Competitive substrate and inhibitor interactions at the physiologically relevant active site of nitrogenase

Nitrogenase catalyzes the MgATP-dependent reduction of dinitrogen gas to ammonia. In addition to the physiological substrate, nitrogenase catalyzes reduction of a variety of other multiply bonded substrates, such as acetylene, nitrous oxide, and azide. Although carbon monoxide (CO) is not reduced by nitrogenase, it is a potent inhibitor of all nitrogenase catalyzed substrate reductions except proton reduction. Here, we present kinetic parameters for an altered Azotobacter vinelandii MoFe protein for which the alphaGly(69) residue was substituted by serine (Christiansen, J., Cash, V. L., Seefeldt, L. C., and Dean, D. R. (2000) J. Biol. Chem. 275, 11459-11464). For the wild type enzyme, CO and acetylene are both noncompetitive inhibitors of dinitrogen reduction. However, for the alphaSer(69) MoFe protein both CO and acetylene have become competitive inhibitors of dinitrogen reduction. CO is also converted from a noncompetitive inhibitor to a competitive inhibitor of acetylene, nitrous oxide, and azide reduction. These results are interpreted in terms of a two-site model. Site 1 is a high affinity acetylene-binding site to which CO also binds, but dinitrogen, azide, and nitrous oxide do not bind. This site is the one primarily accessed during typical acetylene reduction assays. Site 2 is a low affinity acetylene-binding site to which CO, dinitrogen, azide, and nitrous oxide also bind. Site 1 and site 2 are proposed to be located in close proximity within a specific 4Fe-4S face of FeMo cofactor.     

Denitrification by Azospirillum brasilense Sp 7

Nitrous oxide reduction can consistently be demonstrated with high activities in cells of Azospirillum brasilense Sp 7 which are grown anaerobically in the presence of low amounts of nitrite. Azospirillum can even grow anaerobically with nitrous oxide in the absence of any other respiratory electron acceptor. Nitrous oxide reduction by Azospirillum is inhibited by acetylene, amytal and weakly by carbon monoxide. Azospirillum converts nitrous oxide to molecular nitrogen without the formation of ammonia. The cells must, therefore, be supplied with ammonia from nitrogen fixation during anaerobic growth with nitrous oxide. When no other nitrogen compound besides nitrous oxide is available in the medium, the bacteria synthesize nitrogenase from protein reserves in about 2 h. Nitrogenase synthesis is blocked by chloramphenicol under these conditions. In contrast, the addition of nitrate or nitrite to the medium represses the synthesis of nitrogenase. Nitrous oxide reduction by Azospirillum and other microorganisms is possibly of ecological significance, because the reaction performed by the bacteria may remove nitrous oxide from soils.     

In vivo and in vitro kinetics of nitrogenase.

We measured some of the kinetic parameters of nitrogenase to intact systems of Clostridium pasteurianum and Klebsiella pneumoniae to compare them with the kinetics of the enzyme in vitro. We found that the enzyme showed multiple apparent Km values for acetylene reduction in vivo, as it does in vitro. Carbon monoxide was a noncompetitive inhibitor of acetylene reduction; azide was a noncompetitive inhibitor of acetylene reduction, and nitrogen was a partial inhibitor of acetylene reduction. Cyanide was a noncompetitive inhibitor of acetylene reduction in C. pasteurianum but it was a metabolic poison in K. pneumoniae, in addition to being an inhibitor of nitrogenase. The partial nature of nitrogen inhibition was apparent in assays where both nitrogen and CO were present. Nitrogen did not alter the apparent Ki for CO, nor did the presence of CO enhance the competitive effectiveness of nitrogen. By using recombined nitrogenase fractions, we found that the ability of nitrogen to inhibit hydrogen evolution or acetylene reduction varied with the ratio of protein components. The in vivo inhibition of acetylene reduction by dinitrogen was comparable to that obtained with an excess of the Fe protein in vitro. We conclude that there is an effective excess of the Fe protein available under active growth conditions in vivo.     

