Hiroko Izumi-Nakaseko

Epac1-dependent phospholamban phosphorylation mediates the cardiac response to stresses

PKA phosphorylates multiple molecules involved in calcium (Ca2+) handling in cardiac myocytes and is considered to be the predominant regulator of β-adrenergic receptor-mediated enhancement of cardiac contractility; however, recent identification of exchange protein activated by cAMP (EPAC), which is independently activated by cAMP, has challenged this paradigm. Mice lacking Epac1 (Epac1 KO) exhibited decreased cardiac contractility with reduced phospholamban (PLN) phosphorylation at serine-16, the major PKA-mediated phosphorylation site. In Epac1 KO mice, intracellular Ca2+ storage and the magnitude of Ca2+ movement were decreased; however, PKA expression remained unchanged, and activation of PKA with isoproterenol improved cardiac contractility. In contrast, direct activation of EPAC in cardiomyocytes led to increased PLN phosphorylation at serine-16, which was dependent on PLC and PKCε. Importantly, Epac1 deletion protected the heart from various stresses, while Epac2 deletion was not protective. Compared with WT mice, aortic banding induced a similar degree of cardiac hypertrophy in Epac1 KO; however, lack of Epac1 prevented subsequent cardiac dysfunction as a result of decreased cardiac myocyte apoptosis and fibrosis. Similarly, Epac1 KO animals showed resistance to isoproterenol- and aging-induced cardiomyopathy and attenuation of arrhythmogenic activity. These data support Epac1 as an important regulator of PKA-independent PLN phosphorylation and indicate that Epac1 regulates cardiac responsiveness to various stresses.

T-type Ca2+ channels promote oxygenation-induced closure of the rat ductus arteriosus not only by vasoconstriction but also by neointima formation

The ductus arteriosus (DA), an essential vascular shunt for fetal circulation, begins to close immediately after birth. Although Ca2+ influx through several membrane Ca2+ channels is known to regulate vasoconstriction of the DA, the role of the T-type voltage-dependent Ca2+ channel (VDCC) in DA closure remains unclear. Here we found that the expression of α1G, a T-type isoform that is known to exhibit a tissue-restricted expression pattern in the rat neonatal DA, was significantly up-regulated in oxygenated rat DA tissues and smooth muscle cells (SMCs). Immunohistological analysis revealed that α1G was localized predominantly in the central core of neonatal DA at birth. DA SMC migration was significantly increased by α1G overexpression. Moreover, it was decreased by adding α1G-specific small interfering RNAs or using R(−)-efonidipine, a highly selective T-type VDCC blocker. Furthermore, an oxygenation-mediated increase in an intracellular Ca2+ concentration of DA SMCs was significantly decreased by adding α1G-specific siRNAs or using R(−)-efonidipine. Although a prostaglandin E receptor EP4 agonist potently promoted intimal thickening of the DA explants, R(−)-efonidipine (10−6 m) significantly inhibited EP4-promoted intimal thickening by 40% using DA tissues at preterm in organ culture. Moreover, R(−)-efonidipine (10−6 m) significantly attenuated oxygenation-induced vasoconstriction by ∼27% using a vascular ring of fetal DA at term. Finally, R(−)-efonidipine significantly delayed the closure of in vivo DA in neonatal rats. These results indicate that T-type VDCC, especially α1G, which is predominantly expressed in neonatal DA, plays a unique role in DA closure, implying that T-type VDCC is an alternative therapeutic target to regulate the patency of DA.

Essential, Completely Conserved Glycine Residue in the Domain III S2–S3 Linker of Voltage-gated Calcium Channel α1 Subunits in Yeast and Mammals

Voltage-gated Ca2+ channels (VGCCs) mediate the influx of Ca2+ that regulates many cellular events, and mutations in VGCC genes cause serious hereditary diseases in mammals. The yeast Saccharomyces cerevisiae has only one gene encoding the putative pore-forming α1 subunit of VGCC, CCH1. Here, we identify a cch1 allele producing a completely nonfunctional Cch1 protein with a Gly1265 to Glu substitution present in the domain III S2–S3 cytoplasmic linker. Comparison of amino acid sequences of this linker among 58 VGCC α1 subunits from 17 species reveals that a Gly residue whose position corresponds to that of the Cch1 Gly1265 is completely conserved from yeasts to humans. Systematic amino acid substitution analysis using 10 amino acids with different chemical and structural properties indicates that the Gly1265 is essential for Cch1 function because of the smallest residue volume. Replacement of the Gly959 residue of a rat brain Cav1.2 α1 subunit (rbCII), positionally corresponding to the yeast Cch1 Gly1265, with Glu, Ser, Lys, or Ala results in the loss of Ba2+ currents, as revealed by the patch clamp method. These results suggest that the Gly residue in the domain III S2–S3 linker is functionally indispensable from yeasts to mammals. Because the Gly residue has never been studied in any VGCC, these findings provide new insights into the structure-function relationships of VGCCs.

