Nitric oxide inhibits mitochondrial NADH:ubiquinone reductase activity through peroxynitrite formation.

This study was aimed at assessing the effects of long-term exposure to NO of respiratory activities in mitochondria from different tissues (with different ubiquinol contents), under conditions that either promote or prevent the formation of peroxynitrite. Mitochondria and submitochondrial particles isolated from rat heart, liver and brain were exposed either to a steady-state concentration or to a bolus addition of NO. NO induced the mitochondrial production of superoxide anions, hydrogen peroxide and peroxynitrite, the latter shown by nitration of mitochondrial proteins. Long-term incubation of mitochondrial membranes with NO resulted in a persistent inhibition of NADH:cytochrome c reductase activity, interpreted as inhibition of NADH:ubiquinone reductase (Complex I) activity, whereas succinate:cytochrome c reductase activity, including Complex II and Complex III electron transfer, remained unaffected. This selective effect of NO and derived species was partially prevented by superoxide dismutase and uric acid. In addition, peroxynitrite mimicked the effect of NO, including tyrosine nitration of some Complex I proteins. These results seem to indicate that the inhibition of NADH:ubiquinone reductase (Complex I) activity depends on the NO-induced generation of superoxide radical and peroxynitrite and that Complex I is selectively sensitive to peroxynitrite. Inhibition of Complex I activity by peroxynitrite may have critical implications for energy supply in tissues such as the brain, whose mitochondrial function depends largely on the channelling of reducing equivalents through Complex I.

Overexpression of neutrophil neuronal nitric oxide synthase in Parkinson's disease.

Much evidence supports a role of nitric oxide (.NO) and peroxynitrite (ONOO(-)) in experimental and idiopathic Parkinson's disease (PD); moreover, an overexpression of neuronal nitric oxide synthase (nNOS) was recently reported in the basal ganglia of PD patients. In accord, we previously found a 50% increased.NO production rate during the respiratory burst of circulating neutrophils (PMN) from PD patients. As PMN express the nNOS isoform, the objective of the present study was to ascertain whether this increased.NO production is representative of nNOS gene upregulation. PMN were isolated from blood samples obtained from seven PD patients and seven age- and sex-matched healthy donors; nNOS mRNA was amplified by reverse transcriptase-polymerase chain reaction and the products were hybridized with a probe for nNOS. Nitrotyrosine-containing proteins and nNOS were detected by Western blot and NO production rate was measured spectrophotometrically by the conversion of oxymyoglobin to metmyoglobin. The results showed that both.NO production and protein tyrosine nitration were significantly increased in PMN isolated from PD patients (PD 0.09 +/- 0.01 vs 0.06 +/- 0.008 nmol min(-1) 10(6) cells(-1); P < 0.05). In addition, five of the seven PD patients showed about 10-fold nNOS mRNA overexpression; while two of the seven PD patients showed an expression level similar to that of the controls; detection of nNOS protein was more evident in the former group. In summary, it is likely that overexpression of nNOS and formation of ONOO(-) in PMN cells from PD patients emphasizes a potential causal role of.NO in the physiopathology of the illness.

Oxidation of ubiquinol by peroxynitrite: implications for protection of mitochondria against nitrosative damage.

A major pathway of nitric oxide utilization in mitochondria is its conversion to peroxynitrite, a species involved in biomolecule damage via oxidation, hydroxylation and nitration reactions. In the present study the potential role of mitochondrial ubiquinol in protecting against peroxynitrite-mediated damage is examined and the requirements of the mitochondrial redox status that support this function of ubiquinol are established. (1) Absorption and EPR spectroscopy studies revealed that the reactions involved in the ubiquinol/peroxynitrite interaction were first-order in peroxynitrite and zero-order in ubiquinol, in agreement with the rate-limiting formation of a reactive intermediate formed during the isomerization of peroxynitrite to nitrate. Ubiquinol oxidation occurred in one-electron transfer steps as indicated by the formation of ubisemiquinone. (2) Peroxynitrite promoted, in a concentration-dependent manner, the formation of superoxide anion by mitochondrial membranes. (3) Ubiquinol protected against peroxynitrite-mediated nitration of tyrosine residues in albumin and mitochondrial membranes, as suggested by experimental models, entailing either addition of ubiquinol or expansion of the mitochondrial ubiquinol pool caused by selective inhibitors of complexes III and IV. (4) Increase in membrane-bound ubiquinol partially prevented the loss of mitochondrial respiratory function induced by peroxynitrite. These findings are analysed in terms of the redox transitions of ubiquinone linked to both nitrogen-centred radical scavenging and oxygen-centred radical production. It may be concluded that the reaction of mitochondrial ubiquinol with peroxynitrite is part of a complex regulatory mechanism with implications for mitochondrial function and integrity.

