Your search keyword '"Barney, Brett M."' showing total 19 results

1. Precision control of ammonium release in Azotobacter vinelandii.

Author

Barney, Brett M. and Dietz, Benjamin R.

Subjects

*NITROGEN fixation, *GENETIC markers, *NITROGENASES, *POLYHYDROXYBUTYRATE, *GALACTOSE, *BIODEGRADABLE plastics

Abstract

The capture and reduction of atmospheric dinitrogen gas to ammonium can be accomplished through the enzyme nitrogenase in a process known as biological nitrogen fixation (BNF), by a class of microbes known as diazotrophs. The diazotroph Azotobacter vinelandii is a model organism for the study of aerobic nitrogen fixation, and in recent years has been promoted as a potential producer of biofertilizers. Prior reports have demonstrated the potential to partially deregulate BNF in A. vinelandii, resulting in accumulation and extracellular release of ammonium. In many cases, deregulation requires the introduction of transgenic genes or elements to yield the desired phenotype, and the long‐term stability of these strains has been reported to be somewhat problematic. In this work, we constructed two strains of A. vinelandii where regulation can be precisely controlled without the addition of any foreign genes or genetic markers. Regulation is maintained through native promoters found in A. vinelandii that can be induced through the addition of extraneous galactose. These strains result in varied degrees of regulation of BNF, and as a result, the release of extracellular ammonium is controlled in a precise, and galactose concentration‐dependent manner. In addition, these strains yield high biomass levels, similar to the wild‐type A. vinelandii strain and are further able to produce high percentages of the bioplastic polyhydroxybutyrate. [ABSTRACT FROM AUTHOR]

Published

2024

2. Rnf1 is the primary electron source to nitrogenase in a high-ammonium-accumulating strain of Azotobacter vinelandii.

Author

Barney, Brett M. and Plunkett, Mary H.

Subjects

*ELECTRON sources, *NITROGENASES, *NITROGEN fixation, *AZOTOBACTER, *MULTIENZYME complexes, *ATMOSPHERIC ammonia, *ATMOSPHERIC nitrogen

Abstract

The enzyme nitrogenase performs the process of biological nitrogen fixation (BNF), converting atmospheric dinitrogen gas into the biologically accessible ammonia, which is rapidly protonated at physiological pH to yield ammonium. The reduction of dinitrogen requires both ATP and electrons. Azotobacter vinelandii is an aerobic nitrogen-fixing microbe that is a model organism for the study of BNF. Previous reports have described strains of A. vinelandii that are partially deregulated for BNF, resulting in the release of large quantities of ammonium into the growth medium. Determining the source of the electrons required to drive BNF is complicated by the existence of several protein complexes in A. vinelandii that have been linked to BNF in other species. In this work, we used the high-ammonium-accumulating strains of A. vinelandii to probe the source of electrons to nitrogenase by disrupting the Rnf1 and Fix complexes. The results of this work demonstrate the potential of these strains to be used as a tool to investigate the contributions of other enzymes or complexes in the process of BNF. These results provide strong evidence that the Rnf1 complex of A. vinelandii is the primary source of electrons delivered to the nitrogenase enzyme in this partially deregulated strain. The Fix complex under native regulation was unable to provide sufficient electrons to accumulate extracellular ammonium in the absence of the Rnf1 complex. Increased ammonium accumulation could be attained in a strain lacking the Rnf1 complex if the genes of the Fix protein complex were relocated behind the strong promoter of the S-layer protein but still failed to achieve the levels found with just the Rnf1 complex by itself. Key points: • The Rnf1 complex is integral to ammonium accumulation in A. vinelandii. • The Fix complex can be deleted and still achieve ammonium accumulation in A. vinelandii. • A. vinelandii can be engineered to increase the contribution of the Fix complex to ammonium accumulation. [ABSTRACT FROM AUTHOR]

Published

2022

3. Aerobic nitrogen-fixing bacteria for hydrogen and ammonium production: current state and perspectives.

Author

Barney, Brett M.

Subjects

*AEROBIC bacteria, *HYDROGEN production, *NITROGEN fixation, *AZOTOBACTER, *NITROGENASES, *NITROGEN-fixing bacteria, *HYDROGENASE