Effects of substrates (methyl isocyanide,C2H2) and inhibitor (CO) on resting-state wild-type and NifV(-)Klebsiella pneumoniae MoFe proteins

We report the use of electron nuclear double resonance (ENDOR) spectroscopy to examine how the metal sites in the FeMo-cofactor cluster of the resting nitrogenase MoFe protein respond to addition of the substrates acetylene and methyl isocyanide and the inhibitor carbon monoxide. 1H, 57Fe and 95Mo ENDOR measurements were performed on the wild-type and the NifV(-)proteins from Klebsiella pneumoniae. Among the molecules tested, only the addition of acetylene to either protein induced widespread changes in the 57Fe ENDOR spectra. Acetylene also induced increases in intensity from unresolved protons in the proton ENDOR spectra. Thus we conclude that acetylene may bind to the resting-state MoFe protein to perturb the FeMo-cofactor environment. On the other hand, the present results show that methyl isocyanide and carbon monoxide do not substantially alter the FeMo cofactor's geometric and electronic structures. We interpret this as lack of interaction between those two molecules and the FeMo cofactor in the resting state MoFe protein. Thus, although it is generally accepted that substrates or inhibitors bind to the FeMo-cofactor only under turnover condition, this work provides evidence that at least one substrate can perturb the active site of nitrogenase under non-catalytic conditions.     

The acetylene reduction technique as an assay for nitrogenase activity in the methane oxidizing bacterium Methylococcus capsulatus strain bath

The use of acetylene as a convenient assay substrate for nitrogenase in methane oxidising bacteria is complicated by the observation that it is a potent inhibitor of the methane monooxygenase enzyme in both whole cells and cell-free extracts. If the cells were provided with alternative oxidisable carbon substrates other than methane then nitrogen fixing cells would reduce acetylene to ethylene. Hydrogen gas also served as an oxidisable substrate in the assay. Nitrous oxide, which is reduced by nitrogenase to N₂ and H₂O, was not an inhibitor of methane monooxygenase function and could be used as a convenient assay substrate for nitrogenase. Reduction of both substrates by whole cells showed similar response to oxygen in the assay system and in this respect Methylococcus resembles other free living nitrogen fixing aerobes.     

Nitrous oxide reduction in nodules: denitrification or n(2) fixation?

Detached cowpea nodules that contained a nitrous oxide reductase-positive (Nor) rhizobium strain (8A55) and a nitrous oxide reductase-negative (Nor) rhizobium strain (32H1) were incubated with 1% N(2)O (95 atom% N) in the following three atmospheres: (i) aerobic with C(2)H(2) (10%), (ii) aerobic without C(2)H(2), and (iii) anaerobic (argon atmosphere) without C(2)H(2). The greatest production of N(2) occurred anaerobically with 8A55, yet very little was formed with 32H1. Although acetylene reduction activity was slightly higher with 32H1, about 10 times more N(2) was produced aerobically by 8A55 than by 32H1 in the absence of acetylene. The major reductive pathway of N(2)O reduction by denitrifying rhizobium strain 8A55 is by nitrous oxide reductase rather than nitrogenase.     

Interactions of the anesthetic nitrous oxide with bovine heart cytochrome c oxidase. Effects on protein structure, oxidase activity, and other properties

The interactions of nitrous oxide with cytochrome c oxidase isolated from bovine heart muscle have been investigated in search of an explanation for the inhibition of mitochondrial respiration by the inhalation anesthetic. Oxidase activity of the isolated enzyme is partially and reversibly reduced by nitrous oxide. N2O molecules are shown by infrared spectroscopy to occupy sites within the oxidase. Occupancy of sites within the protein by N2O has no observed effects on visible Soret spectra or on the O2 reaction site; no evidence is found for N2O serving as a ligand to a metal. The anesthetic does not substitute for O2 as an oxygen atom donor in either the cytochrome c oxidase or carbon monoxide dioxygenase reactions catalyzed by the enzyme. N2O appears to affect oxidase activity by reducing the rate of electron transfer from cytochrome c to the O2 reaction site rather than by interfering directly with the reduction of O2 to water. Cytochrome c oxidase represents a target site for nitrous oxide and possibly other anesthetics, and the inhibition of oxidase activity may contribute significantly to the anesthetic and/or toxic effects of these substances.     