The regulation of mitochondrial oxygen uptake by redox reactions involving nitric oxide and ubiquinol.

The reversible inhibitory effects of nitric oxide (.NO) on mitochondrial cytochrome oxidase and O(2) uptake are dependent on intramitochondrial.NO utilization. This study was aimed at establishing the mitochondrial pathways for.NO utilization that regulate O-(2) generation via reductive and oxidative reactions involving ubiquinol oxidation and peroxynitrite (ONOO(-)) formation. For this purpose, experimental models consisting of intact mitochondria, ubiquinone-depleted/reconstituted submitochondrial particles, and ONOO(-)-supplemented mitochondrial membranes were used. The results obtained from these experimental approaches strongly suggest the occurrence of independent pathways for.NO utilization in mitochondria, which effectively compete with the binding of.NO to cytochrome oxidase, thereby releasing this inhibition and restoring O(2) uptake. The pathways for.NO utilization are discussed in terms of the steady-state levels of.NO and O-(2) and estimated as a function of O(2) tension. These calculations indicate that mitochondrial.NO decays primarily by pathways involving ONOO(-) formation and ubiquinol oxidation and, secondarily, by reversible binding to cytochrome oxidase.

Circulating plasma factors in Parkinson's disease enhance nitric oxide release of normal human neutrophils.

Nitric oxide (*NO)-mediated toxicity has been involved in neurodegenerative diseases, including Parkinson's disease (PD). We have recently reported an increase of about 50% in *NO production rate in PMA-activated polymorphonuclear leukocytes (PMN) from either newly diagnosed or chronically treated PD patients. As humoral factors in sera from PD patients could inhibit cell dopaminergic activity, the aim of this study was to determine whether a plasma circulating factor from PD patients could modify *NO metabolism in PMN from healthy control subjects. To this purpose, we determined simultaneously the maximal production rate of *NO and hydrogen peroxide (H2O2) of PMA-activated PMN isolated from healthy control subjects in the presence of aliquots of plasma of PD patients. The results showed that, after 30 min incubation, plasma from newly diagnosed (n=4) or from L-Dopa chronically treated (n=7) PD patients enhanced *NO release in neutrophils isolated from healthy controls by about 50% and 47% respectively, with respect to non-parkinsonian control plasma (n = 10); in the same condition, H2O2 production did not differ among the groups. These data suggest that an overproduction of *NO related to plasma circulating factors, already detected at initial stages of the disease, participates in the pathophysiology of Parkinson's disease.

The reaction of nitric oxide with ubiquinol: kinetic properties and biological significance.

The reaction of nitric oxide (*NO) with ubiquinol-0 and ubiquinol-2, short-chain analogs of coenzyme Q, was examined in anaerobic and aerobic conditions in terms of formation of intermediates and stable molecular products. The chemical reactivity of ubiquinol-0 and ubiquinol-2 towards *NO differed only quantitatively, the reactions of ubiquinol-2 being slightly faster than those of ubiquinol-0. The ubiquinol/*NO reaction entailed oxidation of ubiquinol to ubiquinone and reduction of *NO to NO-, the latter identified by its reaction with metmyoglobin to form nitroxylmyoglobin and indirectly by measurement of nitrous oxide (N2O) by gas chromatography. Both the rate of ubiquinone accumulation and *NO consumption were linearly dependent on ubiquinol and *NO concentrations. The stoichiometry of *NO consumed per either ubiquinone formed or ubiquinol oxidized was 1.86 A 0.34. The reaction of *NO with ubiquinols proceeded with intermediate formation of ubisemiquinones that were detected by direct EPR. The second order rate constants of the reactions of ubiquinol-0 and ubiquinol-2 with *NO were 0.49 and 1.6 x 10(4) M(-1)s(-1), respectively. Studies in aerobic conditions revealed that the reaction of *NO with ubiquinols was associated with O2 consumption. The formation of oxyradicals - identified by spin trapping EPR- during ubiquinol autoxidation was inhibited by *NO, thus indicating that the O2 consumption triggered by *NO could not be directly accounted for in terms of oxyradical formation or H2O2 accumulation. It is suggested that oxyradical formation is inhibited by the rapid removal of superoxide anion by *NO to yield peroxynitrite, which subsequently may be involved in the propagation of ubiquinol oxidation. The biological significance of the reaction of ubiquinols with *NO is discussed in terms of the cellular O2 gradients, the steady-state levels of ubiquinols and *NO, and the distribution of ubiquinone (largely in its reduced form) in biological membranes with emphasis on the inner mitochondrial membrane.

