Nitrogenase Explained

Nitrogenase
Ec Number:1.18.6.1
Cas Number:9013-04-1

Nitrogenases are enzymes that are produced by certain bacteria, such as cyanobacteria (blue-green bacteria) and rhizobacteria. These enzymes are responsible for the reduction of nitrogen (N2) to ammonia (NH3). Nitrogenases are the only family of enzymes known to catalyze this reaction, which is a step in the process of nitrogen fixation. Nitrogen fixation is required for all forms of life, with nitrogen being essential for the biosynthesis of molecules (nucleotides, amino acids) that create plants, animals and other organisms. They are encoded by the Nif genes or homologs. They are related to protochlorophyllide reductase.

Classification and structure

Although the equilibrium formation of ammonia from molecular hydrogen and nitrogen has an overall negative enthalpy of reaction (

\DeltaH0=-45.2kJ

mol-1

NH3
), the activation energy is very high (

EA=230-420kJ

mol-1
).[1] Nitrogenase acts as a catalyst, reducing this energy barrier such that the reaction can take place at ambient temperatures.

A usual assembly consists of two components:

  1. The homodimeric Fe-only protein, the reductase which has a high reducing power and is responsible for a supply of electrons.
  2. The heterotetrameric MoFe protein, a nitrogenase which uses the electrons provided to reduce N2 to NH3. In some assemblies it is replaced by a homologous alternative.

Reductase

The Fe protein, the dinitrogenase reductase or NifH, is a dimer of identical subunits which contains one [Fe<sub>4</sub>S<sub>4</sub>] cluster and has a mass of approximately 60-64kDa.[2] The function of the Fe protein is to transfer electrons from a reducing agent, such as ferredoxin or flavodoxin to the nitrogenase protein. Ferredoxin or flavodoxin can be reduced by one of six mechanisms: 1. by a, 2. by a bi-directional hydrogenase, 3. in a photosynthetic reaction center, 4. by coupling electron flow to dissipation of the proton motive force, 5. by electron bifurcation, or 6. by a .[3] The transfer of electrons requires an input of chemical energy which comes from the binding and hydrolysis of ATP. The hydrolysis of ATP also causes a conformational change within the nitrogenase complex, bringing the Fe protein and MoFe protein closer together for easier electron transfer.[4]

Nitrogenase

The MoFe protein is a heterotetramer consisting of two α subunits and two β subunits, with a mass of approximately 240-250kDa.[2] The MoFe protein also contains two iron–sulfur clusters, known as P-clusters, located at the interface between the α and β subunits and two FeMo cofactors, within the α subunits. The oxidation state of Mo in these nitrogenases was formerly thought Mo(V), but more recent evidence is for Mo(III).[5] (Molybdenum in other enzymes is generally bound to molybdopterin as fully oxidized Mo(VI)).

Electrons from the Fe protein enter the MoFe protein at the P-clusters, which then transfer the electrons to the FeMo cofactors. Each FeMo cofactor then acts as a site for nitrogen fixation, with N2 binding in the central cavity of the cofactor.

Variations

The MoFe protein can be replaced by alternative nitrogenases in environments low in the Mo cofactor. Two types of such nitrogenases are known: the vanadium–iron (VFe; Vnf) type and the iron–iron (FeFe; Anf) type. Both form an assembly of two α subunits, two β subunits, and two δ (sometimes γ) subunits. The delta subunits are homologous to each other, and the alpha and beta subunits themselves are homologous to the ones found in MoFe nitrogenase. The gene clusters are also homologous, and these subunits are interchangeable to some degree. All nitrogenases use a similar Fe-S core cluster, and the variations come in the cofactor metal.[6] [7]

The Anf nitrogenase in Azotobacter vinelandii is organized in an anfHDGKOR operon. This operon still requires some of the Nif genes to function. An engineered minimal 10-gene operon that incorporates these additional essential genes has been constructed.[8]

Mechanism

General mechanism

Nitrogenase is an enzyme responsible for catalyzing nitrogen fixation, which is the reduction of nitrogen (N2) to ammonia (NH3) and a process vital to sustaining life on Earth.[9] There are three types of nitrogenase found in various nitrogen-fixing bacteria: molybdenum (Mo) nitrogenase, vanadium (V) nitrogenase, and iron-only (Fe) nitrogenase.[10] Molybdenum nitrogenase, which can be found in diazotrophs such as legume-associated rhizobia,[11] [12] is the nitrogenase that has been studied the most extensively and thus is the most well characterized. Vanadium nitrogenase and iron-only nitrogenase can both be found in select species of Azotobacter as an alternative nitrogenase.[13] Equations 1 and 2 show the balanced reactions of nitrogen fixation in molybdenum nitrogenase and vanadium nitrogenase respectively.

