Your search keyword '"Lukoyanov, Dmitriy"' showing total 13 results

1. Time-Resolved EPR Study of H 2 Reductive Elimination from the Photoexcited Nitrogenase Janus E 4 (4H) Intermediate.

Author

Lukoyanov DA, Krzyaniak MD, Dean DR, Wasielewski MR, Seefeldt LC, and Hoffman BM

Subjects

Catalysis, Models, Molecular, Oxidation-Reduction, Azotobacter vinelandii enzymology, Electron Spin Resonance Spectroscopy methods, Hydrogen chemistry, Nitrogen chemistry, Nitrogenase chemistry

Abstract

Nitrogenase is activated for N 2 reduction through the accumulation of four reducing equivalents at the active-site FeMo-cofactor (FeMo-co: Fe7S9MoC; homocitrate) to form the key Janus intermediate, denoted E 4 (4H), whose lowest-energy structure contains two [Fe-H-Fe] bridging hydrides and two protons bound to the sulfurs that also bridge the Fe pairs. In the critical step of catalysis, a H 2 complex transiently produced by reductive elimination ( re ) of the hydrides of E 4 (4H), denoted E 4 (H 2 ;2H), undergoes H 2 displacement by N 2 , which then undergoes the otherwise energetically unfavorable cleavage of the N≡N triple bond. In pursuing the study of the re activation process, we have employed a photochemical approach to obtaining its atomic-level details. Continuous 450 nm irradiation of the ground state of the dihydride Janus intermediate, denoted E 4 (4H) a , in an EPR cavity at cryogenic temperatures causes photoinduced re of H 2 to generate E 4 (H 2 ;2H). We here extend this photochemical approach with time-resolved EPR studies of the photolysis process on the ns time scale. These studies reveal an additional intermediate in the catalytic reductive elimination process, an isomer of the E 4 (4H) FeMo-co metal-ion core that is formed prior to E 4 (H 2 ;2H) and is thought to be created by breaking an Fe-SH bond, thus further integrating the calculational and structural studies into the experimentally determined mechanism by which nitrogenase is activated to cleave the N≡N triple bond.

Published

2019

2. Mo-, V-, and Fe-Nitrogenases Use a Universal Eight-Electron Reductive-Elimination Mechanism To Achieve N 2 Reduction.

Author

Harris DF, Lukoyanov DA, Kallas H, Trncik C, Yang ZY, Compton P, Kelleher N, Einsle O, Dean DR, Hoffman BM, and Seefeldt LC

Subjects

Azotobacter vinelandii enzymology, Electrons, Iron chemistry, Molybdenum chemistry, Nitrogen chemistry, Nitrogenase chemistry, Oxidation-Reduction, Iron metabolism, Molybdenum metabolism, Nitrogen metabolism, Nitrogenase metabolism

Abstract

Three genetically distinct, but structurally similar, isozymes of nitrogenase catalyze biological N 2 reduction to 2NH 3 : Mo-, V-, and Fe-nitrogenase, named respectively for the metal ( M ) in their active site metallocofactors (metal-ion composition, M Fe 7 ). Studies of the Mo-enzyme have revealed key aspects of its mechanism for N 2 binding and reduction. Central to this mechanism is accumulation of four electrons and protons on its active site metallocofactor, called FeMo-co, as metal bound hydrides to generate the key E 4 (4H) ("Janus") state. N 2 binding/reduction in this state is coupled to reductive elimination ( re ) of the two hydrides as H 2 , the forward direction of a reductive-elimination/oxidative-addition ( re/oa ) equilibrium. A recent study demonstrated that Fe-nitrogenase follows the same re/oa mechanism, as particularly evidenced by HD formation during turnover under N 2 /D 2 . Kinetic analysis revealed that Mo- and Fe-nitrogenases show similar rate constants for hydrogenase-like H 2 formation by hydride protonolysis ( k HP ) but significant differences in the rate constant for H 2 re with N 2 binding/reduction ( k re ). We now report that V-nitrogenase also exhibits HD formation during N 2 /D 2 turnover (and H 2 inhibition of N 2 reduction), thereby establishing the re/oa equilibrium as a universal mechanism for N 2 binding and activation among the three nitrogenases. Kinetic analysis further reveals that differences in catalytic efficiencies do not stem from significant differences in the rate constant ( k HP ) for H 2 production by the hydrogenase-like side reaction but directly arise from the differences in the rate constant ( k re ) for the re of H 2 coupled to N 2 binding/reduction, which decreases in the order Mo > V > Fe.