Disruption of Stard10 gene alters the PPARα-mediated bile acid homeostasis.

STARD10, a member of the steroidogenic acute regulatory protein (StAR)-related lipid transfer (START) protein family, is highly expressed in the liver and has been shown to transfer phosphatidylcholine. Therefore it has been assumed that STARD10 may function in the secretion of phospholipids into the bile. To help elucidate the physiological role of STARD10, we produced Stard10 knockout mice (Stard10(-/-)) and studied their phenotype. Neither liver content nor biliary secretion of phosphatidylcholine was altered in Stard10(-/-) mice. Unexpectedly, the biliary secretion of bile acids from the liver and the level of taurine-conjugated bile acids in the bile were significantly higher in Stard10(-/-) mice than wild type (WT) mice. In contrast, the levels of the secondary bile acids were lower in the liver of Stard10(-/-) mice, suggesting that the enterohepatic cycling is impaired. STARD10 was also expressed in the gallbladder and small intestine where the expression level of apical sodium dependent bile acid transporter (ASBT) turned out to be markedly lower in Stard10(-/-) mice than in WT mice when measured under fed condition. Consistent with the above results, the fecal excretion of bile acids was significantly increased in Stard10(-/-) mice. Interestingly, PPARα-dependent genes responsible for the regulation of bile acid metabolism were down-regulated in the liver of Stard10(-/-) mice. The loss of STARD10 impaired the PPARα activity and the expression of a PPARα-target gene such as Cyp8b1 in mouse hepatoma cells. These results indicate that STARD10 is involved in regulating bile acid metabolism through the modulation of PPARα-mediated mechanism.

Effects of selective IKr channel blockade by E-4031 on ventricular electro-mechanical relationship in the halothane-anesthetized dogs

An inversion of electro-mechanical coupling: namely, mechanical relaxation which precedes electrical repolarization, has been proposed as a surrogate marker to predict the occurrence of drug-induced arrhythmias. The present study was designed to qualitatively and quantitatively clarify the effects of rapidly activating delayed rectifier K+ current (IKr)-selective blockade by E-4031 on the electro-mechanical relationship in vivo. We adopted the halothane-anesthetized canine model (n=4). E-4031 in doses of 0.01 and 0.1 mg/kg that can provide the plasma concentrations effectively to inhibit IKrin vitro significantly delayed the repolarization beyond the initiation of diastole, resulting in the inversion of electro-mechanical coupling, which provides an ideal proarrhythmic substrate, while the durations of left ventricular systole and diastole remained the same. Since these observed changes were solely caused by the repolarization delay, the inversion of electro-mechanical coupling may have a similar extent of sensitivity to QT-interval prolongation as a surrogate marker in predicting the onset of IKr inhibitor-induced arrhythmias.

Characterization of human iPS cell-derived cardiomyocyte sheets as a model to detect drug-induced conduction disturbance

In order to characterize human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) sheets as a model for detecting drug-induced conduction disturbance, we examined their electrophysiological and electropharmacological properties by using the multi-electrode array system with a programmed electrical stimulation protocol. At pre-drug control, the conduction speed, effective refractory period and field potential duration were 0.14 ± 0.01 m/sec, 453 ± 10 msec and 361 ± 9 msec, respectively at a cycle length of 1,000 msec (n = 18). Shortening the pacing cycle length from 1,000 to 600 msec decreased the conduction speed and field potential duration, but prolonged the effective refractory period. Disopyramide, lidocaine and flecainide decreased the conduction speed but prolonged the effective refractory period and field potential duration, whereas the reverse was true for verapamil. Thus, conduction properties of the cell sheet may largely depend on the extent of Na+ channel availability as is the case in the human ventricle. Importantly, there was no relationship between the conduction delay and 1st spike amplitude reduction after the treatment of Na+ channel blockers. These findings may provide crucial guide on future application of this new technology for early phase safety pharmacological screening of new chemical entities.

