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

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.

[1]  L. Seefeldt,et al.  Nitrite and Hydroxylamine as Nitrogenase Substrates: Mechanistic Implications for the Pathway of N2 Reduction , 2014, Journal of the American Chemical Society.

[2]  L. Seefeldt,et al.  A Confirmation of the Quench-Cryoannealing Relaxation Protocol for Identifying Reduction States of Freeze-Trapped Nitrogenase Intermediates , 2014, Inorganic chemistry.

[3]  Dennis R. Dean,et al.  Mechanism of Nitrogen Fixation by Nitrogenase: The Next Stage , 2014, Chemical reviews.

[4]  L. Seefeldt,et al.  On reversible H2 loss upon N2 binding to FeMo-cofactor of nitrogenase , 2013, Proceedings of the National Academy of Sciences.

[5]  L. Seefeldt,et al.  Nitrogenase: a draft mechanism. , 2013, Accounts of chemical research.

[6]  L. Seefeldt,et al.  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. , 2011, Journal of the American Chemical Society.

[7]  L. Seefeldt,et al.  ENDOR/HYSCORE studies of the common intermediate trapped during nitrogenase reduction of N2H2, CH3N2H, and N2H4 support an alternating reaction pathway for N2 reduction. , 2011, Journal of the American Chemical Society.

[8]  B. Hoffman,et al.  Active intermediates in heme monooxygenase reactions as revealed by cryoreduction/annealing, EPR/ENDOR studies. , 2011, Archives of biochemistry and biophysics.

[9]  M. D. Fryzuk,et al.  The hydride route to the preparation of dinitrogen complexes. , 2010, Chemical communications.

[10]  L. Seefeldt,et al.  Is Mo involved in hydride binding by the four-electron reduced (E4) intermediate of the nitrogenase MoFe protein? , 2010, Journal of the American Chemical Society.

[11]  L. Seefeldt,et al.  Trapping an intermediate of dinitrogen (N2) reduction on nitrogenase. , 2009, Biochemistry.

[12]  L. Seefeldt,et al.  Mechanism of Mo-dependent nitrogenase. , 2009, Annual review of biochemistry.

[13]  G. Kubas,et al.  Fundamentals of H2 binding and reactivity on transition metals underlying hydrogenase function and H2 production and storage. , 2007, Chemical reviews.

[14]  L. Seefeldt,et al.  Connecting nitrogenase intermediates with the kinetic scheme for N2 reduction by a relaxation protocol and identification of the N2 binding state , 2007, Proceedings of the National Academy of Sciences.

[15]  L. Seefeldt,et al.  Intermediates Trapped during Nitrogenase Reduction of N⋮N, CH3−NNH, and H2N−NH2 , 2005 .

[16]  L. Seefeldt,et al.  Trapping H- bound to the nitrogenase FeMo-cofactor active site during H2 evolution: characterization by ENDOR spectroscopy. , 2005, Journal of the American Chemical Society.

[17]  P. E. Wilson,et al.  Duplication and extension of the Thorneley and Lowe kinetic model for Klebsiella pneumoniae nitrogenase catalysis using a MATHEMATICA software platform. , 2001, Biophysical chemistry.

[18]  M. Peruzzini,et al.  Recent advances in hydride chemistry , 2001 .

[19]  W. Lanzilotta,et al.  Catalytic and biophysical properties of a nitrogenase Apo-MoFe protein produced by a nifB-deletion mutant of Azotobacter vinelandii. , 1998, Biochemistry.

[20]  B. Burgess,et al.  Mechanism of Molybdenum Nitrogenase , 1997 .

[21]  B. Burgess,et al.  Mechanism of Molybdenum Nitrogenase. , 1996, Chemical reviews.

[22]  J. C. Phillips,et al.  Stretched exponential relaxation in molecular and electronic glasses , 1996 .

[23]  Robert H. Crabtree,et al.  The organometallic chemistry of the transition metals , 1992 .

[24]  F. B. Simpson,et al.  A nitrogen pressure of 50 atmospheres does not prevent evolution of hydrogen by nitrogenase. , 1984, Science.