Published

2019

3. Mechanism of N 2 Reduction Catalyzed by Fe-Nitrogenase Involves Reductive Elimination of H 2 .

Author

Harris DF, Lukoyanov DA, Shaw S, Compton P, Tokmina-Lukaszewska M, Bothner B, Kelleher N, Dean DR, Hoffman BM, and Seefeldt LC

Subjects

Adenosine Triphosphate metabolism, Catalysis, Coenzymes metabolism, Iron analysis, Models, Chemical, Molybdenum analysis, Oxidation-Reduction, Protein Subunits, Recombinant Proteins metabolism, Vanadium analysis, Azotobacter vinelandii enzymology, Bacterial Proteins metabolism, Hydrogen metabolism, Nitrogen metabolism, Oxidoreductases metabolism

Abstract

Of the three forms of nitrogenase (Mo-nitrogenase, V-nitrogenase, and Fe-nitrogenase), Fe-nitrogenase has the poorest ratio of N 2 reduction relative to H 2 evolution. Recent work on the Mo-nitrogenase has revealed that reductive elimination of two bridging Fe-H-Fe hydrides on the active site FeMo-cofactor to yield H 2 is a key feature in the N 2 reduction mechanism. The N 2 reduction mechanism for the Fe-nitrogenase active site FeFe-cofactor was unknown. Here, we have purified both component proteins of the Fe-nitrogenase system, the electron-delivery Fe protein (AnfH) plus the catalytic FeFe protein (AnfDGK), and established its mechanism of N 2 reduction. Inductively coupled plasma optical emission spectroscopy and mass spectrometry show that the FeFe protein component does not contain significant amounts of Mo or V, thus ruling out a requirement of these metals for N 2 reduction. The fully functioning Fe-nitrogenase system was found to have specific activities for N 2 reduction (1 atm) of 181 ± 5 nmol NH 3 min -1 mg -1 FeFe protein, for proton reduction (in the absence of N 2 ) of 1085 ± 41 nmol H 2 min -1 mg -1 FeFe protein, and for acetylene reduction (0.3 atm) of 306 ± 3 nmol C 2 H 4 min -1 mg -1 FeFe protein. Under turnover conditions, N 2 reduction is inhibited by H 2 and the enzyme catalyzes the formation of HD when presented with N 2 and D 2 . These observations are explained by the accumulation of four reducing equivalents as two metal-bound hydrides and two protons at the FeFe-cofactor, with activation for N 2 reduction occurring by reductive elimination of H 2 .

Published

2018

4. Reductive Elimination of H2 Activates Nitrogenase to Reduce the N≡N Triple Bond: Characterization of the E4(4H) Janus Intermediate in Wild-Type Enzyme.

Author

Lukoyanov D, Khadka N, Yang ZY, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Kinetics, Models, Molecular, Nitrogenase chemistry, Oxidation-Reduction, Protein Conformation, Hydrogen metabolism, Nitrogen metabolism, Nitrogenase metabolism

Abstract

We proposed a reductive elimination/oxidative addition (re/oa) mechanism for reduction of N2 to 2NH3 by nitrogenase, based on identification of a freeze-trapped intermediate of the α-70(Val→Ile) MoFe protein as the Janus intermediate that stores four reducing equivalents on FeMo-co as two [Fe-H-Fe] bridging hydrides (denoted E4(4H)). The mechanism postulates that obligatory re of the hydrides as H2 drives reduction of N2 to a state (denoted E4(2N2H)) with a moiety at the diazene (HN═NH) reduction level bound to the catalytic FeMo-co. EPR/ENDOR/photophysical measurements on wild type (WT) MoFe protein now establish this mechanism. They show that a state freeze-trapped during N2 reduction by WT MoFe is the same Janus intermediate, thereby establishing the α-70(Val→Ile) intermediate as a reliable guide to mechanism. Monitoring the Janus state in WT MoFe during N2 reduction under mixed-isotope condition, H2O buffer/D2, and the converse, establishes that the bridging hydrides/deuterides do not exchange with solvent during enzymatic turnover, thereby solving longstanding puzzles. Relaxation of E4(2N2H) to the WT resting-state is shown to occur via oa of H2 and release of N2 to form Janus, followed by sequential release of two H2, demonstrating the kinetic reversibility of the re/oa equilibrium. Relative populations of E4(2N2H)/E4(4H) freeze-trapped during WT turnover furthermore show that the reversible re/oa equilibrium between [E4(4H) + N2] and [E4(2N2H) + H2] is ∼ thermoneutral (ΔreG(0) ∼ -2 kcal/mol), whereas, by itself, hydrogenation of N2(g) is highly endergonic. These findings demonstrate that (i) re/oa accounts for the historical Key Constraints on mechanism, (ii) that Janus is central to N2 reduction by WT enzyme, which (iii) indeed occurs via the re/oa mechanism. Thus, emerges a picture of the central mechanistic steps by which nitrogenase carries out one of the most challenging chemical transformations in biology.

