The McClure and Weiss models of Fe–O2 bonding for oxyhemes, and the HbO2 + NO reaction

For the Fe–O₂(S = 0) linkages of oxyhemes, valence bond (VB) structures are re-presented for the McClure [Fe^II(S = 1) + O₂(S = 1)], Pauling–Coryell [Fe^II(S = 0) + O₂*(S = 0)], and Weiss [Fe^III(S = ½) + O₂ ^?(S = ½)] models of bonding. The VB structures for the McClure and Weiss models are of the increased-valence type, with more electrons participating in bonding than occur in their component Lewis structures. The Fe–O bond number and O–O bond order for the McClure structure are correlated with measured Fe–O and O–O bond lengths for oxymyoglobin. Back-bonding from O ₂ ^? to Fe^III of the Weiss structure gives a restricted form of the McClure structure. The McClure and Weiss increased-valence structures are used to provide VB formulations of mechanisms for the oxyhemoglobin + NO reaction. The products of these two formulations are Hb⁺ and NO₃ ^? (where Hb is hemoglobin) and Hb⁺ and OONO^?, respectively. Because Hb⁺ and NO₃ ^? are the observed products, they provide an experimental procedure for distinguishing the McClure and Weiss models. It is also shown that the same type of agreement between McClure-type theory and experiment occurs for oxycoboglobin + NO, cytochrome P450 monooxygenases, and related hydrogen atom transfer reactions. In the appendices, the results of density functional theory and multireference molecular orbital calculations for oxyhemes are related to one formulation of the increased-valence wavefunction for the McClure model, and theory is presented for the calculation of approximate weights for the Lewis structures that are components of the McClure increased-valence structure.     

Structure of microbial communities performing the simultaneous reduction of Fe(II)EDTA.NO2−and Fe(III)EDTA−

BioDeNOx is a combined physicochemical and biological process for the removal of nitrogen oxides (NOx) from flue gas. In the present study, two anaerobic bioreactors performing BioDeNOx were run consecutively (RUN-1 and RUN-2) at a dilution rate of 0.01 h⁻¹ with Fe(II)EDTA.NO²⁻ and Fe(III)EDTA⁻ as electron acceptors and ethanol as electron donor. The measured protein concentration of the reactor biomass of both runs was 120 mg/l. Different molecular methods were used to determine the identity and abundance of the bacterial populations in both bioreactors. Bacillus azotoformans strain KT-1 was recognized as a key player in Fe(II)EDTA.NO²⁻ reduction. PCR-denaturing gradient gel electrophoresis analysis of the reactor biomass showed a greater diversity in RUN-2 than in RUN-1. Enrichments of Fe(II)EDTA.NO²⁻ and Fe(III)EDTA⁻ reducers and activity assays were conducted using the biomass from RUN-2 as an inoculum. The results on substrate turnover, overall microbial diversity, and enrichments and finally activity assays confirmed that ethanol was used as electron donor for Fe(II)EDTA.NO²⁻ reduction. In addition, the Fe(III)EDTA⁻ reduction rate of the microbial community proved to be feasible enough to run the bioreactors, ruling out the chemical reduction of Fe(III)EDTA⁻ with sulfide as was proposed by other researchers.     

Oxides of Nitrogen (NO· and NO2 –) as Cofactors of the Myeloperoxidase System

Myeloperoxidase is the main peroxisomal protein of neutrophils, monocytes, and a subpopulation of tissue macrophages; it plays the key role in protective and inflammatory responses of the organism. This role is mediated by various diffusible radicals formed during oxidative reactions catalyzed by the enzyme heme. Myeloperoxidase and nitric oxide synthase are stored in peroxisomes. Nitric oxide reacts with the heme of myeloperoxidase. Low nitric oxide concentrations increase peroxidase activity through reduction of Compound II to native myeloperoxidase. Conversely, high nitric oxide concentrations inhibit the catalytic activity of myeloperoxidase through formation of inactive nitrosyl–heme complexes. Such effect of nitric oxide on catalytic activity of myeloperoxidase has various consequences for infectious and local inflammatory processes. Another oxide of nitrogen, nitrite, is a good substrate for myeloperoxidase Compound I but slowly reacts with Compound II. Nitrogen dioxide is formed after nitrite oxidation by myeloperoxidase. Formation of nitrogen dioxide is another protective mechanism and nitration of microbial proteins by myeloperoxidase can represent an additional protective response of peroxisomes.     

