Thermal adaptation of the crucian carp (Carassius carassius) cardiac delayed rectifier current, IKs, by homomeric assembly of Kv7.1 subunits without MinK.

Ectothermic vertebrates experience acute and chronic temperature changes which affect cardiac excitability and may threaten electrical stability of the heart. Nevertheless, ectothermic hearts function over wide range of temperatures without cardiac arrhythmias, probably due to special molecular adaptations. We examine function and molecular basis of the slow delayed rectifier K(+) current (I(Ks)) in cardiac myocytes of a eurythermic fish (Carassius carassius L.). I(Ks) is an important repolarizing current that prevents excessive prolongation of cardiac action potential, but it is extremely slowly activating when expressed in typical molecular composition of the endothermic animals. Comparison of the I(Ks) of the crucian carp atrial myocytes with the currents produced by homomeric K(v)7.1 and heteromeric K(v)7.1/MinK channels in Chinese hamster ovary cells indicates that activation kinetics and pharmacological properties of the I(Ks) are similar to those of the homomeric K(v)7.1 channels. Consistently with electrophysiological properties and homomeric K(v)7.1 channel composition, atrial transcript expression of the MinK subunit is only 1.6-1.9% of the expression level of the K(v)7.1 subunit. Since activation kinetics of the homomeric K(v)7.1 channels is much faster than activation of the heteromeric K(v)7.1/MinK channels, the homomeric K(v)7.1 composition of the crucian carp cardiac I(Ks) is thermally adaptive: the slow delayed rectifier channels can open despite low body temperatures and curtail the duration of cardiac action potential in ectothermic crucian carp. We suggest that the homomeric K(v)7.1 channel assembly is an evolutionary thermal adaptation of ectothermic hearts and the heteromeric K(v)7.1/MinK channels evolved later to adapt I(Ks) to high body temperature of endotherms.

Readthrough of nonsense mutation W822X in the SCN5A gene can effectively restore expression of cardiac Na+ channels.

AIMS: Nonsense mutations in the SCN5A gene result in truncated, non-functional derivatives of the cardiac Na+ channel and thus cause arrhythmias. Studies of other genes suggest that pathogenic phenotypes of nonsense mutations may be alleviated by enhancing readthrough, which enables ribosomes to ignore premature termination codons and produce full-length proteins. Thus, we studied the functional restoration of nonsense-mutated SCN5A. METHODS AND RESULTS: HEK293 cells were transfected with SCN5A cDNA or its mutant carrying W822X, a nonsense mutation associated with Brugada syndrome and sudden cardiac death. The effects of readthrough-enhancing reagents on Na+ channel expression and function were examined in the transfected cells. W822X robustly reduced Na+ current, decreasing maximal Na+ current to <3% of the wild-type level, and inhibited the expression of full-length Na+ channels. When readthrough was enhanced by either reducing translational fidelity with aminoglycosides or decreasing translation termination efficiency with small-interfering RNA against eukaryotic release factor eRF3a, Na+ current of the mutant was restored to approximately 30% of the wild-type level; western blot and immunochemical staining analyses showed the increased expression of full-length channels. When the wild-type and mutant cDNAs were co-transfected, readthrough-enhancing reagents increased Na+ current from 56% to 74% of the wild-type level. Analysis of Na+ channel kinetics showed that the channels expressed from the mutant cDNA under readthrough-enhancing conditions retained the functions of wild-type channels. CONCLUSION: Readthrough-enhancing reagents can effectively suppress SCN5A nonsense mutations and may restore the expression of full-length Na+ channels with normal functions, which might prevent sudden cardiac death in mutation carriers.

A novel inwardly rectifying K+ channel, Kir2.5, is upregulated under chronic cold stress in fish cardiac myocytes.

