Na v 1.8 ↓ I Na
BrS18 HEY2 Transcriptional factor ↑ I Na
Early Repolarization Syndrome (ERS)
ERS6 SCN5A Na v 1.5 ↓ I Na
ERS7 SCN10A Na v 1.8 ↓ I Na
Progressive Cardiac Conduction Disease
SCN5A Na v 1.5 ↓ I Na
SCN1B Na v β3 ↓ or ↑ I Na
Congenital Sick Sinus Syndrome
SCN5A Na v 1.5 ↓ I Na
Atrial Standstill
SCN5A Na v 1.5 ↓ I Na
Familial Atrial Fibrillation
SCN5A Na v 1.5 Different and discordant molecular phenotypes
SCN1B Na v β1 Different and discordant molecular phenotypes
SCN2B Na v β2 Different and discordant molecular phenotypes
Dilated Cardiomyopathy
SCN5A Na v 1.5 Different and discordant molecular phenotypes
Sudden Infant Death Syndrome
SCN5A Na v 1.5 ↓ I Na
CAV3 Caveolin-3 ↓ I Na
GPD1L G3PD1L ↑ late I Na
SCN5A Overlap Syndromes
SCN5A Na v 1.5 ↓ or ↑ I Na

I Na , Sodium current.


Long QT Syndrome


Type 3 congenital long QT syndrome (LQTS; LQT3), which accounts for approximately 5% to 10% of congenital LQTS cases, is caused by gain-of-function mutations in the SCN5A gene, which encodes the α subunit of the Na + channel (Na v 1.5), SCN5A . More than 200 mutations have been identified in SCN5A , with most being missense mutations mainly clustered in Na v 1.5 regions that are involved in fast inactivation (i.e., S4 segment of domain IV, the domain III–domain IV linker, and the cytoplasmic loops between the S4 and S5 segments of domain III and domain IV), or in regions that stabilize fast inactivation (e.g., the C-terminus).


Several mechanisms have been identified to underlie ionic effects of SCN5A mutations in LQT3 ( see eFigs. 31.1 and 31.2 ). Most SCN5A mutations cause a gain of function through disruption of fast inactivation, thus allowing repeated reopening during sustained depolarization and resulting in an abnormal, small, but functionally important sustained (or persistent) noninactivating Na + current (Isus) during action potential plateau. Because the general membrane conductance is small during the action potential plateau, the presence of a persistent inward I Na , even of small amplitude, can potentially have a major impact on the plateau duration and can be sufficient to prolong repolarization and QT interval. QT prolongation and the risk of developing arrhythmia are more pronounced at slow heart rates, when the action potential duration is longer, thereby allowing more I Na to enter the cell.


Other less common mechanisms of SCN5A mutations to cause LQT3 include increased window current, which results from delayed inactivation of mutant Na + channels, occurring at more positive potentials and widening the voltage range during which the Na + channel may reactivate without inactivation. In addition, some mutations cause slower inactivation, which allows longer channel openings and causes a slowly inactivating I Na . This current is I NaL and is to be distinguished from Isus (which does not inactivate). Comparable to Isus, both the window current and I NaL exert their effects during phases 2 and 3 of the action potential, in which normally no or very little I Na is present. Other mutations induce prolonged action potential duration by enhancing recovery from inactivation, an effect that leads to larger peak I Na by increasing the fraction of channels available for activation (because of faster recovery) during subsequent depolarizations. Finally, some mutations can cause increased expression of mutant Na v 1.5 through enhanced messenger RNA (mRNA) translation or protein trafficking to the sarcolemma, decreased protein degradation, or altered modulation by β subunits and regulatory proteins. These effects lead to larger I Na density during phase 0 of the action potential. Importantly, one single SCN5A mutation can potentially cause several changes in the expression and/or gating properties of the resulting Na + channels.


Regardless of the mechanism, increased Na + current (Isus, window current, I NaL , or peak I Na ) upsets the balance between depolarizing and repolarizing currents in favor of depolarization. The resulting delay in the repolarization process triggers early afterdepolarizations (EADs) by reactivation of the L-type Ca 2+ channel during phase 2 or 3 of the action potential, especially in Purkinje fiber myocytes, in which action potential durations are intrinsically longer. Compared with other LQT subtypes, patients with LQT3 are particularly at risk for sudden cardiac death (SCD), and cardiac arrest is often the first clinical event.