Kinetics and mechanism of the reaction of cyanide with molybdenum nitrogenase from Azotobacter vinelandii

The steady-state kinetic behavior of the six-electron reduction of N2 by nitrogenase is known to differ markedly from the six-electron reduction of cyanide in two ways. First, on extrapolation to infinite concentration of cyanide, the H2 evolution reaction is almost completely suppressed whereas at extrapolated infinite concentration of N2, H2 evolution continues. Second, as the ratio of the Fe protein to the MoFe protein increases, the reduction of N2 is favored over H2 evolution, whereas the reduction of cyanide becomes less favored relative to H2 evolution. We have extended these steady-state experiments with Azotobacter vinelandii nitrogenase to include a third observation, that the six-electron reduction of N2 is favored over H2 evolution at high total protein concentrations whereas cyanide reduction is less favored over H2 evolution at high total protein concentrations. All three steady-state observations can be explained by a model whereby cyanide is proposed to bind to a redox state of the MoFe protein more oxidized than that reactive toward H2 evolution and N2 reduction. To test this model, we have examined the pre-steady-state kinetic behavior of both cyanide reduction by A. vinelandii nitrogenase and cyanide inhibition of total electron flow through nitrogenase. The data show that in the presence or absence of cyanide there is a short lag of 100 ms before H2 is detected, followed by a linear phase of H2 evolution lasting for about 3 s, during which time no effects of cyanide are observable. After 3 s electron flow is finally inhibited by cyanide, and the cyanide reduction product CH4 is finally formed.(ABSTRACT TRUNCATED AT 250 WORDS)     

D-erythrose supports nitrogenase activity in isolated Anabaena sp. strain 7120 heterocysts.

Among organic compounds tested for their ability to support nitrogenase activity in isolated heterocysts of Anabaena sp. strain 7120 under argon, D-erythrose (5 mM) was unique in supporting acetylene reduction at 10 times the control rates. Higher concentrations of D-erythrose exhibited substrate inhibition. At 50 kPa of H2, all concentrations of D-erythrose inhibited H2-supported acetylene reduction. The effects of D-erythrose on nitrogenase activity were explored. Erythrose enhanced 15N2 incorporation by heterocysts, but NADP+ did not enhance erythrose-supported acetylene reduction. H2 protected nitrogenase from O2 inactivation, but erythrose did not; erythrose did not counter protection by H2. Tests with inhibitors of electron transport showed that erythrose-supported acetylene reduction requires electron flow through ferredoxin, a b-type cytochrome, and a 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone-sensitive transfer agent whose electron flow is not mediated through the plastoquinone and Rieske iron protein.     

Respiratory physiology and energy conservation efficiency of Campylobacter jejuni

A study of the electron transport chain of the human intestinal pathogen Campylobacter jejuni revealed a rich complement of b- and c-type cytochromes. Two c-type cytochromes were partially purified: one, possibly an oxidase, bound carbon monoxide whereas the other, of high potential was unreactive with carbon monoxide. Respiratory activities determined with membrane vesicles were 50- to 100-fold higher with formate and hydrogen than with succinate, lactate, malate, or NADH as substrates. Evidence for three terminal respiratory components was obtained from respiratory kinetic studies employing cyanide, and the following Ki values for cyanide were determined from Dixon plots: ascorbate + reduced N,N,N', N'-tetramethyl-p-phenylenediamine, K1 + 3.5 muM; malate, K1 = 55 muM; and hydrogen, K1 = 4.5 muM. Two oxidases (K1 = 90 muM, 4.5 mM) participated in the oxidation of succinate, lactate, and formate. Except with formate, 37 muM HQNO inhibited respiration by approximately 50%. Carbon monoxide had little inhibitory effect on respiration except under low oxygen tension (less than 10% air saturation). The stoichiometry of respiratory-driven proton translocation (H+/O) determined with whole cells was approximately 2 for all substrates examined except hydrogen (H+/) = 3.7) and formate (H+/O = 2.5). The higher stoichiometries observed with hydrogen and formate are consistent with their respective dehydrogenase being located on the periplasmic face of the cytoplasmic membrane. The results of this study suggest that the oxidation of hydrogen and formate probably serves as the major sources of energy for growth.     

