Background: Recently, new "targeted" fluorescent probes that react selectively with reactive oxygen and nitrogen species to yield specific products have been discovered. Results: High-throughput fluorescence and HPLC-based methodology for global profiling of ROS/RNS is described. Conclusion: This methodology enables real-time monitoring of multiple oxidants in cellular systems. Significance: The global profiling approach using different ROS/RNS-specific fluorescent probes will help establish the identity of oxidants in redox regulation and signaling.
Background and purpose: 1-methylnicotinamide (MNA) has been considered to be an inactive metabolite of nicotinamide. Here we assessed the anti-thrombotic activity of MNA in vivo. Experimental approach: Antithrombotic action of MNA was studied in normotensive rats with extracorporeal thrombus formation (thrombolysis), in renovascular hypertensive rats with intraarterial thrombus formation (arterial thrombosis) and in a venous thrombosis model in rats (venous thrombosis). Key results: MNA (3-100 mg kg À1 ) induced a dose-dependent and sustained thrombolytic response, associated with a rise in 6-keto-PGF 1a in blood. Various compounds structurally related to MNA were either inactive or weaker thrombolytics. Rofecoxib (0.01-1 mg kg À1 ), dose-dependently inhibited the thrombolytic response of MNA, indomethacin (5 mg kg À1 ) abolished it, while L-NAME (5 mg kg À1 ) were without effect. MNA (3-30 mg kg À1 ) also reduced arterial thrombosis and this effect was abrogated by indomethacin (2.5 mg kg À1 ) as well as by rofecoxib (1 mg kg À1 ). MNA, however, did not affect venous thrombosis. In vitro MNA did not modify platelet aggregation nor induce vasodilation. Conclusions and implications: MNA displayed a profile of anti-thrombotic activity in vivo that surpasses that of closely related compounds. MNA inhibited platelet-dependent thrombosis by a mechanism involving cyclooxygenase-2 and prostacyclin. Our findings suggest that endogenous MNA, produced in the liver by nicotinamide N-methyltransferase, could be an endogenous activator of prostacyclin production and thus may regulate thrombotic as well as inflammatory processes in the cardiovascular system.
Four-ff-bond-linked bis(hydrazine) radical cations s3*+, a3'+, and a8*+ show broad visible absorption bands with Xmax = 512-548 nm in CH3CN at room temperature, attributed to Hush-type charge-transfer bands (transition energies Eop = 52.2-55.8 kcal/mol). The corresponding bis(hydrazyl) radical cations s2,+, a2,+, and a7*+ show near-IR absorption with Xmax = 1062-1199 nm (Eop = 26.9-29.3 kcal/mol). The large difference in Eop is caused by innersphere reorganization energy differences, which are predicted well by AM 1 semiempirical molecular orbital calculations.Hush analysis of the absorption bands produces electronic coupling matrix elements J = 3.5 ± 0.5 kcal/mol for these species, and Marcus-Hush theory predicts intramolecular electron-transfer rate constants which are consistent with the experimental observation that ET is slow on the ESR time scale for the hydrazines and fast for the hydrazyls. The bis-inner hydrazyl radical cation 13,+ exhibits a near-IR absorption band at Xma" = 850 nm which is narrower than those of 2,+ and 7,+ and is concluded not to be a Hush-type charge-transfer band.
Background: Nitroxyl (HNO) is a reactive nitrogen species implicated in cardioprotection. Results: Nitroxyl reacts with oxygen to form an oxidizing and nitrating species, peroxynitrite. Conclusion: In the presence of oxygen, HNO donors may be a source of peroxynitrite. Significance: Peroxynitrite formation should be taken into account in the extracellular milieu when exposing cells to HNO donor under aerobic conditions.
Amplex® Red (10-acetyl-3,7-dihydroxyphenoxazine) is a fluorogenic probe widely used to detect and quantify hydrogen peroxide in biological systems. Detection of hydrogen peroxide is based on peroxidase-catalyzed oxidation of Amplex® Red to resorufin. In this study we investigated the mechanism of one-electron oxidation of Amplex® Red and we present the spectroscopic characterization of transient species formed upon the oxidation. Oxidation process has been studied by a pulse radiolysis technique with one-electron oxidants (N3•, CO3•−, •NO2 and GS•). The rate constants for the Amplex® Red oxidation by N3• (2k = 2.1·109 M−1s−1, at pH = 7.2) and CO3•− (2k = 7.6·108 M−1s−1, at pH = 10.3) were determined. Two intermediates formed during the conversion of Amplex® Red into resorufin have been characterized. Based on the results obtained, the mechanism of transformation of Amplex® Red into resorufin, involving disproportionation of the Amplex® Red-derived radical species, has been proposed. The results indicate that peroxynitrite-derived radicals, but not peroxynitrite itself, are capable to oxidize Amplex® Red to resorufin. We also demonstrate that horseradish peroxidase can catalyze oxidation of Amplex® Red not only by hydrogen peroxide, but also by peroxynitrite, which needs to be considered when employing the probe for hydrogen peroxide detection.
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