A new member of the inward-rectifier K(+) channel subfamily Kir2 was isolated and characterised from the crucian carp (Carassius carassius) heart. When expressed in COS-1 cells this 422 amino acid protein produced an inward-rectifying channel with distinct single-channel conductance, mean open time and open probability. Phylogenetic sequence comparisons indicate that it is not homologous to any known vertebrate Kir channel, yet belongs to the Kir2 subfamily. This novel crucian carp channel increases the number of vertebrate Kir2 channels to five, and has therefore been designated as ccKir2.5 (cc for Carassius carassius). In addition to the ccKir2.5 channel, the ccKir2.2 and ccKir2.1 channels were expressed in the crucian carp heart, ccKir2.1 being present only in trace amounts (<0.8% of all Kir2 transcripts). Whole-cell patch clamp in COS-1 cells demonstrated that ccKir2.5 is a stronger rectifier than ccKir2.2 or ccKir2.1, and therefore passes weakly outward current. Single-channel conductance, mean open time and open probability of ccKir2.5 were, respectively, 1.6, 4.96 and 4.17 times as large as that of ccKir2.2. ccKir2.5 was abundantly expressed in atrium and ventricle of the heart and in skeletal muscle, but was a minor component of Kir2 in brain, liver, gill and kidney. Noticeably, ccKir2.5 was strongly responsive to chronic cold exposure. In fish reared at 4 degrees C for 4 weeks, ccKir2.5 mRNA formed 59.1+/-2.1% and 65.6+/-3.2% of all ccKir2 transcripts in atrium and ventricle, respectively, while in fish maintained at 18 degrees C the corresponding transcript levels were only 16.2+/-1.7% and 23.3+/-1.7%. The increased expression of ccKir2.5 at 4 degrees C occurred at the expense of ccKir2.2, which was the main Kir2 isoform in 18 degrees C acclimated fish. A cold-induced increase in the slope conductance of the ventricular I K1 from 707+/-49 to 1001+/-59 pS pF(-1) (P<0.05) was thus associated with an isoform shift from ccKir2.2 towards ccKir2.5, suggesting that ccKir2.5 is a cold-adapted and ccKir2.2 a warm-adapted isoform of the inward-rectifying K+ channel.

Seasonal acclimatization of brain lipidome in a eurythermal fish (Carassius carassius) is mainly determined by temperature.

Crucian carp (Carassius carassius) is an excellent vertebrate model for studies on temperature adaptation in biological excitable membranes, since the species can tolerate temperatures from 0 to +36 degrees C. To determine how temperature affects the lipid composition of brain, the fish were acclimated for 4 wk at +30, +16, or +4 degrees C in the laboratory, or seasonally acclimatized individuals were captured from the wild throughout the year (temperature = +1 to +23 degrees C), and the brain glycerophospholipid and sphingolipid compositions were analyzed in detail by electrospray-ionization mass spectrometry. Numerous significant temperature-related changes were found in the molecular species composition of the membrane lipids. The most notable and novel finding was a large (approximately 3-fold) increase of the di-22:6n-3 phosphatidylserine and phosphatidylethanolamine species in the cold. Since the increase of 22:6n-3 in the total fatty acyl pool of the brain was small, the formation of di-22:6n-3 aminophospholipid species appears to be a specific adaptation to low temperature. Such highly unsaturated species could be needed to maintain adequate membrane fluidity in the vicinity of transporters and other integral membrane proteins. Plasmalogens increased somewhat at higher temperatures, possibly to protect membranes against oxidation. The modifications of brain lipidome during the 4-wk laboratory acclimation were, in many respects, similar to those found in the wild, which indicates that the seasonal changes observed in the wild are temperature dependent rather than induced by other environmental factors.

Molecular and clinical characterization of a novel SCN5A mutation associated with atrioventricular block and dilated cardiomyopathy.