[Shock: concepts for a definition]. / Shock: conceptos para una definición.

The shock syndrome has been classically considered as a consequence of both decreased tissue perfusion and O2 supply; however, in some types of shock like septic or traumatic ones, regional blood flows may be increased. A decade ago, mitochondrial alterations consistent with uncoupling of oxidative phosphorylation were reported in either endotoxemic or hemorrhagic experimental shock or in humans. Recently, the discovery of nitric oxide (NO) and its increase in the shock state, has opened new perspectives in the understanding of this problem. Nitric oxide produces vasodilatation and, at the same time, increases the mitochondrial production of O2 active species like superoxide anion. Both radicals react to form a strong oxidant that is able to nitrate the phenolic rings of proteins: peroxynitrite. This effect leads to the impairment of the activities of different mitochondrial enzymes like succinate dehydrogenase and ATPase and the mitochondrial function and finally, to decreased energy levels and to multiorgan failure. The increase in NO release is due to the effects of circulating peptides and of increased adhesion of neutrophils to the endothelium and to the positive effects of inflammatory mediators like TNF-alpha and cytokines on inducible NOS (iNOS) expression in endothelium and tissues. It is suggested that the shock state is the consequence of an imbalance between NO and O2 and their metabolites.

Effects of respiratory burst inhibitors on nitric oxide production by human neutrophils.

Human neutrophils (PMN) activated by N-formylmethionyl-leucyl-phenylalanine (fMLP) simultaneously release nitric oxide (.NO), superoxide anion (O2.-) and its dismutation product, hydrogen peroxide (H2O2). To assess whether .NO production shares common steps with the activation of the NADPH oxidase, PMN were treated with inhibitors and antagonists of intracellular signaling pathways and subsequently stimulated either with fMLP or with a phorbol ester (PMA). The G-protein inhibitor, pertussis toxin (1-10 micrograms/ml) decreased H2O2 yield without significantly changing .NO production in fMLP-stimulated neutrophils; no effects were observed in PMA-activated cells. The inhibition of tyrosine kinases by genistein (1-25 micrograms/ml) completely abolished H2O2 release by fMLP-activated neutrophils; conversely, .NO production increased about 1.5- and 3-fold with fMLP and PMA, respectively. Accordingly, orthovanadate, an inhibitor of phosphotyrosine phosphatase, markedly decreased .NO production and increased O2.- release. On the other hand, inhibition of protein kinase C with staurosporine and the use of burst antagonists like adenosine, cholera toxin or dibutyryl-cAMP diminished both H2O2 and .NO production. The results suggest that the activation of the tyrosine kinase pathway in stimulated human neutrophils controls positively O2.- and H2O2 generation and simultaneously maintains .NO production in low levels. In contrast, activation of protein kinase C is a positive modulator for O2.- and .NO production.

Neutrophil function, nitric oxide, and blood oxidative stress in Parkinson's disease.

We studied nitrogen radical nitric oxide (.NO) release and reactive oxygen species (ROS) production by isolated neutrophils after phorbol myristate acetate (PMA) stimulation in 12 newly diagnosed and nine treated Parkinson's disease (PD) patients and 10 age-matched healthy controls. Neutrophils of both groups of PD patients had an elevated PMA-activated release of .NO [61 and 57%, respectively, higher than that of controls (p < 0.05)]. In contrast, H2O2 release was only significantly increased by 56% in chronically treated patients. In agreement, the maximum rate of luminol-dependent chemiluminescence, which partly represents O2- H2O2- .NO interactions, was increased only in the treated group. When other blood markers of oxidative stress were compared, only erythrocyte catalase activity was decreased in both PD patient series by 33 and 39%, respectively (p < 0.05), whereas plasma antioxidant capacity and erythrocyte superoxide dismutase activity levels were decreased only in treated PD patients. This study suggests that neutrophils express a primary alteration of .NO release in PD patients, whereas H2O2 and oxidative-stress parameters are more probably related to the evolution of PD or to effects of treatment with L-dopa.

Nitric oxide inhibits electron transfer and increases superoxide radical production in rat heart mitochondria and submitochondrial particles.

Nitric oxide (.NO) released by S-nitrosoglutathione (GSNO) inhibited enzymatic activities of rat heart mitochondrial membranes. Cytochrome oxidase activity was inhibited to one-half at an effective .NO concentration of 0.1 microM, while succinate- and NADH-cytochrome-c reductase activities were half-maximally inhibited at 0.3 microM .NO. Submitochondrial particles treated with .NO (either from GSNO or from a pure solution) showed increased O(-)(2) and H202 production when supplemented with succinate alone, at rates that were comparable to those of control particles with added succinate and antimycin. Rat heart mitochondria treated with .NO also showed increased H2O2 production. Cytochrome spectra and decreased enzymatic activities in the presence of .NO are consistent with a multiple inhibition of mitochondrial electron transfer at cytochrome oxidase and at the ubiquinone-cytochrome b region of the respiratory chain, the latter leading to the increased O2- production. Electrochemical detection showed that the buildup of a .NO concentration from GSNO was interrupted by submitochondrial particles supplemented with succinate and antimycin and was restored by addition of superoxide dismutase. The inhibitory effect of .NO on cytochrome oxidase was also prevented under the same conditions. Apparently, mitochondrial O2- reacts with .NO to form peroxynitrate and, by removing .NO, reactivates the previously inhibited cytochrome oxidase. It is suggested that, at physiological concentrations of .NO, inhibition of electron transfer, .NO-induced O2- production, and ONOO- formation participate in the regulatory control of mitochondrial oxygen uptake.

Sobre la computabilidad general de la psiquiatría clínica: ¿en que grado es conceptualmente posible procesar la psiquiatría clínica mediante sistemas de expertos? / About general computability of clinical psychiatry

Se examinan las perspectivas conceptuales de la formalización y la computabilidad de la Psiquiatría Clínica. El propósito de esta exploración es la plausibilidad de la aplicación correcta de los Sistemas de Expertos (SE) en Psiquiatría Clínica. Esto está fundado sobre la necesidad de que todo dominio de la aplicación de esquemas computacionales esté bien formalizado. El análisis señala cómo los avances de la sistematización han tenido éxito creciente en el diagnóstico y clasificaciones psiquiátricas en sistemas de uso universal -como el DSM y el ICD- en cuanto las definiciones de nomenclatura y taxonomía sean respetadas. En este aspecto y en la asignación de tratamientos la Psiquiatría Clínica se ha aproximado cada vez más al paradigma médico convencional. Bajo el trasfondo de los desarrollos psiquiátricos en representación del conocimiento (exploración y documentación normalizadas), la evaluación clarificadora (diagnóstico) y el estudio empírico del tratamiento psiquiátrico y con las necesarias restricciones es posible concluir que los SE pueden ser aplicados tanto al diagnóstico psiquiátrico como a la asignación de tratamiento -tanto cuanto la Psiquiatría Clínica esté fundada sobre las mismas definiciones de otros sistemas médicos expertos- a lo menos. Se enfatiza la necesidad de implementar sistemas amistosos con el usuario generados y adaptados localmente y se definen algunas características que sistemas como estos deberían tener. Finalmente, el límite de las aplicaciones en Psiquiatría Clínica depende a la vez de los desarrollos de la formalización en Psiquiatría como de los avances en el diseño de Sistemas de Expertos. Ambos dominios dependen de la Epistemología que subyace y alimenta ambas disciplinas. Esta fuerte dependencia es enfatizada. Horizontes y límites son indicados