Jörg Sandmann

Endogenous nitric oxide synthase inhibitors are responsible for the L-arginine paradox.

L‐Arginine, the substrate of nitric oxide (NO) synthases (NOSs), is found in the mammalian organism at concentrations by far exceeding K M values of these enzymes. Therefore, additional L‐arginine should not enhance NO formation. In vivo, however, increasing L‐arginine concentration in plasma has been shown repeatedly to increase NO production. This phenomenon has been named the L‐arginine paradox; it has found no satisfactory explanation so far. In the present work, evidence for the hypothesis that the endogenous NOS inhibitors methylarginines, asymmetric dimethylarginine being the most powerful (IC50 1.5 μM), are responsible for the L‐arginine paradox is presented.

Assessment of nitric oxide synthase activity in vitro and in vivo by gas chromatography-mass spectrometry

A gas chromatographic-mass spectrometric method for the determination of nitric oxide synthase activity is described. The method is based on the gas chromatographic-mass spectrometric measurement of L-[15N2]arginine-derived [15N]nitrite as its pentafluorobenzyl derivative in the negative-ion chemical ionization mode. Application of the method to the analysis of [15N]nitrite formation by purified neuronal nitric oxide synthase revealed K(M) values of 3.1 microM by Hanes and 4.6 microM by Lineweaver-Burk for L-[15N2]arginine. The corresponding Vmax values were 0.204 and 0.228 micromol [15N]nitrite min(-1) mg(-1) NOS, respectively. N(G)-Nitro-L-arginine and N(G),N(G)-dimethylarginine (asymmetric dimethylarginine) were identified by this method as the most potent enzyme inhibitors. Nitric oxide synthase activity was also assessed in vivo by i.v. injection of L-[15N2]arginine in a rat and determination of plasma [15N]nitrite and [15N]nitrate. The assay described in this work allows for accurate, specific and highly sensitive determination of nitric oxide synthase activity in vitro and in vivo.

Analysis of cysteine and N-acetylcysteine in human plasma by high-performance liquid chromatography at the basal state and after oral administration of N-acetylcysteine

A high-performance liquid chromatographic method for the determination of free reduced cysteine and N-acetylcysteine in human plasma at the basal state and after oral administration of N-acetylcysteine is described. The method is based on acid-catalysed conversion of plasma thiols to the corresponding S-nitroso derivatives by excess of nitrite and their subsequent cation-pairing RP-HPLC with detection at 333 nm. Recovery rates of cysteine and N-acetylcysteine added to human plasma were 94.6 and 99.6%, respectively. Inter- and intra-day precision were below 6%. In healthy humans (n = 5), free reduced cysteine was determined to be (mean+/-S.E.) 10.0+/-0.96 microM. No N-acetylcysteine was detected in plasma of these subjects above the limit of detection (e.g. 170 nM). The method was successfully applied to a pharmacokinetic study on orally administered N-acetylcysteine to healthy volunteers.

Measurement of S-nitrosoalbumin by gas chromatography–mass spectrometry: III. Quantitative determination in human plasma after specific conversion of the S-nitroso group to nitrite by cysteine and Cu2+ via intermediate formation of S-nitrosocysteine and nitric oxide

Highly contradictory data exist on the normal plasma basal levels in humans of S-nitrosoproteins, in particular of S-nitrosoalbumin (SNALB), the most abundant nitric oxide (.NO) transport form in the human circulation with a range of three orders of magnitude (i.e., 10 nM-10 microM). In previous work we reported on a GC-MS method for the quantitative determination of SNALB in human plasma. This method is based on selective extraction of SNALB and its 15N-labeled SNALB analog (S(15)NALB) used as internal standard on HiTrapBlue Sepharose affinity columns, HgCl(2)-catalysed conversion of the S-nitroso groups to nitrite and [15N]nitrite, respectively, their derivatization to the pentafluorobenzyl derivatives and quantification by GC-MS. By this method we had measured SNALB basal plasma levels of 181 nM in healthy humans. It is generally accepted that HgCl(2)-catalysed conversion of S-nitroso groups into nitrite is specific. In consideration of the highly divergent SNALB plasma levels in humans reported so far, we were interested in an additional method that would allow specific conversion of S-nitroso groups into nitrite. We found that treatment with cysteine plus CuSO(4) is as effective and specific as treatment with HgCl(2). The principle of the cysteine/CuSO(4) procedure is based on the transfer of the S-nitroso group from SNALB to cysteine yielding S-nitrosocysteine, and its subsequent highly Cu(2+)-sensitive conversion into nitrite via intermediate.NO formation. Similar SNALB concentrations in the plasma of 10 healthy humans were measured by GC-MS using HgCl(2) (156+/-64 nM) and cysteine/CuSO(4) (205+/-96 nM). Our results strongly suggest that SNALB is an endogenous constituent in human plasma and that its concentration is of the order of 150-200 nM under physiological conditions.

Electrospray ionization mass spectrometry of low-molecular-mass S-nitroso compounds and their thiols

Low-molecular-mass S-nitroso compounds (R-S-N=O) are potent vasodilators and inhibitors of platelet aggregation. This work describes the electrospray ionization mass spectrometric (ESI-MS) analysis of physiological and synthetic low-molecular-mass S-nitroso compounds and their thiols including S-nitrosoglutathione, S-nitrosocysteine, glutathione and cysteine. Mass spectra of the unlabeled and S-15N-labeled low-molecular-mass S-nitroso compounds investigated are characterized by abundant cations due to [M+H]+, [M+Na]+, [(M+H)-NO]+, [2 M+H]+, and [(2 M+H)-2NO]+. Mass spectra of low-molecular-mass thiols are characterized by abundant cations due to [M+H]+, [M+Na]+ and [2M+H]+. Using off-line electrospray ionization tandem mass spectrometry we unequivocally identified S-[15N]nitrosoglutathione in human red blood cells formed after their incubation with S-[15N]nitrosocysteine. These results suggest that ESI-MS in combination with an appropriate liquid chromatographic system should be a useful analytical approach for the on-line quantitative determination of low-molecular-mass S-nitroso compounds in biological fluids in the presence of their thiols and nitrite. Considerations were made about on-line ESI-MS and quantitative measurements.