All nitrogenases are two-component systems made up of Component I (also known as dinitrogenase) and Component II (also known as dinitrogenase reductase). Component I is a MoFe protein in molybdenum nitrogenase, a VFe protein in vanadium nitrogenase, and an Fe protein in iron-only nitrogenase. Component II is a Fe protein that contains the Fe-S cluster., which transfers electrons to Component I. Component I contains 2 metal clusters: the P-cluster, and the FeMo-cofactor (FeMo-co). Mo is replaced by V or Fe in vanadium nitrogenase and iron-only nitrogenase respectively.[14] During catalysis, 2 equivalents of MgATP are hydrolysed which helps to decrease the potential of the to the Fe-S cluster and drive reduction of the P-cluster, and finally to the FeMo-co, where reduction of N2 to NH3 takes place.

Lowe-Thorneley kinetic model

The reduction of nitrogen to two molecules of ammonia is carried out at the FeMo-co of Component I after the sequential addition of proton and electron equivalents from Component II. Steady state, freeze quench, and stopped-flow kinetics measurements carried out in the 70's and 80's by Lowe, Thorneley, and others provided a kinetic basis for this process.[15] [16] The Lowe-Thorneley (LT) kinetic model was developed from these experiments and documents the eight correlated proton and electron transfers required throughout the reaction. Each intermediate stage is depicted as En where n = 0–8, corresponding to the number of equivalents transferred. The transfer of four equivalents are required before the productive addition of N2, although reaction of E3 with N2 is also possible. Notably, nitrogen reduction has been shown to require 8 equivalents of protons and electrons as opposed to the 6 equivalents predicted by the balanced chemical reaction.[17]

Intermediates E0 through E4

Spectroscopic characterization of these intermediates has allowed for greater understanding of nitrogen reduction by nitrogenase, however, the mechanism remains an active area of research and debate. Briefly listed below are spectroscopic experiments for the intermediates before the addition of nitrogen:

E0 – This is the resting state of the enzyme before catalysis begins. EPR characterization shows that this species has a spin of 3/2.[18]

E1 – The one electron reduced intermediate has been trapped during turnover under N2. Mӧssbauer spectroscopy of the trapped intermediate indicates that the FeMo-co is integer spin greater than 1.[19] E2 – This intermediate is proposed to contain the metal cluster in its resting oxidation state with the two added electrons stored in a bridging hydride and the additional proton bonded to a sulfur atom. Isolation of this intermediate in mutated enzymes shows that the FeMo-co is high spin and has a spin of 3/2.[20]

E3 – This intermediate is proposed to be the singly reduced FeMo-co with one bridging hydride and one hydride.

E4 – Termed the Janus intermediate after the Roman god of transitions, this intermediate is positioned after exactly half of the electron proton transfers and can either decay back to E0 or proceed with nitrogen binding and finish the catalytic cycle. This intermediate is proposed to contain the FeMo-co in its resting oxidation state with two bridging hydrides and two sulfur bonded protons. This intermediate was first observed using freeze quench techniques with a mutated protein in which residue 70, a valine amino acid, is replaced with isoleucine.[21] This modification prevents substrate access to the FeMo-co. EPR characterization of this isolated intermediate shows a new species with a spin of ½. ENDOR experiments have provided insight into the structure of this intermediate, revealing the presence of two bridging hydrides. 95Mo and 57Fe ENDOR show that the hydrides bridge between two iron centers.[22] Cryoannealing of the trapped intermediate at -20 °C results in the successive loss of two hydrogen equivalents upon relaxation, proving that the isolated intermediate is consistent with the E4 state. The decay of E4 to E2 + H2 and finally to E0 and 2H2 has confirmed the EPR signal associated with the E2 intermediate.