Analysis of Onset Mechanisms of a Sphingosine 1-Phosphate Receptor Modulator Fingolimod-Induced Atrioventricular Conduction Block and QT-Interval Prolongation

Fingolimod, a sphingosine 1-phosphate (S1P) receptor subtype 1, 3, 4 and 5 modulator, has been used for the treatment of patients with relapsing forms of multiple sclerosis, but atrioventricular conduction block and/or QT-interval prolongation have been reported in some patients after the first dose. In this study, we directly compared the electropharmacological profiles of fingolimod with those of siponimod, a modulator of sphingosine 1-phosphate receptor subtype 1 and 5, using in vivo guinea-pig model and in vitro human ether-a-go-go-related gene (hERG) assay to better understand the onset mechanisms of the clinically observed adverse events. Fingolimod (0.01 and 0.1mg/kg) or siponimod (0.001 and 0.01mg/kg) was intravenously infused over 10min to the halothane-anaesthetized guinea pigs (n=4), whereas the effects of fingolimod (1μmol/L) and siponimod (1μmol/L) on hERG current were examined (n=3). The high doses of fingolimod and siponimod induced atrioventricular conduction block, whereas the low dose of siponimod prolonged PR interval, which was not observed by that of fingolimod. The high dose of fingolimod prolonged QT interval, which was not observed by either dose of siponimod. Meanwhile, fingolimod significantly inhibited hERG current, which was not observed by siponimod. These results suggest that S1P receptor subtype 1 in the heart could be one of the candidates for fingolimod- and siponimod-induced atrioventricular conduction block since S1P receptor subtype 5 is localized at the brain, and that direct IKr inhibition may play a key role in fingolimod-induced QT-interval prolongation.

Antiviral drug vidarabine possessing cardiac type 5 adenylyl cyclase inhibitory property did not affect cardiohemodynamic or electrophysiological variables in the halothane-anesthetized dogs

Vidarabine has been used for the treatment of patients with local and systemic herpes virus infection; moreover, it was recently reported that it inhibits cardiac type 5 adenylyl cyclase. Furthermore, vidarabine has been shown to suppress atrial fibrillation and improve congestive heart failure in experimental models of mice induced by the isoproterenol infusion. Since information that can explain its experimentally demonstrated efficacy against congestive heart failure and atrial fibrillation remains limited, in this study we precisely assessed cardio-electropharmacological effect using the halothane-anesthetized canine model. Vidarabine was intravenously administrated in three escalating doses of 1, 10, 100 mg/kg over 10 min with a pause between the doses (n = 4). Meanwhile, the vehicle dimethyl sulfoxide in volumes of 0.033, 0.033 and 0.33 mL/kg was intravenously administrated in the same manner as was vidarabine (n = 4). No significant difference was detected in any cardiohemodynamic or electrophysiological variables between the vehicle- and vidarabine-treated groups, which indicates that effective doses of vidarabine adequately inhibiting type 5 adenylyl cyclase did not affect the cardiovascular variables in vivo at all, showing its cardiac safety profile under physiological condition. Thus, the clinical utility of vidarabine might be limited to the pathological situation including congestive heart failure with increased adrenergic tone and/or sympathetic nerve-dependent atrial fibrillation.

Possible effects of inhibition of IKr and IKs on field-potential waveforms in the human iPS cell-derived cardiomyocytes sheet.

In order to investigate how IKr and IKs inhibitions affect waveforms of the field potential in the human iPS cell-derived cardiomyocytes sheet, we analyzed the effects of E-4031 and chromanol 293B on the maximum upslope and peak amplitude of its second wave (n = 7 for each drug). E-4031 in 10-100 nM as well as chromanol 293B in 3-30 μM prolonged the field-potential duration, whereas E-4031 decreased the upslope in 10-100 nM and amplitude at 100 nM, which was not observed by chromanol 293B. Thus, the decrease of the upslope can be used as a supplemental marker of drug-induced IKr inhibition.

Electropharmacological effects of amantadine on cardiovascular system assessed with J-Tpeak and Tpeak-Tend analysis in the halothane-anesthetized beagle dogs.

Since amantadine-induced long QT syndrome has been clinically reported, we investigated its electropharmacological effects to estimate the extent of proarrhythmic risk by using the halothane-anesthetized beagle dogs (n = 4). Amantadine in doses of 0.1, 1 and 10 mg/kg was infused over 10 min with a pause of 20 min under the monitoring of multiple cardiovascular variables. J-Tpeak and Tpeak-Tend were separately measured on the lead II electrocardiogram to precisely analyze the net balance between inward and outward current modifications by amantadine. The low dose increased the ventricular contractile force, but suppressed the intraventricular conduction. The middle dose prolonged the QT interval besides enhancing the changes induced by the low dose. The high dose increased the mean blood pressure, left ventricular end-diastolic pressure and total peripheral resistance, and accelerated the atrioventricular nodal conduction, but decreased the cardiac output besides enhancing the changes induced by the middle dose. A reverse use-dependence was confirmed in the repolarization delay. Amantadine hardly affected the J-Tpeak, but prolonged the Tpeak-Tend. Amantadine can be considered to stimulate Ca(2+) channel but inhibit Na(+) and K(+) channels in the in situ heart. J-Tpeak and Tpeak-Tend analysis suggests that amantadine may possess modest risk for arrhythmia.