Nitric oxide contributes to behavioral, cellular, and developmental responses to low oxygen in Drosophila.

A nitric oxide (NO)/cyclic GMP (cGMP) signaling pathway is thought to play an important role in mammalian vasodilation during hypoxia. We show that Drosophila utilizes components of this pathway to respond to hypoxia. Hypoxic exposure rapidly induced exploratory behavior in larvae and arrested the cell cycle. These behavioral and cellular responses were diminished by an inhibitor of NO synthase and by a polymorphism affecting a form of cGMP-dependent protein kinase. Conversely, these responses were induced by ectopic expression of NO synthase. Perturbing components of the NO/cGMP pathway altered both tracheal development and survival during prolonged hypoxia. These results indicate that NO and protein kinase G contribute to Drosophila's ability to respond to oxygen deprivation.     

Dissimilatory nitrate reduction to nitrate, nitrous oxide, and ammonium by Pseudomonas putrefaciens.

The influence of redox potential on dissimilatory nitrate reduction to ammonium was investigated on a marine bacterium, Pseudomonas putrefaciens. Nitrate was consumed (3.1 mmol liter-1), and ammonium was produced in cultures with glucose and without sodium thioglycolate. When sodium thioglycolate was added, nitrate was consumed at a lower rate (1.1 mmol liter-1), and no significant amounts of nitrite or ammonium were produced. No growth was detected in glucose media either with or without sodium thioglycolate. When grown on tryptic soy broth, the production of nitrous oxide paralleled growth. In the same medium, but with sodium thioglycolate, nitrous oxide was first produced during growth and then consumed. Acetylene caused the nitrous oxide to accumulate. These results and the mass balance calculations for different nitrogen components indicate that P. putrefaciens has the capacity to dissimilate nitrate to ammonium as well as to dinitrogen gas and nitrous oxide (denitrification). The dissimilatory pathway to ammonium dominates except when sodium thioglycolate is added to the medium.     

Nitric oxide initiates iron binding to neocuproine.

It was demonstrated that two species of paramagnetic dinitrosyl iron complex (DNIC) with neocuproine form under the following conditions: in addition of neocuproine to a solution of DNIC with phosphate; in gaseous NO treatment of a mixture of Fe(2+) + neocuproine aqueous solutions at pH 6.5-8; and in addition of Fe(2+)--citrate complex + neocuproine to a S-nitrosocysteine (cys-NO) solution. The first form of DNIC with neocuproine is characterized by an EPR signal with g-factor values of 2.087, 2.055, and 2.025, when it is recorded at 77K. At room temperature, the complex displays a symmetric singlet at g = 2.05. The second form of DNIC with neocuproine gives an EPR signal with g-factor values of 2.042, 2.02, and 2.003, which can be recorded at a low temperature only.The revealed complexes are close to DNIC with cysteine in their stability. The ability of neocuproine to bind Fe(2+) in the presence of NO with formation of paramagnetic DNICs warrants critical reevaluation of the statement that neocuproine is only able to bind Cu(+) ions. It was suggested that the observed affinity of neocuproine to iron was due to transition of Fe(2+) in DNIC with neocuproine to Fe(+). In experiments on cys-NO, it was shown that the stabilizing effect of neocuproine on this compound could be due to neocuproine binding to the iron catalyzing decomposition of cys-NO.     

Neuronal nitric oxide synthase is resistant to ethanol.

To test for a possible role of nitric oxide (NO) in the neurotoxicity of ethanol, we studied the effects of ethanol on the neuronal NO synthase (nNOS) both in vitro and in vivo. Ethanol, up to 200 mM, did not change the NOS activity in the cerebellar homogenate or the production of NO by the cultured cerebellar granule cells. The number of NADPH diaphorase-positive cells in the culture did not change after the exposure to 200 mM ethanol in vitro. The NOS activity in the various brain regions of mice remained similar to the controls after the acute (3 g/kg) and the chronic (33 g/kg/day, 3.5 days) administration of ethanol. N(omega)-nitro-L-arginine, a NOS inhibitor, did not affect the ethanol-withdrawal behavior. These results indicate that nNOS is resistant to ethanol at clinically relevant concentrations and that ethanol affects the NO-operated system in the brain through a pathway other than that of nNOS.     

Conversion of proteins to diazeniumdiolate-based nitric oxide donors.