The above intermediates suggest that the metal cluster is cycled between its original oxidation state and a singly reduced state with additional electrons being stored in hydrides. It has alternatively been proposed that each step involves the formation of a hydride and that the metal cluster actually cycles between the original oxidation state and a singly oxidized state.

Distal and alternating pathways for N2 fixation

While the mechanism for nitrogen fixation prior to the Janus E4 complex is generally agreed upon, there are currently two hypotheses for the exact pathway in the second half of the mechanism: the "distal" and the "alternating" pathway.[23] [24] In the distal pathway, the terminal nitrogen is hydrogenated first, releases ammonia, then the nitrogen directly bound to the metal is hydrogenated. In the alternating pathway, one hydrogen is added to the terminal nitrogen, then one hydrogen is added to the nitrogen directly bound to the metal. This alternating pattern continues until ammonia is released. Because each pathway favors a unique set of intermediates, attempts to determine which path is correct have generally focused on the isolation of said intermediates, such as the nitrido in the distal pathway,[25] and the diazene and hydrazine in the alternating pathway. Attempts to isolate the intermediates in nitrogenase itself have so far been unsuccessful, but the use of model complexes has allowed for the isolation of intermediates that support both sides depending on the metal center used. Studies with Mo generally point towards a distal pathway, while studies with Fe generally point towards an alternating pathway.[26] [27]

Specific support for the distal pathway has mainly stemmed from the work of Schrock and Chatt, who successfully isolated the nitrido complex using Mo as the metal center in a model complex.[28] Specific support for the alternating pathway stems from a few studies. Iron only model clusters have been shown to catalytically reduce N2. Small tungsten clusters have also been shown to follow an alternating pathway for nitrogen fixation.[29] The vanadium nitrogenase releases hydrazine, an intermediate specific to the alternating mechanism.[30] However, the lack of characterized intermediates in the native enzyme itself means that neither pathway has been definitively proven. Furthermore, computational studies have been found to support both sides, depending on whether the reaction site is assumed to be at Mo (distal) or at Fe (alternating) in the MoFe cofactor.

Mechanism of MgATP binding

Binding of MgATP is one of the central events to occur in the mechanism employed by nitrogenase. Hydrolysis of the terminal phosphate group of MgATP provides the energy needed to transfer electrons from the Fe protein to the MoFe protein.[31] The binding interactions between the MgATP phosphate groups and the amino acid residues of the Fe protein are well understood by comparing to similar enzymes, while the interactions with the rest of the molecule are more elusive due to the lack of a Fe protein crystal structure with MgATP bound (as of 1996).[32] Three protein residues have been shown to have significant interactions with the phosphates. In the absence of MgATP, a salt bridge exists between residue 15, lysine, and residue 125, aspartic acid. Upon binding, this salt bridge is interrupted. Site-specific mutagenesis has demonstrated that when the lysine is substituted for a glutamine, the protein's affinity for MgATP is greatly reduced[33] and when the lysine is substituted for an arginine, MgATP cannot bind due to the salt bridge being too strong.[34] The necessity of specifically aspartic acid at site 125 has been shown through noting altered reactivity upon mutation of this residue to glutamic acid.[35] Residue 16, serine, has been shown to bind MgATP. Site-specific mutagenesis was used to demonstrate this fact. This has led to a model in which the serine remains coordinated to the Mg2+ ion after phosphate hydrolysis in order to facilitate its association with a different phosphate of the now ADP molecule.[36] MgATP binding also induces significant conformational changes within the Fe protein. Site-directed mutagenesis was employed to create mutants in which MgATP binds but does not induce a conformational change.[37] Comparing X-ray scattering data in the mutants versus in the wild-type protein led to the conclusion that the entire protein contracts upon MgATP binding, with a decrease in radius of approximately 2.0 Å.

Other mechanistic details

Many mechanistic aspects of catalysis remain unknown. No crystallographic analysis has been reported on substrate bound to nitrogenase.