Measurement of S-nitrosoalbumin by gas chromatography-mass spectrometry. II. Quantitative determination of S-nitrosoalbumin in human plasma using S-[15N]nitrosoalbumin as internal standard.

A gas chromatographic-mass spectrometric method for the quantitative determination of S-nitrosoalbumin (SNALB) in human plasma is described. The method is based on selective extraction of SNALB and its 15N-labeled SNALB analog (S15NALB) used as internal standard on HiTrapBlue Sepharose affinity columns, Hg2+ -catalysed conversion of the S-nitroso groups to nitrite and [15N]nitrite, respectively, followed by their derivatization to the pentafluorobenzyl derivatives and quantification by GC-MS. Mean recovery of SNALB and S15NALB from plasma was 45%. Mean precision and accuracy within the range 0-10 microM was 95% and 99%, respectively. The limit of quantitation was determined as 100 nM at a precision of 93.8% and an accuracy of 94.8%. Considerable improvement of method sensitivity is possible by eliminating nitrite present in the elution buffer. The limit of detection was 0.2 nM corresponding to 67 amol of S15NALB. In 0.4-ml aliquots of plasma samples from healthy humans, endogenous SNALB was determined at concentrations of 181+/-150 nM (mean +/- SD, n = 23). External addition of SNALB to these plasma samples at 2 microM and 5 microM serving as quality control samples resulted in quantitative recovery of SNALB. Our results show that SNALB occurs in human plasma at concentrations at least one-order of magnitude smaller than those reported in the literature from measurements using chemiluminescence.

S-Transnitrosylation of albumin in human plasma and blood in vitro and in vivo in the rat

S-Nitrosoalbumin (SNOALB) is the most abundant physiological circulating nitric oxide (NO) carrier regulating NO-dependent biological actions in humans. The mechanisms of its formation and biological actions are still incompletely understood. Nitrosation by authentic NO and S-transnitrosylation of the single sulfhydryl group located at Cys-34 of human albumin by the physiological S-nitroso compounds S-nitrosocysteine (SNOC) and S-nitrosoglutathione (GSNO) are two possible mechanisms. On a quantitative basis, we investigated by gas chromatography-mass spectrometry the contribution of these two mechanisms to SNOALB formation in human plasma and blood in vitro. GSNO and SNOC (0-100 microM) rapidly and efficiently (recovery=35%) S-transnitrosylated albumin to form SNOALB. NO (100 microM) S-nitrosated albumin to SNOALB at a considerably lower extent (recovery=5%). The putative NO-donating drugs glyceryl trinitrate and sodium nitroprusside (each 100 microM) failed completely in S-nitrosating albumin. Bubbling NO into human plasma and blood resulted in formation of SNOALB that inhibited ADP-induced platelet aggregation. Infusion of GS(15)NO in the rat resulted in formation of S(15)NOALB, [(15)N]nitrate and [(15)N]nitrite. Our results suggest that S-transnitrosylation of albumin by SNOC and GSNO could be a more favored mechanism for the formation of SNOALB in the circulation in vivo than S-nitrosation of albumin by NO itself.

Doubts concerning functional endothelial nitric oxide synthase in human erythrocytes

To the editor: Nitric oxide (NO) is involved in the modulation of multiple physiologic functions. NO is produced from L-Arg by the catalytic action of NO synthase (NOS; EC 1.14.13.39).[1][1] Erythrocytes have been reported to express NOS,[2][2][][3][][4][][5][][6][][7]–[8][8] an eNOS isoform.[5][

High-performance liquid chromatographic analysis of nitrite and nitrate in human plasma as S-nitroso-N-acetylcysteine with ultraviolet absorbance detection

A rapid HPLC method with UV absorbance detection at 333 nm for the measurement of nitrite and nitrate in ultrafiltrate samples of human plasma is described. The method is based on hydrochloric acid-catalyzed conversion of nitrite by N-acetyl-L-cysteine to S-nitroso-N-acetyl-L-cysteine and isocratic elution using 10 mM NaH2PO4 in acetonitrile-water, pH 2.0 (15:85, v/v). The limit of detection of the method is 50 nM nitrite. The method was validated by gas chromatography-mass spectrometry.

Specific transport of S-nitrosocysteine in human red blood cells: Implications for formation of S-nitrosothiols and transport of NO bioactivity within the vasculature.

The transport of various S‐nitrosothiols, NO and NO donors in human red blood cells (RBC) and the formation of erythrocytic S‐nitrosoglutathione were investigated. Of the NO species tested only S‐nitrosocysteine was found to form S‐nitrosoglutathione in the RBC cytosol. l‐Serine, l‐cysteine and l‐lysine inhibited formation of S‐nitrosoglutathione. Incubation of RBC pre‐incubated with S‐[15N]nitroso‐l‐cysteine with native plasma or platelet‐rich plasma led to formation of S‐[15N]nitrosoalbumin and inhibited platelet aggregation, respectively. The specific transporter system of S‐nitroso‐l‐cysteine in the RBC membrane may have implications for formation of S‐nitrosoalbumin and S‐nitrosohemoglobin and for transport of NO bioactivity within the vasculature.