Michael reaction of the methoxymethyl-protected monodiazeniumdiolate of piperazine (MOM-PIPERAZI/NO) with 4-maleimidobutyric acid followed by its conversion to the N-hydroxy-succinimido ester produces a reagent capable of transferring the nitric oxide (NO)-donating diazeniumdiolate group to the terminal amines of the lysine residues contained in proteins. The reagent has been used to produce diazeniumdiolated bovine serum albumin (D-BSA) and diazeniumdiolated human serum albumin (D-HSA) containing 22 and 19 modified lysyl groups, respectively. Upon dissolution in pH 7.4 phosphate buffer at 37 degrees C, these albumin derivatives gradually released all of their contained NO (approximately 40 mol/mol of protein) with initial rates of about 30-40 pmol/min/mg and half-lives on the order of 3 weeks. This methodology is now available for use in exploiting the unique specific metabolic interactions of proteins to target NO therapy to specific physiological processes in vivo.     

The survival of skeletal muscle myoblasts in vitro is sensitive to a donor of nitric oxide and superoxide, SIN-1, but not to nitric oxide or peroxynitrite alone.

The survival of skeletal muscle myoblasts in culture after exposure either to a donor of NO, sodium nitroprusside (SNP), or ethanamine, 2,2'-(hydroxynitrosohydrazono)bis-(DETA NONOate), or to a donor of both NO and O(-)(2), 3-morpholinosydnonimine hydrochloride (SIN-1), was investigated. SIN-1 reduced clonogenic survival markedly but donors of NO alone did not. The injurious effect of SIN-1 was prevented by oxyhemoglobin or by uric acid but not by superoxide dismutase. The exposure of myoblasts to authentic peroxynitrite (ONOO(-)) or to DETA NONOate in the presence of an O(-)(2)-generating system did not reduce their survival. The results show that NO or ONOO(-) alone is not detrimental to myoblast survival and suggest that SIN-1 toxicity is, at least in part, mediated by H(2)O(2) in this myoblast culture system.     

Contributions of nitric oxide synthase isoforms to pulmonary oxygen toxicity, local vs. mediated effects

Reactive species of oxygen and nitrogen have been collectively implicated in pulmonary oxygen toxicity, but the contributions of specific molecules are unknown. Therefore, we assessed the roles of several reactive species, particularly nitric oxide, in pulmonary injury by exposing wild-type mice and seven groups of genetically altered mice to >98% O2 at 1, 3, or 4 atmospheres absolute. Genetically altered animals included knockouts lacking either neuronal nitric oxide synthase (nNOS(-/-)), endothelial nitric oxide synthase (eNOS(-/-)), inducible nitric oxide synthase (iNOS(-/-)), extracellular superoxide dismutase (SOD3(-/-)), or glutathione peroxidase 1 (GPx1(-/-)), as well as two transgenic variants (S1179A and S1179D) having altered eNOS activities. We confirmed our earlier finding that normobaric hyperoxia (NBO2) and hyperbaric hyperoxia (HBO2) result in at least two distinct but overlapping patterns of pulmonary injury. Our new findings are that the role of nitric oxide in the pulmonary pathophysiology of hyperoxia depends both on the specific NOS isozyme that is its source and on the level of hyperoxia. Thus, iNOS predominates in the etiology of lung injury in NBO2, and SOD3 provides an important defense. But in HBO2, nNOS is a major contributor to pulmonary injury, whereas eNOS is protective. In addition, we demonstrated that nitric oxide derived from nNOS is involved in a neurogenic mechanism of HBO2-induced lung injury that is linked to central nervous system oxygen toxicity through adrenergic/cholinergic pathways.     

Macrophage oxidation of L-arginine to nitric oxide, nitrite, and nitrate. Tetrahydrobiopterin is required as a cofactor

A new metabolic pathway characterized recently that is expressed in activated macrophages involves the formation of nitric oxide ('N = O) as an intermediate. The 'N = O formed decomposes to nitrite (NO2-) and nitrate (NO3-). The substrate for the reaction is the amino acid arginine which is oxidized at the guanido nitrogen to yield citrulline as the other product of the reaction. The studies reported here show that the activity for this unusual oxidation reaction which is contained in the 100,000 x g supernatant was lost after desalting on a Sephadex G-25 column. A small molecule cofactor was found to be required for the restoration of activity. The addition of (6R)-tetrahydrobiopterin (BH4) and NADPH led to complete recovery of activity in this desalted protein. Analysis of macrophage cell extracts, using high performance liquid chromatography with electrochemical detection, showed that BH4 was present at 17 pmol/10(6) cells or 2.1 microM in macrophage supernatant. Only the (6R)-isomer was present. With the addition of BH4 and NADPH, there was loss of arginine that was equal to the NO2-, NO3-, and citrulline formed. With substoichiometric levels of NADPH relative to BH4, the loss of arginine was greater than the formation of the end products of the reaction. A scheme for the reaction pathway consistent with the results involves N-hydroxylation of arginine as the initial step. The participation of BH4 in this type of oxidative chemistry is consistent with previous characterizations of this co-factor.     

