The heme-copper oxidases of Thermus thermophilus catalyze the reduction of nitric oxide: evolutionary implications.

We show that the heme-copper terminal oxidases of Thermus thermophilus (called ba(3) and caa(3)) are able to catalyze the reduction of nitric oxide (NO) to nitrous oxide (N(2)O) under reducing anaerobic conditions. The rate of NO consumption and N(2)O production were found to be linearly dependent on enzyme concentration, and activity was abolished by enzyme denaturation. Thus, contrary to the eukaryotic enzyme, both T. thermophilus oxidases display a NO reductase activity (3.0 +/- 0.7 mol NO/mol ba(3) x min and 32 +/- 8 mol NO/mol caa(3) x min at [NO] approximately 50 microM and 20 degrees C) that, though considerably lower than that of bona fide NO reductases (300-4,500 mol NO/mol enzyme x min), is definitely significant. We also show that for ba(3) oxidase, NO reduction is associated to oxidation of cytochrome b at a rate compatible with turnover, suggesting a mechanism consistent with the stoichiometry of the overall reaction. We propose that the NO reductase activity of T. thermophilus oxidases may depend on a peculiar Cu(B)(+) coordination, which may be revealed by the forthcoming three-dimensional structure. These findings support the hypothesis of a common phylogeny of aerobic respiration and bacterial denitrification, which was proposed on the basis of structural similarities between the Pseudomonas stutzeri NO reductase and the cbb(3) terminal oxidases. Our findings represent functional evidence in support of this hypothesis.

Mechanism of S-nitrosothiol formation and degradation mediated by copper ions.

Experimental evidence is presented supporting a mechanism of S-nitrosothiol formation and degradation mediated by copper ions using bovine serum albumin, human hemoglobin and glutathione as models. We found that Cu(2+), but not Fe(3+), induces in the presence of NO a fast S-nitrosation of bovine serum albumin and human hemoglobin, and the reaction is prevented by thiol blocking reagents. During the reaction, Cu(+) is accumulated and accounts for destabilization of the S-nitrosothiol formed. In contrast, glutathione rapidly dimerizes in the presence of Cu(2+), the reaction competing with S-nitrosation and therefore preventing the formation of S-nitrosoglutathione. We have combined the presented role of Cu(2+) in S-nitrosothiol formation with the known destabilizing effect of Cu(+), providing a unique simple picture where the redox state of copper determines either the NO release from S-nitrosothiols or the NO scavenging by thiol groups. The reactions described are fast, efficient, and may occur at micromolar concentration of all reactants. We propose that the mechanism presented may provide a general method for in vitro S-nitrosation.

Nitric oxide and cellular respiration.

The role of nitric oxide (NO) as a signalling molecule involved in many pathophysiological processes (e.g., smooth muscle relaxation, inflammation, neurotransmission, apoptosis) has been elaborated during the last decade. Since NO has also been found to inhibit cellular respiration, we review here the available information on the interactions of NO with cytochrome c oxidase (COX), the terminal enzyme of the respiratory chain. The effect of NO on cellular respiration is first summarized to present essential evidence for the fact that NO is a potent reversible inhibitor of in vivo O2 consumption. This information is then correlated with available experimental evidence on the reactions of NO with purified COX. Finally, since COX has been proposed to catalyze the degradation of NO into either nitrous oxide (N2O) or nitrite, we consider the putative role of this enzyme in the catabolism of NO in vivo.

Chloride bound to oxidized cytochrome c oxidase controls the reaction with nitric oxide.

The reaction of nitric oxide (NO) with oxidized fast cytochrome c oxidase was investigated by stopped-flow, amperometry, and EPR, using the enzyme as prepared or after "pulsing." A rapid reduction of cytochrome a is observed with the pulsed, but not with the enzyme as prepared. The reactive species (lambdamax = 424 nm) reacts with NO at k = 2.2 x 10(5) M-1 s-1 at 20 degreesC and is stable for hours unless Cl- is added, in which case it decays slowly (t1/2 approximately 70 min) to an unreactive state (lambdamax = 423 nm) similar to the enzyme as prepared. Thus, Cl- binding prevents a rapid reaction of NO with the oxidized binuclear center. EPR experiments show no new signals within 15 s after addition of NO to the enzyme as prepared. Amperometric measurements show that the pulsed NO-reactive enzyme reacts with high affinity and a stoichiometry of 1 NO/aa3, whereas the enzyme as prepared reacts to a very small extent (<20%). In both cases, the reactivity is abolished by pre-incubation with cyanide. These experiments suggest that the effect of "pulsing" the enzyme, which leads to enhanced NO reactivity, arises from removing Cl- bound at the oxidized cytochrome a3-CuB site.

Determination of Sn(II) in technetium cold kits by voltammetry at the hanging mercury drop electrode (HMDE) and relevant radiopharmaceutical applications.