EPR and M?ssbauer studies of protocatechuate 4,5-dioxygenase. Characterization of a new Fe2+ environment

Protocatechuate 4,5-dioxygenase from Pseudomonas testosteroni has been purified to homogeneity and crystallized. The iron containing, extradiol dioxygenase is shown to be composed of two subunit types (alpha, Mr = 17,700 and beta, Mr = 33,800) in a 1:1 ratio; such a composition has not been observed for other extradiol dioxygenases. The 4.2 K M?ssbauer spectrum of native protocatechuate 4,5-dioxygenase prepared from cells grown in 57Fe-enriched media consists of a doublet with quadrupole splitting, delta EQ = 2.22 mm/s, and isomer shift delta Fe = 1.28 mm/s, demonstrating a high spin Fe2+ site. These parameters, and the temperature dependence of delta EQ, are unique among enzymes but are strikingly similar to those reported for the reaction center of the photosynthetic bacterium Rhodopseudomonas sphaeroides R-26, suggesting very similar ligand environments. The Fe2+ of protocatechuate 4,5-dioxygenase can be oxidized, for instance by H2O2, to yield high spin Fe3+ with EPR g values around g = 6 (and g = 4.3). In the oxidized state, protocatechuate 4,5-dioxygenase is inactive; the iron, however, can be rereduced by ascorbate to yield active enzyme. Our data suggest that protocatechuate binds to Fe2+; the spectra indicate that the ligand binding is heterogenous. The M?ssbauer spectra observed here are fundamentally different from those reported earlier (Zabinski, R., Münck, E., Champion, P., and Wood, J. M. (1972) Biochemistry 11, 3212-3219). The spectra of the earlier (reconstituted) preparations, which had substantially lower specific activities, probably reflect adventitiously bound Fe3+. We discuss here how adventitiously bound iron can be identified and removed. The Fe2+ which is present in native protocatechuate 4,5-dioxygenase and its complexes with substrates and inhibitors reacts quantitatively with nitric oxide to produce a species with electronic spin S = 3/2. The EPR and M?ssbauer spectra of these complexes compare favorably with EDTA . Fe(II) . NO. We have studied the latter complex extensively and have analyzed the M?ssbauer spectra with an S = 3/2 spin Hamiltonian. EPR spectra show that protocatechuate 4,5-dioxygenase-NO complexes with substrates or inhibitors are heterogeneous and consist of several well defined subspecies. The data show that NO, and presumably also O2, has access to the active site Fe2+ in the enzyme-substrate complex. The use of EPR-detectable NO complexes as a rapid and sensitive tool for the study of the EPR silent active site iron of extradiol dioxygenases is discussed.     

M?ssbauer studies of aconitase. Substrate and inhibitor binding, reaction intermediates, and hyperfine interactions of reduced 3Fe and 4Fe clusters

Active beef heart aconitase contains a [4Fe-4S] cluster. One iron of the cluster, Fea, is labile and can be removed easily by oxidation in air to yield the [3Fe-4S]1+ cluster of inactive aconitase. We have previously shown that substrate binds to Fea. We have continued our M?ssbauer studies by further investigating the active and inactive forms of the enzyme. When active aconitase, [4Fe-4S]2+, is mixed with substrate, two species (substrates or intermediates bound to Fea) labeled S1 and S2 are obtained. With the nitroanalogs of citrate and isocitrate, thought to be transition state analogs, and fluorocitrate, species S2, but not S1, is observed, suggesting that S2 represents a carbanion transition state complex. We have prepared M?ssbauer samples by rapid mix/rapid freeze techniques. Using either citrate, isocitrate or cis-aconitate, the natural substrates, we have been able to detect at 0 degree C reaction intermediates in the 5-35 ms time range and, studying enzyme substrate interactions at subzero temperatures in a water/methanol/ethylene glycol solvent, we have observed new species when substrates were added at -60 degrees C. Details of these experiments are given, although in neither case can unique interpretations be offered at this time. We have also investigated reduced active aconitase ([4Fe-4S]1+; EPR at g = 1.94) in the presence of substrate with material selectively enriched with 57Fe in either Fea or the other three cluster sites. The spectra were analyzed with a spin Hamiltonian, and the results are discussed and interpreted in terms of three inequivalent Fe sites in the cluster. Finally, we have studied enzyme containing the reduced [3Fe-4S]0 cluster. There is no indication that citrate binds to the 3Fe cluster, and since no significant activity was observed, we conclude that aconitase containing a 3Fe cluster is not active in either oxidation state.     