LQT9 is caused by gain-of-function mutations on the CAV3 gene, which encodes caveolin-3, a plasma membrane scaffolding protein that interacts with Na v 1.5 and plays a role in compartmentalization and regulation of channel function. Mutations in CAV3 induce kinetic alterations of the Na v 1.5 current that result in persistent Na + current (Isus) and have been reported in cases of sudden infant death syndrome (SIDS).


LQT10 is caused by loss-of-function mutations on the SCN4B gene, which encodes the β subunit (Na v β4) of the Na v 1.5 channel. These mutations likely cause a shift in the inactivation of the I Na toward more positive potentials, resulting in increased window currents at an E m corresponding to phase 3 of the action potential.


LQT12 is caused by mutations on the SNTA1 gene, which encodes α1 syntrophin, a cytoplasmic adaptor protein that enables the interaction among Na v 1.5, nitric oxide synthase, and the sarcolemmal Ca 2+ adenosine triphosphatase (ATPase) complex that appears to regulate ion channel function. By disrupting the interaction between Na v 1.5 and the sarcolemmal Ca 2+ ATPase complex, SNTA1 mutations cause increased Na v 1.5 nitrosylation with consequent reduction of channel inactivation and enhanced Isus densities.


Brugada Syndrome


Brugada syndrome is an autosomal dominant inherited channelopathy characterized by an elevated ST segment or J wave appearing in the right precordial leads. This syndrome is associated with a high incidence of SCD secondary to a rapid polymorphic ventricular tachycardia (VT) or ventricular fibrillation (VF). Approximately 65% of mutations identified in the SCN5A gene are associated with the Brugada syndrome phenotype (Brugada syndrome type 1), and they account for approximately 11% to 28% of cases of Brugada syndrome. So far, more than 300 Brugada syndrome–associated loss-of-function (i.e., reduced peak I Na ) mutations have been described in SCN5A . Some of these mutations result in loss of function secondary to impaired channel trafficking to the cell membrane (i.e., reduced expression of functional Na + channels), disrupted ion conductance (i.e., expression of nonfunctional Na + channels), or altered gating function. Altered gating properties comprise delayed activation (i.e., activation at more positive potentials), earlier inactivation (i.e., inactivation at more negative potentials), faster inactivation, and enhanced slow inactivation.


Most of the mutations are missense mutations, whereby a single amino acid is replaced by a different amino acid. Missense mutations commonly alter the gating properties of mutant channels. Because virtually all reported SCN5A mutation carriers are heterozygous, mutant channels with altered gating may cause up to a 50% reduction of I Na . Different SCN5A mutations can cause different degrees of I Na reduction and therefore different degrees of severity of the clinical phenotype of Brugada syndrome.


In addition to SCN5A mutations, reduction in I Na can be caused by mutations in SCN1B (encoding the β1 and β1b subunits of the Na + channel), SCN2B (encoding the β2 subunit), and SCN3B (encoding the β3 subunit), resulting in the clinical phenotype of Brugada syndrome. Recently, SCN10A (which encodes Na v 1.8, a neuronal Na + channel that appears to play a role in the heart) was identified as a major susceptibility gene for Brugada syndrome (identified in 16.7% of probands). Loss-of-function mutations in SCN10A lead to significant reduction in I Na .


Furthermore, mutations in GPD1L (which encodes the protein G3PD1L protein) affect the trafficking of the cardiac Na + channel to the cell surface, resulting in reduction of I Na and Brugada syndrome. The Brugada phenotype associated with GPD1L mutations is characterized by progressive conduction disease, low sensitivity to procainamide, and a relatively good prognosis.


Mutations in several other genes have been reported to cause reduction in I Na and lead to the Brugada phenotype, including HEY2 (encoding the transcriptional factor HEY2), FGF12 (encoding for a fibroblast growth factor homologous factor-1, which exerts modulatory effects on cardiac Na + and Ca 2+ channels), PKP2 (encoding the desmosomal protein plakophillin-2, a known susceptibility gene for arrhythmogenic right ventricular cardiomyopathy [ARVC]), RANGRF (encoding MOG1, a protein known to modulate the Na + channel), and SLMAP (encoding the sarcolemmal membrane–associated protein, SLMAP, a component of T-tubules and sarcoplasmic reticulum).


Early Repolarization Syndrome


Loss-of-function mutations in the α1 subunit of Na v 1.5 and Na v 1.8 ( SCN5A , SCN10A ) have been reported in patients with early repolarization syndrome.


