Role of plasma S-nitrosothiols in regulation of blood pressure in anesthetized rabbits with special references to hypotensive effects of acetylcholine and nitrovasodilators.

The regulatory role of plasma nitrosothiols (R-SNOs) under steady-state conditions and their possible contribution to pharmacological vasodilation were systematically examined in anesthetized rabbits. Nitrosocystein (Cys-NO), S-nitrosoglutathione (G-SNO), and S-nitrosoalbumin (Alb-SNO) were determined by HPLC-Saville's method with respective sensitivities of 1, 1, and 5 nM. These R-SNOs were not detected under steady-state conditions even in the presence of N-ethylmaleimide, a thiol protective agent used to prevent transnitrosation of R-SNOs. Development of plasma Alb-SNO below 300 nM was observed after intravenous injection (i.v.) of nitric oxide (NO) solution (0.1 to 3 ml/g), NOC7 (an NO releasing agent, above 1 µg/kg), and a low dose of Alb-SNO (10 nmol/kg). However, blood pressure was not significantly reduced by NO solution or Alb-SNO. Intravenous injection of a high dose of Alb-SNO (300 nmol/kg) significantly reduced blood pressure with the appearance not only Alb-SNO in micromolar level in plasma, but also G-SNO in lesser degree. Conversely, the hypotensive effect of Cys-NO (300 nmol/kg, i.v.) and G-SNO (300 nmol/kg, i.v.) accompanied development of Alb-SNO (micromolar level), but not Cys-NO or G-SNO in plasma. R-SNOs were not found in plasma during profound hypotension induced by acetylcholine (10 and 30 µg/kg/min, continuous i.v.), glyceryl trinitrate (100 µg/kg, i.v.), sodium nitroprusside (100 µg/kg, i.v.), and isosorbide dinitrate (300 µg/kg, i.v.). These results indicate that R-SNOs do not play an important role under unstimulated condition. In addition, plasma R-SNOs may not be involved in pharmacological vasodilation where contributions of NO or R-SNOs are suggested.

Arteriovenous differences in NO2- kinetics in anesthetized rabbits.

Despite of the importance of plasma NO2- as an index of endothelial nitric oxide (NO) formation and a substrate for NO production, only a limited kinetic knowledge is available in vivo. To address this issue, we intravenously injected NaNO2 into anesthetized rabbits and quantified changes in arterial and venous plasma NO2- levels. Plasma NO2- levels in arterial blood (956 +/- 220 nM) were slightly, but significantly, higher than those in venous blood (889 +/- 214 nM) under control conditions. Although similar half-lives of the NO2- were observed in arterial and venous plasma, significant arteriovenous differences were observed in the volume of distribution of the central compartment (0.158 +/- 0.007 l/kg in arterial blood and 0.295 +/- 0.015 l/kg in venous blood) and the peripheral compartment (0.259 +/- 0.035 l/kg in arterial blood and 0.135 +/- 0.034 l/kg in venous blood). When NOR1 (authentic NO) was injected, increases in NO2- levels were greater in arterial plasma, and decreases in blood pressure significantly correlated with arterial NO2- levels only (r = 0.90, p < 0.01). These results indicate that changes in NO2- are larger and more easily detectable as an index of NO formation in arterial plasma.

Quantifying nanomolar levels of nitrite in biological samples by HPLC-Griess method: special reference to arterio-venous difference in vivo.

Nitrite (NO(2)(-)) is assumed to play an important role in regulation of vascular tone as a reservoir of nitric oxide (NO). To examine its physiological contribution, however, a sensitive method is required for determination of the true level of NO(2)(-) in biological samples. To this end, practical consideration to avoid NO(2)(-) contamination through the quantification procedure is important. We present here a highly sensitive and accurate method for determining NO(2)(-) in plasma by improving the HPLC-Griess system with minimal NO(2)(-) contamination in the samples. The system achieved high sensitivity (detection limit of 2 nM and sensitivity to 1 nM) and complete separation of the NO(2)(-) signal peak by modifying the system setup and mobile phase. Using this method, we achieved acceptable quantification of low NO(2)(-) levels in plasma. Deproteinization by ultrafiltration and exposure to atmosphere before measurement were identified as the major sources of NO(2)(-) contamination during sample processing. We addressed these issues by the use of methanol for deproteinization and gas-tight caps. These countermeasures allowed us to detect small arterio-venous NO(2)(-) differences in rabbit plasma that may indicate kinetic difference of NO(2)(-) in a small number of samples (n = 6). This difference became prominent when NO(2)(-) or a NO releasing agent, NOR1, was intravenously applied. Our results indicate that application of a sensitive method with careful handling is important for accurate determination of NO(2)(-) and that our method is applicable for further examination of the kinetic features of NO(2)(-) in vivo.