Abstract

Biological nitrogen fixation (BNF) is accomplished through the action of the oxygen-sensitive enzyme nitrogenase. One unique caveat of this reaction is the inclusion of hydrogen gas (H2) evolution as a requirement of the reaction mechanism. In the absence of nitrogen gas as a substrate, nitrogenase will reduce available protons to become a directional ATP-dependent hydrogenase. Aerobic nitrogen-fixing microbes are of particular interest, because these organisms have evolved to perform these reactions with oxygen-sensitive enzymes in an environment surrounded by oxygen. The ability to maintain a functioning nitrogenase in aerobic conditions facilitates the application of these organisms under conditions where most anaerobic nitrogen fixers are excluded. In recent years, questions related to the potential yields of the nitrogenase-derived products ammonium and H2 have grown more approachable to experimentation based on efforts to construct increasingly more complicated strains of aerobic nitrogen fixers such as the obligate aerobe Azotobacter vinelandii. This mini-review provides perspectives of recent and historical efforts to understand and quantify the yields of ammonium and H2 that can be obtained through the model aerobe A. vinelandii, and outstanding questions that remain to be answered to fully realize the potential of nitrogenase in these applications with model aerobic bacteria. [ABSTRACT FROM AUTHOR]

Published

2020

4. Gene Deletions Resulting in Increased Nitrogen Release by Azotobacter vinelandii: Application of a Novel Nitrogen Biosensor.

Author

Barney, Brett M., Eberhart, Lauren J., Ohlert, Janet M., Knutson, Carolann M., and Plunkett, Mary H.

Subjects

*DELETION mutation, *NITROGEN, *AZOTOBACTER vinelandii, *NITROGEN-fixing bacteria, *AMMONIUM, *BIOFERTILIZERS, *NITROGENASES

Abstract

Azotobacter vinelandii is a widely studied model diazotrophic (nitrogen-fixing) bacterium and also an obligate aerobe, differentiating it from many other diazotrophs that require environments low in oxygen for the function of the nitrogenase. As a freeliving bacterium, A. vinelandii has evolved enzymes and transporters to minimize the loss of fixed nitrogen to the surrounding environment. In this study, we pursued efforts to target specific enzymes and further developed screens to identify individual colonies of A. vinelandii producing elevated levels of extracellular nitrogen. Targeted deletions were done to convert urea into a terminal product by disrupting the urease genes that influence the ability of A. vinelandii to recycle the urea nitrogen within the cell. Construction of a nitrogen biosensor strain was done to rapidly screen several thousand colonies disrupted by transposon insertional mutagenesis to identify strains with increased extracellular nitrogen production. Several disruptions were identified in the ammonium transporter gene amtB that resulted in the production of sufficient levels of extracellular nitrogen to support the growth of the biosensor strain. Further studies substituting the biosensor strain with the green alga Chlorella sorokiniana confirmed that levels of nitrogen produced were sufficient to support the growth of this organism when the medium was supplemented with sufficient sucrose to support the growth of the A. vinelandii in coculture. The nature and quantities of nitrogen released by urease and amtB disruptions were further compared to strains reported in previous efforts that altered the nifLA regulatory system to produce elevated levels of ammonium. These results reveal alternative approaches that can be used in various combinations to yield new strains that might have further application in biofertilizer schemes. [ABSTRACT FROM AUTHOR]

Published

2015

5. EXAFS and NRVS Reveal a Conformational Distortion of the FeMo-cofactor in the MoFe Nitrogenase Propargyl Alcohol Complex

Author

George, Simon J., Barney, Brett M., Mitra, Devrani, Igarashi, Robert Y., Guo, Yisong, Dean, Dennis R., Cramer, Stephen P., and Seefeldt, Lance C.

Subjects

*EXTENDED X-ray absorption fine structure, *CONFORMATIONAL analysis, *IRON compounds, *NITROGENASES, *PROPARGYL alcohol, *METAL complexes, *CHEMICAL structure, *BINDING sites

Abstract

Abstract: We have used EXAFS and NRVS spectroscopies to examine the structural changes in the FeMo-cofactor active site of the α-70Ala variant of Azotobacter vinelandii nitrogenase on binding and reduction of propargyl alcohol (PA). The Mo K-edge near-edge and EXAFS spectra are very similar in the presence and absence of PA, suggesting PA does not bind at Mo. By contrast, Fe EXAFS spectra show a clear and reproducible change in the long Fe-Fe interaction at ~3.7Å on PA binding with the apparent appearance of a new Fe-Fe interaction at 3.99Å. An analogous change in the long Mo-Fe 5.1Å interaction is not seen. The NRVS spectra exclude the possibility of large-scale structural change of the FeMo-cofactor involving breaking the μ2 Fe-S-Fe bonds of the Fe6S9X core. The simplest chemically consistent structural change is that the bound form of PA is coordinated at Fe atoms (Fe6 or Fe7) adjacent to the Mo terminus, with a concomitant movement of the Fe away from the central atom X and along the Fe-X bond by about 0.35Å. This study comprises the first experimental evidence of the conformational changes of the FeMo-cofactor active site on binding a substrate or product. [Copyright &y& Elsevier]

Published

2012

6. Unification of reaction pathway and kinetic scheme for N2 reduction catalyzed by nitrogenase.

Author

Lukoyanov, Dmitriy, Zhi-Yong Yang, Barney, Brett M., Dean, Dennis R., Seefeldt, Lance C., and Hoffman, Brian M.

