NITRIC-OXIDE REGULATES THE CALCIUM CURRENT IN ISOLATED HUMAN ATRIAL MYOCYTES

Cardiac Ca2+ current (I-Ca) was shown to be regulated by cGMP in a num ber of different species. Recently, we found that the NO-donor SIN-1 ( 3-morpholino-sydnonimine) exerts a dual regulation of I-Ca in frog ven tricular myocytes via an accumulation of cGMP. To examine whether NO a lso regulates Ca2+ channels in human heart, we investigated the effect s of SIN-1 on I-Ca in isolated human atrial myocytes. An extracellular application of SIN-1 produced a profound stimulatory effect on basal I-Ca at concentrations > 1 pM. Indeed, 10 pM SIN-1 induced a approxima te to 35% increase in I-Ca. The stimulatory effect of SIN-1 was maxima l at 1 nM (approximate to 2-fold increase in I-Ca) and was comparable with the effect of a saturating concentration (1 mu M) of isoprenaline , a beta-adrenergic agonist. Increasing the concentration of SIN-1 to 1-100 mu M reduced the stimulatory effect in two thirds of the cells. The stimulatory effect of SIN-1 was not mimicked by SIN-1C, the cleava ge product of SIN-1 produced after liberation of NO. This suggests tha t NO mediates the effects of SIN-1 on I-CA. Because, in frog heart, th e stimulatory effect of SIN-1 on I-Ca was found to be due to cGMP-indu ced inhibition of cGMP-inhibited phosphodiesterase (cGI-PDE), we compa red the effects of SIN-1 and milrinone, a cGI-PDE selective inhibitor, on I-Ca in human. Milrinone (10 mu M) induced a strong stimulation of I-Ca (approximate to 150%), demonstrating that cGI-PDE controls the a mplitude of basal I-Ca in this tissue. In the presence of milrinone, S IN-1 (0.1-1 nM) had no stimulatory effect on I-Ca suggesting that the effects of SIN-1 and MIL were not additive. We conclude that NO may st imulate I-Ca in human atrial myocytes via inhibition of the cGI-PDE.