Increased susceptibility to atrial tachyarrhythmia in spontaneously hypertensive rat hearts.

Although hypertension is the most prevalent risk factor for atrial fibrillation, there is currently no information available from animal models of hypertension regarding the development of atrial remodeling or increased susceptibility to atrial tachyarrhythmia. Therefore, we examined the susceptibility to atrial tachyarrhythmia and the development of atrial remodeling in excised perfused hearts from male spontaneously hypertensive rats in comparison with age-matched male Wistar-Kyoto normotensive controls at age 3 and 11 months, corresponding with early hypertension and pre-heart failure stages, respectively. The incidence and duration of left atrial tachyarrhythmia induced by burst pacing was greater in hearts from 11-month-old hypertensive animals than either in age-matched controls or in 3-month-old hypertensive rats, although there was no difference between hypertensive and normotensive hearts at 3 months. Thus, hypertension was associated with the development of an arrhythmic substrate. Atrial effective refractory period and the duration of monophasic action potentials recorded from the left atrium were not altered with either hypertension or age, although there were changes in the whole-cell Ca2+ current density of isolated left atrial myocytes. On the other hand, Masson's trichrome staining of wax-embedded sections of left atrium revealed markedly greater interstitial fibrosis in 11-month-old hypertensive rats compared with controls. These data constitute the first experimental evidence that hypertension is associated with the development of a substrate for atrial tachyarrhythmia involving left atrial fibrosis without changes in the atrial effective refractory period and demonstrate that the spontaneously hypertensive rat represents a suitable model for investigating hypertension-associated atrial remodeling.

Evidence for a novel K(+) channel modulated by alpha(1A)-adrenoceptors in cardiac myocytes.

Accumulating evidence suggests that steady-state K(+) currents modulate excitability and action potential duration, particularly in cardiac cell types with relatively abbreviated action potential plateau phases. Despite representing potential drug targets, at present these currents and their modulation are comparatively poorly characterized. Therefore, we investigated the effects of phenylephrine [PE; an alpha(1)-adrenoceptor (alpha(1)-AR) agonist] on a sustained outward K(+) current in rat ventricular myocytes. Under K(+) current-selective conditions at 35 degrees C and whole-cell patch clamp, membrane depolarization elicited transient (I(t)) and steady-state (I(ss)) outward current components. PE (10 microM) significantly decreased I(ss) amplitude, without significant effect on I(t). Preferential modulation of I(ss) by PE was confirmed by intracellular application of the voltage-gated K(+) channel blocker tetraethylammonium, which largely inhibited I(t) without affecting the PE-sensitive current (I(ss,PE)). I(ss,PE) had the properties of an outwardly rectifying steady-state K(+)-selective conductance. Acidification of the external solution or externally applied BaCl(2) or quinidine strongly inhibited I(ss,PE). However, I(ss,PE) was not abolished by anandamide, ruthenium red, or zinc, inhibitors of TASK acid-sensitive background K(+) channels. Furthermore, the PE-sensitive current was partially inhibited by external administration of high concentrations of tetraethylammonium and 4-aminopyridine, which are voltage-gated K(+) channel-blockers. Power spectrum analysis of I(ss,PE) yielded a large unitary conductance of 78 pS. I(ss,PE) resulted from PE activation of the alpha(1A)-AR subtype, involved a pertussis toxin-insensitive G-protein, and was independent of cytosolic Ca(2+). These results collectively demonstrate that alpha(1A)-AR activation results in the inhibition of an outwardly rectifying steady-state K(+) current with properties distinct from previously characterized cardiac K(+) channels.

Gender-related differences in ventricular myocyte repolarization in the guinea pig.

It is well established that gender-differences exist in cardiac electrophysiology and these are thought to contribute to the increased risk of women, compared to men, for the potentially lethal ventricular arrhythmia, torsades de pointes. Data from animal models with abbreviated estrus cycles suggest that androgens may play a protective role in males. However, the role of female sex hormones in gender-differences in cardiac electrophysiology is less clear. This report describes gender differences in ventricular electrophysiology, investigated using the guinea pig heart. Ionic currents and action potentials were compared between ventricular myocytes isolated from male guinea pig hearts and those from females on the day of estrus (day 0) and 4 days post-estrus (day 4). The density of inward rectifier K(+) current (I(K1)) at -120 mV was significantly greater in male myocytes than in female myocytes either at day 0 or day 4. The peak L-type Ca(2+) current (I(Ca)) at +10 mV was also significantly larger in male myocytes than in day 0 and day 4 female myocytes. Moreover, I(Ca) differed significantly between day 0 and day 4 female myocytes, strongly suggesting that I(Ca) density varies around the estrus cycle. Delayed rectifier (I(K)) tail currents were significantly different between male and female day 4 myocytes. Action potential duration (at 90% repolarization; APD(90)) was significantly shorter in male myocytes than in female myocytes at day 0, but not at day 4, broadly consistent with the combined differences in I(K) and I(Ca) between the three groups. Taken together, our data are consistent with the contribution of multiple factors, rather than a single hormone, to gender differences in ventricular repolarization. Since female guinea pigs possess a conventional estrus cycle, our data suggest that this species may be well suited to elucidating the modulatory influence of ovarian steroids on ventricular repolarization and arrhythmic risk. Our findings suggest that further work examining the basis to gender differences in ventricular repolarization in the guinea pig is warranted.