Your search keyword '"Seefeldt LC"' showing total 195 results

1. Towards a Biomanufactory on Mars

Author

Berliner, AJ, Berliner, AJ, Hilzinger, JM, Abel, AJ, McNulty, MJ, Makrygiorgos, G, Averesch, NJH, Sen Gupta, S, Benvenuti, A, Caddell, DF, Cestellos-Blanco, S, Doloman, A, Friedline, S, Ho, D, Gu, W, Hill, A, Kusuma, P, Lipsky, I, Mirkovic, M, Luis Meraz, J, Pane, V, Sander, KB, Shi, F, Skerker, JM, Styer, A, Valgardson, K, Wetmore, K, Woo, SG, Xiong, Y, Yates, K, Zhang, C, Zhen, S, Bugbee, B, Clark, DS, Coleman-Derr, D, Mesbah, A, Nandi, S, Waymouth, RM, Yang, P, Criddle, CS, McDonald, KA, Seefeldt, LC, Menezes, AA, Arkin, AP, Berliner, AJ, Berliner, AJ, Hilzinger, JM, Abel, AJ, McNulty, MJ, Makrygiorgos, G, Averesch, NJH, Sen Gupta, S, Benvenuti, A, Caddell, DF, Cestellos-Blanco, S, Doloman, A, Friedline, S, Ho, D, Gu, W, Hill, A, Kusuma, P, Lipsky, I, Mirkovic, M, Luis Meraz, J, Pane, V, Sander, KB, Shi, F, Skerker, JM, Styer, A, Valgardson, K, Wetmore, K, Woo, SG, Xiong, Y, Yates, K, Zhang, C, Zhen, S, Bugbee, B, Clark, DS, Coleman-Derr, D, Mesbah, A, Nandi, S, Waymouth, RM, Yang, P, Criddle, CS, McDonald, KA, Seefeldt, LC, Menezes, AA, and Arkin, AP

Abstract

A crewed mission to and from Mars may include an exciting array of enabling biotechnologies that leverage inherent mass, power, and volume advantages over traditional abiotic approaches. In this perspective, we articulate the scientific and engineering goals and constraints, along with example systems, that guide the design of a surface biomanufactory. Extending past arguments for exploiting stand-alone elements of biology, we argue for an integrated biomanufacturing plant replete with modules for microbial in situ resource utilization, production, and recycling of food, pharmaceuticals, and biomaterials required for sustaining future intrepid astronauts. We also discuss aspirational technology trends in each of these target areas in the context of human and robotic exploration missions.

Published

2021

2. IR spectroelectrochemical study of ligand binding to the metal centres of nitrogenase

Author

Paengnakorn, P, Ash, PA, Danyal, K, Seefeldt, LC, and Vincent, KA

Published

2016

3. mBio

Author

Emilio Jiménez-Vicente, Dennis R. Dean, Ana Pérez-González, Alvaro Salinero-Lanzarote, Zhi-Yong Yang, Lance C. Seefeldt, Jakob Gies-Elterlein, Oliver Einsle, American Society for Microbiology, Perez-Gonzalez, A, Jimenez-Vicente, E, Gies-Elterlein, J, Salinero-Lanzarote, A, Einsle, O, Seefeldt, LC, Dean, DR, Perez-Gonzalez, A [0000-0002-7724-9985], Jimenez-Vicente, E [0000-0002-2843-5132], Gies-Elterlein, J [0000-0003-2773-2888], Salinero-Lanzarote, A [0000-0001-5980-460X], Einsle, O [0000-0001-8722-2893], Seefeldt, LC [0000-0002-6457-9504], and Dean, DR [0000-0001-8960-6196]

Subjects

0301 basic medicine, Assembly, Coenzymes, ONLY NITROGENASE, 01 natural sciences, chemistry.chemical_compound, molybdenum, NUCLEOTIDE-SEQUENCE, Catalytic Domain, IRON-MOLYBDENUM COFACTOR, N-2 REDUCTION, MUTATIONAL ANALYSIS, biology, TRANSCRIPTIONAL REGULATION, Protein primary structure, Nitrogenase, QR1-502, FeFe-cofactor, Biochemistry, Azotobacter vinelandii, FeMo-cofactor, FeV-cofactor, Nitrogen fixation, Life Sciences & Biomedicine, 0605 Microbiology, Research Article, assembly, VANADIUM NITROGENASE, Molybdoferredoxin, Nitrogen, STRUCTURAL GENES, 010402 general chemistry, Microbiology, Cofactor, 03 medical and health sciences, IN-VITRO SYNTHESIS, Bacterial Proteins, Biosynthesis, Nitrogen Fixation, Virology, Molybdenum, Active site, Vanadium, biology.organism_classification, nitrogenase, 0104 chemical sciences, 030104 developmental biology, chemistry, Biocatalysis, biology.protein, vanadium, Function (biology)

Abstract

Deutsche Forschungsgemeinschaft RTG1976, The nitrogen-fixing microbe Azotobacter vinelandii has the ability to produce three genetically distinct, but mechanistically similar, components that catalyze nitrogen fixation. For two of these components, the Mo-dependent and V-dependent components, their corresponding metal-containing active site cofactors, designated FeMo-cofactor and FeV-cofactor, respectively, are preformed on separate molecular scaffolds designated NifEN and VnfEN, respectively. From prior studies, and the present work, it is now established that neither of these scaffolds can replace the other with respect to their in vivo cofactor assembly functions. Namely, a strain inactivated for NifEN cannot produce active Mo-dependent nitrogenase nor can a strain inactivated for VnfEN produce an active V-dependent nitrogenase. It is therefore proposed that metal specificities for FeMo-cofactor and FeV-cofactor formation are supplied by their respective assembly scaffolds. In the case of the third, Fe-only component, its associated active site cofactor, designated FeFe-cofactor, requires neither the NifEN nor VnfEN assembly scaffold for its formation. Furthermore, there are no other genes present in A. vinelandii that encode proteins having primary structure similarity to either NifEN or VnfEN. It is therefore concluded that FeFe-cofactor assembly is completed within its cognate catalytic protein partner without the aid of an intermediate assembly site. IMPORTANCE Biological nitrogen fixation is a complex process involving the nitrogenases. The biosynthesis of an active nitrogenase involves a large number of genes and the coordinated function of their products. Understanding the details of the assembly and activation of the different nitrogen fixation components, in particular the simplest one known so far, the Fe-only nitrogenase, would contribute to the goal of transferring the necessary genetic elements of bacterial nitrogen fixation to cereal crops to endow them with the capacity for self-fertilization. In this work, we show that there is no need for a scaffold complex for the assembly of the FeFe-cofactor, which provides the active site for Fe-only nitrogenase. These results are in agreement with previously reported genetic reconstruction experiments using a non-nitrogen-fixing microbe. In aggregate, these findings provide a high degree of confidence that the Fe-only system represents the simplest and, therefore, most attractive target for mobilizing nitrogen fixation into plants., Work performed in the laboratory of D.R.D. was supported by Bill and Melinda Gates Foundation grants BNF Cereals Phase II (OPP1143172) and BNF Cereals phase III (INV-005889), work performed in the laboratory of O.E. was supported by funds from Deutsche Forschungsgemeinschaft grant RTG1976, and work performed in the laboratory of L.C.S. was supported by a grant from the U.S. Department of Energy, Office of Science, (BES) DE-SC0010687.

Published

2021

4. Iron-molybdenum cofactor synthesis by a thermophilic nitrogenase devoid of the scaffold NifEN.

Author

Payá-Tormo L, Echavarri-Erasun C, Makarovsky-Saavedra N, Pérez-González A, Yang ZY, Guo Y, Seefeldt LC, and Rubio LM

Subjects

Escherichia coli metabolism, Escherichia coli genetics, Molybdoferredoxin metabolism, Metalloproteins metabolism, Metalloproteins genetics, Pteridines metabolism, Azotobacter vinelandii metabolism, Azotobacter vinelandii genetics, Azotobacter vinelandii enzymology, Molybdenum Cofactors, Nitrogenase metabolism, Nitrogenase genetics, Bacterial Proteins metabolism, Bacterial Proteins genetics, Coenzymes metabolism

Abstract

The maturation and installation of the active site metal cluster (FeMo-co, Fe 7 S 9 CMo- R -homocitrate) in Mo-dependent nitrogenase requires the protein product of the nifB gene for production of the FeS cluster precursor (NifB-co, [Fe 8 S 9 C]) and the action of the maturase complex composed of the protein products from the nifE and nifN genes. However, some putative diazotrophic bacteria, like Roseiflexus sp. RS-1, lack the nifEN genes, suggesting an alternative pathway for maturation of FeMo-co that does not require NifEN. In this study, the Roseiflexus NifH, NifB, and apo-NifDK proteins produced in Escherichia coli are shown to be sufficient for FeMo-co maturation and insertion into the NifDK protein to achieve active nitrogenase. The E. coli expressed NifDK RS contained P-clusters but was devoid of FeMo-co (referred to as apo-NifDK RS ). Apo-NifDK RS could be activated for N 2 reduction by addition of preformed FeMo-co. Further, it was found that apo-NifDK RS plus E. coli produced NifB RS and NifH RS were sufficient to yield active NifDK RS when incubated with the necessary substrates (homocitrate, molybdate, and S -adenosylmethionine [SAM]), demonstrating that these proteins can replace the need for NifEN in maturation of Mo-nitrogenase. The E. coli produced NifH RS and NifB RS proteins were independently shown to be functional. The reconstituted NifDK RS demonstrated reduction of N 2 , protons, and acetylene in ratios observed for Azotobacter vinelandii NifDK. These findings reveal a distinct NifEN-independent pathway for nitrogenase activation involving NifH RS , NifB RS , and apo-NifDK RS ., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

5. Microscale Thermophoresis (MST) as a Tool to Study Binding Interactions of Oxygen-Sensitive Biohybrids.

Author

Jagilinki BP, Willis MA, Mus F, Sharma R, Pellows LM, Mulder DW, Yang ZY, Seefeldt LC, King PW, Dukovic G, and Peters JW