Familial Progressive Cardiac Conduction Disease


Loss-of-function SCN5A mutations have been linked to familial forms of progressive cardiac conduction disease (referred to as hereditary Lenègre disease, primary cardiac conduction system disease, and familial AV block). This disease is characterized by slowing of electrical conduction through the atria, AVN, His bundle, Purkinje fibers, and ventricles, accompanied by an age-related degenerative process and fibrosis of the cardiac conduction system, in the absence of structural or systemic disease. It is often reflected by varying degrees of AV block and bundle branch block. Whether the age-dependent fibrosis of the conduction system is a primary degenerative process in progressive cardiac conduction disease or a physiological process that is accelerated by I Na reduction remains to be established. A single loss-of-function SCN5A mutation can cause isolated progressive cardiac conduction disease or can be combined with the Brugada syndrome (overlap syndrome). Loss-of-function mutations in SCN1B also have been identified in patients with progressive cardiac conduction disease who carried no mutation in SCN5A .


Congenital Sick Sinus Syndrome


Although I Na does not play a prominent role in sinus node activity, mutations in SCN5A have been linked to sick sinus syndrome, manifesting as sinus bradycardia, sinus arrest, sinoatrial block, or a combination of these conditions, which can progress to atrial inexcitability (atrial standstill). Loss-of-function SCN5A mutations result in reduced peak I Na density, hyperpolarizing shifts in the voltage dependence of steady-state channel availability, and slow recovery from inactivation. These effects likely cause reduced automaticity, decreased excitability, and conduction slowing or block of impulses generated in the sinus node to the surrounding atrial tissue. Sinus node dysfunction can also manifest concomitantly with other phenotypes that are linked to SCN5A loss-of-function mutations such as Brugada syndrome and progressive cardiac conduction disorders.


Familial Atrial Fibrillation


Loss-of-function mutations, gain-of-function mutations, and common polymorphisms on the SCN5A gene have been identified in some cases of atrial fibrillation (AF) occurring in young patients with structurally normal hearts. It is speculated that I Na reduction can predispose to AF by slowing the electrical conduction velocity and thereby facilitating reentry. On the other hand, gain-of-function mutations can potentially predispose to AF by increasing atrial excitability. AF can occur in patients with other phenotypes of Na + channelopathies, including LQT3, Brugada syndrome, dilated cardiomyopathy, and sinus node dysfunction. Furthermore, mutations in the SCN1B gene (encoding the β1 subunit of the Na + channel) and the SCN2B gene (encoding the β2 subunit of the Na + channel) have been identified in patients with AF, many of whom displayed ECG patterns suggestive of the Brugada syndrome.


Dilated Cardiomyopathy


Some cases of familial dilated cardiomyopathy have been linked to SCN5A mutations. Dilated cardiomyopathy–linked SCN5A mutations cause diverse loss-of-function and gain-of-function changes in the gating properties, but how such changes evoke contractile dysfunction is not understood. It is speculated that SCN5A mutations disrupt the interactions between the mutant Na + channels and intracellular (or extracellular) proteins that are essential for normal cardiomyocyte structure and architecture. Notably, dilated cardiomyopathy with SCN5A mutations often display atrial or ventricular arrhythmias (including AF, VT, and VF), sinus node dysfunction, AV block, and intraventricular conduction delay.


Sudden Infant Death Syndrome


Gain-of-function mutations in SCN5A may be the most prevalent genetic cause of SIDS. SCN5A mutations in SIDS commonly increase Isus. Less frequently, loss-of-function mutations in SCN5A or CAV3 and gain-of-function mutations in GPD1-L have also been found in infants with SIDS. However, it is possible that in these patients SIDS represents a malignant form of LQT3 or Brugada syndrome that manifests during infancy.


Overlap Syndrome


A single SCN5A mutation can result in multiple clinical phenotypes and rhythm disturbances within the same family, a phenomenon now referred to as “cardiac sodium channel overlap syndrome.” Not surprisingly, loss-of-function SCN5A mutations have often been associated with overlapping phenotypes of Brugada syndrome, sinus node dysfunction, and progressive cardiac conduction disorders, which all share similar underlying mechanisms that implicate I Na reduction. More surprisingly, some SCN5A mutations are associated with both BrS1 (I Na loss-of-function) and LQT3 (I Na gain-of-function). Carriers of these mutants present with BrS1, LQT3, or a mixed ECGs with both ST-segment abnormalities and QT elongation. These mutations are likely associated with altered gating properties in a manner that results in both reduction of the peak I Na and augmentation of the persistent I Na . Furthermore, it is likely that genetic background and clinical and environmental factors play a role in the variable disease expressivity and severity.


