Eun Yeong Seo scite author profile

Neuronal nitric oxide synthase (NOS1 or nNOS) exerts negative inotropic and positive lusitropic effects through Ca(2+) handling processes in cardiac myocytes from healthy hearts. However, underlying mechanisms of NOS1 in diseased hearts remain unclear. The present study aims to investigate this question in angiotensin II (Ang II)-induced hypertensive rat hearts (HP). Our results showed that the systolic function of left ventricle (LV) was reduced and diastolic function was unaltered (echocardiographic assessment) in HP compared to those in shams. In isolated LV myocytes, contraction was unchanged but peak [Ca(2+)]i transient was increased in HP. Concomitantly, relaxation and time constant of [Ca(2+)]i decay (tau) were faster and the phosphorylated fraction of phospholamban (PLN-Ser(16)/PLN) was greater. NOS1 protein expression and activity were increased in LV myocyte homogenates from HP. Surprisingly, inhibition of NOS1 did not affect contraction but reduced peak [Ca(2+)]i transient; prevented faster relaxation without affecting the tau of [Ca(2+)]i transient or PLN-Ser(16)/PLN in HP, suggesting myofilament Ca(2+) desensitization by NOS1. Indeed, relaxation phase of the sarcomere length-[Ca(2+)]i relationship of LV myocytes shifted to the right and increased [Ca(2+)]i for 50% of sarcomere shortening (EC50) in HP. Phosphorylations of cardiac myosin binding protein-C (cMyBP-C(282) and cMyBP-C(273)) were increased and cardiac troponin I (cTnI(23/24)) was reduced in HP. Importantly, NOS1 or PKG inhibition reduced cMyBP-C(273) and cTnI(23/24) and reversed myofilament Ca(2+) sensitivity. These results reveal that NOS1 is up-regulated in LV myocytes from HP and exerts positive lusitropic effect by modulating myofilament Ca(2+) sensitivity through phosphorylation of key regulators in sarcomere.

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Inhibition of Ca2+-Release–Activated Ca2+ Channel (CRAC) and K+ Channels by Curcumin in Jurkat-T Cells

Shin

Seo

Pang

et al. 2011

J Pharmacol Sci

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Abstract. The increase in cytoplasmic Ca] c of Jurkat-T cells using the patch clamp technique and fura-2 spectrofluorimetry. Curcumin (10 μM) inhibited store-operated Ca 2+ entry (SOCE). Consistently, dose-dependent inhibition of I CRAC by curcumin was confirmed in Jurkat-T (IC 50 , 5.9 μM) and the HEK293 cells overexpressing Orai1 and STIM1 (IC 50 , 0.6 μM). Also, curcumin inhibited both I Kv (IC 50 , 11.9 μM) and I SK4 (IC 50 , 4.2 μM). The other polyphenols (rosmarinic acid, resveratrol, and epigallocatechin gallate at 10 -30 μM) had no effect on SOCE and showed only a partial inhibition of the K + currents. In summary, among the tested polyphenolic agents, curcumin showed prominent inhibition of major ion channels in lymphocytes, which might contribute to the anti-inflammatory effects of curcumin.

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Exercise training increases inwardly rectifying K+ current and augments K+-mediated vasodilatation in deep femoral artery of rats

Jin

Kim

Seo

et al. 2011

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The present study provides evidence that regular exercise up-regulates I(Kir) in DFA and CA myocytes. Although the increase in I(Kir) was observed in two types of arteries, augmentation of K(+)-induced relaxation was observed only in the DFA of ET rats, possibly due to the increased Na(+) conductance in CA myocytes. The increases in I(Kir) and K(+)-induced vasodilatation of the arteries of skeletal muscle suggest novel mechanisms of improved exercise hyperaemia with physical training.