Abstract

Microscale thermophoresis (MST) is a technique used to measure the strength of molecular interactions. MST is a thermophoretic -based technique that monitors the change in fluorescence associated with the movement of fluorescent-labeled molecules in response to a temperature gradient triggered by an IR LASER. MST has advantages over other approaches for examining molecular interactions, such as isothermal titration calorimetry, nuclear magnetic resonance, biolayer interferometry, and surface plasmon resonance, requiring a small sample size that does not need to be immobilized and a high-sensitivity fluorescence detection. In addition, since the approach involves the loading of samples into capillaries that can be easily sealed, it can be adapted to analyze oxygen-sensitive samples. In this Bio-protocol , we describe the troubleshooting and optimization we have done to enable the use of MST to examine protein-protein interactions, protein-ligand interactions, and protein-nanocrystal interactions. The salient elements in the developed procedures include 1) loading and sealing capabilities in an anaerobic chamber for analysis using a NanoTemper MST located on the benchtop in air, 2) identification of the optimal reducing agents compatible with data acquisition with effective protection against trace oxygen, and 3) the optimization of data acquisition and analysis procedures. The procedures lay the groundwork to define the determinants of molecular interactions in these technically demanding systems. Key features • Established procedures for loading and sealing tubes in an anaerobic chamber for subsequent analysis. • Sodium dithionite (NaDT) could easily be substituted with one electron-reduced 1,1'-bis(3-sulfonatopropyl)-4,4'-bipyridinium [(SPr) 2 V•] to perform sensitive biophysical assays on oxygen-sensitive proteins like the MoFe protein. • Established MST as an experimental tool to quantify binding affinities in novel enzyme-quantum dot biohybrid complexes that are extremely oxygen-sensitive., Competing Interests: Competing interestsThe authors declare no competing interests., (©Copyright : © 2024 The Authors; This is an open access article under the CC BY-NC license.)

Published

2024

6. Ancient nitrogenases are ATP dependent.

Author

Harris DF, Rucker HR, Garcia AK, Yang Z-Y, Chang SD, Feinsilber H, Kaçar B, and Seefeldt LC

Subjects

Nitrogenase metabolism, Nitrogenase genetics, Nitrogenase chemistry, Evolution, Molecular, Nitrogen Fixation genetics, Oxidation-Reduction, Hydrolysis, Adenosine Triphosphate metabolism, Azotobacter vinelandii enzymology, Azotobacter vinelandii genetics, Azotobacter vinelandii metabolism

Abstract

Life depends on a conserved set of chemical energy currencies that are relics of early biochemistry. One of these is ATP, a molecule that, when paired with a divalent metal ion such as Mg 2+ , can be hydrolyzed to support numerous cellular and molecular processes. Despite its centrality to extant biochemistry, it is unclear whether ATP supported the function of ancient enzymes. We investigate the evolutionary necessity of ATP by experimentally reconstructing an ancestral variant of the N 2 -reducing enzyme nitrogenase. The Proterozoic ancestor is predicted to be ~540-2,300 million years old, post-dating the Great Oxidation Event. Growth rates under nitrogen-fixing conditions are ~80% of those of wild type in Azotobacter vinelandii . In the extant enzyme, the hydrolysis of two MgATP is coupled to electron transfer to support substrate reduction. The ancestor has a strict requirement for ATP with no other nucleotide triphosphate analogs (GTP, ITP, and UTP) supporting activity. Alternative divalent metal ions (Fe 2+ , Co 2+ , and Mn 2+ ) support activity with ATP but with diminished activities compared to Mg 2+ , similar to the extant enzyme. Additionally, it is shown that the ancestor has an identical efficiency in ATP hydrolyzed per electron transferred to the extant of two. Our results provide direct laboratory evidence of ATP usage by an ancient enzyme.IMPORTANCELife depends on energy-carrying molecules to power many sustaining processes. There is evidence that these molecules may predate the rise of life on Earth, but how and when these dependencies formed is unknown. The resurrection of ancient enzymes provides a unique tool to probe the enzyme's function and usage of energy-carrying molecules, shedding light on their biochemical origins. Through experimental reconstruction, this research investigates the ancestral dependence of a nitrogen-fixing enzyme on the energy carrier ATP, a requirement for function in the modern enzyme. We show that the resurrected ancestor does not have generalist nucleotide specificity. Rather, the ancestor has a strict requirement for ATP, like the modern enzyme, with similar function and efficiency. The findings elucidate the early-evolved necessity of energy-yielding molecules, delineating their role in ancient biochemical processes. Ultimately, these insights contribute to unraveling the intricate tapestry of evolutionary biology and the origins of life-sustaining dependencies., Competing Interests: The authors declare no conflict of interest.

Published

2024

7. Hole-scavenging in photo-driven N 2 reduction catalyzed by a CdS-nitrogenase MoFe protein biohybrid system.

Author

Clinger A, Yang ZY, Pellows LM, King P, Mus F, Peters JW, Dukovic G, and Seefeldt LC

Subjects

Molybdoferredoxin metabolism, Oxidation-Reduction, Dithionite metabolism, Catalysis, Ascorbic Acid metabolism, Nitrogenase metabolism, Azotobacter vinelandii metabolism, Sulfides, Cadmium Compounds

Abstract

The light-driven reduction of dinitrogen (N 2 ) to ammonia (NH 3 ) catalyzed by a cadmium sulfide (CdS) nanocrystal‑nitrogenase MoFe protein biohybrid is dependent on a range of different factors, including an appropriate hole-scavenging sacrificial electron donor (SED). Here, the impact of different SEDs on the overall rate of N 2 reduction catalyzed by a CdS quantum dot (QD)-MoFe protein system was determined. The selection of SED was guided by several goals: (i) molecules with standard reduction potentials sufficient to reduce the oxidized CdS QD, (ii) molecules that do not absorb the excitation wavelength of the CdS QD, and (iii) molecules that could be readily reduced by sustainable processes. Earlier studies utilized buffer molecules or ascorbic acid as the SED. The effectiveness of ascorbic acid as SED was compared to dithionite (DT), triethanolamine (TEOA), and hydroquinone (HQ) across a range of concentrations in supporting N 2 reduction to NH 3 in a CdS QD-MoFe protein photocatalytic system. It was found that TEOA supported N 2 reduction rates comparable to those observed for dithionite and ascorbic acid. HQ was found to support significantly higher rates of N 2 reduction compared to the other SEDs at a concentration of 50 mM. A comparison of the rates of N 2 reduction by the biohybrid complex to the standard reduction potential (E o ) of the SEDs reveals that E o is not the only factor impacting the efficiency of hole-scavenging. These findings reveal the importance of the SED properties for improving the efficiency of hole-scavenging in the light-driven N 2 reduction reaction catalyzed by a CdS QD-MoFe protein hybrid., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

8. A voltammetric study of nitrogenase MoFe-protein using low-potential electron transfer mediators.

Author

Badalyan A, Yang ZY, and Seefeldt LC

Subjects

Electrons, Electron Transport, Oxidation-Reduction, Proteins, Adenosine Triphosphate metabolism, Nitrogenase chemistry, Nitrogenase metabolism, Molybdoferredoxin metabolism

Abstract

The molybdenum-iron protein (MoFeP), a component of the enzyme nitrogenase, catalyzes the reduction of an array of small molecules, including N 2 to NH 3 . In microorganisms, during the catalytic cycle, MoFeP receives electrons from the obligate biological redox partner iron protein (FeP) in a process coupled to the hydrolysis of two MgATP per one electron transferred. Despite the favorable redox properties of the cofactors, the requirement of the MgATP hydrolysis significantly decreases the energy efficiency of MoFeP. Therefore, remarkable efforts have been devoted to electrochemically activating MoFeP without FeP and MgATP. Previously, MoFeP was adsorbed on an electrode surface and revealed a slow catalysis with and without electron transfer mediators. However, enzyme adsorption can cause conformational and structural changes in a fragile protein molecule and alter its catalytic activity. In this work, MoFeP was electrochemically studied in solution. Various electron transfer mediators with potentials ranging from -0.3 V to -1 V (vs. NHE) were examined with MoFeP using cyclic voltammetry. No significant catalytic activity of the MoFeP was observed with any of the tested mediators. This indicates that efficient electrochemical activation of MoFeP cannot be achieved exclusively by increasing the driving force between the MoFeP redox cofactors and an electron donor., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier B.V. All rights reserved.)

Published

2024

9. Low-temperature trapping of N2 reduction reaction intermediates in nitrogenase MoFe protein-CdS quantum dot complexes.

Author

Pellows LM, Vansuch GE, Chica B, Yang ZY, Ruzicka JL, Willis MA, Clinger A, Brown KA, Seefeldt LC, Peters JW, Dukovic G, Mulder DW, and King PW

Subjects

Molybdoferredoxin chemistry, Molybdoferredoxin metabolism, Temperature, Oxidation-Reduction, Nitrogenase chemistry, Nitrogenase metabolism, Electron Spin Resonance Spectroscopy methods, Quantum Dots, Azotobacter vinelandii metabolism

Abstract

The biological reduction of N2 to ammonia requires the ATP-dependent, sequential delivery of electrons from the Fe protein to the MoFe protein of nitrogenase. It has been demonstrated that CdS nanocrystals can replace the Fe protein to deliver photoexcited electrons to the MoFe protein. Herein, light-activated electron delivery within the CdS:MoFe protein complex was achieved in the frozen state, revealing that all the electron paramagnetic resonance (EPR) active E-state intermediates in the catalytic cycle can be trapped and characterized by EPR spectroscopy. Prior to illumination, the CdS:MoFe protein complex EPR spectrum was composed of a S = 3/2 rhombic signal (g = 4.33, 3.63, and 2.01) consistent with the FeMo-cofactor in the resting state, E0. Illumination for sequential 1-h periods at 233 K under 1 atm of N2 led to a cumulative attenuation of E0 by 75%. This coincided with the appearance of S = 3/2 and S = 1/2 signals assigned to two-electron (E2) and four-electron (E4) reduced states of the FeMo-cofactor, together with additional S = 1/2 signals consistent with the formation of E6 and E8 states. Simulations of EPR spectra allowed quantification of the different E-state populations, along with mapping of these populations onto the Lowe-Thorneley kinetic scheme. The outcome of this work demonstrates that the photochemical delivery of electrons to the MoFe protein can be used to populate all of the EPR active E-state intermediates of the nitrogenase MoFe protein cycle., (© 2023 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).)

Published

2023

10. High Affinity Electrostatic Interactions Support the Formation of CdS Quantum Dot:Nitrogenase MoFe Protein Complexes.