Acquired Diseases


In heart failure, peak I Na is reduced (likely secondary to reduced SCN5A expression), whereas I NaL is increased (likely because of increased phosphorylation of Na + channels). Na v 1.5 expression is reduced in the surviving myocytes in the border zone of the myocardial infarct. Importantly, Na + channel blockers can increase the risk for SCD in patients with ischemic heart disease, possibly by facilitating the initiation of reentrant excitation waves. In addition, I NaL increases during myocardial ischemia, explaining why I NaL inhibition may be an effective therapy for chronic stable angina. Na v 1.5 expression is reduced in response to persistent atrial tachyarrhythmias as part of the “electrical remodeling” process, leading to attenuation of I Na .


Furthermore, mutations in SCN5A can predispose affected individuals to acquired LQTS induced by a variety of drugs such as antihistamines or antibiotics. These mutations result in changes in channel activity that exert a significant impact on action potential duration only when combined with drug-induced alteration of other channels.




Potassium Channels


Structure and Physiology


Cardiac K + channels are membrane-spanning proteins that allow the passive movement of K + ions across the cell membrane along its electrochemical gradient. The ion-conducting or pore-forming subunit is generally referred to as the α subunit. The backbone carbonyl oxygen contributed by tripeptide sequence glycine-tyrosine-glycine plus the side-chain oxygens from threonine in the sequence TXGYG (where X represents a variable residue) is common to the pore of all K + channels and constitutes the signature motif for determining K + ion selectivity. A gating mechanism controls switching between open-conducting and closed-nonconducting states.


K + channels represent the most diverse class of cardiac ion channels ( Fig. 2.4 ). The diversity of K + currents in native tissues exceeds the number of K + channel genes identified. The explanations for this diversity include alternative splicing of gene products, posttranslational modification, and heterologous assembly of β subunits within the same family and assembly with accessory β subunits that modulate channel properties. Even small differences in channel composition give rise to significant functional diversity.




Fig. 2.4


Molecular Compositions of Cardiac Potassium (K + ) Channels.

Amino termini (N) and carboxyl termini (C) are indicated. (A) Voltage-gated (K v ) , inward rectifier (Kir) , and two-pore α subunits are integral membrane proteins with six, two, and four membrane-spanning domains, respectively. (B) These α subunits assemble as tetramers or dimers to form K + -selective pores.

(Modified from Oudit GY, Backx PH. Voltage-regulated potassium channels. In Zipes DP, Jalife J, eds. Cardiac Electrophysiology: From Cell to Bedside . 5th ed. Philadelphia: Saunders; 2009:29–42.)


Cardiac K + channels can be categorized as voltage-gated (K v ) and ligand-gated channels. In K v channels, pore opening is coupled to the movement of a voltage sensor within the membrane electric field, and they include the rapidly activating and inactivating transient outward current (I to ); the ultrarapid (I Kur ), rapid (I Kr ), and slow (I Ks ) components of the delayed rectifier current; and the inward rectifier current (I K1 ). In contrast, pore opening in ligand-gated channels is coupled to the binding of an organic molecule, including channels activated by a decrease in the intracellular concentration of adenosine triphosphate (K ATP ) or by acetylcholine (K ACh ). Other classes of K + channels respond to different stimuli, including changes in intracellular Ca 2+ concentration and G proteins.


On the basis of the primary amino acid sequence of the α subunit, K + channels have been classified into three major families ( Table 2.2 ):



  • 1.

    Channels containing six transmembrane segments and a single pore. This architecture is typical of K v channels.


  • 2.

    Channels containing two transmembrane segments (M1 and M2) and a single pore. This architecture is typical of inward rectifier K + (Kir) channels, including K1, K ATP , and K ACh channels. These channels conduct K + currents more in the inward direction than the outward and play an important role in setting the resting potential close to the equilibrium potential for K + and in repolarization. Kir channels form either homotetramers or heterotetramers.


  • 3.

    Channels containing four transmembrane segments and two pores (K 2P ). These channels exist as homodimers or heterodimers. K 2P currents display little time or voltage dependence.