Sulfide Alleviation of the Acetylene Inhibition of Nitrous Oxide Reduction in Soil

The alleviation of the acetylene blockage of nitrous oxide reduction by sulfide was studied in anaerobically incubated Brookston soil to better characterize the process. Removal of nitrate-derived nitrous oxide from soil amended with acetylene and sulfide occurred earlier in the presence of glucose than it did in its absence. This was attributed to the influence of glucose on nitrous oxide production rather than reduction during the early stages of the soil incubation. Glucose was found to have no effect on reduction of injected nitrous oxide in the presence of acetylene- and sulfide-amended soil, whereas carbon dioxide significantly stimulated reduction. It is suggested that the microorganism(s) involved may use carbon dioxide as a cellular carbon source. The sulfide added to the soil probably did not act solely as an electron donor, as the number of electrons required to reduce the added nitrous oxide in our systems was greater than the amount supplied by the sulfide. The soil pH at which the alleviation occurred was 6.7 and was not affected by the sulfide treatment.     

Nitrogenase. VII. Effect of component ratio, ATP and H2 on the distribution of electrons to alternative substrates.

Some kinetic properties of purified component I (Mo-Fe protein) and component II (Fe protein) of nitrogenase (EC 1.7.99.2) from Azotobacter vinelandii have been examined. The apparent Km values for reducible substrates (0.1 atm for N2, 0.01 atm for acetylene) and dithionite (0.5 mM) are similar for osmotically shocked cell lysates and purified components. However, the ATP dependence of acetylene and N2 reduction varies sigmoidally with ATP concentration and as a function of the relative and absolute concentration of components I and II in the assay. Acetylene is reduced in preference to N2 in competitive assays when component I is in relative excess. Acetylene reduction is not as dependent upon ATP concentration as is N2 reduction, so that acetylene is also a preferred substrate at lower ATP levels. Hydrogen specifically inhibits N2 reduction, diverting electrons to acetylene when both substrates are present in the assay. We propose a model of the enzyme activity, in which the substrates for reduction are bound to component I with electrons being activated by component II. ATP may be involved in activating electrons and in maintaining the appropriate conformation or reduction state of components to allow effective reduction of substrates. The relative rate of reduction of alternative substrates is dependent on the concentration of the particular state(s) capable of reacting with each substrate. The concentration of a particular state of component I is a function of components I, II and ATPL     

The kinetics of the reduction of isocyanides, acetylenes and the cyanide ion by nitrogenase preparation from Azotobacter chroococcum and the effects of inhibitors

1. Nitrogen-fixing preparations from Azotobacter chroococcum reduced substrates with the following K(m) values: methyl isocyanide, 1.8x10(-4)m; ethyl isocyanide, 2.5x10(-2)m; cyanide ion, 1.4x10(-3)m; acetylene, 1.2x10(-4)m. 2. Nitrogen, carbon monoxide or hydrogen competitively inhibited isocyanide reduction with the following K(i) values: hydrogen, 1.3x10(-3)m; carbon monoxide, 6.8x10(-6)m; nitrogen, 4.3x10(-4)m. 3. Living nitrogen-fixing bacteria, and isolated clover nodules, formed methane from methyl isocyanide. 4. These results are discussed in relation to other work and possible mechanisms of nitrogen fixation.     