Author

Pellows LM, Willis MA, Ruzicka JL, Jagilinki BP, Mulder DW, Yang ZY, Seefeldt LC, King PW, Dukovic G, and Peters JW

Subjects

Static Electricity, Nitrogenase chemistry, Nitrogenase metabolism, Electron Transport, Molybdoferredoxin chemistry, Molybdoferredoxin metabolism, Quantum Dots

Abstract

Nitrogenase MoFe protein can be coupled with CdS nanocrystals (NCs) to enable photocatalytic N 2 reduction. The nature of interactions that support complex formation is of paramount importance in intermolecular electron transfer that supports catalysis. In this work we have employed microscale thermophoresis to examine binding interactions between 3-mercaptopropionate capped CdS quantum dots (QDs) and MoFe protein over a range of QD diameters (3.4-4.3 nm). The results indicate that the interactions are largely electrostatic, with the strength of interactions similar to that observed for the physiological electron donor. In addition, the strength of interactions is sensitive to the QD diameter, and the binding interactions are significantly stronger for QDs with smaller diameters. The ability to quantitatively assess NC protein interactions in biohybrid systems supports strategies for understanding properties and reaction parameters that are important for obtaining optimal rates of catalysis in biohybrid systems.

Published

2023

11. Fe protein docking transduces conformational changes to MoFe nitrogenase active site in a nucleotide-dependent manner.

Author

Tokmina-Lukaszewska M, Huang Q, Berry L, Kallas H, Peters JW, Seefeldt LC, Raugei S, and Bothner B

Abstract

The reduction of dinitrogen to ammonia catalyzed by nitrogenase involves a complex series of events, including ATP hydrolysis, electron transfer, and activation of metal clusters for N 2 reduction. Early evidence shows that an essential part of the mechanism involves transducing information between the nitrogenase component proteins through conformational dynamics. Here, millisecond time-resolved hydrogen-deuterium exchange mass spectrometry was used to unravel peptide-level protein motion on the time scale of catalysis of Mo-dependent nitrogenase from Azotobacter vinelandii. Normal mode analysis calculations complemented this data, providing insights into the specific signal transduction pathways that relay information across protein interfaces at distances spanning 100 Å. Together, these results show that conformational changes induced by protein docking are rapidly transduced to the active site, suggesting a specific mechanism for activating the metal cofactor in the enzyme active site., (© 2023. The Author(s).)

Published

2023

12. Cryo-annealing of Photoreduced CdS Quantum Dot-Nitrogenase MoFe Protein Complexes Reveals the Kinetic Stability of the E 4 (2N2H) Intermediate.

Author

Vansuch GE, Mulder DW, Chica B, Ruzicka JL, Yang ZY, Pellows LM, Willis MA, Brown KA, Seefeldt LC, Peters JW, Dukovic G, and King PW

Abstract

A critical step in the mechanism of N 2 reduction to 2NH 3 catalyzed by the enzyme nitrogenase is the reaction of the four-electron/four-proton reduced intermediate state of the active-site FeMo-cofactor (E 4 (4H)). This state is a junction in the catalytic mechanism, either relaxing by the reaction of a metal bound Fe-hydride with a proton forming H 2 or going forward with N 2 binding coupled to the reductive elimination ( re ) of two Fe-hydrides as H 2 to form the E 4 (2N2H) state. E 4 (2N2H) can relax to E 4 (4H) by the oxidative addition ( oa ) of H 2 and release of N 2 or can be further reduced in a series of catalytic steps to release 2NH 3 . If the H 2 re / oa mechanism is correct, it requires that oa of H 2 be associative with E 4 (2N2H). In this report, we have taken advantage of CdS quantum dots in complex with MoFe protein to achieve photodriven electron delivery in the frozen state, with cryo-annealing in the dark, to reveal details of the E-state species and to test the stability of E 4 (2N2H). Illumination of frozen CdS:MoFe protein complexes led to formation of a population of reduced intermediates. Electron paramagnetic resonance spectroscopy identified E-state signals including E 2 and E 4 (2N2H), as well as signals suggesting the formation of E 6 or E 8 . It is shown that in the frozen state when pN 2 is much greater than pH 2 , the E 4 (2N2H) state is kinetically stable, with very limited forward or reverse reaction rates. These results establish that the oa of H 2 to the E 4 (2N2H) state follows an associative reaction mechanism.

Published

2023

13. Electrochemical experiments define potentials associated with binding of substrates and inhibitors to nitrogenase MoFe protein.

Author

Chen T, Ash PA, Seefeldt LC, and Vincent KA

Subjects

Oxidation-Reduction, Proteins metabolism, Nitrogen Fixation, Nitrogenase chemistry, Nitrogenase metabolism, Molybdoferredoxin chemistry, Molybdoferredoxin metabolism

Abstract

Nitrogenases catalyse the 6-electron reduction of dinitrogen to ammonia, passing through a series of redox and protonation levels during catalytic substrate reduction. The molybdenum-iron nitrogenase is the most well-studied, but redox potentials associated with proton-coupled transformations between the redox levels of the catalytic MoFe protein have proved difficult to pin down, in part due to a complex electron-transfer pathway from the partner Fe protein, linked to ATP-hydrolysis. Here, we apply electrochemical control to the MoFe protein of Azotobacter vinelandii nitrogenase, using europium(III/II)-ligand couples as low potential redox mediators. We combine insight from the electrochemical current response with data from gas chromatography and in situ infrared spectroscopy, in order to define potentials for the binding of a series of inhibitors (carbon monoxide, methyl isocyanide) to the metallo-catalytic site of the MoFe protein, and the onset of catalytic transformation of alternative substrates (protons and acetylene) by the enzyme. Thus, we associate potentials with the redox levels for inhibition and catalysis by nitrogenase, with relevance to the elusive mechanism of biological nitrogen fixation.

Published

2023

14. A conformational equilibrium in the nitrogenase MoFe protein with an α-V70I amino acid substitution illuminates the mechanism of H 2 formation.

Author

Lukoyanov DA, Yang ZY, Shisler K, Peters JW, Raugei S, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Amino Acid Substitution, Oxidation-Reduction, Molecular Conformation, Amino Acids, Protons, Nitrogenase chemistry, Nitrogenase metabolism, Molybdoferredoxin chemistry, Molybdoferredoxin metabolism

Abstract

Study of α-V70I-substituted nitrogenase MoFe protein identified Fe6 of FeMo-cofactor (Fe 7 S 9 MoC-homocitrate) as a critical N 2 binding/reduction site. Freeze-trapping this enzyme during Ar turnover captured the key catalytic intermediate in high occupancy, denoted E 4 (4H), which has accumulated 4[e - /H + ] as two bridging hydrides, Fe2-H-Fe6 and Fe3-H-Fe7, and protons bound to two sulfurs. E 4 (4H) is poised to bind/reduce N 2 as driven by mechanistically-coupled H 2 reductive-elimination of the hydrides. This process must compete with ongoing hydride protonation (HP), which releases H 2 as the enzyme relaxes to state E 2 (2H), containing 2[e - /H + ] as a hydride and sulfur-bound proton; accumulation of E 4 (4H) in α-V70I is enhanced by HP suppression. EPR and 95 Mo ENDOR spectroscopies now show that resting-state α-V70I enzyme exists in two conformational states, both in solution and as crystallized, one with wild type (WT)-like FeMo-co and one with perturbed FeMo-co. These reflect two conformations of the Ile residue, as visualized in a reanalysis of the X-ray diffraction data of α-V70I and confirmed by computations. EPR measurements show delivery of 2[e - /H + ] to the E 0 state of the WT MoFe protein and to both α-V70I conformations generating E 2 (2H) that contains the Fe3-H-Fe7 bridging hydride; accumulation of another 2[e - /H + ] generates E 4 (4H) with Fe2-H-Fe6 as the second hydride. E 4 (4H) in WT enzyme and a minority α-V70I E 4 (4H) conformation as visualized by QM/MM computations relax to resting-state through two HP steps that reverse the formation process: HP of Fe2-H-Fe6 followed by slower HP of Fe3-H-Fe7, which leads to transient accumulation of E 2 (2H) containing Fe3-H-Fe7. In the dominant α-V70I E 4 (4H) conformation, HP of Fe2-H-Fe6 is passively suppressed by the positioning of the Ile sidechain; slow HP of Fe3-H-Fe7 occurs first and the resulting E 2 (2H) contains Fe2-H-Fe6. It is this HP suppression in E 4 (4H) that enables α-V70I MoFe to accumulate E 4 (4H) in high occupancy. In addition, HP suppression in α-V70I E 4 (4H) kinetically unmasks hydride reductive-elimination without N 2 -binding, a process that is precluded in WT enzyme.

Published

2023

15. Enzymatic N 2 activation: general discussion.

Author

Abi Ghaida F, Brinkert K, Chen P, DeBeer S, Hoffman BM, Holland PL, Laxmi S, MacFarlane D, Peters JC, Peters JW, Pickett CJ, Seefeldt LC, Shylin SI, Stephens IEL, Vincent KA, Wang Q, and Westhead O

Published

2023

16. The Fe Protein Cycle Associated with Nitrogenase Catalysis Requires the Hydrolysis of Two ATP for Each Single Electron Transfer Event.

Author

Yang ZY, Badalyan A, Hoffman BM, Dean DR, and Seefeldt LC

Subjects

Electrons, Hydrolysis, Adenosine Triphosphate chemistry, Oxidation-Reduction, Iron metabolism, Catalysis, Electron Spin Resonance Spectroscopy, Nitrogenase chemistry, Molybdoferredoxin chemistry

Abstract

A central feature of the current understanding of dinitrogen (N 2 ) reduction by the enzyme nitrogenase is the proposed coupling of the hydrolysis of two ATP, forming two ADP and two Pi, to the transfer of one electron from the Fe protein component to the MoFe protein component, where substrates are reduced. A redox-active [4Fe-4S] cluster associated with the Fe protein is the agent of electron delivery, and it is well known to have a capacity to cycle between a one-electron-reduced [4Fe-4S] 1+ state and an oxidized [4Fe-4S] 2+ state. Recently, however, it has been shown that certain reducing agents can be used to further reduce the Fe protein [4Fe-4S] cluster to a super-reduced, all-ferrous [4Fe-4S] 0 state that can be either diamagnetic ( S = 0) or paramagnetic ( S = 4). It has been proposed that the super-reduced state might fundamentally alter the existing model for nitrogenase energy utilization by the transfer of two electrons per Fe protein cycle linked to hydrolysis of only two ATP molecules. Here, we measure the number of ATP consumed for each electron transfer under steady-state catalysis while the Fe protein cluster is in the [4Fe-4S] 1+ state and when it is in the [4Fe-4S] 0 state. Both oxidation states of the Fe protein are found to operate by hydrolyzing two ATP for each single-electron transfer event. Thus, regardless of its initial redox state, the Fe protein transfers only one electron at a time to the MoFe protein in a process that requires the hydrolysis of two ATP.