Published

2016

5. Identification of a key catalytic intermediate demonstrates that nitrogenase is activated by the reversible exchange of N₂ for H₂.

Author

Lukoyanov D, Yang ZY, Khadka N, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Catalytic Domain, Coenzymes metabolism, Electron Spin Resonance Spectroscopy, Enzyme Activation, Kinetics, Nitrogenase chemistry, Temperature, Biocatalysis, Hydrogen metabolism, Nitrogen metabolism, Nitrogenase metabolism

Abstract

Freeze-quenching nitrogenase during turnover with N2 traps an S = ½ intermediate that was shown by ENDOR and EPR spectroscopy to contain N2 or a reduction product bound to the active-site molybdenum-iron cofactor (FeMo-co). To identify this intermediate (termed here EG), we turned to a quench-cryoannealing relaxation protocol. The trapped state is allowed to relax to the resting E0 state in frozen medium at a temperature below the melting temperature; relaxation is monitored by periodically cooling the sample to cryogenic temperature for EPR analysis. During -50 °C cryoannealing of EG prepared under turnover conditions in which the concentrations of N2 and H2 ([H2], [N2]) are systematically and independently varied, the rate of decay of EG is accelerated by increasing [H2] and slowed by increasing [N2] in the frozen reaction mixture; correspondingly, the accumulation of EG is greater with low [H2] and/or high [N2]. The influence of these diatomics identifies EG as the key catalytic intermediate formed by reductive elimination of H2 with concomitant N2 binding, a state in which FeMo-co binds the components of diazene (an N-N moiety, perhaps N2 and two [e(-)/H(+)] or diazene itself). This identification combines with an earlier study to demonstrate that nitrogenase is activated for N2 binding and reduction through the thermodynamically and kinetically reversible reductive-elimination/oxidative-addition exchange of N2 and H2, with an implied limiting stoichiometry of eight electrons/protons for the reduction of N2 to two NH3.

Published

2015

6. Nitrite and hydroxylamine as nitrogenase substrates: mechanistic implications for the pathway of N₂ reduction.

Author

Shaw S, Lukoyanov D, Danyal K, Dean DR, Hoffman BM, and Seefeldt LC

Subjects

Hydroxylamine chemistry, Nitrites chemistry, Nitrogen chemistry, Nitrogenase chemistry, Oxidation-Reduction, Substrate Specificity, Hydroxylamine metabolism, Nitrites metabolism, Nitrogen metabolism, Nitrogenase metabolism

Abstract

Investigations of reduction of nitrite (NO2(-)) to ammonia (NH3) by nitrogenase indicate a limiting stoichiometry, NO2(-) + 6e(-) + 12ATP + 7H(+) → NH3 + 2H2O + 12ADP + 12Pi. Two intermediates freeze-trapped during NO2(-) turnover by nitrogenase variants and investigated by Q-band ENDOR/ESEEM are identical to states, denoted H and I, formed on the pathway of N2 reduction. The proposed NO2(-) reduction intermediate hydroxylamine (NH2OH) is a nitrogenase substrate for which the H and I reduction intermediates also can be trapped. Viewing N2 and NO2(-) reductions in light of their common reduction intermediates and of NO2(-) reduction by multiheme cytochrome c nitrite reductase (ccNIR) leads us to propose that NO2(-) reduction by nitrogenase begins with the generation of NO2H bound to a state in which the active-site FeMo-co (M) has accumulated two [e(-)/H(+)] (E2), stored as a (bridging) hydride and proton. Proton transfer to NO2H and H2O loss leaves M-[NO(+)]; transfer of the E2 hydride to the [NO(+)] directly to form HNO bound to FeMo-co is one of two alternative means for avoiding formation of a terminal M-[NO] thermodynamic "sink". The N2 and NO2(-) reduction pathways converge upon reduction of NH2NH2 and NH2OH bound states to form state H with [-NH2] bound to M. Final reduction converts H to I, with NH3 bound to M. The results presented here, combined with the parallels with ccNIR, support a N2 fixation mechanism in which liberation of the first NH3 occurs upon delivery of five [e(-)/H(+)] to N2, but a total of seven [e(-)/H(+)] to FeMo-co when obligate H2 evolution is considered, and not earlier in the reduction process.