Effect of Supplemental Electron Donors on the Microbial Reduction of Fe(III), Sulfate, and CO2 in Coal Mining–Impacted Freshwater Lake Sediments

Abstract In acidic mining-impacted lake sediments, the microbial reduction of Fe(III) is the dominant electron-accepting process, whereas the reduction of sulfate seems to be restricted to a narrow sediment zone of elevated pH and lower amounts of total and reactive iron. To evaluate the microbial heterogeneity and the commensal interactions of the microbial community, the flow of supplemental carbon and reductant was evaluated in four different zones of the sediment in anoxic microcosms at the in situ temperature of 12°C. Substrate consumption, product formation, and the potential to reduce Fe(III) and sulfate were similar with both upper and lower sediment zones. In the upper acidic iron-rich sediment zone, the rate of Fe(II) formation 204 nmol ml⁻¹ d⁻¹ was enhanced to 833 nmol ml⁻¹ d⁻¹ and 462 nmol ml⁻¹ d⁻¹ by supplemental glucose and H₂, respectively. Supplemental lactate and acetate were not consumed under acidic conditions and decreased the rate of Fe(II) formation to 130 nmol ml⁻¹ d⁻¹ and 52 nmol ml⁻¹ d⁻¹, respectively. When the pH of the upper sediment increased above pH 5, acetate-dependent reduction of sulfate was initiated even though the pool of Fe(III) was not depleted. In deeper sediment zones with elevated pH, the rapid consumption of acetate was always coincident to a decrease in the concentration of sulfate and soluble Fe(II), indicating the formation of Fe(II) sulfides. Although the reduction of Fe(III) was still an ongoing process in deeper sediment zones, the formation of Fe(II) was only slightly enhanced by the consumption of glucose or cellobiose, but not by H₂ or acetate. H₂-utilizing acetogens seemed to be involved in the consumption of H₂. These collective results indicated (i) that the reduction of Fe(III) predominated over the reduction of sulfate as long as the sediment remained acidic and carbon-limited, and (ii) that the sulfate-reducing microbiota in this heterogeneous sediment were better adapted to the geochemical gradients present than were other neutrophilic dissimilatory Fe(III) reducers. Received: 17 February 2000; Accepted: 22 June 2000; Online Publication: 28 August 2000     

Characteristics of Injury and Recovery of Net NO3? Transport of Barley Seedlings from Treatments of NaCl

The nature of the injury and recovery of nitrate uptake (net uptake) from NaCl stress in young barley (Hordeum vulgare L, var CM 72) seedlings was investigated. Nitrate uptake was inhibited rapidly by NaCl, within 1 minute after exposure to 200 millimolar NaCl. The duration of exposure to saline conditions determined the time of recovery of NO₃⁻ uptake from NaCl stress. Recovery was dependent on the presence of NO₃⁻ and was inhibited by cycloheximide, 6-methylpurine, and cerulenin, respective inhibitors of protein, RNA, and sterol/fatty acid synthesis. These inhibitors also prevented the induction of the NO₃⁻ uptake system in uninduced seedlings. Uninduced seedlings exhibited endogenous NO₃⁻ transport activity that appeared to be constitutive. This constitutive activity was also inhibited by NaCl. Recovery of constitutive NO₃⁻ uptake did not require the presence of NO₃⁻.     

Reduction of maternal care: a new benefit of multiple mating?