Published

2023

17. Nitrogenase resurrection and the evolution of a singular enzymatic mechanism.

Author

Garcia AK, Harris DF, Rivier AJ, Carruthers BM, Pinochet-Barros A, Seefeldt LC, and Kaçar B

Subjects

Nitrogen Fixation, Amino Acid Sequence, Nitrogen metabolism, Nitrogenase chemistry, Nitrogenase genetics, Nitrogenase metabolism, Azotobacter vinelandii genetics, Azotobacter vinelandii metabolism

Abstract

The planetary biosphere is powered by a suite of key metabolic innovations that emerged early in the history of life. However, it is unknown whether life has always followed the same set of strategies for performing these critical tasks. Today, microbes access atmospheric sources of bioessential nitrogen through the activities of just one family of enzymes, nitrogenases. Here, we show that the only dinitrogen reduction mechanism known to date is an ancient feature conserved from nitrogenase ancestors. We designed a paleomolecular engineering approach wherein ancestral nitrogenase genes were phylogenetically reconstructed and inserted into the genome of the diazotrophic bacterial model, Azotobacter vinelandii, enabling an integrated assessment of both in vivo functionality and purified nitrogenase biochemistry. Nitrogenase ancestors are active and robust to variable incorporation of one or more ancestral protein subunits. Further, we find that all ancestors exhibit the reversible enzymatic mechanism for dinitrogen reduction, specifically evidenced by hydrogen inhibition, which is also exhibited by extant A. vinelandii nitrogenase isozymes. Our results suggest that life may have been constrained in its sampling of protein sequence space to catalyze one of the most energetically challenging biochemical reactions in nature. The experimental framework established here is essential for probing how nitrogenase functionality has been shaped within a dynamic, cellular context to sustain a globally consequential metabolism., Competing Interests: AG, DH, AR, BC, AP, LS, BK No competing interests declared, (© 2023, Garcia et al.)

Published

2023

18. 13 C ENDOR Characterization of the Central Carbon within the Nitrogenase Catalytic Cofactor Indicates That the CFe 6 Core Is a Stabilizing "Heart of Steel".

Author

Lukoyanov DA, Yang ZY, Pérez-González A, Raugei S, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Carbon metabolism, Catalysis, Electron Spin Resonance Spectroscopy methods, Oxidation-Reduction, Steel, Molybdoferredoxin chemistry, Nitrogenase chemistry

Abstract

Substrates and inhibitors of Mo-dependent nitrogenase bind and react at Fe ions of the active-site FeMo-cofactor [7Fe-9S-C-Mo-homocitrate] contained within the MoFe protein α-subunit. The cofactor contains a CFe 6 core, a carbon centered within a trigonal prism of six Fe, whose role in catalysis is unknown. Targeted 13 C labeling of the carbon enables electron-nuclear double resonance (ENDOR) spectroscopy to sensitively monitor the electronic properties of the Fe-C bonds and the spin-coupling scheme adopted by the FeMo-cofactor metal ions. This report compares 13 CFe 6 ENDOR measurements for (i) the wild-type protein resting state ( E 0 ; α-Val 70 ) to those of (ii) α-Ile 70 , (iii) α-Ala 70 -substituted proteins; (iv) crystallographically characterized CO-inhibited "hi-CO" state; (v) E 4 (4H) Janus intermediate, activated for N 2 binding/reduction by accumulation of 4[e - /H + ]; (vi) E 4 (2H)* state containing a doubly reduced FeMo-cofactor without Fe-bound substrates; and (vii) propargyl alcohol reduction intermediate having allyl alcohol bound as a ferracycle to FeMo-cofactor Fe6. All states examined, both S = 1/2 and 3/2 exhibited near-zero 13 C isotropic hyperfine coupling constants, C a = [-1.3 ↔ +2.7] MHz. Density functional theory computations and natural bond orbital analysis of the Fe-C bonds show that this occurs because a (3 spin-up/3 spin-down) spin-exchange configuration of CFe 6 Fe-ion spins produces cancellation of large spin-transfers to carbon in each Fe-C bond. Previous X-ray diffraction and DFT both indicate that trigonal-prismatic geometry around carbon is maintained with high precision in all these states. The persistent structure and Fe-C bonding of the CFe 6 core indicate that it does not provide a functionally dynamic (hemilabile) "beating heart"─instead it acts as "a heart of steel", stabilizing the structure of the FeMo-cofactor-active site during nitrogenase catalysis.

Published

2022

19. Mechanistic Insights into Nitrogenase FeMo-Cofactor Catalysis through a Steady-State Kinetic Model.

Author

Harris DF, Badalyan A, and Seefeldt LC

Subjects

Catalysis, Kinetics, Oxidation-Reduction, Molybdoferredoxin metabolism, Nitrogenase chemistry

Abstract

Mo-nitrogenase catalyzes the challenging N 2 -to-NH 3 reduction. This complex reaction proceeds through a series of intermediate states (E n ) of its active site FeMo-cofactor. An understanding of the kinetics of the conversion between E n states is central to defining the mechanism of nitrogenase. Here, rate constants of key steps have been determined through a steady-state kinetic model with fits to experimental data. The model reveals that the rate for H 2 formation from the early electron populated state E 2 (2H) is much slower than that from the more reduced E 4 (4H) state. Further, it is found that the competing reactions of H 2 formation and N 2 binding at the E 4 (4H) state occur with equal rate constants. The H 2 -dependent reverse reaction of the N 2 binding step is found to have a rate constant of 5.5 ± 0.2 (atm H 2 ) -1 s -1 (7.2 ± 0.3 (mM H 2 ) -1 s -1 ). Importantly, the reduction of N 2 bound to FeMo-cofactor proceeds with a rate constant of 1 ± 0.1 s -1 , revealing a previously unrecognized slow step in the Mo-nitrogenase catalytic cycle associated with the chemical transformation of N 2 to 2 NH 3 . Finally, the populations of E n states under different reaction conditions are predicted, providing a powerful tool to guide the spectroscopic and mechanistic studies of Mo-nitrogenase.

Published

2022

20. Photosynthetic biohybrid coculture for tandem and tunable CO 2 and N 2 fixation.

Author

Cestellos-Blanco S, Chan RR, Shen YX, Kim JM, Tacken TA, Ledbetter R, Yu S, Seefeldt LC, and Yang P

Subjects

Acetates metabolism, Ammonia, Coculture Techniques, Ecosystem, Nitrogen metabolism, Carbon Dioxide metabolism, Firmicutes growth & development, Firmicutes metabolism, Nitrogen Fixation, Photosynthesis, Rhodopseudomonas growth & development, Rhodopseudomonas metabolism

Abstract

Solar-driven bioelectrosynthesis represents a promising approach for converting abundant resources into value-added chemicals with renewable energy. Microorganisms powered by electrochemical reducing equivalents assimilate CO 2 , H 2 O, and N 2 building blocks. However, products from autotrophic whole-cell biocatalysts are limited. Furthermore, biocatalysts tasked with N 2 reduction are constrained by simultaneous energy-intensive autotrophy. To overcome these challenges, we designed a biohybrid coculture for tandem and tunable CO 2 and N 2 fixation to value-added products, allowing the different species to distribute bioconversion steps and reduce the individual metabolic burden. This consortium involves acetogen Sporomusa ovata , which reduces CO 2 to acetate, and diazotrophic Rhodopseudomonas palustris , which uses the acetate both to fuel N 2 fixation and for the generation of a biopolyester. We demonstrate that the coculture platform provides a robust ecosystem for continuous CO 2 and N 2 fixation, and its outputs are directed by substrate gas composition. Moreover, we show the ability to support the coculture on a high-surface area silicon nanowire cathodic platform. The biohybrid coculture achieved peak faradaic efficiencies of 100, 19.1, and 6.3% for acetate, nitrogen in biomass, and ammonia, respectively, while maintaining product tunability. Finally, we established full solar to chemical conversion driven by a photovoltaic device, resulting in solar to chemical efficiencies of 1.78, 0.51, and 0.08% for acetate, nitrogenous biomass, and ammonia, correspondingly. Ultimately, our work demonstrates the ability to employ and electrochemically manipulate bacterial communities on demand to expand the suite of CO 2 and N 2 bioelectrosynthesis products.

Published

2022

21. A colorimetric method to measure in vitro nitrogenase functionality for engineering nitrogen fixation.

Author

Payá-Tormo L, Coroian D, Martín-Muñoz S, Badalyan A, Green RT, Veldhuizen M, Jiang X, López-Torrejón G, Balk J, Seefeldt LC, Burén S, and Rubio LM

Subjects

Colorimetry, Nitrogen metabolism, Saccharomyces cerevisiae metabolism, Nitrogen Fixation genetics, Nitrogenase metabolism

Abstract

Biological nitrogen fixation (BNF) is the reduction of N 2 into NH 3 in a group of prokaryotes by an extremely O 2 -sensitive protein complex called nitrogenase. Transfer of the BNF pathway directly into plants, rather than by association with microorganisms, could generate crops that are less dependent on synthetic nitrogen fertilizers and increase agricultural productivity and sustainability. In the laboratory, nitrogenase activity is commonly determined by measuring ethylene produced from the nitrogenase-dependent reduction of acetylene (ARA) using a gas chromatograph. The ARA is not well suited for analysis of large sample sets nor easily adapted to automated robotic determination of nitrogenase activities. Here, we show that a reduced sulfonated viologen derivative (S 2 V red ) assay can replace the ARA for simultaneous analysis of isolated nitrogenase proteins using a microplate reader. We used the S 2 V red to screen a library of NifH nitrogenase components targeted to mitochondria in yeast. Two NifH proteins presented properties of great interest for engineering of nitrogen fixation in plants, namely NifM independency, to reduce the number of genes to be transferred to the eukaryotic host; and O 2 resistance, to expand the half-life of NifH iron-sulfur cluster in a eukaryotic cell. This study established that NifH from Dehalococcoides ethenogenes did not require NifM for solubility, [Fe-S] cluster occupancy or functionality, and that NifH from Geobacter sulfurreducens was more resistant to O 2 exposure than the other NifH proteins tested. It demonstrates that nitrogenase components with specific biochemical properties such as a wider range of O 2 tolerance exist in Nature, and that their identification should be an area of focus for the engineering of nitrogen-fixing crops., (© 2022. The Author(s).)

