Veronika Hoeke1, Laura Tociu2, David A Case3, Lance C Seefeldt4, Simone Raugei5, Brian M Hoffman1. 1. Department of Chemistry , Northwestern University , Evanston , Illinois 60208 , United States. 2. Department of Chemistry , University of Chicago , Chicago , Illinois 60637 , United States. 3. Department of Chemistry and Chemical Biology , Rutgers University , Piscataway , New Jersey 08854 , United States. 4. Department of Chemistry and Biochemistry , Utah State University , Logan , Utah 84322 , United States. 5. Physical Sciences Division , Pacific Northwestern National Laboratory , Richland , Washington 99352 , United States.
Abstract
We have shown that the key state in N2 reduction to two NH3 molecules by the enzyme nitrogenase is E4(4H), the "Janus" intermediate, which has accumulated four [e-/H+] and is poised to undergo reductive elimination of H2 coupled to N2 binding and activation. Initial 1H and 95Mo ENDOR studies of freeze-trapped E4(4H) revealed that the catalytic multimetallic cluster (FeMo-co) binds two Fe-bridging hydrides, [Fe-H-Fe]. However, the analysis failed to provide a satisfactory picture of the relative spatial relationships of the two [Fe-H-Fe]. Our recent density functional theory (DFT) study yielded a lowest-energy form, denoted as E4(4H)(a), with two parallel Fe-H-Fe planes bridging pairs of "anchor" Fe on the Fe2,3,6,7 face of FeMo-co. However, the relative energies of structures E4(4H)(b), with one bridging and one terminal hydride, and E4(4H)(c), with one pair of anchor Fe supporting two bridging hydrides, were not beyond the uncertainties in the calculation. Moreover, a structure of V-dependent nitrogenase resulted in a proposed structure analogous to E4(4H)(c), and additional structures have been proposed in the DFT studies of others. To resolve the nature of hydride binding to the Janus intermediate, we performed exhaustive, high-resolution CW-stochastic 1H-ENDOR experiments using improved instrumentation, Mims 2H ENDOR, and a recently developed pulsed-ENDOR protocol ("PESTRE") to obtain absolute hyperfine interaction signs. These measurements are coupled to DFT structural models through an analytical point-dipole Hamiltonian for the hydride electron-nuclear dipolar coupling to its "anchoring" Fe ions, an approach that overcomes limitations inherent in both experimental interpretation and computational accuracy. The result is the freeze-trapped, lowest-energy Janus intermediate structure, E4(4H)(a).
We have shown that the key state in n class="Chemical">n class="Chemical">N2 reduction to two pn>an class="Chemical">NH3 molecules by the enzyme nitrogenase is E4(4H), the "Janus" intermediate, which has accumulated four [e-/H+] and is poised to undergo reductive elimination of H2 coupled to N2 binding and activation. Initial 1H and 95Mo ENDOR studies of freeze-trapped E4(4H) revealed that the catalytic multimetallic cluster (FeMo-co) binds two Fe-bridging hydrides, [Fe-H-Fe]. However, the analysis failed to provide a satisfactory picture of the relative spatial relationships of the two [Fe-H-Fe]. Our recent density functional theory (DFT) study yielded a lowest-energy form, denoted as E4(4H)(a), with two parallel Fe-H-Fe planes bridging pairs of "anchor" Fe on the Fe2,3,6,7 face of FeMo-co. However, the relative energies of structures E4(4H)(b), with one bridging and one terminal hydride, and E4(4H)(c), with one pair of anchor Fe supporting two bridging hydrides, were not beyond the uncertainties in the calculation. Moreover, a structure of V-dependent nitrogenase resulted in a proposed structure analogous to E4(4H)(c), and additional structures have been proposed in the DFT studies of others. To resolve the nature of hydride binding to the Janus intermediate, we performed exhaustive, high-resolution CW-stochastic 1H-ENDOR experiments using improved instrumentation, Mims 2H ENDOR, and a recently developed pulsed-ENDOR protocol ("PESTRE") to obtain absolute hyperfine interaction signs. These measurements are coupled to DFT structural models through an analytical point-dipole Hamiltonian for the hydride electron-nuclear dipolar coupling to its "anchoring" Fe ions, an approach that overcomes limitations inherent in both experimental interpretation and computational accuracy. The result is the freeze-trapped, lowest-energy Janus intermediate structure, E4(4H)(a).
Authors: Robert Y Igarashi; Mikhail Laryukhin; Patricia C Dos Santos; Hong-In Lee; Dennis R Dean; Lance C Seefeldt; Brian M Hoffman Journal: J Am Chem Soc Date: 2005-05-04 Impact factor: 15.419
Authors: Daniel Sippel; Michael Rohde; Julia Netzer; Christian Trncik; Jakob Gies; Katharina Grunau; Ivana Djurdjevic; Laure Decamps; Susana L A Andrade; Oliver Einsle Journal: Science Date: 2018-03-30 Impact factor: 47.728
Authors: Dmitriy Lukoyanov; Zhi-Yong Yang; Dennis R Dean; Lance C Seefeldt; Brian M Hoffman Journal: J Am Chem Soc Date: 2010-03-03 Impact factor: 15.419
Authors: R Adam Kinney; Dennis G H Hetterscheid; Brian S Hanna; Richard R Schrock; Brian M Hoffman Journal: Inorg Chem Date: 2010-01-18 Impact factor: 5.165
Authors: Lance C Seefeldt; Zhi-Yong Yang; Dmitriy A Lukoyanov; Derek F Harris; Dennis R Dean; Simone Raugei; Brian M Hoffman Journal: Chem Rev Date: 2020-03-16 Impact factor: 60.622
Authors: Dmitriy A Lukoyanov; Zhi-Yong Yang; Dennis R Dean; Lance C Seefeldt; Simone Raugei; Brian M Hoffman Journal: J Am Chem Soc Date: 2020-12-16 Impact factor: 15.419
Authors: Casey Van Stappen; Laure Decamps; George E Cutsail; Ragnar Bjornsson; Justin T Henthorn; James A Birrell; Serena DeBeer Journal: Chem Rev Date: 2020-04-02 Impact factor: 60.622
Authors: William R Buratto; Ricardo B Ferreira; Vincent J Catalano; Ricardo García-Serres; Leslie J Murray Journal: Dalton Trans Date: 2021-01-04 Impact factor: 4.390
Authors: Ana Pérez-González; Zhi-Yong Yang; Dmitriy A Lukoyanov; Dennis R Dean; Lance C Seefeldt; Brian M Hoffman Journal: J Am Chem Soc Date: 2021-06-10 Impact factor: 16.383