TABLE 2.2

Genetic and Molecular Basis of Cardiac Potassium Currents






































































































































































Current α Subunit α Subunit Gene β Subunit/Accessory Proteins β Subunit Gene
Voltage-Gated Channels (K v )
I to,f K v 4.2 KCND2 MiRP1 KCNE2
K v 4.3 KCND3 MiRP2 KCNE3
KChIP1 KCNIP1
KChIP2 KCNIP2
DPP6 DPP6
I to,s K v 1.4 KCNA4 K v β1 KCNB1
K v 1.7 KCNA7 K v β2 KCNB2
K v β3 KCNB3
K v β4 KCNB4
I Kur K v 1.5 KCNA5 K v β1 KCNAB1
K v β2 KCNAB2
K v β3 KCNB3
I Kr K v 11.1 (HERG) KCNH2 minK KCNE1
MiRP1 KCNE2
MiRP2 KCNE3
I Ks K v 7.1 (K v LQT1) KCNQ1 minK KCNE1
MiRP1 KCNE2
MiRP2 KCNE3
MiRP3 KCNE4
MiRP4 KCNE5
Inward Rectifier Channels (Kir)
I K1 Kir2.1 KCNJ2 AKAP5 AKAP5
Kir2.2 KCNJ12
Kir2.3 KCNJ14
I KACh Kir3.1 (GIRK1) KCNJ3
Kir3.4 (GIRK4) KCNJ5
I KATP Kir6.1 KCNJ8 SUR1 ABCC8
Kir6.2 KCNJ11 SUR2 ABCC9
Two-Pore Channels (K 2P )
ITWIK-1 K 2P 1.1 (TWIK-1) KCNK1
ITASK-1 K 2P 3.1 (TASK-1) KCNK3
ITASK-3 K 2P 9.1 (TASK-3) KCNK9
ITALK-2 K 2P 17.1 (TALK-2) KCNK17
Calcium-Activated Channels (SK, KCa)
ISK KCa2.1 (SK1) KCNN1
KCa2.2 (SK2) KCNN2
KCa2.3 (SK3) KCNN3


Each voltage-gated K + channel (K v family) is formed by the coassembly of four identical (homotetramers) or a combination of four different (from the same subfamily, heterotetramers) α subunits (K v α). A total of 38 genes has been cloned and assigned to 12 subfamilies of K v α (K v 1 to K v 12) on the basis of sequence similarities. Most K v subfamilies contain many individual channel members (e.g., K v 1 has eight members, identified as K v 1.1 to K v 1.8, with gene designations KCNA1 to KCNA8 , respectively).


Each K v α contains one domain consisting of six membrane-spanning segments (S1 to S6), connected to each other by alternating intracellular and extracellular peptide loops (similar to one of the four domains of voltage-gated Na + and Ca 2+ channels), with both the amino terminus (N-terminus) and the C-terminus located on the intracellular side of the membrane. The central ion-conducting pore region is formed by the S5 and S6 segments and the S5-S6 linker (P segment); the S5-S6 linker is responsible for K + ion selectivity. The S4 segment serves as the voltage sensor.


K v α can generate voltage-dependent K + current when expressed in heterologous systems. However, the assembly of a functional tetramer can occur only in the presence of multiple auxiliary units (see Table 2.2 ). In many cases, auxiliary subunits coassociate with K v α and likely modulate cell surface expression, gating kinetics, and drug sensitivity of the α subunit complex. Most K + channel β subunits assemble with α subunits and give rise to an α4β4 complex. K + channel β subunits represent a diverse molecular group, which includes (1) cytoplasmic proteins (K v β1 to K v β4, KChIP, and KChAP) that interact with the intracellular domains of K v α; (2) single transmembrane spanning proteins (e.g., minK and minK-related proteins [MiRPs]) encoded by the KCNE gene family; and (3) large ATP-binding cassette (ABC) transport-related proteins (e.g., the sulfonylurea receptors [SURs]).


Similar to voltage-dependent Na + (Na v ) and Ca 2+ (Ca v ) channels, K v channels typically fluctuate among distinct conformational states because of molecular movements in response to voltage changes across the cell membrane (voltage-dependent gating). The K v channel activates (opens) on membrane depolarization, thus allowing the rapid passage of K + ions across the sarcolemma. After opening, the channel undergoes conformational transition in a time-dependent manner to a stable nonconducting (inactivated) state. Inactivated channels are incapable of reopening, even if the transmembrane voltage is favorable, unless they “recover” from inactivation (i.e., enter the closed state) on membrane repolarization. Closed (preopen) channels are nonconducting but can be activated on membrane depolarization.


Four mechanistically distinct types of K v channel inactivation that are associated with distinct molecular domains have been identified: N-type, C/P-type, AG-type, and U-type. N-type (“ball and chain”) inactivation involves physical occlusion of the intracellular mouth of the channel pore through binding of a small group of amino acids (“inactivation ball tethered to a chain”) at the extreme N-terminus.