Published

2022

22. AnfO controls fidelity of nitrogenase FeFe protein maturation by preventing misincorporation of FeV-cofactor.

Author

Pérez-González A, Jimenez-Vicente E, Salinero-Lanzarote A, Harris DF, Seefeldt LC, and Dean DR

Subjects

Bacterial Proteins metabolism, Catalytic Domain, Molybdoferredoxin metabolism, Azotobacter vinelandii genetics, Nitrogenase genetics, Nitrogenase metabolism

Abstract

Azotobacter vinelandii produces three genetically distinct, but structurally and mechanistically similar nitrogenase isozymes designated as Mo-dependent, V-dependent, or Fe-only based on the heterometal contained within their associated active site cofactors. These catalytic cofactors, which provide the site for N 2 binding and reduction, are, respectively, designated as FeMo-cofactor, FeV-cofactor, and FeFe-cofactor. Fe-only nitrogenase is a poor catalyst for N 2 fixation, when compared to the Mo-dependent and V-dependent nitrogenases and is only produced when neither Mo nor V is available. Under conditions favoring the production of Fe-only nitrogenase a gene product designated AnfO preserves the fidelity of Fe-only nitrogenase by preventing the misincorporation of FeV-cofactor, which results in the accumulation of a hybrid enzyme that cannot reduce N 2 . These results are interpreted to indicate that AnfO controls the fidelity of Fe-only nitrogenase maturation during the physiological transition from conditions that favor V-dependent nitrogenase utilization to Fe-only nitrogenase utilization to support diazotrophic growth., (© 2022 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.)

Published

2022

23. The One-Electron Reduced Active-Site FeFe-Cofactor of Fe-Nitrogenase Contains a Hydride Bound to a Formally Oxidized Metal-Ion Core.

Author

Lukoyanov DA, Harris DF, Yang ZY, Pérez-González A, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Electron Spin Resonance Spectroscopy, Hydrogen chemistry, Metals metabolism, Molybdoferredoxin metabolism, Oxidation-Reduction, Electrons, Nitrogenase chemistry

Abstract

The nitrogenase active-site cofactor must accumulate 4e - /4H + (E 4 (4H) state) before N 2 can bind and be reduced. Earlier studies demonstrated that this E 4 (4H) state stores the reducing-equivalents as two hydrides, with the cofactor metal-ion core formally at its resting-state redox level. This led to the understanding that N 2 binding is mechanistically coupled to reductive-elimination of the two hydrides that produce H 2 . The state having acquired 2e - /2H + (E 2 (2H)) correspondingly contains one hydride with a resting-state core redox level. How the cofactor accommodates addition of the first e - /H + (E 1 (H) state) is unknown. The Fe-nitrogenase FeFe-cofactor was used to address this question because it is EPR-active in the E 1 (H) state, unlike the FeMo-cofactor of Mo-nitrogenase, thus allowing characterization by EPR spectroscopy. The freeze-trapped E 1 (H) state of Fe-nitrogenase shows an S = 1/2 EPR spectrum with g = [1.965, 1.928, 1.779]. This state is photoactive, and under 12 K cryogenic intracavity , 450 nm photolysis converts to a new and likewise photoactive S = 1/2 state (denoted E 1 (H)*) with g = [2.009, 1.950, 1.860], which results in a photostationary state, with E 1 (H)* relaxing to E 1 (H) at temperatures above 145 K. An H/D kinetic isotope effect of 2.4 accompanies the 12 K E 1 (H)/E 1 (H)* photointerconversion. These observations indicate that the addition of the first e - /H + to the FeFe-cofactor of Fe-nitrogenase produces an Fe-bound hydride, not a sulfur-bound proton. As a result, the cluster metal-ion core is formally one-electron oxidized relative to the resting state. It is proposed that this behavior applies to all three nitrogenase isozymes.

Published

2022

24. Dissecting Electronic-Structural Transitions in the Nitrogenase MoFe Protein P-Cluster during Reduction.

Author

Chica B, Ruzicka J, Pellows LM, Kallas H, Kisgeropoulos E, Vansuch GE, Mulder DW, Brown KA, Svedruzic D, Peters JW, Dukovic G, Seefeldt LC, and King PW

Subjects

Electron Spin Resonance Spectroscopy, Electronics, Nitrogenase chemistry, Oxidation-Reduction, Azotobacter vinelandii metabolism, Molybdoferredoxin chemistry

Abstract

The [8Fe-7S] P-cluster of nitrogenase MoFe protein mediates electron transfer from nitrogenase Fe protein during the catalytic production of ammonia. The P-cluster transitions between three oxidation states, P N , P + , P 2+ of which P N ↔P + is critical to electron exchange in the nitrogenase complex during turnover. To dissect the steps in formation of P + during electron transfer, photochemical reduction of MoFe protein at 231-263 K was used to trap formation of P + intermediates for analysis by EPR. In complexes with CdS nanocrystals, illumination of MoFe protein led to reduction of the P-cluster P 2+ that was coincident with formation of three distinct EPR signals: S = 1/2 axial and rhombic signals, and a high-spin S = 7/2 signal. Under dark annealing the axial and high-spin signal intensities declined, which coincided with an increase in the rhombic signal intensity. A fit of the time-dependent changes of the axial and high-spin signals to a reaction model demonstrates they are intermediates in the formation of the P-cluster P + resting state and defines how spin-state transitions are coupled to changes in P-cluster oxidation state in MoFe protein during electron transfer.

Published

2022

25. A conformational role for NifW in the maturation of molybdenum nitrogenase P-cluster.

Author

Van Stappen C, Jiménez-Vicente E, Pérez-González A, Yang ZY, Seefeldt LC, DeBeer S, Dean DR, and Decamps L

Abstract

Reduction of dinitrogen by molybdenum nitrogenase relies on complex metalloclusters: the [8Fe:7S] P-cluster and the [7Fe:9S:Mo:C:homocitrate] FeMo-cofactor. Although both clusters bear topological similarities and require the reductive fusion of [4Fe:4S] sub-clusters to achieve their respective assemblies, P-clusters are assembled directly on the NifD 2 K 2 polypeptide prior to the insertion of FeMo-co, which is fully assembled separately from NifD 2 K 2 . P-cluster maturation involves the iron protein NifH 2 as well as several accessory proteins, whose role has not been elucidated. In the present work, two NifD 2 K 2 species bearing immature P-clusters were isolated from an Azotobacter vinelandii strain in which the genes encoding NifH and the accessory protein NifZ were deleted, and characterized by X-ray absorption spectroscopy and EPR. These analyses showed that both NifD 2 K 2 complexes harbor clusters that are electronically and structurally similar, with each NifDK unit containing two [4Fe:4S] 2+/+ clusters. Binding of the accessory protein NifW parallels a decrease in the distance between these clusters, as well as a subtle change in their coordination. These results support a conformational role for NifW in P-cluster biosynthesis, bringing the two [4Fe:4S] precursors closer prior to their fusion, which may be crucial in challenging cellular contexts., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2022

26. Specificity of NifEN and VnfEN for the Assembly of Nitrogenase Active Site Cofactors in Azotobacter vinelandii.

Author

Pérez-González A, Jimenez-Vicente E, Gies-Elterlein J, Salinero-Lanzarote A, Yang ZY, Einsle O, Seefeldt LC, and Dean DR

Subjects

Azotobacter vinelandii enzymology, Azotobacter vinelandii genetics, Bacterial Proteins metabolism, Biocatalysis, Coenzymes genetics, Molybdoferredoxin metabolism, Nitrogen metabolism, Nitrogen Fixation genetics, Nitrogenase metabolism, Azotobacter vinelandii metabolism, Catalytic Domain, Coenzymes metabolism, Nitrogenase chemistry

Abstract

The nitrogen-fixing microbe Azotobacter vinelandii has the ability to produce three genetically distinct, but mechanistically similar, components that catalyze nitrogen fixation. For two of these components, the Mo-dependent and V-dependent components, their corresponding metal-containing active site cofactors, designated FeMo-cofactor and FeV-cofactor, respectively, are preformed on separate molecular scaffolds designated NifEN and VnfEN, respectively. From prior studies, and the present work, it is now established that neither of these scaffolds can replace the other with respect to their in vivo cofactor assembly functions. Namely, a strain inactivated for NifEN cannot produce active Mo-dependent nitrogenase nor can a strain inactivated for VnfEN produce an active V-dependent nitrogenase. It is therefore proposed that metal specificities for FeMo-cofactor and FeV-cofactor formation are supplied by their respective assembly scaffolds. In the case of the third, Fe-only component, its associated active site cofactor, designated FeFe-cofactor, requires neither the NifEN nor VnfEN assembly scaffold for its formation. Furthermore, there are no other genes present in A. vinelandii that encode proteins having primary structure similarity to either NifEN or VnfEN. It is therefore concluded that FeFe-cofactor assembly is completed within its cognate catalytic protein partner without the aid of an intermediate assembly site. IMPORTANCE Biological nitrogen fixation is a complex process involving the nitrogenases. The biosynthesis of an active nitrogenase involves a large number of genes and the coordinated function of their products. Understanding the details of the assembly and activation of the different nitrogen fixation components, in particular the simplest one known so far, the Fe-only nitrogenase, would contribute to the goal of transferring the necessary genetic elements of bacterial nitrogen fixation to cereal crops to endow them with the capacity for self-fertilization. In this work, we show that there is no need for a scaffold complex for the assembly of the FeFe-cofactor, which provides the active site for Fe-only nitrogenase. These results are in agreement with previously reported genetic reconstruction experiments using a non-nitrogen-fixing microbe. In aggregate, these findings provide a high degree of confidence that the Fe-only system represents the simplest and, therefore, most attractive target for mobilizing nitrogen fixation into plants.