Subjects

NITROGENASES, DIAZENES, ELECTRONS, PROTONS, ELECTRON spin echo envelope modulation spectroscopy, HYDROGENATION

Abstract

Nitrogenase catalyzes the reduction of N2 and protons to yield two NH3 and one H2. Substrate binding occurs at a complex organo-metallocluster called FeMo-cofactor (FeMo-co). Each catalytic cycle involves the sequential delivery of eight electrons/protons to this cluster, and this process has been framed within a kinetic scheme developed by Lowe and Thorneley. Rapid freezing of a modified nitrogenase under turnover conditions using diazene, methyldiazene (HN = N-CH3), or hydrazine as substrate recently was shown to trap a common S=½ intermediate, designated I. It was further concluded that the two N-atoms of N2 are hydrogenated alternately ("Alternating" (A) pathway). In the present work, Q-band CW EPR and 95Mo ESEEM spectroscopy reveal such samples also contain a common intermediate with FeMo-co in an integer-spin state having a ground-state "non-Kramers" doublet. This species, designated H, has been characterized by ESEEM spectroscopy using a combination of 14,15N isotopologs plus 1,2H isotopologs of methyldiazene. It is concluded that: H has NH2 bound to FeMo-co and corresponds to the penultimate intermediate of N2 hydrogenation, the state formed after the accumulation of seven electrons/protons and the release of the first NH3; I corresponds to the final intermediate in N2 reduction, the state formed after accumulation of eight electrons/protons, with NH3 still bound to FeMo-co prior to release and regeneration of resting-state FeMo-co. A proposed unification of the Lowe-Thorneley kinetic model with the "prompt" alternating reaction pathway represents a draft mechanism for N2 reduction by nitrogenase. [ABSTRACT FROM AUTHOR]

Published

2012

7. Insights into substrate binding at FeMo-cofactor in nitrogenase from the structure of an α-70Ile MoFe protein variant

Author

Sarma, Ranjana, Barney, Brett M., Keable, Stephen, Dean, Dennis R., Seefeldt, Lance C., and Peters, John W.

Subjects

*NITROGENASES, *MOLECULAR structure, *METALLOPROTEINS, *TRANSITION metals, *SUBSTRATES (Materials science), *LEUCINE, *INTERMEDIATES (Chemistry), *X-rays, *PROTEIN structure, *CHEMICAL reduction

Abstract

Abstract: The X-ray crystal structure is presented for a nitrogenase MoFe protein where the alpha subunit residue at position 70 (α-70Val) has been substituted by the amino acid isoleucine (α-70Ile). Substitution of α-70Val by α-70Ile results in a MoFe protein that is hampered in its ability to reduce a range of substrates including acetylene and N2, yet retains normal proton reduction activity. The 2.3Å structure of the α-70Ile MoFe protein is compared to the α-70Val wild-type MoFe protein, revealing that the δ methyl group of α-70Val is positioned over Fe6 within the active site FeMo-cofactor. This work provides strong crystallographic support for the previously proposed model that substrates bind and are reduced at a single 4Fe–4S face of the FeMo-cofactor and that when α-70Val is substituted by α-70Ile access of substrates to Fe6 of this face is effectively blocked. Furthermore the detailed examination of the structure provides the basis for understanding the ability to trap and characterize hydrides in the variant, contributing significantly to our understanding of substrate access and substrate reduction at the FeMo-cofactor active site of nitrogenase. [Copyright &y& Elsevier]

Published

2010

8. Trapping an Intermediate of Dinitrogen (N2) Reduction on Nitrogense.

Author

Barney, Brett M., Lukoyanov, Dmitriy, Igarashi, Robert Y., Laryukhin, Mikhait, Tran-Chin Yang, Dean, Dennis R., Hoffman, Brian M., and Seefeldt, Lance C.

Subjects

*NITROGENASES, *ATOMS, *AMINO acids, *IRON proteins, *SPECTRUM analysis, *PARTICLES (Nuclear physics)