Published

2014

7. On reversible H2 loss upon N2 binding to FeMo-cofactor of nitrogenase.

Author

Yang ZY, Khadka N, Lukoyanov D, Hoffman BM, Dean DR, and Seefeldt LC

Subjects

Carbon Isotopes metabolism, Gas Chromatography-Mass Spectrometry, Oxidation-Reduction, Hydrogen metabolism, Molybdoferredoxin metabolism, Nitrogen metabolism, Nitrogen Fixation physiology, Nitrogenase metabolism

Abstract

Nitrogenase is activated for N2 reduction by the accumulation of four electrons/protons on its active site FeMo-cofactor, yielding a state, designated as E4, which contains two iron-bridging hydrides [Fe-H-Fe]. A central puzzle of nitrogenase function is an apparently obligatory formation of one H2 per N2 reduced, which would "waste" two reducing equivalents and four ATP. We recently presented a draft mechanism for nitrogenase that provides an explanation for obligatory H2 production. In this model, H2 is produced by reductive elimination of the two bridging hydrides of E4 during N2 binding. This process releases H2, yielding N2 bound to FeMo-cofactor that is doubly reduced relative to the resting redox level, and thereby is activated to promptly generate bound diazene (HN=NH). This mechanism predicts that during turnover under D2/N2, the reverse reaction of D2 with the N2-bound product of reductive elimination would generate dideutero-E4 [E4(2D)], which can relax with loss of HD to the state designated E2, with a single deuteride bridge [E2(D)]. Neither of these deuterated intermediate states could otherwise form in H2O buffer. The predicted E2(D) and E4(2D) states are here established by intercepting them with the nonphysiological substrate acetylene (C2H2) to generate deuterated ethylenes (C2H3D and C2H2D2). The demonstration that gaseous H2/D2 can reduce a substrate other than H(+) with N2 as a cocatalyst confirms the essential mechanistic role for H2 formation, and hence a limiting stoichiometry for biological nitrogen fixation of eight electrons/protons, and provides direct experimental support for the reductive elimination mechanism.

Published

2013

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

Author

Lukoyanov D, Yang ZY, Barney BM, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Electron Spin Resonance Spectroscopy, Kinetics, Models, Biological, Oxidation-Reduction, Spin Labels, Biocatalysis, Metabolic Networks and Pathways, Nitrogen metabolism, Nitrogenase metabolism

Abstract

Nitrogenase catalyzes the reduction of N(2) and protons to yield two NH(3) and one H(2). 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-CH(3)), 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 N(2) are hydrogenated alternately ("Alternating" (A) pathway). In the present work, Q-band CW EPR and (95)Mo 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 (14,15)N isotopologs plus (1,2)H isotopologs of methyldiazene. It is concluded that: H has NH(2) bound to FeMo-co and corresponds to the penultimate intermediate of N(2) hydrogenation, the state formed after the accumulation of seven electrons/protons and the release of the first NH(3); I corresponds to the final intermediate in N(2) reduction, the state formed after accumulation of eight electrons/protons, with NH(3) 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 N(2) reduction by nitrogenase.

Published

2012

9. 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 D, Dikanov SA, Yang ZY, Barney BM, Samoilova RI, Narasimhulu KV, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Hydrazines chemistry, Imides chemistry, Models, Molecular, Nitrogen chemistry, Nitrogenase chemistry, Oxidation-Reduction, Hydrazines metabolism, Imides metabolism, Nitrogen metabolism, Nitrogenase metabolism

Abstract

Enzymatic N(2) 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 N(2) is hydrogenated in three steps until the first NH(3) is liberated, and then the remaining nitrido-N is hydrogenated three more times to yield the second NH(3). 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 NH(3) liberated only during the fifth step. A recent combination of X/Q-band EPR and (15)N, (1,2)H ENDOR measurements suggested that states trapped during turnover of the α-70(Ala)/α-195(Gln) MoFe protein with diazene or hydrazine as substrate correspond to a common intermediate (here denoted I) in which FeMo-co binds a substrate-derived [N(x)H(y)] 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 (14/15)N, (1,2)H ENDOR/HYSCORE/ESEEM measurements that characterize the N-atom(s) and proton(s) associated with this moiety. The experiments establish that turnover with N(2)H(2), CH(3)N(2)H, and N(2)H(4) 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 N(2)H(2), CH(3)N(2)H, and N(2)H(4) via a common A reaction pathway, and that the same is true for N(2) itself, with Fe ion(s) providing the site of reaction.