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Wall stretch and thromboxane A2 activate NO synthase (eNOS) in pulmonary arterial smooth muscle cells via H2O2 and Akt-dependent phosphorylation

Kim

Yoo

Jang

et al. 2016

Pflugers Arch - Eur J Physiol

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Pulmonary arteries (PAs) have high compliance, buffering the wide ranges of blood flow. Here, we addressed a hypothesis that PA smooth muscle cells (PASMCs) express nitric oxide synthases (NOS) that might be activated by mechanical stress and vasoactive agonists. In the myograph study of endothelium-denuded rat PAs, NOS inhibition (L-NAME) induced strong contraction (96 % of 80 mM KCl-induced contraction (80K)) in the presence of 5 nM U46619 (thromboxane A2 (TXA2) analogue) with relatively high basal stretch (2.94 mN, S(+)). With lower basal stretch (0.98 mN, S(-)), however, L-NAME application following U46619 (TXA2/L-NAME) induced weak contraction (27 % of 80K). Inhibitors of nNOS and iNOS had no such effect in S(+) PAs. In endothelium-denuded S(+) mesenteric and renal arteries, TXA2/L-NAME-induced contraction was only 18 and 21 % of 80K, respectively. Expression of endothelial-type NOS (eNOS) in rat PASMCs was confirmed by RT-PCR and immunohistochemistry. Even in S(-) PAs, pretreatment with H2O2 (0.1-10 μM) effectively increased the sensitivity to TXA2/L-NAME (105 % of 80K). Vice versa, NADPH oxidase inhibitors, reactive oxygen species scavengers, or an Akt inhibitor (SC-66) suppressed TXA2/L-NAME-induced contraction in S(+) PAs. In a human PASMC line, immunoblot analysis showed the following: (1) eNOS expression, (2) Ser(1177) phosphorylation by U46619 and H2O2, and (3) Akt activation (Ser(473) phosphorylation) by U46619. In the cell-attached patch clamp study, H2O2 facilitated membrane stretch-activated cation channels in rat PASMCs. Taken together, the muscular eNOS in PAs can be activated by TXA2 and mechanical stress via H2O2 and Akt-mediated signaling, which may counterbalance the contractile signals from TXA2 and mechanical stimuli.

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Low K+ current in arterial myocytes with impaired K+-vasodilation and its recovery by exercise in hypertensive rats

Seo

Kim

Zhao

et al. 2014

Pflugers Arch - Eur J Physiol

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K(+) channels determine the plasma membrane potential of vascular myocytes, influencing arterial tone. In many types of arteries, a moderate increase in [K(+)]e induces vasorelaxation by augmenting the inwardly rectifying K(+) channel current (I Kir). K(+)-vasodilation matches regional tissue activity and O2 supply. In chronic hypertension (HT), small arteries and arterioles undergo various changes; however, ion channel remodeling is poorly understood. Here, we investigated whether K(+) channels and K(+)-induced vasodilation are affected in deep femoral (DFA) and cerebral artery (CA) myocytes of angiotensin II-induced hypertensive rats (Ang-HT). Additionally, we tested whether regular exercise training (ET) restores HT-associated changes in K(+) channel activity. In Ang-HT, both the voltage-gated K(+) channel current (I Kv) and I Kir were decreased in DFA and CA myocytes, and were effectively restored and further increased by combined ET for 2 weeks (HT-ET). Consistently, K(+)-vasodilation of the DFA was impaired in Ang-HT, and recovered in HT-ET. Interestingly, ET did not reverse the decreased K(+)-vasodilation of CA. CA myocytes from the Ang-HT and HT-ET groups demonstrated, apart from K(+) channel changes, an increase in nonselective cationic current (I NSC). In contrast, DFA myocytes exhibited decreased I NSC in both the Ang-HT and HT-ET groups. Taken together, the decreased K(+) conductance in Ang-HT rats and its recovery by ET suggest increased peripheral arterial resistance in HT and the anti-hypertensive effects of ET, respectively. In addition, the common upregulation of I NSC in the CA in the Ang-HT and HT-ET groups might imply a protective adaptation preventing excessive cerebral blood flow under HT and strenuous exercise.

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Eun Yeong Seo

Myofilament Ca2+ desensitization mediates positive lusitropic effect of neuronal nitric oxide synthase in left ventricular myocytes from murine hypertensive heart

Inhibition of Ca2+-Release–Activated Ca2+ Channel (CRAC) and K+ Channels by Curcumin in Jurkat-T Cells

Exercise training increases inwardly rectifying K+ current and augments K+-mediated vasodilatation in deep femoral artery of rats

Wall stretch and thromboxane A2 activate NO synthase (eNOS) in pulmonary arterial smooth muscle cells via H2O2 and Akt-dependent phosphorylation

Low K+ current in arterial myocytes with impaired K+-vasodilation and its recovery by exercise in hypertensive rats

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