Abstract

Nitrogenase reduces dinitrogen (N2) by six electrons and six protons at an active-site metallocluster called FeMo cofactor, to yield two ammonia molecules. Insights into the mechanism of substrate reduction by nitrogenase have come from recent successes in trapping and characterizing intermediates generated during the reduction of protons as well as nitrogenous and alkyne substrates by MoFe proteins with amino acid substitutions. Here, we describe an intermediate generated at a high concentration during reduction of the natural nitrogenase substrate, N2, by wild-type MoFe protein, providing evidence that it contains N2 bound to the active-site FeMo cofactor. When MoFe protein was frozen at 77 K during steady- state turnover with N2, the S = 3⁄2 EPR signal (g [4.3, 3.64, 2.00]) arising from the resting state of FeMo cofactor was observed to convert to a rhombic, S = ½, signal (g [2.08, 1.99, 1.97]). The intensity of the N2-dependent EPR signal increased with increasing N2 partial pressure, reaching a maximum intensity of approximately 20% of that of the original FeMo cofactor signal at ≥ 0.2 atm N2. An almost complete loss of resting FeMo cofactor signal in this sample implies that the remainder of the enzyme has been reduced to an EPR-silent intermediate state. The N2-dependent EPR signal intensity also varied with the ratio of Fe protein to MoFe protein (electron flux through nitrogenase), with the maximum signal intensity observed with a ratio of 2:1 (1:1 Fe protein:FeMo cofactor) or higher. The pH optimum for the signal was 7.1. The N2-dependent EPR signal intensity exhibited a linear dependence on the square root of the EPR microwave power in contrast to the nonlinear response of signal intensity observed for hydrazine-, diazene-, and methyldiazene-trapped states. 15N ENDOR spectroscopic analysis of MoFe protein captured during turnover with 15N2 revealed a 15N nuclear spin coupled to the FeMo cofactor with a hyperfine tensor A [0.9, 1.4, 0.45] MHz establishing that an N2-derived species was trapped on the FeMo cofactor. The observation of a single type of 15N-coupled nucleus from the field dependence, along with the absence of an associated exchangeable ¹H ENDOR signal, is consistent with an N2 molecule bound end-on to the FeMo cofactor. [ABSTRACT FROM AUTHOR]

Published

2009

9. A substrate channel in the nitrogenase MoFe protein.

Author

Barney, Brett M., Yurth, Michael G., Dos Santos, Patricia C., Dean, Dennis R., and Seefeldt, Lance C.

Subjects

*NITROGENASES, *ORGANOMETALLIC compounds, *X-ray crystallography, *AMINO acids, *PROTEINS

Abstract

Nitrogenase catalyzes the six electron/six proton reduction of N2 to two ammonia molecules at a complex organometallocluster called “FeMo cofactor.” This cofactor is buried within the α-subunit of the MoFe protein, with no obvious access for substrates. Examination of high-resolution X-ray crystal structures of MoFe proteins from several organisms has revealed the existence of a water-filled channel that extends from the solvent-exposed surface to a specific face of FeMo cofactor. This channel could provide a pathway for substrate and product access to the active site. In the present work, we examine this possibility by substituting four different amino acids that line the channel with other residues and analyze the impact of these substitutions on substrate reduction kinetic parameters. Each of the MoFe protein variants was purified and kinetic parameters were established for the reduction of the substrates N2, acetylene, azide, and propyne. For each MoFe protein, Vmax values for the different substrates were found to be nearly unchanged when compared with the values for the wild-type MoFe protein, indicating that electron delivery to the active site is not compromised by the various substitutions. In contrast, the Km values for these substrates were found to increase significantly (up to 22-fold) in some of the MoFe protein variants compared with the wild-type MoFe protein values. Given that each of the amino acids that were substituted is remote from the active site, these results are consistent with the water-filled channel functioning as a substrate channel in the MoFe protein. [ABSTRACT FROM AUTHOR]

Published

2009

10. Crystal Structure of the L Protein of Rhodobacter sphaeroides Light-Independent Protochiorophyllide Reductase with MgADP Bound: A Homologue of the Nitrogenase Fe Protein.

Author

Sarma, Ranjana, Barney, Brett M., Hamilton, Trinity L., Jones, Alma, Seefeldt, Lance C., and Peters, John W.

Subjects

*NITROGENASES, *PROTEINS, *AZOTOBACTER, *NUCLEOTIDES, *BIOSYNTHESIS, *AMMONIA

Abstract

ABSTRACT: The L protein (BchL) of the dark-operative protochiorophyllide reductase (DPOR) from Rhodobacter sphaeroides has been purified from an Azotobacter vinelandii expression system; its interaction with nucleotides has been examined, and the X-ray structure of the protein has been determined with bound MgADP to 1.6 A resolution. DPOR catalyzes the reduction of protochiorophyllide to chiorophyllide, a reaction critical to the biosynthesis of bacteriochiorophylls. The DPOR holoenzyme is comprised of two component proteins, the dimeric BchL protein and the heterotetrameric BchN/BchB protein. The DPOR component proteins share significant overall similarities with the nitrogenase Fe protein (NifH) and the MoFe (NifDK) protein, the enzyme system responsible for reduction of dinitrogen to ammonia. Here, BchL was expressed in A. vinelandii and purified to homogeneity using an engineered polyhistidine tag. The purified, recombinant BchL was found to contain 3.6 mol of Fe/mol of BchL homodimer, consistent with the presence of a [4Fe-4S] cluster and analogous to the [4Fe-4S1 cluster present in the Fe protein. The MgATP- and MgADP-induced conformational changes in BchL were examined by an Fe chelation assay and found to be distinctly different from the nucleotide-stimulated Fe release observed for the Fe protein. The recombinant BchL was crystallized with bound MgADP, and the structure was determined to 1.6 A resolution. BchL is found to share overall structural similarity with the nitrogenase Fe protein, including the subunit bridging [4Fe-4S] cluster and nucleotide binding sites. Despite the high level of structural similarity, however, BchL is found to be incapable of substituting for the Fe protein in a nitrogenase substrate reduction assay. The newly determined structure of BchL and its comparison to its close homologue, the nitrogenase Fe protein, provide the basis for understanding how these highly related proteins can discriminate between their respective functions in microbial systems where each must function simultaneously. [ABSTRACT FROM AUTHOR]