C/P-type inactivation involves conformational changes in the external mouth of the pore. C/P-type inactivation exists in almost all K + channels and may reflect a slow constriction of the pore. This inactivation process is thought to be voltage independent, coupled to channel opening, and is usually slower than N-type inactivation. Recovery from C/P-type inactivation is relatively slow and weakly voltage dependent. Importantly, the rate of C/P-type inactivation and recovery can be strongly influenced by other factors. C/P-type inactivation is strongly accelerated by N-type inactivation, and is promoted by extracellular H + ions. Unlike N-type inactivation, C/P-type inactivation is prevented by extracellular K + ions binding to the face of the pore. These interactions render C/P-type inactivation an important biophysical process in regulating repetitive electrical activity and determining certain physiological properties such as refractoriness, drug binding, and sensitivity to extracellular ions.


AG-type inactivation involves conformational changes in S4 that inactivate K v channels directly from the closed (preopen) state. In addition, some K v channels also show another type of inactivation (U-type), which exhibits a U -shaped voltage dependence with prolonged stimulation rates. Those channels appear to exhibit preferential inactivation at intermediate depolarizing voltages (corresponding to preactivated closed state) than at more positive voltages (corresponding to the open state). The exact conformational changes underlying U-type inactivation remain unclear. Importantly, there is extreme diversity in the kinetic and potentially molecular properties of K v channel inactivation, particularly of C/P-type inactivation.


Function


K + channels are a diverse and ubiquitous group of membrane proteins that regulate K + ion flow across the cell membrane on the electrochemical gradient and regulate the resting E m , the frequency of pacemaker cells, and the shape and duration of the cardiac action potential. Because the concentration of K + ions outside the cell membrane is approximately 25-fold lower than that in the intracellular fluid, the opening of K + channels generates an outward current resulting from the efflux of positively charged ions that offers a mechanism to counteract, dampen, or restrict the depolarization front (phases 1 through 4 of the action potential) triggered by an influx of cations (Na + and Ca 2+ ).


The variation in the level of expression of K + channels that participate in the genesis of the cardiac action potential explains the regional differences of the configuration and duration of cardiac action potentials from sinus node and atrial to ventricular myocytes and across the myocardial wall (endocardium, midmyocardium, and epicardium). Moreover, the expression and properties of K + channels are not static; heart rate, neurohumoral state, pharmacological agents, cardiovascular diseases (cardiac hypertrophy and failure, myocardial infarction [MI]), and arrhythmias (e.g., AF) can influence those properties, and they underlie the change in action potential configuration in response to variation in heart rate and various physiological and pathological conditions.


Transient Outward Potassium Current


Structure and Physiology


Cardiac I to channels are macromolecular protein complexes, comprising four pore-forming K v α subunits and a variety of K v channel accessory (β) subunits (see Fig. 2.4 ). Two major types of I to have been characterized: (1) I to1 generated by voltage-dependent, Ca 2+ -independent K v channels; and (2) I to2 generated by Ca 2+ -activated Cl channels. In human atrial and ventricular myocytes, the presence of I to2 has not been clearly demonstrated.


I to1 (which is referred to as I to ) displays two phenotypes with distinct recovery kinetics: a rapid or fast I to (I to,fast or I to,f ) phenotype and a slower phenotype (I to,slow or I to,s ). The transient nature of I to is secondary to its rapid activation (with time constants of less than 10 milliseconds for both I to,f and I to,s ) and rapid inactivation (25 to 80 milliseconds for I to,f and 80 to 200 milliseconds for I to,s ). However, whereas I to,f recovers rapidly from inactivation (60 to 100 milliseconds), I to,s recovers slowly (with time constants on the order of seconds).


K v channels mediating I to,s are formed by the coassembly of four α subunits from the K v 1.x subfamily (primarily K v 1.4, and possibly K v 1.7), whereas those mediating I to,f are formed by the coassembly of four α subunits from the K v 4.x subfamily (primarily K v 4.3, and possibly K v 4.2) (see Table 2.2 ). Among the various accessory subunits identified, a crucial role has been definitively demonstrated only for KChIP2, and potentially for MiRP2.


Function


I to is a prominent repolarizing current; it partially repolarizes the membrane, shapes the rapid (phase 1) repolarization of the action potential, and sets the height of the initial plateau (phase 2). Thus the activity of I to channels influences the activation of voltage-gated L-type Ca 2+ channels and the balance of inward and outward currents during the plateau (mainly the L-type Ca 2+ current [I CaL ] and the delayed rectifier K + currents), thereby mediating the duration and the amplitude of phase 2.