Nitrogenase is able to reduce acetylene, but is inhibited by carbon monoxide, which binds to the enzyme and thereby prevents binding of dinitrogen. Dinitrogen prevent acetylene binding, but acetylene does not inhibit binding of dinitrogen and requires only one electron for reduction to ethylene.[38] Due to the oxidative properties of oxygen, most nitrogenases are irreversibly inhibited by dioxygen, which degradatively oxidizes the Fe-S cofactors. This requires mechanisms for nitrogen fixers to protect nitrogenase from oxygen in vivo. Despite this problem, many use oxygen as a terminal electron acceptor for respiration. Although the ability of some nitrogen fixers such as Azotobacteraceae to employ an oxygen-labile nitrogenase under aerobic conditions has been attributed to a high metabolic rate, allowing oxygen reduction at the cell membrane, the effectiveness of such a mechanism has been questioned at oxygen concentrations above 70 μM (ambient concentration is 230 μM O2), as well as during additional nutrient limitations.[39] A molecule found in the nitrogen-fixing nodules of leguminous plants, leghemoglobin, which can bind to dioxygen via a heme prosthetic group, plays a crucial role in buffering O2 at the active site of the nitrogenase, while concomitantly allowing for efficient respiration.[40]

Nonspecific reactions

In addition to dinitrogen reduction, nitrogenases also reduce protons to dihydrogen, meaning nitrogenase is also a dehydrogenase. A list of other reactions carried out by nitrogenases is shown below:[41] [42]

HC≡CHH2C=CH2

N - =N+=O → N2 + H2O

N=N=N - → N2 + NH3

CH4, NH3, H3C–CH3, H2C=CH2 (CH3NH2)

N≡C–R → RCH3 + NH3

C≡N–R → CH4, H3C–CH3, H2C=CH2, C3H8, C3H6, RNH2

O=C=SCO + H2S[43]

O=C=O → CO + H2O

S=C=N - → H2S + HCN [44]

O=C=N - → H2O + HCN, CO + NH3

Furthermore, dihydrogen functions as a competitive inhibitor,[45] carbon monoxide functions as a non-competitive inhibitor, and carbon disulfide functions as a rapid-equilibrium inhibitor of nitrogenase.

Vanadium nitrogenases have also been shown to catalyze the conversion of CO into alkanes through a reaction comparable to Fischer-Tropsch synthesis.

Organisms that synthesize nitrogenase

There are two types of bacteria that synthesize nitrogenase and are required for nitrogen fixation. These are:

Similarity to other proteins

The three subunits of nitrogenase exhibit significant sequence similarity to three subunits of the light-independent version of protochlorophyllide reductase that performs the conversion of protochlorophyllide to chlorophyll. This protein is present in gymnosperms, algae, and photosynthetic bacteria but has been lost by angiosperms during evolution.[46]

Separately, two of the nitrogenase subunits (NifD and NifH) have homologues in methanogens that do not fix nitrogen e.g. Methanocaldococcus jannaschii.[47] Little is understood about the function of these "class IV" nif genes,[48] though they occur in many methanogens. In M. jannaschii they are known to interact with each other and are constitutively expressed.

Measurement of nitrogenase activity

As with many assays for enzyme activity, it is possible to estimate nitrogenase activity by measuring the rate of conversion of the substrate (N2) to the product (NH3). Since NH3 is involved in other reactions in the cell, it is often desirable to label the substrate with 15N to provide accounting or "mass balance" of the added substrate. A more common assay, the acetylene reduction assay or ARA, estimates the activity of nitrogenase by taking advantage of the ability of the enzyme to reduce acetylene gas to ethylene gas. These gases are easily quantified using gas chromatography.[49] Though first used in a laboratory setting to measure nitrogenase activity in extracts of Clostridium pasteurianum cells, ARA has been applied to a wide range of test systems, including field studies where other techniques are difficult to deploy. For example, ARA was used successfully to demonstrate that bacteria associated with rice roots undergo seasonal and diurnal rhythms in nitrogenase activity, which were apparently controlled by the plant.[50]

Unfortunately, the conversion of data from nitrogenase assays to actual moles of N2 reduced (particularly in the case of ARA), is not always straightforward and may either underestimate or overestimate the true rate for a variety of reasons. For example, H2 competes with N2 but not acetylene for nitrogenase (leading to overestimates of nitrogenase by ARA). Bottle or chamber-based assays may produce negative impacts on microbial systems as a result of containment or disruption of the microenvironment through handling, leading to underestimation of nitrogenase. Despite these weaknesses, such assays are very useful in assessing relative rates or temporal patterns in nitrogenase activity.