Cost/benefit analyses have been used to understand the evolutionof mating by females with multiple males, as in extrapair copulations(EPCs), which are now known to occur commonly in socially monogamousand polygynous birds. Indirect (genetic) benefits have beeninvoked to explain such mating patterns in some cases, butdirect benefits have received less attention. We report a studyof direct benefits in the communally rearing Mexican jay (Aphelocoma ultramarina). The social mate of the mother (putative father)is the most reliable feeder of the young in his nest, regardlessof cuckoldry. Feedings provided by social fathers are not reducedin relation to their paternity loss. In contrast, mothers havingnestlings sired by a second male tend to have lower feedingrates than those without such young. Secondary fathers provideda significantly higher level of feeding to the brood of theirfemale than did (1) random nonbreeders of all ages and bothsexes, (2) random male nonbreeders of all ages, and (3) older(2+ years), male nonbreeders. Surprisingly, however, broodswith two fathers did not receive a higher level of total feeding,despite our observation that two-father broods had two more helpers, on average, compared to broods without extra fathers.Regardless of age or breeding status, males were more frequentfeeders than females. This study provides the first evidencethat one of the major costs of reproduction, maternal careof nestlings, is reduced for females that have young sired by secondary males.     

Reduction of metabolism during hibernation and daily torpor in mammals and birds: temperature effect or physiological inhibition?

Summary The present study addresses the controversy of whether the reduction in energy metabolism during torpor in endotherms is strictly a physical effect of temperature (Q₁₀) or whether it involves an additional metabolic inhibition. Basal metabolic rates (BMR; measured as oxygen consumption, ), metabolic rates during torpor, and the corresponding body temperatures (T _b) in 68 mammalian and avian species were assembled from the literature (n=58) or determined in the present study (n=10). The Q₁₀ for change in between normothermia and torpor decreased from a mean of 4.1 to 2.8 with decreasingT _b from 30 to <10°C in hibernators (species that show prolonged torpor). In daily heterotherms (species that show shallow, daily torpor) the Q₁₀ remained at a constant value of 2.2 asT _b decreased. In hibernators with aT _b<10°C, the Q₁₀ was inversely related to body mass. The increase of mass-specific metabolic rate with decreasing body mass, observed during normothermia (BMR), was not observed during torpor in hibernators and the slope relating metabolic rate and mass was almost zero. In daily heterotherms, which had a smaller Q₁₀ than the hibernators, no inverse relationship between the Q₁₀ and body mass was observed, and consequently the metabolic rate during torpor at the sameT _b was greater than that of hibernators. These findings show that the reduction in metabolism during torpor of daily heterotherms and large hibernators can be explained largely by temperature effects, whereas a metabolic inhibition in addition to temperature effects may be used by small hibernators to reduce energy expenditure during torpor.Abbreviation BMR basal metabolic rate     

Hg2+-induced leakage of electrolytes and inhibition of NO3 − utilization inNostoc calcicola

Summary The effect of mercury (Hg²⁺) in the absence and presence of methylmercury (CH₃Hg⁺), cadmium (Cd²⁺), copper (Cu²⁺), nickel (Ni²⁺) and calcium (Ca²⁺) on Nostoc calcicola Bréb. has been studied in terms of electrolyte leakage, NO₃ ^– uptake and in vivo nitrate reductase (NR) activity to discover any possible correlation among such parameters under Hg²⁺ stress. Leakage of electrolytes from Hg²⁺-treated cyanobacterial cells was directly proportional to Hg²⁺ concentrations and exposure time. In comparison to NO₃ ^– uptake, an about 60-fold slower rate of NR activity was observed in the untreated cultures, the former being five times more Hg²⁺-sensitive. A non-competitive synergistic interaction of Hg²⁺ with CH₃Hg⁺ or Cd²⁺ and antagonistic with that of Ni²⁺ or Ca²⁺ has been observed for both the processes of NO₃ ^– utilization. The antagonistic interaction of Cu²⁺ with Hg²⁺ in terms of NO₃ ^– uptake and synergistic with respect to NR activity, has been attributed to the dual bonding preference of Cu²⁺ for cellular ligands. These findings suggest that (a) a statistically significant correlation exists among such parameters; (b) Hg²⁺ predominantly attacks the cyanobacterial cell membrane; (c) Hg²⁺ inhibits NO₃ ^– utilization; (d) the presence of other cations increases or decreases the inhibitory actions of Hg²⁺.     