Published

2008

11. Diazene (HN=NH) Is a Substrate for Nitrogenase: Insights into the Pathway of N2 Reduction.

Author

Barney, Brett M., McClead, Jammi, Lukoyanov, Dmitriy, Laryukhin, Mikhail, Tran-Chin Yang, Dean, Dennis R., Hoffman, Brian M., and Seefeldt, Lance C.

Subjects

*NITROGENASES, *AZODICARBONAMIDE, *METAL clusters, *AMMONIA, *ELECTRONS, *PROTONS, *CHEMICAL reactions

Abstract

Nitrogenase catalyzes the sequential addition of six electrons and six protons to a N2 that is bound to the active site metal cluster FeMo-cofactor, yielding two ammonia molecules. The nature of the intermediates bound to FeMo-cofactor along this reduction pathway remains unknown, although it has been suggested that there are intermediates at the level of reduction of diazene (HN=NH, also called diimide) and hydrazine (H2N-NH2). Through in situ generation of diazene during nitrogenase turnover, we show that diazene is a substrate for the wild-type nitrogenase and is reduced to NH3. Diazene reduction, like N2 reduction, is inhibited by H2. This contrasts with the absence of H2 inhibition when nitrogenase reduces hydrazine. These results support the existence of an intermediate early in the N2 reduction pathway at the level of reduction of diazene. Freeze-quenching a MoFe protein variant with α-195His substituted by Gln and α-70Val substituted by Ala during steady-state turnover with diazene resulted in conversion of the S = ¾ resting state FeMo-cofactor to a novel S = ½ state with g1 = 2.09,g2 = 2.01, and g3 ∼ 1.98. 15N- and 1H-ENDOR establish that this state consists of a diazene-derived [-NHx] moiety bound to FeMo-cofactor. This moiety is indistinguishable from the hydrazine-derived [-NHx] moiety bound to FeMo-cofactor when the same MoFe protein is trapped during turnover with hydrazine. These observations suggest that diazene joins the normal N2-reduction pathway, and that the diazene- and hydrazine-trapped turnover states represent the same intermediate in the normal reduction of N2 by nitrogenase. Implications of these findings for the mechanism of N2 reduction by nitrogenase are discussed. [ABSTRACT FROM AUTHOR]

Published

2007

12. Connecting nitrogenase intermediates with the kinetic scheme for N2 reduction by a relaxation protocol and identification of the N2 binding state.

Author

Lukoyanov, Dmitriy, Barney, Brett M., Dean, Dennis R., Seefeldt, Lance C., and Hoffman, Brian M.

Subjects

*NITROGENASES, *OXIDOREDUCTASES, *PROTEINS, *ELECTRONS, *ENZYMES, *ATOMS

Abstract

A major obstacle to understanding the reduction of N2 to NH3 by nitrogenase has been the impossibility of synchronizing electron delivery to the MoFe protein for generation of specific enzymatic intermediates. When an intermediate is trapped without synchronous electron delivery, the number of electrons, n, it has accumulated is unknown. Consequently, the intermediate is untethered from kinetic schemes for reduction, which are indexed by n. We show that a trapped intermediate itself provides a "synchronously prepared" initial state, and its relaxation to the resting state at 253 K, conditions that prevent electron delivery to MoFe protein, can be analyzed to reveal n and the nature of the relaxation reactions. The approach is applied to the "H+/H- intermediate" (A) that appears during turnover both in the presence and absence of N2 substrate. A exhibits an S = 1/2 EPR signal from the active-site iron-molybdenum cofactor (FeMo-co) to which are bound at least two hydrides/protons. A undergoes two-step relaxation to the resting state (C): A → B → C, where B has an S = 3/2 FeMo-co. Both steps show large solvent kinetic isotope effects: KIE ≈ 3-4 (85% D2O). In the context of the Lowe-Thorneley kinetic scheme for N2 reduction, these results provide powerful evidence that H2 is formed in both relaxation steps, that A is the catalytically central state that is activated for N2 binding by the accumulation of n = 4 electrons, and that B has accumulated n = 2 electrons. [ABSTRACT FROM AUTHOR]

Published

2007

13. A methyldiazene (HN=N-CH3)-derived species bound to the nitrogenase active-site FeMo cofactor: Implications for mechanism.