Published

2021

27. Exploring the Role of the Central Carbide of the Nitrogenase Active-Site FeMo-cofactor through Targeted 13 C Labeling and ENDOR Spectroscopy.

Author

Pérez-González A, Yang ZY, Lukoyanov DA, Dean DR, Seefeldt LC, and Hoffman BM

Subjects

Azotobacter vinelandii enzymology, Carbon Isotopes, Catalytic Domain, Electron Spin Resonance Spectroscopy, Isotope Labeling, Molecular Conformation, Molybdoferredoxin chemistry, Nitrogenase chemistry, Nitrogenase isolation & purification, Molybdoferredoxin metabolism, Nitrogenase metabolism

Abstract

Mo-dependent nitrogenase is a major contributor to global biological N 2 reduction, which sustains life on Earth. Its multi-metallic active-site FeMo-cofactor (Fe 7 MoS 9 C-homocitrate) contains a carbide (C 4- ) centered within a trigonal prismatic CFe 6 core resembling the structural motif of the iron carbide, cementite. The role of the carbide in FeMo-cofactor binding and activation of substrates and inhibitors is unknown. To explore this role, the carbide has been in effect selectively enriched with 13 C, which enables its detailed examination by ENDOR/ESEEM spectroscopies. 13 C-carbide ENDOR of the S = 3/2 resting state (E 0 ) is remarkable, with an extremely small isotropic hyperfine coupling constant, C a = +0.86 MHz. Turnover under high CO partial pressure generates the S = 1/2 hi-CO state, with two CO molecules bound to FeMo-cofactor. This conversion surprisingly leaves the small magnitude of the 13 C carbide isotropic hyperfine-coupling constant essentially unchanged, C a = -1.30 MHz. This indicates that both the E 0 and hi-CO states exhibit an exchange-coupling scheme with nearly cancelling contributions to C a from three spin-up and three spin-down carbide-bound Fe ions. In contrast, the anisotropic hyperfine coupling constant undergoes a symmetry change upon conversion of E 0 to hi-CO that may be associated with bonding and coordination changes at Fe ions. In combination with the negligible difference between CFe 6 core structures of E 0 and hi-CO, these results suggest that in CO-inhibited hi-CO the dominant role of the FeMo-cofactor carbide is to maintain the core structure, rather than to facilitate inhibitor binding through changes in Fe-carbide covalency or stretching/breaking of carbide-Fe bonds.

Published

2021

28. The electronic structure of FeV-cofactor in vanadium-dependent nitrogenase.

Author

Yang ZY, Jimenez-Vicente E, Kallas H, Lukoyanov DA, Yang H, Martin Del Campo JS, Dean DR, Hoffman BM, and Seefeldt LC

Abstract

The electronic structure of the active-site metal cofactor (FeV-cofactor) of resting-state V-dependent nitrogenase has been an open question, with earlier studies indicating that it exhibits a broad S = 3/2 EPR signal (Kramers state) having g values of ∼4.3 and 3.8, along with suggestions that it contains metal-ions with valencies [1V 3+ , 3Fe 3+ , 4Fe 2+ ]. In the present work, genetic, biochemical, and spectroscopic approaches were combined to reveal that the EPR signals previously assigned to FeV-cofactor do not correlate with active VFe-protein, and thus cannot arise from the resting-state of catalytically relevant FeV-cofactor. It, instead, appears resting-state FeV-cofactor is either diamagnetic, S = 0, or non-Kramers, integer-spin ( S = 1, 2 etc. ). When VFe-protein is freeze-trapped during high-flux turnover with its natural electron-donating partner Fe protein, conditions which populate reduced states of the FeV-cofactor, a new rhombic S = 1/2 EPR signal from such a reduced state is observed, with g = [2.18, 2.12, 2.09] and showing well-defined 51 V ( I = 7/2) hyperfine splitting, a iso = 110 MHz. These findings indicate a different assignment for the electronic structure of the resting state of FeV-cofactor: S = 0 (or integer-spin non-Kramers state) with metal-ion valencies, [1V 3+ , 4Fe 3+ , 3Fe 2+ ]. Our findings suggest that the V 3+ does not change valency throughout the catalytic cycle., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

29. Grand challenges in the nitrogen cycle.

Author

Lehnert N, Musselman BW, and Seefeldt LC

Abstract

In this Viewpoint, we address some of the limitations within our current understanding of the complex chemistry of the enzymes used in the Nitrogen Cycle. Further understanding of these chemical processes will play a large role in limiting the anthropogenic effects on our environment.

Published

2021

30. Mechanical coupling in the nitrogenase complex.

Author

Huang Q, Tokmina-Lukaszewska M, Johnson LE, Kallas H, Ginovska B, Peters JW, Seefeldt LC, Bothner B, and Raugei S

Subjects

Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Azotobacter vinelandii enzymology, Binding Sites, Deuterium Exchange Measurement, Electron Transport, Models, Molecular, Protein Binding, Molybdoferredoxin chemistry, Molybdoferredoxin metabolism

Abstract

The enzyme nitrogenase reduces dinitrogen to ammonia utilizing electrons, protons, and energy obtained from the hydrolysis of ATP. Mo-dependent nitrogenase is a symmetric dimer, with each half comprising an ATP-dependent reductase, termed the Fe Protein, and a catalytic protein, known as the MoFe protein, which hosts the electron transfer P-cluster and the active-site metal cofactor (FeMo-co). A series of synchronized events for the electron transfer have been characterized experimentally, in which electron delivery is coupled to nucleotide hydrolysis and regulated by an intricate allosteric network. We report a graph theory analysis of the mechanical coupling in the nitrogenase complex as a key step to understanding the dynamics of allosteric regulation of nitrogen reduction. This analysis shows that regions near the active sites undergo large-scale, large-amplitude correlated motions that enable communications within each half and between the two halves of the complex. Computational predictions of mechanically regions were validated against an analysis of the solution phase dynamics of the nitrogenase complex via hydrogen-deuterium exchange. These regions include the P-loops and the switch regions in the Fe proteins, the loop containing the residue β-188Ser adjacent to the P-cluster in the MoFe protein, and the residues near the protein-protein interface. In particular, it is found that: (i) within each Fe protein, the switch regions I and II are coupled to the [4Fe-4S] cluster; (ii) within each half of the complex, the switch regions I and II are coupled to the loop containing β-188Ser; (iii) between the two halves of the complex, the regions near the nucleotide binding pockets of the two Fe proteins (in particular the P-loops, located over 130 Å apart) are also mechanically coupled. Notably, we found that residues next to the P-cluster (in particular the loop containing β-188Ser) are important for communication between the two halves., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

31. Comment on "Structural evidence for a dynamic metallocofactor during N 2 reduction by Mo-nitrogenase".

Author

Peters JW, Einsle O, Dean DR, DeBeer S, Hoffman BM, Holland PL, and Seefeldt LC

Subjects

Catalytic Domain, Nitrogenase metabolism, Azotobacter vinelandii, Molybdoferredoxin

Abstract

Kang et al (Reports, 19 June 2020, p. 1381) report a structure of the nitrogenase MoFe protein that is interpreted to indicate binding of N 2 or an N 2 -derived species to the active-site FeMo cofactor. Independent refinement of the structure and consideration of biochemical evidence do not support this claim., (Copyright © 2021, American Association for the Advancement of Science.)

Published

2021

32. Revealing a role for the G subunit in mediating interactions between the nitrogenase component proteins.

Author

Pence N, Lewis N, Alleman AB, Seefeldt LC, and Peters JW

Subjects

Azotobacter vinelandii enzymology, Bacterial Proteins chemistry, Multiprotein Complexes chemistry, Nitrogenase chemistry

Abstract

Azotobacter vinelandii contains three forms of nitrogenase known as the Mo-, V-, and Fe-nitrogenases. They are all two-component enzyme systems, where the catalytic component, referred to as NifDK, VnfDGK, and AnfDGK, associates with the reductase component, the Fe protein or NifH, VnfH, and AnfH respectively. AnfDGK and VnfDGK have an additional subunit compared to NifDK, termed gamma or AnfG and VnfG, whose role is unknown. The expression of each nitrogenase is tightly regulated by metal availability, however it is known that there is crosstalk between the Mo- and V‑nitrogenases but the Fe‑nitrogenase components cannot support substrate reduction with its Mo‑nitrogenase counterparts. Here, docking models for the nitrogenase complexes were generated in ClusPro 2.0 based on the crystal structure of the Mo‑nitrogenase and refined using the HADDOCK 2.2 refinement interface to identify structural determinants that enable crosstalk between the Mo- and V‑nitrogenase but not the Fe‑nitrogenase. Differing salt bridge interactions were identified at the binding interface of each complex. Specifically, positively charged residues of VnfG enable complementary interactions with NifH and VnfH but not AnfH. Similarly, negatively charged residues of AnfG enable interactions with AnfH but not NifH or VnfH. A role for the G subunit is revealed where VnfG could be mediating crosstalk between the Mo- and V‑nitrogenases while the AnfG subunit on AnfDGK makes interactions with NifH and VnfH unfavorable, reducing competition with NifDK and funneling electrons to the most efficient nitrogenase., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

33. The flexible N-terminus of BchL autoinhibits activity through interaction with its [4Fe-4S] cluster and released upon ATP binding.