See also

Further reading

Notes and References

  1. Modak . J. M. . vanc . 2002 . Haber Process for Ammonia Synthesis . Resonance . 7 . 9. 69–77 . 10.1007/bf02836187. 195305228 .
  2. Burges BK, Lowe DJ . Mechanism of Molybdenum Nitrogenase . . 96 . 7 . 1996 . 2983–3011 . 10.1021/cr950055x . 11848849.
  3. Alleman AB, Peters JW . 2023 . Mechanisms for Generating Low Potential Electrons across the Metabolic Diversity of Nitrogen-Fixing Bacteria . Appl Environ Microbiol . 89 . 5 . e00378-23 . 10.1128/aem.00378-23 . 37154716 . 10231201.
  4. Lawson DM, Smith BE . Molybdenum nitrogenases: a crystallographic and mechanistic view . Metal Ions in Biological Systems . 39 . 75–119 . 2002 . 11913144 .
  5. 4510703 . 26213424 . 10.1002/zaac.201400446 . 641 . 1 . Molybdenum L-Edge XAS Spectra of MoFe Nitrogenase . 2015 . Z Anorg Allg Chem . 65–71 . Bjornsson R, Delgado-Jaime MU, Lima FA, Sippel D, Schlesier J, Weyhermüller T, Einsle O, Neese F, DeBeer S.
  6. Book: Hales BJ. Catalysts for Nitrogen Fixation: Nitrogenases, Relevant Chemical Models and Commercial Processes . 255–279 . Springer Netherlands . 978-1-4020-3611-8 . 10.1007/978-1-4020-3611-8_10 . Vanadium Nitrogenase. 2004 .
  7. Book: Schneider K, Mueller A. Catalysts for Nitrogen Fixation: Nitrogenases, Relevant Chemical Models and Commercial Processes . 281–307 . Springer Netherlands . 978-1-4020-3611-8 . 10.1007/978-1-4020-3611-8_11 . Iron-Only Nitrogenase: Exceptional Catalytic, Structural and Spectroscopic Features. 2004 .
  8. Yang J, Xie X, Wang X, Dixon R, Wang YP . Reconstruction and minimal gene requirements for the alternative iron-only nitrogenase in Escherichia coli . Proceedings of the National Academy of Sciences of the United States of America . 111 . 35 . E3718-25 . September 2014 . 25139995 . 10.1073/pnas.1411185111 . free . 4156695. 2014PNAS..111E3718Y .
  9. Hoffman BM, Lukoyanov D, Yang ZY, Dean DR, Seefeldt LC . Mechanism of nitrogen fixation by nitrogenase: the next stage . Chemical Reviews . 114 . 8 . 4041–62 . April 2014 . 24467365 . 4012840 . 10.1021/cr400641x .
  10. Peters JW, Szilagyi RK . Exploring new frontiers of nitrogenase structure and mechanism . Current Opinion in Chemical Biology . 10 . 2 . 101–8 . April 2006 . 16510305 . 10.1016/j.cbpa.2006.02.019 . Bioinorganic chemistry / Biocatalysis and biotransformation .
  11. Rubio LM, Ludden PW . Biosynthesis of the iron-molybdenum cofactor of nitrogenase . Annual Review of Microbiology . 62 . 1 . 93–111 . 2008 . 18429691 . 10.1146/annurev.micro.62.081307.162737 . free .
  12. Franche . Claudine . Lindström . Kristina . Elmerich . Claudine . vanc . December 2008 . Nitrogen-fixing bacteria associated with leguminous and non-leguminous plants . Plant and Soil . 321. 1–2. 35–59. 10.1007/s11104-008-9833-8. 10892514 . 0032-079X.
  13. Book: Catalysts for Nitrogen Fixation . Schneider K, Müller A . January 2004 . Springer Netherlands . 978-90-481-6675-6 . Smith BE, Richards RL, Newton WE . Nitrogen Fixation: Origins, Applications, and Research Progress. 281–307. 10.1007/978-1-4020-3611-8_11.
  14. Schmidt . Frederik V. . Schulz . Luca . Zarzycki . Jan . Prinz . Simone . Oehlmann . Niels N. . Erb . Tobias J. . Rebelein . Johannes G. . 2023-12-07 . Structural insights into the iron nitrogenase complex . Nature Structural & Molecular Biology . en . 1–9 . 10.1038/s41594-023-01124-2 . 1545-9985. free . 10803253 .
