New biological paramagnetic center: octahedrally coordinated nickel(III) in the methanogenic bacteria.

Methanobacterium bryantii was grown in medium supplemented with nickel-61, an isotope with a nuclear spin of 3/2. The appearance of nuclear hyperfine structure in the electron paramagnetic resonance spectrum of a cell extract identified a previously observed signal as nickel(III) in an environment of octahedral coordination with rhombic distortions.

Nitrite inhibition of Clostridium botulinum: electron spin resonance detection of iron-nitric oxide complexes.

Vegetative cells of Clostridium botulinum were shown to contain iron-sulfur proteins that react with added nitrite to form iron-nitric oxide complexes, with resultant destruction of the iron-sulfur cluster. Inactivation of iron-sulfur enzymes (especially ferredoxin) by binding of nitric oxide would almost certainly inhibit growth, and thus is probably the mechanism of botulinal inhibition by nitrite in foods.

Interleukin 1 beta induces the formation of nitric oxide by beta-cells purified from rodent islets of Langerhans. Evidence for the beta-cell as a source and site of action of nitric oxide.

Nitric oxide has recently been implicated as the effector molecule that mediates IL-1 beta-induced inhibition of glucose-stimulated insulin secretion and beta-cell specific destruction. The pancreatic islet represents a heterogeneous cell population containing both endocrine cells (beta-[insulin], alpha-]glucagon], gamma[somatostatin], and PP-[polypeptide] secreting cells) and non-endocrine cells (fibroblast, macrophage, endothelial, and dendritic cells). The purpose of this investigation was to determine if the beta-cell, which is selectively destroyed during insulin-dependent diabetes mellitus, is both a source of IL-1 beta-induced nitric oxide production and also a site of action of this free radical. Pretreatment of beta-cells, purified by FACS with IL-1 beta results in a 40% inhibition of glucose-stimulated insulin secretion that is prevented by the nitric oxide synthase inhibitor, NG-monomethyl-L-arginine (NMMA). IL-1 beta induces the formation of nitric oxide by purified beta-cells as evidenced by the accumulation of cGMP, which is blocked by NMMA. IL-1 beta also induces the accumulation of cGMP by the insulinoma cell line Rin-m5F, and both NMMA as well as the protein synthesis inhibitor cycloheximide prevent this cGMP accumulation. Iron-sulfur proteins appear to be intracellular targets of nitric oxide. IL-1 beta induces the formation of an iron-dinitrosyl complex by Rin-m5F cells indicating that nitric oxide mediates the destruction of iron-sulfur clusters of iron containing enzymes. This is further demonstrated by IL-1 beta-induced inhibition of glucose oxidation by purified beta-cells, mitochondrial aconitase activity of dispersed islet cells, and mitochondrial aconitase activity of Rin-m5F cells, all of which are prevented by NMMA. IL-1 beta does not appear to affect FACS-purified alpha-cell metabolic activity or intracellular cGMP levels, suggesting that IL-1 beta does not exert any effect on alpha-cells. These results demonstrate that the islet beta-cell is a source of IL-1 beta-induced nitric oxide production, and that beta-cell mitochondrial iron-sulfur containing enzymes are one site of action of nitric oxide.

The characterization of energized and partially de-energized (respiration-independent) beta-galactoside transport into Escherichia coli.

Unidirectional fluxes of [14C]lactose by whole cells of Escherichia coli under highly energized and partially de-energized (in the presence of CN-) conditions are analyzed kinetically. When the cells are energized, the value for V influx is 0.45 +/- 0.01 mM internal concentration increment/s and Kt is 0.26 +/- 0.03 mM. At an external concentration of 0.61 mM the steady-state internal concentration is 0.25 M, reached after about 1h. The maximum steady-state concentration ratio is 2-10(3). The efflux process under these conditions is non-saturable, being linearly dependent upon internal concentration over the range 25-250 mM with a first-order rate constant of 8.8 +/- 0.2-10(-4) S-1. The transport in the presence of CN- is active, with a maximum concentration ratio (internal concentration/external concentration) of 104, and the uptake is mimicked by anoxia (less than 70 ppm O2). The effects of CN- are to lower the V for influx and to change the efflux from a non-saturable to a saturable process with a value for Kt (60 mM) intermediate between that for energized efflux (greater than 250 mM) and influx (0.3-0.6 mM), the latter value not changing appreciably. Partial de-energization thus affects both the influx and efflux processes.