Author

Corless EI, Saad Imran SM, Watkins MB, Bacik JP, Mattice JR, Patterson A, Danyal K, Soffe M, Kitelinger R, Seefeldt LC, Origanti S, Bennett B, Bothner B, Ando N, and Antony E

Subjects

Adenosine Triphosphate chemistry, Catalysis, Iron-Sulfur Proteins chemistry, Mass Spectrometry, Nitrogenase chemistry, Nitrogenase metabolism, Photosynthesis, Protochlorophyllide chemistry, Protochlorophyllide metabolism, Substrate Specificity, Adenosine Triphosphate metabolism, Iron-Sulfur Proteins metabolism

Abstract

A key step in bacteriochlorophyll biosynthesis is the reduction of protochlorophyllide to chlorophyllide, catalyzed by dark-operative protochlorophyllide oxidoreductase. Dark-operative protochlorophyllide oxidoreductase contains two [4Fe-4S]-containing component proteins (BchL and BchNB) that assemble upon ATP binding to BchL to coordinate electron transfer and protochlorophyllide reduction. But the precise nature of the ATP-induced conformational changes is poorly understood. We present a crystal structure of BchL in the nucleotide-free form where a conserved, flexible region in the N-terminus masks the [4Fe-4S] cluster at the docking interface between BchL and BchNB. Amino acid substitutions in this region produce a hyperactive enzyme complex, suggesting a role for the N-terminus in autoinhibition. Hydrogen-deuterium exchange mass spectrometry shows that ATP binding to BchL produces specific conformational changes leading to release of the flexible N-terminus from the docking interface. The release also promotes changes within the local environment surrounding the [4Fe-4S] cluster and promotes BchL-complex formation with BchNB. A key patch of amino acids, Asp-Phe-Asp (the 'DFD patch'), situated at the mouth of the BchL ATP-binding pocket promotes intersubunit cross stabilization of the two subunits. A linked BchL dimer with one defective ATP-binding site does not support protochlorophyllide reduction, illustrating nucleotide binding to both subunits as a prerequisite for the intersubunit cross stabilization. The masking of the [4Fe-4S] cluster by the flexible N-terminal region and the associated inhibition of the activity is a novel mechanism of regulation in metalloproteins. Such mechanisms are possibly an adaptation to the anaerobic nature of eubacterial cells with poor tolerance for oxygen., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

34. Electron Redistribution within the Nitrogenase Active Site FeMo-Cofactor During Reductive Elimination of H 2 to Achieve N≡N Triple-Bond Activation.

Author

Lukoyanov DA, Yang ZY, Dean DR, Seefeldt LC, Raugei S, and Hoffman BM

Subjects

Animals, Azotobacter vinelandii enzymology, Catalytic Domain, Electron Transport, Hydrogen chemistry, Molybdoferredoxin chemistry, Nitrogenase chemistry

Abstract

Nitrogen fixation by nitrogenase begins with the accumulation of four reducing equivalents at the active-site FeMo-cofactor (FeMo-co), generating a state (denoted E 4 (4H)) with two [Fe-H-Fe] bridging hydrides. Recently, photolytic reductive elimination ( re ) of the E 4 (4H) hydrides showed that enzymatic re of E 4 (4H) hydride yields an H 2 -bound complex (E 4 (H 2 ,2H)), in a process corresponding to a formal 2-electron reduction of the metal-ion core of FeMo-co. The resulting electron-density redistribution from Fe-H bonds to the metal ions themselves enables N 2 to bind with concomitant H 2 release, a process illuminated here by QM/MM molecular dynamics simulations. What is the nature of this redistribution? Although E 4 (H 2 ,2H) has not been trapped, cryogenic photolysis of E 4 (4H) provides a means to address this question. Photolysis of E 4 (4H) causes hydride- re with release of H 2 , generating doubly reduced FeMo-co (denoted E 4 (2H)*), the extreme limit of the electron-density redistribution upon formation of E 4 (H 2 ,2H). Here we examine the doubly reduced FeMo-co core of the E 4 (2H)* limiting-state by 1 H, 57 Fe, and 95 Mo ENDOR to illuminate the partial electron-density redistribution upon E 4 (H 2 ,2H) formation during catalysis, complementing these results with corresponding DFT computations. Inferences from the E 4 (2H)* ENDOR results as extended by DFT computations include (i) the Mo-site participates negligibly, and overall it is unlikely that Mo changes valency throughout the catalytic cycle; and (ii) two distinctive E 4 (4H) 57 Fe signals are suggested as associated with structurally identified "anchors" of one bridging hydride, two others with identified anchors of the second, with NBO-analysis further identifying one anchor of each hydride as a major recipient of electrons released upon breaking Fe-H bonds.

Published

2020

35. CO as a substrate and inhibitor of H + reduction for the Mo-, V-, and Fe-nitrogenase isozymes.

Author

Harris DF, Jimenez-Vicente E, Yang ZY, Hoffman BM, Dean DR, and Seefeldt LC

Subjects

Catalysis, Oxidation-Reduction, Carbon Monoxide chemistry, Hydrogen chemistry, Iron chemistry, Molybdenum chemistry, Nitrogenase chemistry, Vanadium chemistry

Abstract

Three known nitrogenase isozymes, Mo-, V-, and Fe-, catalyze biological reduction of dinitrogen (N 2 ) to ammonia (NH 3 ). All three utilize the same reductive elimination mechanism: an intermediate with two metal-bound hydrides reductively-eliminates hydrogen gas (H 2 ) in a reaction coupled to binding and activation of N 2 . Nonetheless, the three isozymes show dramatically different relative rates of H 2 formation and N 2 reduction, revealing important differences in reactivity with substrates. Carbon monoxide (CO) has been characterized as both an inhibitor and substrate for Mo- and V‑nitrogenases, but not for the Fe‑nitrogenase. Here, we present a comparative study of the reactivity of the three isozymes with CO, examining CO both as a substrate and as an inhibitor of proton (H + ) reduction under steady-state conditions. For Mo‑nitrogenase, there is neither detectable reduction of CO nor inhibition of H + reduction. Fe- and V‑nitrogenase show CO reduction and inhibition of H + reduction that depends on the CO partial pressure. For V‑nitrogenase, ethylene (C 2 H 4 ) is the major reduction product with a maximum specific activity of ~7.5 nmol C 2 H 4 /nmol VFe protein/min at 1 atm CO. The major product of CO reduction for Fe‑nitrogenase is methane (CH 4 ) with a maximum specific activity of ~4.8 nmol CH 4 /nmol FeFe protein/min at 0.05 atm CO. The rate of CH 4 production by Fe‑nitrogenase progressively increases to a maximum at 0.05 atm CO and then declines by ~90% with increasing CO partial pressure up to 1 atm. CO does not inhibit proton reduction in Mo‑nitrogenase but shows 16% inhibition for V‑nitrogenase and 35% for Fe‑nitrogenase., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

36. An Experimentally Evaluated Thermodynamic Approach to Estimate Growth of Photoheterotrophic Purple Non-sulfur Bacteria.

Author

Doloman A and Seefeldt LC

Abstract

Distribution of energy during the growth and formation of useful chemicals by microorganisms can define the overall performance of a biotechnological system. However, to date, this distribution has not been used to reliably predict growth characteristics of phototrophic microorganisms. The presented research addresses this application by estimating the photon-associated Gibbs energy delivered for the photoheterotrophic growth of purple non-sulfur bacteria and production of dihydrogen. The approach is successfully evaluated with the data from a fed-batch growth of Rhodopseudomonas palustris nifA ∗ fixing N 2 gas in phototrophic conditions and a reliable prediction of growth characteristics is demonstrated. Additionally, literature-available experimental data is collected and used for evaluation of the presented thermodynamic approach to predict photoheterotrophic growth yields. A proposed thermodynamic framework with modification to account for the phototrophic growth can be used to predict growth rates in broader environmental niches and to assess the possibility for the development of novel biotechnological applications in light-induced biological systems., (Copyright © 2020 Doloman and Seefeldt.)

Published

2020

37. Defining Intermediates of Nitrogenase MoFe Protein during N 2 Reduction under Photochemical Electron Delivery from CdS Quantum Dots.

Author

Chica B, Ruzicka J, Kallas H, Mulder DW, Brown KA, Peters JW, Seefeldt LC, Dukovic G, and King PW

Subjects

Azotobacter vinelandii enzymology, Cadmium Compounds chemistry, Electron Transport, Molybdoferredoxin chemistry, Oxidation-Reduction, Photochemical Processes, Quantum Dots chemistry, Sulfides chemistry, Cadmium Compounds metabolism, Molybdoferredoxin metabolism, Quantum Dots metabolism, Sulfides metabolism

Abstract

Coupling the nitrogenase MoFe protein to light-harvesting semiconductor nanomaterials replaces the natural electron transfer complex of Fe protein and ATP and provides low-potential photoexcited electrons for photocatalytic N 2 reduction. A central question is how direct photochemical electron delivery from nanocrystals to MoFe protein is able to support the multielectron ammonia production reaction. In this study, low photon flux conditions were used to identify the initial reaction intermediates of CdS quantum dot (QD):MoFe protein nitrogenase complexes under photochemical activation using EPR. Illumination of CdS QD:MoFe protein complexes led to redox changes in the MoFe protein active site FeMo-co observed as the gradual decline in the E 0 resting state intensity that was accompanied by an increase in the intensity of a new " g eff = 4.5" EPR signal. The magnetic properties of the g eff = 4.5 signal support assignment as a reduced S = 3/2 state, and reaction modeling was used to define it as a two-electron-reduced "E 2 " intermediate. Use of a MoFe protein variant, β-188 Cys , which poises the P cluster in the oxidized P + state, demonstrated that the P cluster can function as a site of photoexcited electron delivery from CdS to MoFe protein. Overall, the results establish the initial steps for how photoexcited CdS delivers electrons into the MoFe protein during reduction of N 2 to ammonia and the role of electron flux in the photochemical reaction cycle.

Published

2020

38. Reduction of Substrates by Nitrogenases.

Author

Seefeldt LC, Yang ZY, Lukoyanov DA, Harris DF, Dean DR, Raugei S, and Hoffman BM

Subjects

Biocatalysis, Carbon Dioxide chemistry, Carbon Dioxide metabolism, Carbon Monoxide chemistry, Carbon Monoxide metabolism, Isoenzymes chemistry, Isoenzymes metabolism, Models, Molecular, Nitrogen chemistry, Nitrogen metabolism, Nitrogenase chemistry, Oxidation-Reduction, Substrate Specificity, Nitrogenase metabolism

Abstract

Nitrogenase is the enzyme that catalyzes biological N 2 reduction to NH 3 . This enzyme achieves an impressive rate enhancement over the uncatalyzed reaction. Given the high demand for N 2 fixation to support food and chemical production and the heavy reliance of the industrial Haber-Bosch nitrogen fixation reaction on fossil fuels, there is a strong need to elucidate how nitrogenase achieves this difficult reaction under benign conditions as a means of informing the design of next generation synthetic catalysts. This Review summarizes recent progress in addressing how nitrogenase catalyzes the reduction of an array of substrates. New insights into the mechanism of N 2 and proton reduction are first considered. This is followed by a summary of recent gains in understanding the reduction of a number of other nitrogenous compounds not considered to be physiological substrates. Progress in understanding the reduction of a wide range of C-based substrates, including CO and CO 2 , is also discussed, and remaining challenges in understanding nitrogenase substrate reduction are considered.