  15. Burgess BK, Lowe DJ . Mechanism of Molybdenum Nitrogenase . Chemical Reviews . 96 . 7 . 2983–3012 . November 1996 . 11848849 . 10.1021/cr950055x.
  16. Wilson PE, Nyborg AC, Watt GD . Duplication and extension of the Thorneley and Lowe kinetic model for Klebsiella pneumoniae nitrogenase catalysis using a MATHEMATICA software platform . Biophysical Chemistry . 91 . 3 . 281–304 . July 2001 . 11551440 . 10.1016/S0301-4622(01)00182-X .
  17. Simpson FB, Burris RH . A nitrogen pressure of 50 atmospheres does not prevent evolution of hydrogen by nitrogenase . Science . 224 . 4653 . 1095–7 . June 1984 . 6585956 . 10.1126/science.6585956 . 1984Sci...224.1095S .
  18. Barney BM, Lee HI, Dos Santos PC, Hoffman BM, Dean DR, Seefeldt LC . Breaking the N2 triple bond: insights into the nitrogenase mechanism . Dalton Transactions . 19 . 2277–84 . May 2006 . 16688314 . 10.1039/B517633F .
  19. Yoo . Sun Jae . Angove . Hayley C. . Papaefthymiou . Vasilios . Burgess . Barbara K. . Münck . Eckard . vanc . May 2000 . Mössbauer Study of the MoFe Protein of Nitrogenase from Azotobacter vinelandii Using Selective 57Fe Enrichment of the M-Centers . Journal of the American Chemical Society . 122 . 20 . 4926–4936 . 10.1021/ja000254k .
  20. Lukoyanov D, Barney BM, Dean DR, Seefeldt LC, Hoffman BM . Connecting nitrogenase intermediates with the kinetic scheme for N2 reduction by a relaxation protocol and identification of the N2 binding state . Proceedings of the National Academy of Sciences of the United States of America . 104 . 5 . 1451–5 . January 2007 . 17251348 . 1785236 . 10.1073/pnas.0610975104 . 2007PNAS..104.1451L . free .
  21. Igarashi RY, Laryukhin M, Dos Santos PC, Lee HI, Dean DR, Seefeldt LC, Hoffman BM . Trapping H- bound to the nitrogenase FeMo-cofactor active site during H2 evolution: characterization by ENDOR spectroscopy . Journal of the American Chemical Society . 127 . 17 . 6231–41 . May 2005 . 15853328 . 10.1021/ja043596p .
  22. Doan PE, Telser J, Barney BM, Igarashi RY, Dean DR, Seefeldt LC, Hoffman BM . 57Fe ENDOR spectroscopy and 'electron inventory' analysis of the nitrogenase E4 intermediate suggest the metal-ion core of FeMo-cofactor cycles through only one redox couple . Journal of the American Chemical Society . 133 . 43 . 17329–40 . November 2011 . 21980917 . 3232045 . 10.1021/ja205304t .
  23. Neese F . The Yandulov/Schrock cycle and the nitrogenase reaction: pathways of nitrogen fixation studied by density functional theory . Angewandte Chemie . 45 . 2 . 196–9 . December 2005 . 16342309 . 10.1002/anie.200502667 .
  24. Hinnemann. Berit. Nørskov. Jens K. . vanc . Catalysis by Enzymes: The Biological Ammonia Synthesis . Topics in Catalysis. 37. 1. 55–70 . 2008 . 10.1007/s11244-006-0002-0 . 93357657.
  25. Schrock RR . Catalytic reduction of dinitrogen to ammonia at a single molybdenum center . Accounts of Chemical Research . 38 . 12 . 955–62 . December 2005 . 16359167 . 2551323 . 10.1021/ar0501121 .