The density of I to varies across the myocardial wall and in different regions of the heart. In human ventricles, I to densities are much higher in the epicardium and midmyocardium than in the endocardium. Furthermore, I to,f and I to,s are differentially expressed in the myocardium, thus contributing to regional heterogeneities in action potential waveforms. I to,f is the principal subtype expressed in human atrium. The markedly higher densities of I to,f , together with the expression of the ultrarapid delayed rectifier K + current, accelerate the early phase of repolarization and lead to lower plateau potentials and shorter action potentials in atrial as compared with ventricular cells. Due to its slow recovery kinetics, I to,s plays a limited role in repolarization compared to I to,f , especially at faster heart rates.


Although both I to,f and I to,s are expressed in the ventricle, I to,f is more prominent in the epicardium and midmyocardium (putative M cells) than in the endocardium, whereas I to,s is mainly present in the endocardium and Purkinje fiber cells. These regional differences are responsible for the shorter duration and the prominent phase 1 notch and the “spike-and-dome” morphology of epicardial and midmyocardial compared with endocardial action potentials. A prominent I to -mediated action potential notch in ventricular epicardium but not endocardium produces a transmural voltage gradient during early ventricular repolarization that registers as a J wave or J point elevation on the ECG. I to densities are also reportedly higher in right than in left (midmyocardial and epicardial) ventricular myocytes, consistent with the more pronounced spike-and-dome morphology of right, compared with left, ventricular action potentials, particularly in the epicardium.


Furthermore, variations in cardiac repolarization associated with I to regional differences strongly influence intracellular Ca 2+ transient by modulating Ca 2+ entry via the I CaL and Na + -Ca 2+ exchanger, thereby regulating excitation-contraction coupling and regional modulation of myocardial contractility and hence synchronizing the timing of force generation between different ventricular regions and enhancing mechanical efficiency.


Regulation


I to channels are subject to α- and β-adrenergic regulation. α-Adrenergic stimulation reduces I to ; concomitant β-adrenergic stimulation appears to counteract the α-adrenergic effect, at least in part. The effects of α- and β-adrenergic stimulation are exerted by phosphorylation of the K v 1.4, K v 4.2, and K v 4.3 α-subunits by PKA as well as PKC. Calmodulin-dependent kinase II, on the other hand, has been shown to be involved in enhancement of I to . Adrenergic stimulation is also an important determinant of transient outward channel downregulation in cardiac disease. Chronic α-adrenergic stimulation and angiotensin II reduce I to channel expression, which explains channel downregulation in many types of chronic heart disease.


KChIP2, when coexpressed with K v 4.3, increases surface channel density and current amplitude, slows channel inactivation, and markedly accelerates the recovery from inactivation. In the ventricle, KChIP2 mRNA is 25-fold more abundant in the epicardium than in the endocardium. This gradient parallels the gradient in I to expression, whereas K v 4.3 mRNA is expressed at equal levels across the ventricular wall. Thus transcriptional regulation of the KChIP2 gene is the primary determinant of I to expression in the ventricular wall.


Observations suggest that MiRP2 is required for the physiological functioning of human I to,f channels and that gain-of-function mutations in MiRP2 predispose to Brugada syndrome through augmentation of I to,f .


I to is strongly rate dependent. I to fails to recover from previous inactivation at very fast heart rates; thus tachycardia is associated with reduction of I to , which can be manifest as a decrease in the magnitude of the J wave on the surface ECG. Hence abrupt changes in rate and pauses have important consequences for the early repolarization of the membrane.


I to can be enhanced by aging, low sympathetic activity, high parasympathetic activity, bradycardia, hypothermia, and drugs. Estrogen suppresses the expression of the K v 4.3 channel and results in reduced I to and a shallow phase 1 notch.


Phase 1 notch of the action potential modulates the kinetics of slower activating ion currents and consequently the later phases of the action potential. Initial enhancement of phase 1 notch promotes phase 2 dome and delays repolarization, presumably by delaying the peak of I CaL . However, further enhancement of phase 1 notch prevents the rising of phase 2 dome and abbreviates action potential duration, presumably by deactivation or voltage modulation that reduces I CaL . Thus progressive deepening of phase 1 notch can cause initial enhancement followed by sudden disappearance of phase 2 dome and corresponding prolongation followed by abbreviation of action potential duration. On the other hand, modulators that decrease I to lead to a shift of the plateau phase into the positive range of potentials, thus increasing the activation of the delayed rectifier currents, promoting faster repolarization, and reducing the electrochemical driving force for Ca 2+ and hence I CaL . Phase 1 notch also affects the function of the Na + -Ca 2+ exchanger and subsequently intracellular Ca 2+ handling and Na + channel function.