Cytogenetic study of persons occupationally exposed to ethylene oxide.

Ten persons occupationally exposed to ethylene oxide (EO), used in the sterilization of medical instruments, were studied at a hospital. The estimated concentration to which they were exposed was 60-69 ppm, TWA. Peripheral blood samples from 10 workers and 10 controls of the same age and sex were taken to determine the frequency of sister-chromatid exchanges (SCE) and chromosomal aberrations (CA). The mean frequencies of SCE/cell (X = S) were 13.27 for the exposed workers and 6.05 for controls. Chromosome aberration frequencies in exposed individuals were significantly increased compared with controls. A significant relationship between the frequencies of SCE and CA and EO exposure was demonstrated. Blood chemistry parameters such as urea, creatinine, uric acid, lactic dehydrogenase, glutamic oxaloacetic and pyruvic transaminases, luteinizing gonadotropin and follicle stimulating gonadotropin and thyrotropin were also measured and found to be within the normal range.     

Nitric oxide binding to oxygenated hemoglobin under physiological conditions.

We have added nitric oxide (NO) to hemoglobin in 0.1 M and 0.01 M phosphate buffers as well as to whole blood, all as a function of hemoglobin oxygen saturation. We found that in all these conditions, the amount of nitrosyl hemoglobin (HbNO) formed follows a model where the rates of HbNO formation and methemoglobin (metHb) formation (via hemoglobin oxidation) are independent of oxygen saturation. These results contradict those of an earlier report where, at least in 0.01 M phosphate, an elevated amount of HbNO was formed at high oxygen saturations. A radical rethink of the reaction of oxyhemoglobin with NO under physiological conditions was called for based on this previous proposition that the primary product is HbNO rather than metHb and nitrate. Our results indicate that no such radical rethink is called for.     

Initial nitrous oxide,carbon dioxide,and methane costs of converting conservation reserve program grassland to row crops under no‐till vs. conventional tillage

Around 4.4 million ha of land in USDA Conservation Reserve Program (CRP) contracts will expire between 2013 and 2018 and some will likely return to crop production. No‐till (NT) management offers the potential to reduce the global warming costs of CO₂, CH₄, and N₂O emissions during CRP conversion, but to date there have been no CRP conversion tillage comparisons. In 2009, we converted portions of three 9–21 ha CRP fields in Michigan to conventional tillage (CT) or NT soybean production and reserved a fourth field for reference. Both CO₂ and N₂O fluxes increased following herbicide application in all converted fields, but in the CT treatment substantial and immediate N₂O and CO₂ fluxes occurred after tillage. For the initial 201‐day conversion period, average daily N₂O fluxes (g N₂O‐N ha^?1 d^?1) were significantly different in the order: CT (47.5 ± 6.31, n = 6) ? NT (16.7 ± 2.45, n = 6) ? reference (2.51 ± 0.73, n = 4). Similarly, soil CO₂ fluxes in CT were 1.2 times those in NT and 3.1 times those in the unconverted CRP reference field. All treatments were minor sinks for CH₄ (?0.69 ± 0.42 to ?1.86 ± 0.37 g CH₄–C ha^?1 d^?1) with no significant differences among treatments. The positive global warming impact (GWI) of converted soybean fields under both CT (11.5 Mg CO₂e ha^?1) and NT (2.87 Mg CO₂e ha^?1) was in contrast to the negative GWI of the unconverted reference field (?3.5 Mg CO₂e ha^?1) with on‐going greenhouse gas (GHG) mitigation. N₂O contributed 39.3% and 55.0% of the GWI under CT and NT systems with the remainder contributed by CO₂ (60.7% and 45.0%, respectively). Including foregone mitigation, we conclude that NT management can reduce GHG costs by ~60% compared to CT during initial CRP conversion.