Author

Barney, Brett M., Lukoyanov, Dmitriy, Tran-Chin Yang, Dean, Dennis R., Hoffman, Brian M., and Seefeidt, Lance C.

Subjects

*BINDING sites, *IRON-molybdenum alloys, *PROTEIN S, *NITROGENASES, *OXIDOREDUCTASES, *BIOCHEMISTRY

Abstract

Methyldiazene (HNNCH3) isotopomers labeled with 15N at the terminal or internal nitrogens or with 13C or ²H were used as substrates for the nitrogenase α-195Gln-substituted MoFe protein. Freeze quenching under turnover traps an S = 1/2 state that has been characterized by EPR and ¹H-, 15N-, and 13C-electron nuclear double resonance spectroscopies. These studies disclosed the following: (i) a methyldiazene-derived species is bound to the active-site FeMo cofactor; (ii) this species binds through an [-NHx] fragment whose N derives from the methyldiazene terminal N; and (iii) the internal N from methyldiazene probably does not bind to FeMo cofactor. These results constrain possible mechanisms for reduction of methyldiazene. In the Chatt-Schrock mechanism for N2 reduction, H atoms sequentially add to the distal N before NN bond cleavage (d-mechanism). In a d-mechanism for methyldiazene reduction, a bound [-NHx] fragment only occurs after reduction by three electrons, which leads to NN bond cleavage and the release of the first NH3. Thus, the appearance of bound [-NHx] is compatible with the d-mechanism only if it represents a late stage in the reduction process. In contrast are mechanisms where H atoms add alternately to distal and proximal nitrogens before NN cleavage (a-mechanism) and release of the first NH3 after reduction by five electrons. An [-NHx] fragment would be bound at every stage of methyldiazene reduction in an a-mechanism. Although current information does not rule out the d-mechanism, the a-mechanism is more attractive because proton delivery to substrate has been specifically compromised in α-195Gln-substituted MoFe protein. [ABSTRACT FROM AUTHOR]

Published

2006

14. Substrate Interaction at an Iron-Sulfur Face of the FeMo-cofactor iring Nitrogenase Catalysis.

Author

Barney, Brett M., Igarashi, Robert Y., Dos Santos, Patricia C., Dean, Dennis R., and Seefeldt, Lance C.

Subjects

*NITROGENASES, *CATALYSIS, *NITROGEN fixation, *ACETYLENE, *IRON, *SULFUR, *AMINO acids

Abstract

Nitrogenase catalyzes biological dinitrogen fixation, the reduction of N2 to 2NH3. Recently, the binding site for a non-physiological alkyne substrate (propargyl alcohol, HC≡C-CH2OH) was localized to a specific Fe-S face of the FeMo-cofactor approached by the MoFe protein amino acid α-70Val. Here we provide, evidence to indicate that the smaller alkyne substrate acetylene (HC≡CH), the physiological substrate dinitrogen, and its semi-reduced form hydrazine (H2N-NH2) interact with the same Fe-S face of the FeMo-cofactor. Hydrazine is a relatively poor substrate for the wild-type (α-70Val) MoFe protein. Substitution of the α-70Val residue by an amino acid having a smaller side chain (alanine) dramatically enhanced hydrazine reduction activity. Conversely, substitution of α-70Val by an amino acid having a larger side chain (isoleucine) significantly lowered the capacity of the MoFe protein to reduce dinitrogen, hydrazine, or acetylene. [ABSTRACT FROM AUTHOR]

Published

2004

15. Intermediates Trapped during Nitrogenase Reduction of N...N, CH3-N=NH, and H2N-NH2.

Author

Barney, Brett M., Tran-Chin Yang, Igarashi, Robert Y., Santos, Patricia C. Dos, Laryukhin, Mikhail, Hong-In Lee, Hoffman, Brian M., Dean, Dennis R., and Seefeldt, Lance C.

Subjects

*NITROGENASES, *CHEMICAL reduction, *INTERMEDIATES (Chemistry), *OXIDOREDUCTASES, *ORGANIC compounds, *NITROGEN

Abstract

The article presents the first report of a high-population intermediate trapped during an early stage of N2 reduction by nitrogenase. Three nitrogenase turnover systems were freeze-quenched during steady-state enzymatic turnover. The observation of distinct splittings is suggested that three different states represent distinct stages of N2 reduction. However, as each intermediate is formed in a different MoFe protein variant, one must consider whether environmental differences have induced differences in an otherwise equivalent common state that accumulates during turnover of all three substrates.