Pharmacology


Quinidine, 4-aminopyridine, flecainide, and propafenone produce an open channel blockade and accelerate I to inactivation. Quinidine, but not flecainide or propafenone, produces a frequency-dependent block of I to that results from a slow rate of drug dissociation from the channel. Quinidine has relatively strong I to blocking effect, whereas flecainide mildly blocks I to .


I to blockers can potentially prolong the action potential duration in the atrium and in ischemic ventricular myocardium. However, because the net effects of I to blockade on repolarization depend on secondary changes in other currents, the reduction of I to density can result in a shortening of the ventricular action potential. Moreover, heterogeneous ventricular distribution of I to can cause marked dispersion of repolarization across the ventricular wall that, when accompanied by prominent conduction delays related to Na + channel blockade, results in extrasystolic activity through a phase 2 reentrant mechanisms.


Currently no cardioselective and channel-specific I to openers or blockers are available for clinical use. Development of an I to -selective drug is expected to be beneficial in patients with primary abnormality in the I to or in other channels, such as the Brugada syndrome, in which heterogeneity in the expression of I to between epicardium and endocardium in the RV results in the substrate responsible for reentry and ventricular arrhythmias.


Inherited Channelopathies


Gain-of-function mutations in KCND3 (which encodes the α-subunit of of the I to channel [K v 4.3]) and KCNE3 (which encodes the auxiliary β subunit [MiRP2]) result in an increase in I to density and cause Brugada syndrome. Furthermore, gain-of-function mutations in SCN1B (which encodes the auxiliary β1 subunit of the Na + channel), in addition to reducing I Na , can also increase I to . Mutations in SEMA3A (which encodes semaphorin) were also implicated in Brugada syndrome by increasing I to .


In addition, gain-of-function mutations in KCND3 and KCNE3 have been linked to familial AF. KCNE3 mutations were found to increase I to,f and were postulated to cause AF by shortening action potential duration and facilitating atrial reentrant excitation waves ( Table 2.3 ).



TABLE 2.3

Inherited Cardiac Potassium Channelopathies

































































































































































Clinical Phenotype Gene Protein Functional Effect
Long QT Syndrome (LQTS)
LQT1 KCNQ1 (K v LQT1) K v 7.1 ↓ I Ks
LQT2 KCNH2 (HERG) K v 11.1 ↓ I Kr
LQT5 KCNE1 MinK ↓ I Ks
LQT6 KCNE2 MiRP1 ↓ I Kr
LQT7 (Andersen-Tawil syndrome) KCNJ2 Kir2.1 ↓ I K1
LQT11 AKAP9 Yotiao ↓ I Ks
LQT13 KCNJ5 Kir3.4 (GIRK4) ↓ I KACh
Brugada Syndrome (BrS)
BrS6 KCNE3 MiRP2 ↑ I to
BrS8 KCNJ8 Kir6.1 ↑ I KATP
BrS10 KCND3 K v 4.3 ↑ I to
BrS13 ABCC9 SUR2A ↑ I KATP
BrS19 SEMA3A Semaphorin ↑ I to
Short QT Syndrome (SQTS)
SQT1 KCNH2 (HERG) K v 11.1 ↑ I Kr
SQT2 KCNQ1 (K v LQT1) K v 7.1 ↑ I Ks
SQT3 KCNJ2 Kir2.1 ↑ I K1
Early Repolarization Syndrome (ERS)
ERS1 KCNJ8 Kir6.1 ↑ I KATP
ERS 5 ABCC9 SUR2A ↑ I KATP
Catecholaminergic Polymorphic Ventricular Tachycardia Phenocopy
KCNJ8 Kir2.1 ↓ I K1
Familial Atrial Fibrillation
KCNE1 MinK ↑ I Ks
KCNE2 MiRP1 ↑ I Kr
KCNE3 MiRP2 ↑ I to /↑ I Kr
KCNQ1 (K v LQT1) K v 7.1 ↑ I Ks
KCND3 K v 4.3 ↑ I to
KCNJ2 Kir2.1 ↑ I K1
KCNA5 K v 1.5 ↓ K ur
KCNJ5 Kir3.4 (GIRK4) ↓ K ACh
ABCC9 SUR2A ↓ K ATP
KCNK3 K 2P 3.1 (TASK-1) ↓ ITASK-1

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Jun 17, 2019 | Posted by in CARDIOLOGY | Comments Off on Cardiac Ion Channels

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