Estradiol relaxes rat aorta via endothelium-dependent and -independent mechanisms.

The effects of estrogen on arterial function are heterogeneous with respect to vessel and/or species. We have investigated 17beta-estradiol-induced relaxation in isolated rat aorta with regard to the role of the vascular endothelium and ionic mechanisms. Estrogen induced a concentration-dependent relaxation of 46.5 +/- 7.9% and 70.1 +/- 12.2% (10(-8) and 10(-7)M), which was reduced by endothelial denudation. Furthermore, L-nitroarginine methyl ester completely abrogated this effect; however, estradiol did not relax KCl-contracted rings. Tetraethyl ammonium (1 mmol/l) completely blocked estradiol-induced relaxation. Estradiol increased [cGMP] in isolated aortic rings via NO, but did not significantly affect NOS activity in endothelial cells. Thus, estrogen can relax rat aorta in vitro via both endothelium-dependent and -independent mechanisms involving the NO/cGMP and potassium channel signaling system.

Endothelium-independent effect of estrogen on Ca(2+)-activated K(+) channels in human coronary artery smooth muscle cells.

OBJECTIVE: Postmenopausal estrogen replacement therapy lowers the incidence of cardiovascular disease, suggesting that estrogens support cardiovascular function. Estrogens dilate coronary arteries; however, little is known about the molecular basis of how estrogen affects the human coronary circulation. The cellular/molecular effects of estrogen action on human coronary smooth muscle were investigated in the present study. METHODS: Patch-clamp and fluorescent microscopy studies were performed on human coronary myocytes in the absence of endothelium. RESULTS: Estrogen increased whole-cell currents over a range of membrane potentials, and further studies indicated that the large-conductance (186.5 +/- 3 pS), calcium- and voltage-activated potassium (BK(Ca)) channel was the target of estrogen action. Channel activity was stimulated approximately 15-fold by nanomolar concentrations of 17 beta-estradiol, and this stimulation was reversed >90% by inhibiting cGMP-dependent protein kinase activity with 300 nM KT5823. 17 beta-Estradiol increased the level of cGMP and nitric oxide in human myocytes, and the stimulatory effect of estrogen on channel activity and NO production was reversed by inhibiting NO synthase with 10 microM N(G)-monomethyl-L-arginine. CONCLUSIONS: Our cellular and molecular studies identify the BK(Ca) channel as a target of estrogen action in human coronary artery smooth muscle. This response to estrogen involves cGMP-dependent phosphorylation of the BK(Ca) channel or a closely associated regulatory molecule, and further evidence suggests involvement of the NO/cGMP signaling system in coronary smooth muscle. These findings are the first to provide direct evidence for a molecular mechanism that can account for endothelium-independent effects of estrogen on human arteries, and may also help explain why estrogens reduce myocardial ischemia and stimulate coronary blood flow in patients with diseased coronary arteries.

Potassium (BK(Ca)) currents are reduced in microvascular smooth muscle cells from insulin-resistant rats.

Insulin resistance (IR) syndrome is associated with impaired vascular relaxation; however, the underlying pathophysiology is unknown. Potassium channel activation causes vascular smooth muscle hyperpolarization and relaxation. The present study determined whether a reduction in large conductance calcium- and voltage-activated potassium (BK(Ca)) channel activity contributes to impaired vascular relaxation in IR rats. BK(Ca) channels were characterized in mesenteric microvessels from IR and control rats. Macroscopic current density was reduced in myocytes from IR animals compared with controls. In addition, inhibition of BK(Ca) channels with tetraethylammonium (1 mM) or iberiotoxin (100 nM) was greater in myocytes from control (70%) compared with IR animals (approximately 20%). Furthermore, activation of BK(Ca) channels with NS-1619 was three times more effective at increasing outward current in cells from control versus IR animals. Single channel and Western blot analysis of BK(Ca) channels revealed similar conductance, amplitude, voltage sensitivity, Ca2+ sensitivity, and expression density between the two groups. These data provide the first direct evidence that microvascular potassium currents are reduced in IR and suggest a molecular mechanism that could account for impaired vascular relaxation in IR.