We examined whether the inhibition of nitric oxide (NO) synthesis by NG-nitro-L-arginine (lNNA) abolished pacing-induced preconditioning, and if prolonged exposure to cholesterol-enriched diet led to the loss of preconditioning due to decreased cardiac NO formation. Therefore, Wistar rats fed 2% cholesterol-enriched diet or standard diet for 24 weeks were treated with a single dose of 1 mg/kg lNNA or its solvent at the end of the week 24, respectively. Isolated hearts from all groups were subjected to either preconditioning induced by three consecutive periods of pacing at 600 beats/min for 5 min, with 5-min interpacing periods, or time-matched non-preconditioning perfusion, followed by a 10-min coronary occlusion, respectively. In the control group, coronary occlusion after a non-preconditioning protocol decreased aortic flow (AF) from 45.4+/-2.4 to 15.6+/-1.5 ml/min, and resulted in a lactate dehydrogenase (LDH) release of 219+/-55 mU/min/g, however, preconditioning attenuated the consequences of coronary occlusion [AF: 27.3+/-1.7 ml/min (P<0.05); LDH: 44+/-14 mU/min/g (P<0.05)]. Preconditioning did not confer protection in the lNNA-treated (AF: 17.4+/-1.5 ml/min; LDH: 151+/-21 mU/min/g), and/or in the high-cholesterol-fed groups (AF: 15.7+/-1.2 ml/min; LDH: 168+/-22 mU/min/g). Preconditioning was preserved however, when hearts were treated with lNNA after the preconditioning protocol [AF: 29.6+/-2.2 ml/min (P<0.05); LDH: 48+/-17 mU/min/g (P<0.05)]. Both lNNA treatment and cholesterol-enriched diet markedly decreased cardiac NO content assayed by electron spin resonance spectroscopy. We conclude that NO may be involved in the triggering mechanism of pacing-induced preconditioning, the protective effect of which is blocked by sustained exposure to dietary cholesterol, possibly by influencing cardiac metabolism of NO.
Copyright 1997 Academic Press Limited.