BACKGROUND: Increased susceptibility to dilated cardiomyopathy has been observed in patients carrying mutations in the SCN5A gene, but the underlying mechanism remains unclear. In this study, we identified and characterized, both in vitro and clinically, an SCN5A mutation associated with familial progressive atrioventricular block of adult onset and dilated cardiomyopathy in a Chinese family. METHODS AND RESULTS: Among 32 family members, 5 were initially diagnosed with atrioventricular block after age 30; 4 were studied, 3 of whom later developed dilated cardiomyopathy. We found a heterozygous single-nucleotide mutation resulting in an amino acid substitution (A1180V) in all studied patients and in 6 other younger unaffected members but not in 200 control chromosomes. When expressed with the beta1 subunit, the mutated channels exhibited a -4.5-mV shift of inactivation with slower recovery leading to a rate-dependent Na(+) current reduction and a moderate increase in late Na(+) current. Clinical study revealed that although QRS duration decreased with increasing heart rate in noncarrier family members, this change was blunted in unaffected carriers whose ECG and heart function were normal. Resting corrected QT interval of unaffected carriers was significantly longer than that of noncarriers, even though it was still within the normal range. CONCLUSIONS: A1180V expresses a mild Na(+) channel phenotype in vitro and a corresponding clinical phenotype in unaffected mutation carriers, implying that A1180V caused structural heart disease in affected carriers by disturbing Na(+) influx and, hence, cellular Na(+) homeostasis. The high penetrance of A1180V suggests this phenotype as a high risk factor for dilated cardiomyopathy with preceding atrioventricular block.

Effect of temperature and prolonged anoxia exposure on electrophysiological properties of the turtle (Trachemys scripta) heart.

Cardiac activity of the turtle (Trachemys scripta) is greatly depressed with cold acclimation and anoxia. We examined what electrophysiological modifications accompany and perhaps facilitate this depression of cardiac activity. Turtles were first acclimated to 21 degrees C or 5 degrees C and held under either normoxic or anoxic (6 h at 21 degrees C; 14 days at 5 degrees C) conditions. We then measured cardiac action potentials (APs) using spontaneously contracting whole heart preparations and whole cell current densities of sarcolemmal ion channels using isolated ventricular myocytes under appropriate normoxic and anoxic conditions. Compared with 21 degrees C-acclimated turtles, 5 degrees C-acclimated turtles exhibited a less negative resting membrane potential (by 18-29 mV), a 4.7- to 6.8-fold slower AP upstroke rate, and a 4.2- to 4.9-fold greater AP duration. Correspondingly, peak densities of ventricular voltage-gated Na(+) (I(Na)) and L-type Ca(2+) currents and inward slope conductances of inward rectifier K(+) (I(K1)) channel current were approximately 1/7th (Q(10) = 3.4), 1/13th (Q(10) = 5.0), and one-half (Q(10) = 1.4) of those of 21 degrees C-acclimated ventricular myocytes, respectively. With anoxia at 21 degrees C, peak I(Na) density doubled and ventricular AP duration increased by 47%, a change proportional to the reported approximately 30% reduction of intrinsic heart rate. In contrast, with anoxia at 5 degrees C, ventricular AP characteristics were unaffected; of the ion currents investigated, only the inward conductance via I(K1) changed significantly (reduced by 46%). The present findings indicate that cold temperature, more so than prolonged anoxia, results in substantial modifications of cardiac APs and reduction of ventricular ion current densities. These changes likely prepare cardiac muscle for winter anoxia conditions.

Cloning and expression of cardiac Kir2.1 and Kir2.2 channels in thermally acclimated rainbow trout.