Sequential Oxidation and Reduction of Mono Methyl Ethers of Methyl 4,6-O-Benzylidene-α- and β-d-Glucopyranosides

(1) Both glutaminases A and B of Pseudomonas aeruginosa are inactivated by urea and guanidine hydrochloride, and the activities are partially restored by removal of the denaturants, while sodium lauryl sulfate denatured irreversibly the isozymes. (2) Glutaminase A consists of 4 identical subunits (mol. wt, 35,000) and B is composed of one polypeptide chain (mol. wt., 67,000). (3) Glutaminase A, which catalyzes the hydrolysis and also the hydroxylaminolysis of L and D isomers of glutamine and asparagine, does not act on γ-N-substituted glutamine e.g., γ-glutamylhydrazide. Some l- and d-γ-glutamyl derivatives, e.g., l- and d-γ-glutamyl-hydrazide, l- and d-γ-glutamylmethylester, and l-γ-glutamyl-l-alanine are substrates for glutaminase B, which does not catalyze the hydrolysis and hydroxylaminolysis of asparagine. α-Amino adipamic acid and α-amino substituted amino acids are inert for both the isozymes. (4) The acylation step is rate-limiting in the catalytic reactions by both the isozymes.     

Reaction of peroxynitrite with carbon dioxide: intermediates and determination of the yield of CO3 •– and NO2 •

CO2 catalyses the isomerization of the biological toxin ONOO- to NO3- via an intermediate, presumably ONOOCO2-, which has an absorption maximum near 650 nm. The reflection spectrum of solid NMe4+ ONOO- exposed to CO2 shows a similar band near 650 nm; this absorption decays over minutes. Stopped-flow experiments in which CO2 solutions were mixed with alkaline ONOO- solutions indicate the formation of at least one intermediate. The initial absorption at 302 nm is less than that of ONOO-, which indicates that reactions take place within the mixing time, and this absorption is dependent (but not linearly) on the ONOO- and CO2 concentrations. We found that reaction of peroxynitrite with carbon dioxide forms some trioxocarbonate(*1-) (CO3*-) and nitrogen dioxide (NO2*) radicals via homolysis of the O-O bond in ONOOCO2-. We determined the extent of radical formation by mixing peroxynitrite, carbon dioxide and nitrogen monoxide. The later reacts with CO3*- and NO2* radicals to form, effectively, three NO2- per homolysis; ONOOCO2- that does not undergo homolysis yields NO3- and CO2. Based on the NO3- and NO2- analyses, the extent of conversion to NO3- is 96 +/- 1% and that of homolysis is 3 +/- 1%, respectively, significantly less than that reported in the literature.     

On the reactivity of tetracyanonitrosylferrate(2−). III. Redox reactivity of [Fe(CN)4NO]2−

Redox properties of the ion [Fe(CN)₄NO]²⁻ were studied electrochemically both in non-aqueous and aqueous media in the absence of free cyanide ions. It was found that while the reduction proceeds smoothly the oxidation is not observed at the electrode in the attainable potential range, and can be achieved only by Br₂ oxidation taking place as oxidative addition. Aspects of the redox reactivity are discussed and the overall scheme of reactions of the tetracyanonitrosylferrate(2−) and derived species is given.     

FEMORAL SHAFT FRACTURES—A Study of Closed Reduction and Open Treatment

A comparative study was made of 58 cases of closed femoral shaft fractures treated by skeletal traction, and 24 cases of closed femoral shaft fractures treated by open reduction with internal fixation.Although complications occurred in some cases, intramedullary nailing appeared to be the most satisfactory method, resulting in primary union, in decreased time of recumbency and time in hospital, in earlier ambulation and in less residual disability.Success of intramedullary nailing depends largely upon adequate training or experience of the surgeon in the technical operative aspects of the procedure and in postoperative management.Placing supplemental autogenous iliac bone chips at the fracture site in closed femoral fractures in which intramedullary nailing is performed appears to enhance callus formation and bony consolidation.Skeletal traction should be utilized on all patients whose general physical condition does not permit operative intervention.     

Sequential Oxidation and Reduction of Some Methyl 4,6-O-Benzylidene-α- and β-d-Glucopyranoside Derivatives

Reduction of methyl 4,6-O-benzylidene-α- and β-d-glycopyranosidulose derivatives with sodium borohydride was carried out. From the yield of the axial and equatorial epimers, a possible mechanism of the borohydride reduction and factors determining the directions of the reagent’s attack to a carbonyl group are discussed.