Anaerobic respiration in the Rhodospirillaceae: characterisation of pathways and evaluation of roles in redox balancing during photosynthesis

Abstract Recent discoveries relating to pathways of anaerobic electron transport in the Rhodospirillaceae are reviewed. The main emphasis is on the organism Rhodobacter capsulatus ** but comparisons are made with Rhodobacter sphaeroides ** f. sp. denitrificans and Rhodopseudomonas palustris . The known electron acceptors for anaerobic respiration in Rhodobacter capsulatus are trimethylamine- N -oxide (TMAO), dimethyl sulphoxide (DMSO), nitrate and nitrous oxide. In each case respiration generates a proton electrochemical gradient and in some cases can support growth on non-fermentable carbon sources. However, the principal objective of this review is to discuss the possibility that, apart from a role in energy conservation, anaerobic respiration in the photosynthetic bacteria may have a special function in maintaining redox balance during photosynthetic metabolism. Thus the electron acceptors mentioned above may serve as auxiliary oxidants: (a) to maintain an optimal redox poise of the photosynthetic electron transport chain; (b) to provide a sink for electrons during phototrophic growth on highly reduced carbon substrates.
Molecular properties of the nitrate reductase, nitrous oxide reductase and a single enzyme responsible for reduction of TMAO and DMSO are discussed. These enzymes are all located in the periplasm. Electrons destined for all three enzymes can originate from the rotenone-sensitive NADH dehydrogenase but do not proceed through the antimycin- and myxothiazol-sensitive cytochrome b/c₁ complex. It is likely, therefor, that the pathways of anaerobic respiration overlap with the cyclic photosynthetic electron transport chain only at the level of the ubiquinone pool. Redox components which might be involved in the terminal branches of anaerobic respiration are discussed.     

Metabolism of acetylene by Nocardia rhodochrous.

A Nocardia rhodochrous strain capable of utilizing acetylene as its sole source of carbon and energy exhibited slow growth on low concentrations of acetaldehyde. Resting cells incubated with acetylene formed a product identified as acetaldehyde, but attempts to demonstrate acetylene hydrase activity in cell-free extracts were unsuccessful. Acetaldehyde dehydrogenase in N. rhodochrous was found to be NAD+ linked and nonacylating, converting acetaldehyde to acetate. Specific activities of acetaldehyde dehydrogenase, acetothiokinase, and isocitrate lyase were enhanced in cells grown on acetylene and ethanol as compared with cells grown on alternate substrates. These results suggest that acetylene is catabolized via acetaldehyde to acetate and eventually to acetyl coenzyme A. Acetylene oxidation in N. rhodochrous appears to be constitutive and is not inhibited in the presence of either ethylene, nitrous oxide, or methane.     

Measurement of Denitrification in Two Freshwater Sediments by an In Situ Acetylene Inhibition Method

An acetylene inhibition method was satisfactorily used for the in situ measurement of denitrification in two sediment-water systems incubated for not more than 22 h. In the presence of added nitrate, denitrification acted as a source of nitrous oxide in a drainage pond, but acted as a sink in its absence. The averaged rates of nitrous oxide accumulation with nitrate enrichment in the absence and presence of acetylene were 0.15 and 0.30 mg of N m⁻²h⁻¹, respectively. Acetylene reduction at an average rate of 0.07 mmol of C₂H₄ formed m⁻²h⁻¹ was simultaneously measured in the absence of added nitrate. In a small eutrophic lake where nitrogen was nonlimiting, the in situ rates of sediment denitrification were 0.09 and 0.11 mg of N m⁻²h⁻¹ in the presence and absence of macrophytes, respectively, and no acetylene reduction activity was found.     

Blockage by acetylene of nitrous oxide reduction in Pseudomonas perfectomarinus.

Suspensions of denitrifying cells of Pseudomonas perfectomarinus reduced nitrate and nitrate as expected to dinitrogen; but, in the presence of acetylene, nitrous oxide accumulated when nitrate or nitrate was reduced. When supplied at the outset in place of nitrate and nitrate, nitrous oxide was rapidly reduced to dinitrogen by cells incubated in anaerobic vessels in the absence of acetylene. In the presence of 0.01 atmospheres of acetylene, however, nitrous oxide was not reduced. Ethylene was not produced, nor did it influence the rate of nitrous oxide reduction when provided instead of acetylene. Cells exposed to 0.01 atmospheres of acetylene for as long as 400 min were able to reduce nitrous oxide after removal of acetylene at a rate comparable to that of cells not exposed to acetylene. Acetylene did not affect the production or functioning of assimilatory nitrate or nitrite reductase in axenic cultures of Enterobacter aerogenes or Trichoderma uride. While exposed to acetylene, bacteria in marine sediment slurries produced measurable quantities of nitrous oxide from glucose- or acetate-dependent reduction of added nitrate. Possible use of acetylene blockage for measurement of denitrification in unamended marine sediments is discussed.     