A novel approach for the determination of the stannous content in cold kits for labelling with 99mTc is described. The method is based on differential pulse polarography on the hanging mercury drop electrode in a methanol/water/perchloric acid mixture and is easy to perform. Examples for the determination of tin(II) in fractionated technetium cold kits are shown. The stability of tin(II) in solution was mainly dependent on the storage temperature and the kit composition. The low stability of stannous ions under certain conditions was shown to be the main reason for low radiochemical purity. Limits and dangers of fractionating kits are discussed and related to content and instability of tin(II).

Cytochrome c oxidase does not catalyze the anaerobic reduction of NO.

A possible role of reduced cytochrome c oxidase in the metabolism of nitric oxide (NO) has been examined with amperometric and stopped-flow photometric techniques. Reduced purified cytochrome c oxidase and mitochondria showed no catalytic reaction with NO under anaerobic conditions within more than 30 minutes. Only fast binding of NO to the reduced enzyme in a 1:1 stoichiometric ratio was observed. The NO binding rate was strongly decreased in the presence of 1 mM cyanide. These data indicate that, contrary to previous proposals, cytochrome c oxidase in the absence of oxygen does not contribute to physiological NO metabolism.

Direct determination of oxygen by HPLC. 1. Basic principles of a sensitive and selective oxygen sensor.

The basic principles of a novel, versatile, sensitive, and selective oxygen-sensing assay are presented in this paper. For the first time, liquid chromatography with electrochemical detection (at the hmde) has been used for the determination of oxygen. All factors concerning optimization of the chromatographic separation conditions and electrochemical detection with respect to direct determination of oxygen even in complex biological samples are discussed. Due to the combination of a chromatographic technique with amperometric detection, a high selectivity can be achieved. A direct and linear relationship between the oxygen concentration in the sample and the reduction current was verified in a large concentration range from saturation down to trace level oxygen concentrations. The novel oxygen-sensing assay provides a much higher sensitivity compared to conventional oxygen sensors. In principle, O(2) concentrations down to 4.5 × 10(-)(9) mol L(-)(1) O(2) (corresponding to a signal-to-noise ratio of 3) can be detected. Precision was determined by repeated measurements (n = 6) of air-saturated solutions (2.5 × 10(-)(4) mol L(-)(1) O(2), 20 °C, 920 mbar) which yielded relative standard deviations of lower than 0.2%.

Direct determination of oxygen by HPLC. 2. Chamber and sample application system for determination of o(2) at trace levels.

All oxygen measurement systems so far available are characterized by a lack of suitable precision and/or required limit of detection, which would be essential for a great variety of applications. In this paper, a novel oxygen chamber together with a completely new concept of sample application ("two-chamber-siphon technique") is presented which can be used in combination with the previously reported chromatographic oxygen sensor (part 1). This new oxygen-sensing assay exhibits several advantages in comparison to conventional oxygen measurement systems: e.g., the uncontrollable influence of the surrounding atmosphere as well as oxygen consumption and storage processes are excluded. For the first time, measurements of molecular oxygen below 1 × 10(-)(7) mol L(-)(1) can be performed. Reliable quantification of oxygen in liquids and also in gaseous and solid samples can be achieved with utmost sensitivity (LOD 4.9 × 10(-)(9) mol L(-)(1) O(2) = 98 fmol of oxygen on column) and precision (RSD = 0.7%, n = 8).

Determination of trace levels of niguldipine in urine and blood by adsorptive stripping voltammetry at the hanging mercury drop electrode.

A relatively simple electroanalytical procedure for the determination of niguldipine in biological samples is described. The technique involves adsorptive accumulation of the drug at the hanging mercury drop electrode (HMDE) followed by a differential-pulse polarographic determination of the preconcentrated species. The adsorptive stripping response is evaluated with respect to various experimental conditions, such as solvent composition and pH of the supporting electrolyte, accumulation potential and accumulation time. After a simple sample preparation, the method can be used for the determination of niguldipine in blood and urine. Interfering substances are simply removed by precipitation, adding a small amount of 5% ZnSO4 solution and ethanol to the urine or blood sample and centrifuging the mixture. A limit of detection of 6.7 ng per ml of urine and 41 ng per ml of blood is found with a mean recovery of 96% in urine and 71% in blood. The mean relative errors are 8.4% and 2.2%, respectively.

Adsorptive stripping voltammetry of nicardipine at a HMDE; determination of trace levels nicardipine in blood and urine.

The redox behaviour of nicardipine, a 1,4-dihydropyridine calcium antagonist, has been studied in different media on mercury, glassy carbon, gold and platinum electrodes using various voltammetric techniques. A highly sensitive adsorptive stripping voltammetric method for the determination of nicardipine based on adsorption of the drug onto mercury, followed by differential pulse voltammetric determination of the surface species, is described. All factors (pH, supporting electrolyte, accumulation potential and time, etc.) influencing adsorption as well as voltammetric response are discussed. The application of adsorptive stripping voltammetry at the hanging mercury drop electrode (HMDE) to the determination of trace levels of nicardipine in human urine and blood is illustrated, without an extraction procedure being necessary prior to the voltammetric measurement. A limit of detection of 4.8 ng per ml urine and 34 ng per ml blood is found with a mean recovery of nicardipine in urine and blood of 97%. The mean relative error does not exceed 6.5%.