Published

2005

16. 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.

Author

Doan, Peter E., Telser, Joshua, Barney, Brett M., Igarashi, Robert Y., Dean, Dennis R., Seefeldt, Lance C., and Hoffman, Brian M.

Subjects

*BINDING sites, *METAL clusters, *NITROGENASES, *ELECTRONS, *METAL ions, *ELECTRON spin, *ALKYNES

Abstract

N2 binds to the active-site metal cluster in the nitrogenase MoFe protein, the FeMo-cofactor ([7Fe-9S-Mo-homocitrate-X]; FeMo-co) only after the MoFe protein has accumulated three or four electrons/protons (E3 or E4 states), with the E4 state being optimally activated. Here we study the FeMo-co 57Fe atoms of E4 trapped with the α-70Val-Ile MoFe protein variant through use of advanced ENDOR methods: 'random-hop' Davies pulsed 35 GHz ENDOR; difference triple resonance; the recently developed Pulse-Endor-SaTuration and REcovery (PESTRE) protocol for determining hyperfine-coupling signs; and Raw-DATA (RD)-PESTRE, a PESTRE variant that gives a continuous sign readout over a selected radiofrequency range. These methods have allowed experimental determination of the signed isotropic 57Fe hyperfine couplings for five of the seven iron sites of the reductively activated E4 FeMo-co, and given the magnitude of the coupling for a sixth. When supplemented by the use of sum-rules developed to describe electron-spin coupling in FeS proteins, these 57Fe measurements yield both the magnitude and signs of the isotropic couplings for the complete set of seven Fe sites of FeMo-co in E4. In light of the previous findings that FeMo-co of E4 binds two hydrides in the form of (Fe-(μ-H-)-Fe) fragments, and that molybdenum has not become reduced, an 'electron inventory' analysis assigns the formal redox level of FeMo-co metal ions in E4 to that of the resting state (MN), with the four accumulated electrons residing on the two Fe-bound hydrides. Comparisons with earlier 57Fe ENDOR studies and electron inventory analyses of the bio-organometallic intermediate formed during the reduction of alkynes and the CO-inhibited forms of nitrogenase (hi-CO and lo-CO) inspire the conjecture that throughout the eight-electron reduction of N2 plus 2H+ to two NH3 plus H2, the inorganic core of FeMo-co cycles through only a single redox couple connecting two formal redox levels: those associated with the resting state, MN, and with the one-electron reduced state, MR. We further note that this conjecture might apply to other complex FeS enzymes. [ABSTRACT FROM AUTHOR]

Published

2011

17. Alkyne substrate interaction within the nitrogenase MoFe protein

Author

Dos Santos, Patricia C., Mayer, Suzanne M., Barney, Brett M., Seefeldt, Lance C., and Dean, Dennis R.

Subjects

*NITROGENASES, *NITROGEN fixation, *AMMONIA, *ALKYNES, *HYDROCARBONS, *PROTEIN S, *ALANINE

Abstract

Abstract: Nitrogenase catalyzes the biological reduction of N2 to ammonia (nitrogen fixation), as well as the two-electron reduction of the non-physiological alkyne substrate acetylene (HC≡CH). A complex metallo-organic species called FeMo-cofactor provides the site of substrate reduction within the MoFe protein, but exactly where and how substrates interact with FeMo-cofactor remains unknown. Recent results have shown that the MoFe protein α-70Val residue, whose side chain approaches one Fe–S face of FeMo-cofactor, plays a significant role in defining substrate access to the active site. For example, substitution of α-70Val by alanine results in an increased capacity for the reduction of the larger alkyne propyne (HC≡C–CH3), whereas, substitution by isoleucine at this position nearly eliminates the capacity for the reduction of acetylene. These and complementary spectroscopic studies led us to propose that binding of short chain alkynes occurs with side-on binding to Fe atom 6 within FeMo-cofactor. In the present work, the α-70Val residue was substituted by glycine and this MoFe protein variant shows an increased capacity for reduction of the terminal alkyne, 1-butyne (HC≡C–CH2–CH3). This protein shows no detectable reduction of the internal alkyne 2-butyne (H3C–C≡C–CH3). In contrast, substitution of the nearby α-191Gln residue by alanine, in combination with the α-70Ala substitution, does result in significant reduction of 2-butyne, with the exclusive product being 2-cis-butene. These results indicate that the reduction of alkynes by nitrogenases involves side-on binding of the alkyne to Fe6 within FeMo-cofactor, and that a terminal acidic proton is not required for reduction. The successful design of amino acid substitutions that permit the targeted accommodation of an alkyne that otherwise is not a nitrogenase substrate provides evidence to support the current model for alkyne interaction within the nitrogenase MoFe protein. [Copyright &y& Elsevier]

Published

2007

18. ENDOR/HYSCORE Studies of the Common Intermediate Trapped during Nitrogenase Reduction of N2H2, CH3N2H, and N2H4 Support an Alternating Reaction Pathway for N2 Reduction.