  26. Rodriguez MM, Bill E, Brennessel WW, Holland PL . N₂reduction and hydrogenation to ammonia by a molecular iron-potassium complex . Science . 334 . 6057 . 780–3 . November 2011 . 22076372 . 3218428 . 10.1126/science.1211906 . 2011Sci...334..780R .
  27. Anderson JS, Rittle J, Peters JC . Catalytic conversion of nitrogen to ammonia by an iron model complex . Nature . 501 . 7465 . 84–7 . September 2013 . 24005414 . 3882122 . 10.1038/nature12435 . 2013Natur.501...84A .
  28. Chatt J, Dilworth JR, Richards RL . Recent advances in chemistry of nitrogen-fixation . Chem. Rev. . 1978 . 78 . 6 . 589–625 . 10.1021/cr60316a001.
  29. Murakami J, Yamaguchi W . Reduction of N2 by supported tungsten clusters gives a model of the process by nitrogenase . Scientific Reports . 2 . 407 . 2012-05-14 . 22586517 . 3350986 . 10.1038/srep00407 . 2012NatSR...2E.407M .
  30. Dilworth MJ, Eady RR . Hydrazine is a product of dinitrogen reduction by the vanadium-nitrogenase from Azotobacter chroococcum . The Biochemical Journal . 277 . 2 . 465–8 . July 1991 . 1859374 . 10.1042/bj2770465 . 1151257.
  31. Hageman RV, Burris RH . Nitrogenase and nitrogenase reductase associate and dissociate with each catalytic cycle . Proceedings of the National Academy of Sciences of the United States of America . 75 . 6 . 2699–702 . June 1978 . 275837 . 392630 . 10.1073/pnas.75.6.2699. 1978PNAS...75.2699H . free .
  32. Georgiadis MM, Komiya H, Chakrabarti P, Woo D, Kornuc JJ, Rees DC . Crystallographic structure of the nitrogenase iron protein from Azotobacter vinelandii . Science . 257 . 5077 . 1653–9 . September 1992 . 1529353 . 10.1126/science.1529353. 1992Sci...257.1653G .
  33. Seefeldt LC, Morgan TV, Dean DR, Mortenson LE . Mapping the site(s) of MgATP and MgADP interaction with the nitrogenase of Azotobacter vinelandii. Lysine 15 of the iron protein plays a major role in MgATP interaction . The Journal of Biological Chemistry . 267 . 10 . 6680–8 . April 1992 . 10.1016/S0021-9258(19)50480-X . 1313018 . free .
  34. Ryle MJ, Lanzilotta WN, Mortenson LE, Watt GD, Seefeldt LC . Evidence for a central role of lysine 15 of Azotobacter vinelandii nitrogenase iron protein in nucleotide binding and protein conformational changes . The Journal of Biological Chemistry . 270 . 22 . 13112–7 . June 1995 . 7768906 . 10.1074/jbc.270.22.13112 . free .
  35. Wolle D, Dean DR, Howard JB . Nucleotide-iron-sulfur cluster signal transduction in the nitrogenase iron-protein: the role of Asp125 . Science . 258 . 5084 . 992–5 . November 1992 . 1359643 . 10.1126/science.1359643 . 1992Sci...258..992W .
  36. 1962. Nuclear Magnetic Resonance Spectra of Adenosine Di- and Triphosphate . Journal of Biological Chemistry. 237. 176–181. 10.1016/S0021-9258(18)81382-5 . free . Cohn . Mildred . Hughes . Thomas R. .
  37. Chen L, Gavini N, Tsuruta H, Eliezer D, Burgess BK, Doniach S, Hodgson KO . MgATP-induced conformational changes in the iron protein from Azotobacter vinelandii, as studied by small-angle x-ray scattering . The Journal of Biological Chemistry . 269 . 5 . 3290–4 . February 1994 . 10.1016/S0021-9258(17)41861-8 . 8106367 . free .
  38. Seefeldt LC, Dance IG, Dean DR . Substrate interactions with nitrogenase: Fe versus Mo . Biochemistry . 43 . 6 . 1401–9 . February 2004 . 14769015 . 10.1021/bi036038g .