Published

2011

10. Trapping an intermediate of dinitrogen (N2) reduction on nitrogenase.

Author

Barney BM, Lukoyanov D, Igarashi RY, Laryukhin M, Yang TC, Dean DR, Hoffman BM, and Seefeldt LC

Subjects

Azotobacter vinelandii enzymology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Catalytic Domain, Electron Spin Resonance Spectroscopy, Electron Transport, Enzyme Stability, Freezing, Hydrogen-Ion Concentration, Oxidation-Reduction, Molybdoferredoxin chemistry, Molybdoferredoxin metabolism, Nitrogen chemistry, Nitrogen metabolism

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 = 1/2, 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 > or = 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.

Published

2009

11. Testing if the interstitial atom, X, of the nitrogenase molybdenum-iron cofactor is N or C: ENDOR, ESEEM, and DFT studies of the S = 3/2 resting state in multiple environments.

Author

Lukoyanov D, Pelmenschikov V, Maeser N, Laryukhin M, Yang TC, Noodleman L, Dean DR, Case DA, Seefeldt LC, and Hoffman BM

Subjects

Iron metabolism, Models, Molecular, Molecular Conformation, Molybdenum metabolism, Carbon chemistry, Iron chemistry, Molybdenum chemistry, Nitrogen chemistry, Nitrogenase metabolism, Sulfur chemistry

Abstract

A high-resolution (1.16 A) X-ray structure of the nitrogenase molybdenum-iron (MoFe) protein revealed electron density from a single N, O, or C atom (denoted X) inside the central iron prismane ([6Fe]) of the [MoFe7S9:homocitrate] FeMo-cofactor (FeMo-co). We here extend earlier efforts to determine the identity of X through detailed tests of whether X = N or C by interlocking and mutually supportive 9 GHz electron spin echo envelope modulation (ESEEM) and 35 GHz electron-nuclear double resonance (ENDOR) measurements on 14/15N and 12/13C isotopomers of FeMo-co in three environments: (i) incorporated into the native MoFe protein environment; (ii) extracted into N-methyl formamide solution; and (iii) incorporated into the NifX protein, which acts as a chaperone during FeMo-co biosynthesis. These measurements provide powerful evidence that X not equal N/C, unless X in effect is magnetically decoupled from the S = 3/2 electron spin system of resting FeMo-co. They reveal no signals from FeMo-co in any of the three environments that can be assigned to X from either 14/15N or 13C: If X were either element, its maximum observed hyperfine coupling at all fields of measurement is estimated to be A(14/15NX) < 0.07/0.1 MHz, A(13CX) < 0.1 MHz, corresponding to intrinsic couplings of about half these values. In parallel, we have explicitly calculated the hyperfine tensors for X = 14/15N/13C/17O, nuclear quadrupole coupling constant e2qQ for X = 14N, and hyperfine constants for the Fe sites of S = 3/2 FeMo-co using density functional theory (DFT) in conjunction with the broken-symmetry (BS) approach for spin coupling. If X = C/N, then the decoupling required by experiment strongly supports the "BS7" spin coupling of the FeMo-co iron sites, in which a small X hyperfine coupling is the result of a precise balance of spin density contributions from three spin-up and three spin-down (3 upward arrow:3 downward arrow) iron atoms of the [6Fe] prismane "waist" of FeMo-co; this would rule out the "BS6" assignment (4 upward arrow:2 downward arrow for [6Fe]) suggested in earlier calculations. However, even with the BS7 scheme, the hyperfine couplings that would be observed for X near g2 are sufficiently large that they should have been detected: we suggest that the experimental results are compatible with X = N only if aiso(14/15NX) < 0.03-0.07/0.05-0.1 MHz and aiso(13CX) < 0.05-0.1 MHz, compared with calculated values of aiso(14/15NX) = 0.3/0.4 MHz and aiso(13CX) = 1 MHz. However, the DFT uncertainties are large enough that the very small hyperfine couplings required by experiment do not necessarily rule out X = N/C.

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 D, Barney BM, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Electron Spin Resonance Spectroscopy, Electrons, Hydrogen-Ion Concentration, Kinetics, Models, Chemical, Protein Binding, Protons, Substrate Specificity, Azotobacter vinelandii enzymology, Biochemistry methods, Molybdoferredoxin chemistry, Nitrogen chemistry, Nitrogenase chemistry

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 approximately 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.

Published

2007

13. 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