Author

Lukoyanov, Dmitriy, Dikanov, Sergei A., Zhi-Yong Yang, Barney, Brett M., Samoilova, Rimma I., Narasimhulu, Kuppala V., Dean, Dennis R., Seefeldt, Lance C., and Hoffman, Brian M.

Subjects

*NITROGENASES, *IRON, *MOLYBDENUM, *HYDROGENATION, *HYDRAZINES, *NITROGEN, *PROTONS

Abstract

Enzymatic N2 reduction proceeds along a reaction pathway composed of a sequence of intermediate states generated as a dinitrogen bound to the active-site iron-molybdenum cofactor (FeMo-co) of the nitrogenase MoFe protein undergoes six steps of hydrogenation (e-/H+ delivery). There are two competing proposals for the reaction pathway, and they invoke different intermediates. In the 'Distal' (D) pathway, a single N of N2 is hydrogenated in three steps until the first NH3 is liberated, and then the remaining nitrido-N is hydrogenated three more times to yield the second NH3. In the 'Alternating' (A) pathway, the two N's instead are hydrogenated alternately, with a hydrazine-bound intermediate formed after four steps of hydrogenation and the first NH3 liberated only during the fifth step. A recent combination of X/Q-band EPR and 15N, 1,2H ENDOR measurements suggested that states trapped during turnover of the α-70Ala/α-195Gln MoFe protein with diazene or hydrazine as substrate correspond to a common intermediate (here denoted I) in which FeMo-co binds a substrate-derived [NxHy] moiety, and measurements reported here show that turnover with methyldiazene generates the same intermediate. In the present report we describe X/Q-band EPR and 14/15N, 1,2H ENDOR/HYSCORE/ESEEM measurements that characterize the N-atom(s) and proton(s) associated with this moiety. The experiments establish that turnover with N2H2, CH3N2H, and N2H4 in fact generates a common intermediate, I, and show that the N-N bond of substrate has been cleaved in I. Analysis of this finding leads us to conclude that nitrogenase reduces N2H2, CH3N2H, and N2H4 via a common A reaction pathway, and that the same is true for N2 itself, with Fe ion(s) providing the site of reaction. [ABSTRACT FROM AUTHOR]

Published

2011

19. Uncoupling Nitrogenase: Catalytic Reduction of Hydrazine to Ammonia by a MoFe Protein in the Absence of Fe Protein-ATP.

Author

Danyal, Karamatullah, Inglet, Boyd S., Vincent, Kylie A., Barney, Brett M., Hoffman, Brian M., Armstrong, Fraser A., Dean, Dennis R., and Seefeldt, Lance C.

Subjects

*HYDRAZINE, *NITROGEN compounds, *IRON proteins, *ADENOSINE triphosphate, *NITROGENASES, *AMMONIA, *CHARGE exchange

Abstract

The catalytic reduction of hydrazine (N2H4) to ammonia by a β-98Tyr→His MoFe protein in the absence of the Fe protein or ATP is reported. The reduction of N2 or other substrates (e.g., hydrazine, protons, acetylene) by nitrogenase normally requires the transient association of the two nitrogenase component proteins, the Fe protein and the MoFe protein. The Fe protein, with two bound MgATP molecules, transfers one electron to the MoFe protein during each association, coupled to the hydrolysis of two MgATP. All substrate reduction reactions catalyzed by nitrogenase require delivery of electrons by the Fe protein coupled to the hydrolysis of MgATP. We report that when a single amino acid within the MoFe protein (β-98Tyr) is substituted by His, the resulting MoFe protein supports catalytic reduction of the nitrogenous substrate hydrazine (N2H4) to two ammonia molecules when provided with a low potential reductant, polyaminocarboxylate ligated EuII (Em -1.1 V vs NHE). The wild-type and a number of other MoFe proteins with amino acid substitutions do not show significant rates of hydrazine reduction under these conditions, whereas the β-98His MoFe protein catalyzes hydrazine reduction at rates up to 170 nmol NH3/min/mg MoFe protein. This rate of hydrazine reduction is 94% of the rate catalyzed by the β-98His or wild-type MoFe protein when combined with the Fe protein, ATP, and reductant under comparable conditions. The β-98His MoFe protein reduction of hydrazine in the absence of the Fe protein showed saturation kinetics for the concentration of reductant and substrate. The implications of these results in understanding the nitrogenase mechanism are discussed. [ABSTRACT FROM AUTHOR]

Published

2010