  39. Oelze J . Respiratory protection of nitrogenase in Azotobacter species: is a widely held hypothesis unequivocally supported by experimental evidence? . FEMS Microbiology Reviews . 24 . 4 . 321–33 . October 2000 . 10978541 . 10.1111/j.1574-6976.2000.tb00545.x . free .
  40. Ott . Thomas . van Dongen . Joost T. . Gu¨nther . Catrin . Krusell . Lene . Desbrosses . Guilhem . Vigeolas . Helene . Bock . Vivien . Czechowski . Tomasz . Geigenberger . Peter . Udvardi . Michael K. . March 29, 2005 . Symbiotic Leghemoglobins Are Crucial for Nitrogen Fixation in Legume Root Nodules but Not for General Plant Growth and Development . Current Biology . 15 . 6 . 531–535 . 10.1016/j.cub.2005.01.042 . 0960-9822 . Physiological analysis of nodules from LbRNAi plants revealed the crucial contribution of leghemoglobins to establishing low free-oxygen concentrations but high energy status in nodules, conditions that are necessary for effective SNF..
  41. Rivera-Ortiz JM, Burris RH . Interactions among substrates and inhibitors of nitrogenase . Journal of Bacteriology . 123 . 2 . 537–45 . August 1975 . 1150625 . 235759 . 10.1128/JB.123.2.537-545.1975.
  42. Schrauzer GN . Nonenzymatic simulation of nitrogenase reactions and the mechanism of biological nitrogen fixation . Angewandte Chemie . 14 . 8 . 514–22 . August 1975 . 810048 . 10.1002/anie.197505141 .
  43. Seefeldt LC, Rasche ME, Ensign SA . Carbonyl sulfide and carbon dioxide as new substrates, and carbon disulfide as a new inhibitor, of nitrogenase . Biochemistry . 34 . 16 . 5382–9 . April 1995 . 7727396 . 10.1021/bi00016a009 .
  44. Rasche ME, Seefeldt LC . Reduction of thiocyanate, cyanate, and carbon disulfide by nitrogenase: kinetic characterization and EPR spectroscopic analysis . Biochemistry . 36 . 28 . 8574–85 . July 1997 . 9214303 . 10.1021/bi970217e .
  45. Guth JH, Burris RH . Inhibition of nitrogenase-catalyzed NH3 formation by H2 . Biochemistry . 22 . 22 . 5111–22 . October 1983 . 6360203 . 10.1021/bi00291a010 .
  46. Li J, Goldschmidt-Clermont M, Timko MP . Chloroplast-encoded chlB is required for light-independent protochlorophyllide reductase activity in Chlamydomonas reinhardtii . The Plant Cell . 5 . 12 . 1817–29 . December 1993 . 8305874 . 160407 . 10.1105/tpc.5.12.1817 .
  47. Staples CR, Lahiri S, Raymond J, Von Herbulis L, Mukhophadhyay B, Blankenship RE . Expression and association of group IV nitrogenase NifD and NifH homologs in the non-nitrogen-fixing archaeon Methanocaldococcus jannaschii . Journal of Bacteriology . 189 . 20 . 7392–8 . October 2007 . 17660283 . 2168459 . 10.1128/JB.00876-07 .
  48. Raymond J, Siefert JL, Staples CR, Blankenship RE. Robert E. Blankenship . The natural history of nitrogen fixation . Molecular Biology and Evolution . 21 . 3 . 541–54 . March 2004 . 14694078 . 10.1093/molbev/msh047 . free .
  49. Dilworth MJ . Acetylene reduction by nitrogen-fixing preparations from Clostridium pasteurianum . Biochimica et Biophysica Acta (BBA) - General Subjects . 127 . 2 . 285–94 . October 1966 . 5964974 . 10.1016/0304-4165(66)90383-7 .
  50. Sims GK, Dunigan EP . 1984 . Diurnal and seasonal variations in nitrogenase activity (C2H2 reduction) of rice roots. . Soil Biology and Biochemistry . 16 . 15–18 . 10.1016/0038-0717(84)90118-4.