Potassium currents are plastic entities that modify electrical activity of the heart in various physiological conditions including chronic thermal stress. We examined the molecular basis of the inward rectifier K+ current (IK1) in rainbow trout acclimated to cold (4 degrees C, CA) and warm (18 degrees C, WA) temperature. Inward rectifier K+ channel (Kir)2.1 and Kir2.2 transcripts were expressed in atrium and ventricle of the trout heart, K(ir)2.1 being the major component in both cardiac chambers. The relative expression of Kir2.2 was, however, higher (P < 0.05) in atrium than ventricle. The density of ventricular IK1 was approximately 25% larger (P < 0.05) in WA than CA trout. Furthermore, the IK1 of the WA trout was 10 times more sensitive to Ba2+ (IC50 0.18 +/- 0.42 microM) than the IK1 of the CA trout (1.17 +/- 0.44 microM) (P < 0.05), and opening kinetics of single Kir2 channels was slower in WA than CA trout (P < 0.05). When expressed in COS-1 cells, the homomeric Kir2.2 channels demonstrated higher Ba2+ sensitivity (2.88 +/- 0.42 microM) than Kir2.1 channels (24.99 +/- 7.40 microM) (P < 0.05). In light of the different Ba2+ sensitivities of rainbow trout (om)Kir2.1 and omKir2.2 channels, it is concluded that warm acclimation increases either number or activity of the omK(ir)2.2 channels in trout ventricular myocytes. The functional changes in I(K1) are independent of omKir2 transcript levels, which remained unaltered by thermal acclimation. Collectively, these findings suggest that thermal acclimation modifies functional properties and subunit composition of the trout Kir2 channels, which may be needed for regulation of cardiac excitability at variable temperatures.

Sarcolemmal ion currents and sarcoplasmic reticulum Ca2+ content in ventricular myocytes from the cold stenothermic fish, the burbot (Lota lota).

The burbot (Lota lota) is a cold stenothermic fish species whose heart is adapted to function in the cold. In this study we use whole-cell voltage-clamp techniques to characterize the electrophysiological properties of burbot ventricular myocytes and to test the hypothesis that changes in membrane currents and intracellular Ca2+ cycling associated cold-acclimation in other fish species are routine for stenothermic cold-adapted species. Experiments were performed at 4 degrees C, which is the body temperature of burbot for most of the year, and after myocytes were acutely warmed to 11 degrees C, which is in the upper range of temperatures experienced by burbot in nature. Results on K+ channels support our hypothesis as the relative density of K-channel conductances in the burbot heart are similar to those found for cold-acclimated cold-active fish species. I(K1) conductance was small (39.2+/-5.4 pS pF(-1) at 4 degrees C and 71.4+/-1.7 pS pF(-1) at 11 degrees C) and I(Kr) was large (199+/-27 pS pF(-1) at 4 degrees C and 320.3+/-8 pS pF(-1) at 11 degrees C) in burbot ventricular myocytes. We found high Na+-Ca2+ exchange (NCX) activity (35.9+/-6.3 pS pF(-1) at 4 degrees C and 58.6+/-8.4 pS pF(-1) at 11 degrees C between -40 and 20 mV), suggesting that it may be the primary pathway for sarcolemmal (SL) Ca2+ influx in this species. In contrast, the density (I(Ca), 0.81+/-0.13 pA pF(-1) at 4 degrees C, and 1.35+/-0.18 pA pF(-1) at 11 degrees C) and the charge (Q(Ca), 0.24+/-0.043 pC pF(-1) at 4 degrees C and 0.21+/-0.034 pC pF(-1) at 11 degrees C) carried by the L-type Ca2+ current was small. Our results on sarcolemmal ion currents in burbot ventricular myocytes suggest that cold stenothermy and compensative cold-acclimation involve many of the same subcellular adaptations that culminate in enhanced excitability in the cold.

Seasonal changes in glycogen content and Na+-K+-ATPase activity in the brain of crucian carp.