Published

2020

39. Correction to "Establishing a Thermodynamic Landscape for the Active Site of Mo-Dependent Nitrogenase".

Author

Hickey DP, Cai R, Yang ZY, Grunau K, Einsle O, Seefeldt LC, and Minteer SD

Published

2020

40. Correction to "High-Resolution ENDOR Spectroscopy Combined with Quantum Chemical Calculations Reveals the Structure of Nitrogenase Janus Intermediate E 4 (4H)".

Author

Hoeke V, Tociu L, Case DA, Seefeldt LC, Raugei S, and Hoffman BM

Published

2019

41. An Efficient Viologen-Based Electron Donor to Nitrogenase.

Author

Badalyan A, Yang ZY, Hu B, Luo J, Hu M, Liu TL, and Seefeldt LC

Subjects

Azotobacter vinelandii metabolism, Cations chemistry, Cations metabolism, Dimerization, Electrons, Models, Molecular, Molybdoferredoxin metabolism, Oxidation-Reduction, Paraquat chemistry, Azotobacter vinelandii enzymology, Nitrogenase metabolism, Paraquat metabolism

Abstract

Nitrogenase catalyzes the reduction of N 2 to NH 3 , supporting all biological nitrogen fixation. Electron donors to this enzyme are ferredoxin or flavodoxin ( in vivo ) and sodium dithionite ( in vitro ). Features of these electron donors put a limit on spectrophotometric studies and electrocatalytic applications of nitrogenase. Although it is common to use methyl viologen as an electron donor for many low-potential oxidoreductases, decreased nitrogenase activity is observed with an increasing concentration of methyl viologen, limiting its utility under many circumstances. In this work, we suggest that this concentration-dependent decrease in activity can be explained by the formation of a dimer of the radical cation of methyl viologen (Me 2 V •+ ) 2 at higher methyl viologen concentrations. In addition, viologens functionalized with positively and negatively charged groups were synthesized and studied using spectroscopy and cyclic voltammetry. A sulfonated viologen derivative, 1,1'-bis(3-sulfonatopropyl)-4,4'-bipyridinium radical {[(SPr) 2 V • ] - }, was found to support full nitrogenase activity up to a mediator concentration of 3 mM, while the positively charged viologen derivative was not an efficient reductant of nitrogenase due to the high standard redox potential. The utility of [(SPr) 2 V • ] - as an electron donor for nitrogenase was demonstrated by a simple, sensitive spectrophotometric assay for nitrogenase activity that can provide accurate values for the specific activity and turnover rate constant under argon. Under N 2 , the formation of ammonia was confirmed. Because of the observed full activity of nitrogenase and low overpotential, [(SPr) 2 V • ] - should also prove to be valuable for nitrogenase electrocatalysis, including bioelectrosynthetic N 2 reduction.

Published

2019

42. Establishing a Thermodynamic Landscape for the Active Site of Mo-Dependent Nitrogenase.

Author

Hickey DP, Cai R, Yang ZY, Grunau K, Einsle O, Seefeldt LC, and Minteer SD

Subjects

Biosensing Techniques, Catalysis, Catalytic Domain, Coenzymes, Electrochemical Techniques instrumentation, Electrochemical Techniques methods, Electrolysis, Electron Transport, Enzymes, Immobilized chemistry, Enzymes, Immobilized metabolism, Hydrogels chemistry, Magnetic Resonance Spectroscopy, Nitrogen chemistry, Nitrogen metabolism, Nitrogenase chemistry, Nitrogenase metabolism, Oxidoreductases chemistry, Oxidoreductases metabolism, Polyethyleneimine chemistry, Thermodynamics, Molybdenum metabolism, Molybdoferredoxin chemistry, Molybdoferredoxin metabolism

Abstract

Nitrogenase enzymes are the only biological catalysts able to convert N 2 to NH 3 . Molybdenum-dependent nitrogenase consists of two proteins and three metallocofactors that sequentially shuttle eight electrons between three distinct metallocofactors during the turnover of one molecule of N 2 . While the kinetics of isolated nitrogenase has been extensively studied, little is known about the thermodynamics of its cofactors under catalytically relevant conditions. Here, we employ a recently described pyrene-modified linear poly(ethylenimine) hydrogel to immobilize the catalytic protein of nitrogenase onto an electrode surface. The resulting electroenzymatic interface enabled direct measurement of reduction potentials associated with each metallocofactor of the nitrogenase complex, illuminating the role of nitrogenase reductase in altering the potential landscape in the active site of nitrogenase and revealing the endergonic nature of electron-transfer steps associated with the conversion of N 2 to NH 3 under physiological conditions.

Published

2019

43. 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

44. Spectroscopic Description of the E 1 State of Mo Nitrogenase Based on Mo and Fe X-ray Absorption and Mössbauer Studies.

Author

Van Stappen C, Davydov R, Yang ZY, Fan R, Guo Y, Bill E, Seefeldt LC, Hoffman BM, and DeBeer S

Abstract

Mo nitrogenase (N2ase) utilizes a two-component protein system, the catalytic MoFe and its electron-transfer partner FeP, to reduce atmospheric dinitrogen (N 2 ) to ammonia (NH 3 ). The FeMo cofactor contained in the MoFe protein serves as the catalytic center for this reaction and has long inspired model chemistry oriented toward activating N 2 . This field of chemistry has relied heavily on the detailed characterization of how Mo N2ase accomplishes this feat. Understanding the reaction mechanism of Mo N2ase itself has presented one of the most challenging problems in bioinorganic chemistry because of the ephemeral nature of its catalytic intermediates, which are difficult, if not impossible, to singly isolate. This is further exacerbated by the near necessity of FeP to reduce native MoFe, rendering most traditional means of selective reduction inept. We have now investigated the first fundamental intermediate of the MoFe catalytic cycle, E 1 , as prepared both by low-flux turnover and radiolytic cryoreduction, using a combination of Mo Kα high-energy-resolution fluorescence detection and Fe K-edge partial-fluorescence-yield X-ray absorption spectroscopy techniques. The results demonstrate that the formation of this state is the result of an Fe-centered reduction and that Mo remains redox-innocent. Furthermore, using Fe X-ray absorption and 57 Fe Mössbauer spectroscopies, we correlate a previously reported unique species formed under cryoreducing conditions to the natively formed E 1 state through annealing, demonstrating the viability of cryoreduction in studying the catalytic intermediates of MoFe.

Published

2019

45. Phototrophic N 2 and CO 2 Fixation Using a Rhodopseudomonas palustris -H 2 Mediated Electrochemical System With Infrared Photons.

Author

Soundararajan M, Ledbetter R, Kusuma P, Zhen S, Ludden P, Bugbee B, Ensign SA, and Seefeldt LC

Abstract

A promising approach for the synthesis of high value reduced compounds is to couple bacteria to the cathode of an electrochemical cell, with delivery of electrons from the electrode driving reductive biosynthesis in the bacteria. Such systems have been used to reduce CO 2 to acetate and other C-based compounds. Here, we report an electrosynthetic system that couples a diazotrophic, photoautotrophic bacterium, Rhodopseudomonas palustris TIE-1, to the cathode of an electrochemical cell through the mediator H 2 that allows reductive capture of both CO 2 and N 2 with all of the energy coming from the electrode and infrared (IR) photons. R. palustris TIE-1 was shown to utilize a narrow band of IR radiation centered around 850 nm to support growth under both photoheterotrophic, non-diazotrophic and photoautotrophic, diazotrophic conditions with growth rates similar to those achieved using broad spectrum incandescent light. The bacteria were also successfully cultured in the cathodic compartment of an electrochemical cell with the sole source of electrons coming from electrochemically generated H 2 , supporting reduction of both CO 2 and N 2 using 850 nm photons as an energy source. Growth rates were similar to non-electrochemical conditions, revealing that the electrochemical system can fully support bacterial growth. Faradaic efficiencies for N 2 and CO 2 reduction were 8.5 and 47%, respectively. These results demonstrate that a microbial-electrode hybrid system can be used to achieve reduction and capture of both CO 2 and N 2 using low energy IR radiation and electrons provided by an electrode.

Published

2019

46. High-Resolution ENDOR Spectroscopy Combined with Quantum Chemical Calculations Reveals the Structure of Nitrogenase Janus Intermediate E 4 (4H).

Author

Hoeke V, Tociu L, Case DA, Seefeldt LC, Raugei S, and Hoffman BM

Subjects

Electron Spin Resonance Spectroscopy, Nitrogenase metabolism, Protein Conformation, Density Functional Theory, Nitrogenase chemistry

Abstract

We have shown that the key state in N 2 reduction to two NH 3 molecules by the enzyme nitrogenase is E 4 (4H), the "Janus" intermediate, which has accumulated four [e - /H + ] and is poised to undergo reductive elimination of H 2 coupled to N 2 binding and activation. Initial 1 H and 95 Mo ENDOR studies of freeze-trapped E 4 (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 E 4 (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 E 4 (4H) (b) , with one bridging and one terminal hydride, and E 4 (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 E 4 (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 1 H-ENDOR experiments using improved instrumentation, Mims 2 H 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, E 4 (4H) (a) .

Published

2019

47. 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

48. The NifZ accessory protein has an equivalent function in maturation of both nitrogenase MoFe protein P-clusters.

Author

Jimenez-Vicente E, Yang ZY, Martin Del Campo JS, Cash VL, Seefeldt LC, and Dean DR

Subjects

Azotobacter vinelandii genetics, Bacterial Proteins genetics, Molybdoferredoxin genetics, Nitrogenase genetics, Azotobacter vinelandii metabolism, Bacterial Proteins metabolism, Molybdoferredoxin metabolism, Nitrogenase metabolism

Abstract

The Mo-dependent nitrogenase comprises two interacting components called the Fe protein and the MoFe protein. The MoFe protein is an α 2 β 2 heterotetramer that harbors two types of complex metalloclusters, both of which are necessary for N 2 reduction. One type is a 7Fe-9S-Mo-C-homocitrate species designated FeMo-cofactor, which provides the N 2 -binding catalytic site, and the other is an 8Fe-7S species designated the P-cluster, involved in mediating intercomponent electron transfer to FeMo-cofactor. The MoFe protein's catalytic partner, