Endogenous endothelial nitric oxide synthase-derived nitric oxide is a physiological regulator of myocardial oxygen consumption.

Our objective was to determine the precise role of endothelial nitric oxide synthase (eNOS) as a modulator of cardiac O2 consumption and to further examine the role of nitric oxide (NO) in the control of mitochondrial respiration. Left ventricle O2 consumption in mice with defects in the expression of eNOS [eNOS (-/-)] and inducible NOS [iNOS (-/-)] was measured with a Clark-type O2 electrode. The rate of decreases in O2 concentration was expressed as a percentage of the baseline. Baseline O2 consumption was not significantly different between groups of mice. Bradykinin (10(-4) mol/L) induced significant decreases in O2 consumption in tissues taken from iNOS (-/-) (-28+/-4%), wild-type eNOS (+/+) (-22+/-4%), and heterozygous eNOS(+/-) (-22+/-5%) but not homozygous eNOS (-/-) (-3+/-4%) mice. Responses to bradykinin in iNOS (-/-) and both wild-type and heterozygous eNOS mice were attenuated after NOS blockade with N-nitro-L-arginine methyl ester (L-NAME) (-2+/-5%, -3+/-2%, and -6+/-5%, respectively, P<0.05). In contrast, S-nitroso-N-acetyl-penicillamine (SNAP, 10(-4) mol/L), which releases NO spontaneously, induced decreases in myocardial O2 consumption in all groups of mice, and such responses were not affected by L-NAME. In addition, pretreatment with bacterial endotoxin elicited a reduction in basal O2 consumption in tissues taken from normal but not iNOS (-/-)-deficient mice. Our results indicate that the pivotal role of eNOS in the control of myocardial O2 consumption and modulation of mitochondrial respiration by NO may have an important role in pathological conditions such as endotoxemia in which the production of NO is altered.

Role of nitric oxide in the control of renal oxygen consumption and the regulation of chemical work in the kidney.

Inhibition of NO synthesis has recently been shown to increase oxygen extraction in vivo, and NO has been proposed to play a significant role in the regulation of oxygen consumption by both skeletal and cardiac muscle in vivo and in vitro. It was our aim to determine whether NO also has such a role in the kidney, a tissue with a relatively low basal oxygen extraction. In chronically instrumented conscious dogs, administration of an inhibitor of NO synthase, nitro-L-arginine (NLA, 30 mg/kg i.v.), caused a maintained increase in mean arterial pressure and renal vascular resistance and a decrease in heart rate (all P<0.05). At 60 minutes, urine flow rate and glomerular flow rate decreased by 44+/-12% and 45+/-7%, respectively; moreover, the amount of sodium reabsorbed fell from 16+/-1.7 to 8.5+/-1.1 mmol/min (all P<0.05). At this time, oxygen uptake and extraction increased markedly by 115+/-37% and 102+/-34%, respectively (P<0.05). Oxygen consumption also significantly increased from 4.5+/-0.6 to 7.1+/-0.9 mL O2/min. Most important, the ratio of oxygen consumption to sodium reabsorbed increased dramatically from 0.33+/-0.07 to 0.75+/-0.11 mL O2/mmol Na+ (P<0.05), suggesting a reduction in renal efficiency for transporting sodium. In vitro, both a NO-donating agent and the NO synthase-stimulating agonist bradykinin significantly decreased both cortical and medullary renal oxygen consumption. In conclusion, NO plays a role in maintaining a balance between oxygen consumption and sodium reabsorption, the major ATP-consuming process in the kidney, in conscious dogs, and NO can inhibit mitochondrial oxygen consumption in canine renal slices in vitro.

Mechanisms of nitrate accumulation in plasma during pacing-induced heart failure in conscious dogs.

The goal of this study was to understand the mechanisms behind the changes in plasma NOx during heart failure. Heart failure is associated with an increase in plasma nitrate levels, and yet most experimental evidence demonstrates a reduction in endothelial nitric oxide production during heart failure. Dogs were chronically instrumented for measurement of systemic hemodynamics and left ventricular (LV) dimensions. Hearts were paced at 210 bpm for 3 weeks (n = 14) and then 240 bpm for 1 week (n = 7). Hemodynamics, arterial blood gases, plasma NOx, and creatinine levels were monitored weekly. Heart failure was evidenced by cachexia, ascites, and hemodynamic alterations. Resting heart rate rose (94 +/- 6 to 135 +/- 9 bpm), and LV dP/dt fell (2810 +/- 82 to 1471 +/- 99 mm Hg/s), while LV end diastolic pressure quadrupled (5.8 +/- 0.7 to 25 +/- 0.8 mm Hg), and diastolic wall stress quadrupled (11 +/- 1.3 to 43 +/- 6.0 g/cm2, all P < 0.05). These changes occurred during a doubling in plasma NOx (5.5 +/- 1.5 to 10 +/- 1.6 microM, P < 0.05). There were no changes in plasma NOx through 3 weeks of pacing. Plasma creatinine levels increased 450% (from 0.27 +/- 0.32 to 1.21 +/- 0.63 mg%). Stimulated nitrite production by agonists in sieved coronary microvessels was unchanged after 3 weeks of pacing but was reduced after heart failure. Plasma NOx did not correlate with LV dP/dt or systolic wall stress but correlated directly with LV EDP or diastolic wall stress and inversely with cardiac work. Plasma NOx rose in direct relation to plasma creatinine levels (Y = 4.8X + 2.8, r2 = 0.84), suggesting that the rise in plasma NOx during heart failure is due to decreased renal function not increased NO production.