Changes in the number of Na+-K+-ATPase alpha-subunits, Na+-K+-ATPase activity and glycogen content of the crucian carp (Carassius carassius) brain were examined to elucidate relative roles of energy demand and supply in adaptation to seasonal anoxia. Fish were collected monthly around the year from the wild for immediate laboratory assays. Equilibrium dissociation constant and Hill coefficient of [3H]ouabain binding to brain homogenates were 12.87+/-2.86 nM and -1.18+/-0.07 in June and 11.93+/-2.81 nM and -1.17+/-0.06 in February (P>0.05), respectively, suggesting little changes in Na+-K+-ATPase alpha-subunit composition of the brain between summer and winter. The number of [3H]ouabain binding sites and Na-K-ATPase activity varied seasonally (P<0.001) but did not show clear connection to seasonal changes in oxygen content of the fish habitat. Six weeks' exposure of fish to anoxia in the laboratory did not affect Na+-K+-ATPase activity (P>0.05) confirming the anoxia resistance of the carp brain Na pump. Although anoxia did not suppress the Na pump, direct Q10 effect on Na+-K+-ATPase at low temperatures resulted in 10 times lower catalytic activity in winter than in summer. Brain glycogen content showed clear seasonal cycling with the peak value of 203.7+/-16.1 microM/g in February and a 15 times lower minimum (12.9+/-1.2) in July. In winter glycogen stores are 15 times larger and ATP requirements of Na+-K+-ATPase at least 10 times less than in summer. Accordingly, brain glycogen stores are sufficient to fuel brain function for about 8 min in summer and 16 h in winter, meaning about 150-fold extension of brain anoxia tolerance by seasonal changes in energy supply-demand ratio.

Activation-coupled inactivation in the bacterial potassium channel KcsA.

X-ray structures of the bacterial K+ channel KcsA have led to unparalleled progress in our understanding of ion channel structures. The KcsA channel has therefore been a prototypic model used to study the structural basis of ion channel function, including the gating mechanism. This channel was previously found to close at near-neutral intracellular pH (pH(i)) and to open at acidic pH(i). Here, we report the presence of a previously unknown channel inactivation process that occurs after the KcsA channel is activated. In our experiments, mammalian cells transfected with a codon-optimized synthetic gene encoding the KcsA protein expressed K+-selective channels that activated in response to a decrease in pH(i). Using patch-clamp and rapid solution exchange techniques, we observed that the KcsA channels inactivated within hundreds of milliseconds after channel activation. At all tested pHs, inactivation always accompanied activation, and it was profoundly accelerated in the same pH range at which activation increased steeply. Recovery from inactivation was observed, and its extent depended on the pH(i) and the amount of time that the channel was inactive. KcsA channel inactivation can be described by a kinetic model in which pH(i) controls inactivation through pH-dependent activation. This heretofore-undocumented inactivation process increases the complexity of KcsA channel function, but it also offers a potential model for studying the structural correspondence of ion channel inactivation.

Seasonality of dihydropyridine receptor binding in the heart of an anoxia-tolerant vertebrate, the crucian carp (Carassius carassius L.).

Prolonged anoxia tolerance of facultative anaerobes is based on metabolic depression and thus on controlled reduction of energy-utilizing processes. One proposed survival mechanism is the closing of ion channels to decrease energetic cost of ion pumping (Hochachka PW. Science 231: 234-241, 1986). To test this hypothesis, the involvement of L-type Ca2+ channels in seasonal anoxia tolerance of the vertebrate heart was examined by determining the number of [methyl-3H]PN200-110 (a ligand of L-type Ca2+ channel alpha-subunit) binding sites of the cardiac tissue and the density of Ca2+ current in ventricular myocytes of an anoxia-resistant fish species, the crucian carp. In their natural environment, the fish were exposed for > 3 mo of hypoxia (O2 < 2.5 mg/l) followed by almost 8 wk of anoxia that resulted in abrupt depletion of cardiac glycogen stores in late spring. Unexpectedly, however, the number of [methyl-3H]PN200-110 binding sites did not decline in hypoxia/anoxia as predicted by the channel arrest hypothesis but remained constant for most of the year. However, in early summer, the number of [methyl-3H]PN200-110 binding sites doubled for a period of approximately 2 mo, which functionally appeared as a 74% larger Ca2+ current density. Thus the anoxia tolerance of the carp heart cannot be based on downregulation of Ca2+ channel units in myocytes but is likely to depend on suppressed heart rate, i.e., regulation of the heart at the systemic level, and direct depressive effects of low temperature on Ca2+ current to achieve savings in cardiac work load and ion pumping. The summer peak in the number of functional Ca2+ channels indicates a short period of high cardiac activity possibly associated with reproduction and active perfusion of tissues after the winter stresses.

