Aiqiu Zhao

Basal and IGF-I-dependent regulation of potassium channels by MAP kinases and PI3-kinase during eccentric cardiac hypertrophy

The potassium channels I(K) and I(K1), responsible for the action potential repolarization and resting potential respectively, are altered during cardiac hypertrophy. The activation of insulin-like growth factor-I (IGF-I) during hypertrophy may affect channel activity. The aim was to examine the modulatory effects of IGF-I on I(K) and I(K1) through mitogen-activated protein kinase (MAPK) and phosphatidylinositol 3-kinase (PI3K) pathways during hypertrophy. With the use of specific inhibitors for ERK1/2 (PD98059), p38 MAPK (SB203580) and PI3K/Akt (LY294002), Western blot and whole cell patch-clamp were conducted on sham and aorto-caval shunt-induced hypertrophy adult rat myocytes. Basal activation levels of MAPKs and Akt were increased during hypertrophy. Acute IGF-I (10(-8) M) enhanced basal activation levels of these kinases in normal hearts but only those of Akt in hypertrophied ones. I(K) and I(K1) activities were lowered by IGF-I. Inhibition of ERK1/2, p38 MAPK, or Akt reduced basal I(K) activity by 70, 32, or 50%, respectively, in normal cardiomyocytes vs. 53, 34, or 52% in hypertrophied ones. However, basal activity of I(K1) was reduced by 45, 48, or 45% in the former vs. 63, 43, or 24% in the latter. The inhibition of either MAPKs or Akt alleviated IGF-I effects on I(K) and I(K1). We conclude that basal I(K) and I(K1) are positively maintained by steady-state Akt and ERK activities. K+ channels seem to be regulated in a dichotomic manner by acutely stimulated MAPKs and Akt. Eccentric cardiac hypertrophy may be associated with a change in the regulation of the steady-state basal activities of K+ channels towards MAPKs, while that of the acute IGF-I-stimulated ones toward Akt.

Effects of IGF-1 on I(K) and I(K1) Channels via PI3K/Akt Signaling in Neonatal Cardiac Myocytes.

Previous studies suggest that sarcolemmal potassium currents play important roles in cardiac hypertrophy. IGF-1 contributes to cardiac hypertrophy via activation of PI3K/Akt signaling. However, the relationships between IGF-1, PI3K/Akt signaling and sarcolemmal potassium currents remain unknown. Therefore, we tested the hypothesis that IGF-1 and PI3K/Akt signaling, independently, decrease sarcolemmal potassium currents in cardiac myocytes of neonatal rats. We compared the delayed outward rectifier (IK) and the inward rectifier (IK) current densities resulting from IGF-1 treatments to those resulting from simulation of PI3K/Akt signaling using adenoviral (Ad) BD110 and wild-type Akt and to those resulting from inhibition of PI3K signaling by LY294002. Ad.BD110 and Ad.Akt decreased IK and these decrements were attenuated by LY 294002. The IGF-1 treatments decreased both IK and IK1 but only the IK decrement was attenuated by LY294002. These findings demonstrate that IGF-1 may contribute to cardiac hypertrophy by PI3K/Akt signal transduction mechanisms in neonatal rat cardiomyocytes. Failure of LY294002 to effectively antagonize IGF-1 induced decrements in IK1 suggests that a signal pathway adjunct to PI3K/Akt contributes to IGF-1 protection against arrhythmogenesis in these myocytes. Our findings imply that sarcolemmal outward and inward rectifier potassium channels are substrates for IGF-1/PI3K/Akt signal transduction molecules.

Modulation of atrial contraction by PKA and PKC during the compensated phase of eccentric cardiac hypertrophy

Abstract.Calcium homeostasis is intimately regulated by protein kinase phosphorylation cascades that are also involved in the induction and maintenance of cardiac hypertrophy. In addition, the development of cardiac hypertrophy has been associated with alteration in the activation of the adrenergic system. Therefore, we investigated the specific role of protein kinase A (PKA) and C (PKC) on cardiac muscle contractile activity in the presence and absence of adrenergic stimulation. Isolated left atrial preparations from sham– and volume overload–induced cardiac hypertrophied rats were superfused with Tyrode and electrically stimulated at 0.75 Hz. Contraction was assessed in the basal and pre–stimulated (norepinephrine, 10–9M) states. Specific inhibitors, KT 5720 for PKA and Ro-32-0432 for PKC, were used. Peak tension development in left atria from sham–operated rats was more sensitive to PKC– than PKA–inhibition, whereas this differential sensitivity was abolished in the hypertrophied hearts. This difference was mainly due to an increase in the role of PKA in the contractile response. Developed peak tension by left atria from shunt rats was higher than that from sham rats, but when expressed to relative tissue mass, hypertrophied muscle showed weaker contraction than that from the sham group. In addition, the left atrial velocity of contraction in the sham is PKA–sensitive, while that of the shunt is PKC–sensitive. Furthermore, the velocity of relaxation shows dependency on both protein kinases, with PKC having a greater effect than PKA in the hypertrophied group. NE increased the PTD and the velocity of contraction (+dT/dt) through PKA and PKC dependent mechanisms, without affecting the velocity of relaxation (–dT/dt) in atrial muscle from sham rats. In contrast, during eccentric hypertrophy NE effectively reduced PTD as well as the –dT/dt through a PKC–dependent mechanism. The present study demonstrates that during early development of moderate eccentric cardiac hypertrophy there is: (1) a reduced specific peak tension developed due to an imbalance in the PKA and PKC activation; (2) a change in the protein kinase dependence of the velocity of contraction and relaxation from PKA to PKC with atrial hypertrophy; and (3) a negative inotropic response to adrenergic receptor stimulation. These functional responses may play a critical role in the cardiac performance during the progression of eccentric cardiac hypertrophy into the decompensated phase and heart failure.

Regulation of the instantaneous inward rectifier and the delayed outward rectifier potassium channels by Captopril and Angiotensin II via the Phosphoinositide-3 kinase pathway in volume-overload-induced hypertrophied cardiac myocytes

Summary Background Early development of cardiac hypertrophy may be beneficial but sustained hypertrophic activation leads to myocardial dysfunction. Regulation of the repolarizing currents can be modulated by the activation of humoral factors, such as angiotensin II (ANG II) through protein kinases. The aim of this work is to assess the regulation of IK and IK1 by ANG II through the PI3-K pathway in hypertrophied ventricular myocytes. Material/Methods Cardiac eccentric hypertrophy was induced through volume-overload in adult male rats by aorto-caval shunt (3 weeks). After one week half of the rats were given captopril (2 weeks; 0.5 g/l/day) and the other half served as control. The voltage-clamp and western blot techniques were used to measure the delayed outward rectifier potassium current (IK) and the instantaneous inward rectifier potassium current (IK1) and Akt activity, respectively. Results Hypertrophied cardiomyocytes showed reduction in IK and IK1. Treatment with captopril alleviated this difference seen between sham and shunt cardiomyocytes. Acute administration of ANG II (10−6M) to cardiocytes treated with captopril reduced IK and IK1 in shunts, but not in sham. Captopril treatment reversed ANG II effects on IK and IK1 in a PI3-K-independent manner. However in the absence of angiotensin converting enzyme inhibition, ANG II increased both IK and IK1 in a PI3-K-dependent manner in hypertrophied cardiomyocytes. Conclusions Thus, captopril treatment reveals a negative effect of ANG II on IK and IK1, which is PI3-K independent, whereas in the absence of angiotensin converting enzyme inhibition IK and IK1 regulation is dependent upon PI3-K.