Blockage by acetylene of nitrous oxide reduction in Pseudomonas perfectomarinus.

Suspensions of denitrifying cells of Pseudomonas perfectomarinus reduced nitrate and nitrate as expected to dinitrogen; but, in the presence of acetylene, nitrous oxide accumulated when nitrate or nitrate was reduced. When supplied at the outset in place of nitrate and nitrate, nitrous oxide was rapidly reduced to dinitrogen by cells incubated in anaerobic vessels in the absence of acetylene. In the presence of 0.01 atmospheres of acetylene, however, nitrous oxide was not reduced. Ethylene was not produced, nor did it influence the rate of nitrous oxide reduction when provided instead of acetylene. Cells exposed to 0.01 atmospheres of acetylene for as long as 400 min were able to reduce nitrous oxide after removal of acetylene at a rate comparable to that of cells not exposed to acetylene. Acetylene did not affect the production or functioning of assimilatory nitrate or nitrite reductase in axenic cultures of Enterobacter aerogenes or Trichoderma uride. While exposed to acetylene, bacteria in marine sediment slurries produced measurable quantities of nitrous oxide from glucose- or acetate-dependent reduction of added nitrate. Possible use of acetylene blockage for measurement of denitrification in unamended marine sediments is discussed.     

Comparison of carbon monoxide,nitric oxide,and nitrite as inhibitors of the nitrogenase from Clostridium pasteurianum

A comparative study of CO, NO, and nitrite as inhibitors of nitrogenase has been carried out. Confirming previous studies, we found that CO inhibits acetylene reduction, but not H₂ evolution nor ATP hydrolysis. On the other hand, NO and nitrite both inhibit acetylene reduction, H₂ evolution, and ATP hydrolysis. Nitrogenase inhibition by CO is readily reversible, whereas the effects of NO and nitrite are irreversible. NO was found to inactivate rapidly and irreversibly the Fe protein, but not the Mo-Fe protein. In the presence of NO, part of the iron of the Fe protein is complexed by bathophenanthrolinedisulfonate, which suggests that NO disrupts the Fe₄S₄ cluster present in the protein. Like NO, nitrite reacts preferentially with the Fe protein, and it also induces complexation of the iron by bathophenanthrolinedisulfonate. We found that under the conditions normally used for the assay of nitrogenase, nitrite is reduced by dithionite. Even though the latter reaction proceeds at a very low rate, enough NO is evolved to inhibit nitrogenase. In view of the striking similarities between the inhibitory effects of NO and nitrite, we suggest that nitrogenase may be inhibited not by nitrite itself, but rather by the nitric oxide produced by the reduction of nitrite.     

Nitrous Oxide Reduction in Nodules: Denitrification or N2 Fixation?

Detached cowpea nodules that contained a nitrous oxide reductase-positive (Nor⁺) rhizobium strain (8A55) and a nitrous oxide reductase-negative (Nor⁻) rhizobium strain (32H1) were incubated with 1% ¹⁵N₂O (95 atom% ¹⁵N) in the following three atmospheres: (i) aerobic with C₂H₂ (10%), (ii) aerobic without C₂H₂, and (iii) anaerobic (argon atmosphere) without C₂H₂. The greatest production of ¹⁵N₂ occurred anaerobically with 8A55, yet very little was formed with 32H1. Although acetylene reduction activity was slightly higher with 32H1, about 10 times more ¹⁵N₂ was produced aerobically by 8A55 than by 32H1 in the absence of acetylene. The major reductive pathway of N₂O reduction by denitrifying rhizobium strain 8A55 is by nitrous oxide reductase rather than nitrogenase.