Regulation of action potential duration under acute heat stress by I(K,ATP) and I(K1) in fish cardiac myocytes.

The mechanism underlying temperature-dependent shortening of action potential (AP) duration was examined in the fish (Carassius carassius L.) heart ventricle. Acute temperature change from +5 to +18 degrees C (heat stress) shortened AP duration from 2.8 +/- 0.3 to 1.3 +/- 0.1 s in intact ventricles. In 56% (18 of 32) of enzymatically isolated myocytes, heat stress also induced reversible opening of ATP-sensitive K+ channels and increased their single-channel conductance from 37 +/- 12 pS at +8 degrees C to 51 +/- 13 pS at +18 degrees C (Q10 = 1.38) (P < 0.01; n = 12). The ATP-sensitive K+ channels of the crucian carp ventricle were characterized by very low affinity to ATP both at +8 degrees C [concentration of Tris-ATP that produces half-maximal inhibition of the channel (K1/2)= 1.35 mM] and +18 degrees C (K1/2 = 1.85 mM). Although acute heat stress induced ATP-sensitive K+ current (IK,ATP) in patch-clamped myocytes, similar heat stress did not cause any glibenclamide (10 microM)-sensitive changes in AP duration in multicellular ventricular preparations. Examination of APs and K+ currents from the same myocytes by alternate recording under current-clamp and voltage-clamp modes revealed that changes in AP duration were closely correlated with temperature-specific changes in the voltage-dependent rectification of the background inward rectifier K+ current IK1. In approximately 15% of myocytes (4 out of 27), IK,ATP-dependent shortening of AP followed the IK1-induced AP shortening. Thus heat stress-induced shortening of AP duration in crucian carp ventricle is primarily dependent on IK1. IK,ATP is induced only in response to prolonged temperature elevation or perhaps in the presence of additional stressors.

The induction of an ATP-sensitive K(+) current in cardiac myocytes of air- and water-breathing vertebrates.

Opening of ATP-sensitive potassium channels (K(ATP)) is an effective cardioprotective mechanism in mammals. The amplitude of the ATP-sensitive K(+) current (I(K,ATP)) and the opening sensitivity of K(ATP) channels are, however, poorly known in ectotherms. As O(2)-sensing mechanisms and reactions to O(2) deficiency differ in aquatic and terrestrial animals, we hypothesised that the response of K(ATP) channels to metabolic inhibition would be different between air- and water-breathers. We therefore compared I(K,ATP) in ventricular myocytes of an anoxia-sensitive (Oncorhynchus mykiss) and an anoxia-tolerant fish (Carassius carassius), two amphibians (Xenopus laevis and Rana temporaria) and a terrestrial reptile (Lacerta vivipara) using the whole-cell patch-clamp method. I(K,ATP) was induced by preventing mitochondrial and/or glycolytic ATP production and perfusing myocytes with an ATP-free pipette solution. All species had a glibenclamide-sensitive I(K,ATP), but the current amplitude was much greater in air-breathers than in water-breathers. Furthermore, the I(K,ATP) in air-breathers was more sensitive to intracellular ATP depletion than in water-breathing animals. These findings indicate that I(K,ATP) is larger and more easily induced in air- than water-breathers. In all ectotherms, the first response to complete metabolic inhibition was the induction of a large inward current, the amplitude of which exceeded that of I(K,ATP). Thus, the protective effect of the I(K,ATP) may be physiologically significant only during partial metabolic blockade.