Aminoguanidine, a novel inhibitor of nitric oxide formation, prevents diabetic vascular dysfunction.

Increased blood flow and vascular leakage of proteins preferentially affect tissues that are sites of diabetic complications in humans and animals. These vascular changes in diabetic rats are largely prevented by aminoguanidine. Glucose-induced vascular changes in nondiabetic rats are also prevented by aminoguanidine and by NG-monomethyl-L-arginine (NMMA), an established inhibitor of nitric oxide (NO.) formation from L-arginine. Aminoguanidine and NMMA are equipotent inhibitors of interleukin-1 beta-induced 1) nitrite formation (an oxidation product of NO.) and cGMP accumulation by the rat beta-cell insulinoma cell line RINm5F, and 2) inhibition of glucose-stimulated insulin secretion and formation of iron-nitrosyl complexes by islets of Langerhans. In contrast, NMMA is approximately 40 times more potent than aminoquanidine in elevating blood pressure in nondiabetic rats. These results demonstrate that aminoguanidine inhibits NO. production and suggest a role for NO. in the pathogenesis of diabetic vascular complications.

Mechanism of lactose-proton cotransport in Escherichia coli. Kinetic results in terms of the site exposure model.

Rigorous kinetic derivations are presented for the Site Exposure mechanism of lactose-proton cotransport in E. coli [J. Theor. Biol. (1978) 75, 35-50]. Proton translocation inwards is solely associated with the external exposure of the galactoside binding site. A symmetric dimer configuration of the transporter is proposed, resulting in two forms corresponding to the cis and the trans orientation of the binding sites. The cis to trans orientation is inherently unfavorable, induced only by transmembrane substrate gradients. Recently reported extensive kinetic data are straightforwardly predicted by this mechanism, including the complicated effects on the apparent affinity and maximal velocity of uptake exhibited by changes in the magnitude of the proton electrochemical gradient.

Tetrahydrobiopterin-dependent nitrite oxidation to nitrate in isolated rat hepatocytes.

We have found that isolated rat hepatocytes and cell extracts catalyze the stoichiometric conversion of nitrite (either as a product of the oxidation of endogenously synthesized nitric oxide or added as sodium nitrite) to nitrate, which in extracts requires the presence of tetrahydrobiopterin and is inhibited by cyanide but apparently not by carbon monoxide. The reaction is sensitive to heat denaturation and does not involve oxidation of NO2- by a peroxidative or radical oxygen mechanism. These results indicate the presence of a hitherto undescribed mammalian mechanism of inorganic nitrogen oxide oxidation that may be a protective mechanism against one potentially damaging effect of endogenous .NO production (NO2- formation), and also that assays of .NO formation based on NO2- determination alone may be an inaccurate measurement of this activity.

Nitrogen oxide-induced autoprotection in isolated rat hepatocytes.

Pretreatment of rat hepatocytes with low-dose nitrogen oxide (addition of SNAP in vitro or induction of nitric oxide synthase in vitro or in vivo) imparts resistance to killing and decrease in aconitase and mitochondrial electron transfer from a second exposure to a higher dose of SNAP. Induction of this resistance is prevented by cycloheximide, indicating upregulation of protective protein(s). Ferritin levels are increased as are non-heme iron-NO EPR signals. Tin-protoporphyrin (SnPP) prevents protection, suggesting involvement of hsp32 (heme oxygenase) and/or guanylyl cyclase (GC). Cross-resistance to H2O2 killing is also observed, which is also prevented by cycloheximide and SnPP. Thus, hepatocytes possess inducible protective mechanisms against nitrogen oxide and reactive oxygen toxicity.

Coinduction of nitric oxide synthesis and intracellular nonheme iron-nitrosyl complexes in murine cytokine-treated fibroblasts.

Murine fibroblasts treated with interferon-gamma plus tumor necrosis factor-alpha plus lipopolysaccharide produce nitrite and EPR-observable intracellular nonheme iron-thiol-dinitrosyl species. Inhibition of .NO synthesis or de novo tetrahydrobiopterin (BH4) synthesis decreases nitrite and the EPR signal. The effects of BH4 synthesis inhibition are prevented by sepapterin, which increases BH4 through the salvage pathway.

Inhibition of target cell mitochondrial electron transfer by tumor necrosis factor.

Using digitonin permeabilization to assay mitochondrial electron transfer, we have found that respiratory activity (succinoxidase and cytochrome oxidase) in three mouse fibroblast lines is completely eliminated by incubation with human recombinant tumor necrosis factor-alpha (hrTNF). As with cytotoxicity, hrTNF-induced mitochondrial dysfunction occurs in resistant cells upon inhibition of protein synthesis, whereas sensitive cells exhibit spontaneous respiratory inhibition. In C3HA cells, inhibition is detectable 1.5-2 h after hrTNF addition, preceding cell lysis by at least 5 h (as measured by dye exclusion), and is approximately coincidental with morphological changes we have previously reported for this cell line. LM cells also exhibit inhibition of electron transfer, coincidental with morphological changes. These results suggest that bioenergetic dysfunction may be involved in the cytotoxic mechanism of TNF.

Rat liver postischemic lipid peroxidation and vasoconstriction depend on ischemia time.

In this investigation, we used chemiluminescence to study the ability of increasing durations of ischemia (1, 2, or 2.5 h) to induce enhanced generation of reactive oxygen species in a crystalloid perfused rat liver model. To evaluate the effect of reactive oxygen species generation upon the development of the postischemic hypoperfusion, hepatic vascular resistance was simultaneously monitored. One hour of ischemia did not produce sustained reactive oxygen species generation or development of no-reflow. Two hours of ischemia did not result in sustained reactive oxygen species generation but did produce no-reflow. Sustained reactive oxygen production was achieved after 2.5 h of ischemia and was accompanied by the development of no-reflow. We found that 2.5 h of ischemia is the threshold for sustained lipid peroxidation. Both lipid peroxidation and no-reflow could be mitigated through the administration of superoxide dismutase. Superoxide dismutase could reduce the amount of cell injury due to the enhanced lipid peroxidation induced by 2.5 h of ischemia. Limitation of reactive oxygen species generation to a critical threshold, either by restricting the duration of ischemia or by pharmacological intervention, may be an important means of preventing further cellular injury through no-reflow and lipid peroxidation.

Cellular antioxidant and pro-oxidant actions of nitric oxide.

We describe a biphasic action of nitric oxide (NO) in its effects on oxidative killing of isolated cells: low concentrations protect against oxidative killing, while higher doses enhance killing, and these two effects occur by distinct mechanisms. While low doses of NO (from (Z)-1-[N-(3-ammonio propyl)-N-(n-propyl)-amino]-diazen-1-ium-1,2(2) diolate [PAPA/NO] or S-nitroso-N-acetyl-L-penicillamine [SNAP] prevent killing of rat hepatocytes by t-butylhydroperoxide (tBH), further increasing doses result in increased killing. Similar effects occur with rat hepatoma cells treated with PAPA/NO and tBH or H2O2. Increased killing with higher concentrations of NO donor is due to both NO and tBH, because NO donor alone is without effect. Glutathione (GSH) is not involved in either of these actions. Based on measurements of thiobarbituric acid-reactive substances (TBARS) and effects of lipid radical scavenger (DPPD) and deferoxamine, the protective effect, but not the enhancing effect, involves peroxidative chemistry. Fructose has no effect on tBH killing alone but provides substantial protection against killing by higher concentrations of NO plus tBH, suggesting that the enhancing effect involves mitochondrial dysfunction. Hepatocytes, when stimulated to produce NO endogenously, become resistant to tBH killing, indicative of the presence of an NO-triggered antioxidant defensive mechanism. The finding that the protective effects of low concentrations of NO and the harmful effects of high concentrations of NO are fundamentally different in nature suggest that therapeutic interventions could be designed, which selectively prevent its pro-oxidant activity at high concentrations, thus converting NO from a "Janus-faced" modulator of oxidant injury into a "pure" protectant.

Regulation of tumor necrosis factor cytotoxicity by calcineurin.

Cyclosporin (CsA) inhibits mitochondrial death signaling and opposes tumor necrosis factor (TNF)-induced apoptosis in vitro. However, CsA is also a potent inhibitor of calcineurin, a phosphatase that may participate in cell death. Therefore, we tested the hypothesis that calcineurin regulates TNF cytotoxicity in rat hepatoma cells (FTO2B). TNF-treated FTO2B cells appeared apoptotic by DNA fragmentation, nuclear condensation, annexin V binding, and caspase activation. We studied two calcineurin inhibitors, CsA and FK506, and found that each potently inhibited TNF cytotoxicity. Western blot demonstrated calcineurin in FTO2B homogenates. In a model of mitochondrial permeability transition (MPT), we found that CsA prevented MPT and cytochrome c release, while FK506 inhibited neither. In summary, we present evidence that calcineurin participates in an apoptotic death pathway activated by TNF. CsA may oppose programmed cell death by inhibiting calcineurin activity and/or inhibiting mitochondrial signaling.

Multilocular cysts of the peritoneum.

Multilocular cysts of the peritoneum diagnosed at the Mayo Clinic from 1907 through 1981 were examined and divided, on the basis of their light microscopic features, into two groups--cystic mesotheliomas and cystic lymphangiomas. There are apparent clinical differences between the two groups. Cystic mesotheliomas tend to occur in adult females and often recur. Cystic lymphangiomas occur most often in males, often develop in children, and rarely recur, if at all. The distinguishing histologic features are the cytologic characteristics of the cells lining the cysts and the presence or absence of smooth muscle in the wall of the cysts.

Detection of nitric oxide by electron paramagnetic resonance spectroscopy during rejection and graft-versus-host disease after small-bowel transplantation in the rat.

BACKGROUND: Our previous observation that nitric oxide (NO) is synthesized during antigen-specific immune reactions in vitro led us to investigate whether NO is produced during the in vivo immune response to a vascularized organ allograft. METHODS: Orthotopic small-bowel transplantation in the rat was performed by standard microsurgical techniques in the LBNF1 to Lewis (rejection alone), Lewis to LBNF1 (graft-versus-host disease [GVHD] alone), and a syngeneic strain combination with and without immunosuppressive therapy with FK 506. The recipient serum NO2-/NO3- levels (stable end products of NO metabolism) were measured and erythrocytes were evaluated for the presence of nitrosylferrohemoglobin (specific for NO bound to hemoglobin). RESULTS: Animals that acutely rejected small-bowel allografts or suffered from acute GVHD showed significantly elevated serum NO2-/NO3- levels on days 6 and 9, and nitrosylferrohemoglobin electron paramagnetic resonance signals of different intensity were detected on days 3, 6, and 9. FK 506-treated allograft recipients and recipients of syngeneic grafts showed normal serum NO2-/NO3- levels and lacked nitrosylferrohemoglobin signals at all time points. CONCLUSIONS: This study indicates that NO is produced early during the course of small-bowel allograft rejection and GVHD and might therefore serve as a simple marker to detect such immune reactions.

Inhaled nitric oxide partially reverses hypoxic pulmonary vasoconstriction in the dog.

Nitric oxide (NO) inhaled during a hypoxia-induced increase in pulmonary vasomotor tone decreases pulmonary arterial pressure (Ppa). We conducted this study to better characterize the hemodynamic effects induced by NO inhalation during hypoxic pulmonary vasoconstriction in 11 anesthetized ventilated dogs. Arterial and venous systemic and pulmonary pressures and aortic flow probe-derived cardiac output were recorded, and nitrosylhemoglobin (NO-Hb) and methemoglobin (MetHb) were measured. The effects of 5 min of NO inhalation at 0, 17, 28, 47, and 0 ppm during hyperoxia (inspiratory fraction of O2 = 0.5) and hypoxia (inspiratory fraction of O2 = 0.16) were observed. NO inhalation has no measurable effects during hyperoxia. Hypoxia induced an increase in Ppa that reached plateau levels after 5 min. Exposure to 28 and 47 ppm NO induced an immediate (< 30 s) decrease in Ppa and calculated pulmonary vascular resistance (P < 0.05 each) but did not return either to baseline hyperoxic values. Increasing the concentration of NO to 74 and 145 ppm in two dogs during hypoxia did not induce any further decreases in Ppa. Reversing hypoxia while NO remained at 47 ppm further decreased Ppa and pulmonary vascular resistance to baseline values. NO inhalation did not induce decreases in systemic arterial pressure. MetHb remained low, and NO-Hb was unmeasurable. We concluded that NO inhalation only partially reversed hypoxia-induced increases in pulmonary vasomotor tone in this canine model. These effects are immediate and selective to the pulmonary circulation.

Effect of inhaled nitric oxide on pulmonary hemodynamics after acute lung injury in dogs.

Increased pulmonary vascular resistance (PVR) and mismatch in ventilation-to-perfusion ratio characterize acute lung injury (ALI). Pulmonary arterial pressure (Ppa) decreases when nitric oxide (NO) is inhaled during hypoxic pulmonary vasoconstriction (HPV); thus NO inhalation may reduce PVR and improve gas exchange in ALI. We studied the hemodynamic and gas exchange effects of NO inhalation during HPV and then ALI in eight anesthetized open-chest mechanically ventilated dogs. Right atrial pressure, Ppa, and left ventricular and arterial pressures were measured, and cardiac output was estimated by an aortic flow probe. Shunt and dead space were also estimated. The effect of 5-min exposures to 0, 17, 28, 47, and 0 ppm inhaled NO was recorded during hyperoxia, hypoxia, and oleic acid-induced ALI. During ALI, partial beta-adrenergic blockade (propranolol, 0.15 mg/kg i.v.) was induced and 74 ppm NO was inhaled. Nitrosylhemoglobin (NO-Hb) and methemoglobin (MetHb) levels were measured. During hyperoxia, NO inhalation had no measurable effects. Hypoxia increased Ppa (from 19.8 +/- 6.1 to 28.3 +/- 8.7 mmHg, P < 0.01) and calculated PVR (from 437 +/- 139 to 720 +/- 264 dyn.s.cm-5, P < 0.01), both of which decreased with 17 ppm NO. ALI decreased arterial PO2 and increased airway pressure, shunt, and dead space ventilation. Ppa (19.8 +/- 6.1 vs. 23.4 +/- 7.7 mmHg) and PVR (437 +/- 139 vs. 695 +/- 359 dyn.s.cm-5, P < 0.05) were greater during ALI than during hyperoxia. No inhalation had no measureable effect during ALI before or after beta-adrenergic blockade. MetHb remained low, and NO-Hb was unmeasurable. Bolus infusion of nitroglycerin (15 micrograms) induced an immediate decrease in Ppa and PVR during ALI.(ABSTRACT TRUNCATED AT 250 WORDS)

Hemodynamic effects and metabolic fate of inhaled nitric oxide in hypoxic piglets.

We describe the hemodynamic effects and metabolic fate of inhaled NO gas in 12 anesthetized piglets. Pulmonary and systemic hemodynamic responses to incremental [NO] (5-80 ppm) were tested during ventilation with high- [0.30 inspired O2 fraction (FIO2)] and low-O2 (0.10 FIO2) mixtures. In six animals, inhalation of 40 ppm NO was maintained over 6 h to test effects of prolonged exposure (0.30 FIO2). In the other six animals, pulmonary hypertension was induced by hypoxic ventilation (0.10 FIO2) and responses to NO were tested. Inhaled low [NO] partially reversed pulmonary hypertension induced by alveolar hypoxia; mean pulmonary arterial pressure decreased from 31.4 +/- 2.3 mmHg during hypoxia to 18.2 +/- 1.2 mmHg during 5 ppm NO. Mean pulmonary arterial pressure at 0.10 FIO2 did not fall further at higher [NO] (10-40 ppm) and never reached control levels. Pulmonary vascular resistance increased with institution of hypoxic ventilation and fell with subsequent administration of NO, ultimately reaching control levels. Inhaled NO did not affect systemic vascular resistance. Plasma levels of NO2- + NO3- and methemoglobin (MetHb) levels increased with increasing [NO]. Over 6 h of NO administration during high-O2 ventilation, MetHb equilibrated at subtoxic levels while NO2- + NO3- increased. Nitrosylhemoglobin, analyzed by electron paramagnetic resonance spectrophotometry was not detected in blood at any time. At the relatively low concentrations (5-80 ppm) that are effective in relieving experimental pulmonary hypertension induced by alveolar hypoxia, inhaled NO gas causes accumulation of NO2- + NO3- in plasma and a small increase in MetHb but no detectable nitrosylhemoglobin.

Mild hypothermia protects against postischemic hepatic endothelial injury and decreases the formation of reactive oxygen species.

The ability of mild hypothermia (MH; 34 degrees C) to protect against postischemic endothelial injury and decrease reactive oxygen species' (ROS) formation was studied using lucigenin and luminol enhanced chemiluminescence (CL). Lucigenin CL is largely specific for superoxide, while luminol reacts with many ROS. Isolated rat livers perfused under constant flow in a non-recirculating system were exposed to 2.5 h of ischemia after 0.5 h perfusion with Krebs-Henseleit buffer at either normothermia (38 degrees C) or mild hypothermia (34 degrees C) (n = 5, all groups). CL (cps), vascular resistance (Woods units), O2 consumption, and potassium efflux were measured at the end of perfusion, and at 0 min reperfusion, and every 30 min during reperfusion. For both the lucigenin and luminol groups, CL and vascular resistance increased significantly (repeat measures ANOVA, P <0.05) for normothermia (NT, 38 degrees C) but not mild hypothermia. Potassium efflux did not change significantly for the mild hypothermia groups. In the luminol enhanced group, oxygen consumption was greater in the mildly hypothermic group at 1 h and 1.5 h of reperfusion. Mild hypothermia decreased postischemic ROS production. Increased vascular resistance in the normothermia group may indicate an endothelial injury. Mild hypothermia appears to protect against this injury.

Nitric oxide metabolism in canine sepsis: relation to regional blood flow.

PURPOSE: To investigate the role of nitric oxide (NO) in early endotoxemia on the systemic and regional blood flow by measuring the plasma nitrite/nitrate (NOx) and blood nitrosyl-hemoglobin (NO-Hb) levels. MATERIALS AND METHODS: This was a prospective, controlled, experimental study conducted in an animal research laboratory on 15 male mongrel dogs. Escherichia coli endotoxin (1 mg/kg) was injected intravenously. RESULTS: Hepatic, renal, and iliac blood flow and cardiac output (CO) were measured before and 15, 30, 45, 90 and 180 minutes after injection of Escherichia coli endotoxin (1 mg/kg) (n = 6). NOx efflux from the organs was calculated by measuring plasma NOx levels. The arterial blood levels of NO-Hb were also measured (n = 4). As control studies, blood samples from dogs (n = 5) without exposure to endotoxin were assayed at 180 minutes for NOx and NO-Hb. Following endotoxin injection, mean arterial pressure decreased and reached its lowest value at 90 minutes (baseline vs. 90 minutes: 119.1+/-5.8 vs. 82.5+/-16.7 mm Hg, P<.0001). Hepatic artery blood flow increased significantly (baseline vs. 180 minutes: 23.6+/-12.0 vs. 170.0+/-68.4 mL/ min, P<.0001). There were no significant changes in plasma levels of NOx, uptake or release of NOx across the measured vascular beds, NO-Hb levels at any time point. In the portal system, the portal vein flow correlated with NOx release (R = 0.69, P<.0001). CONCLUSION: In the early phase of endotoxemia in the dog, the significant reduction in systemic vascular resistance and hepatic arterial resistance are not associated with any measurable NOx release in the systemic circulation or the liver.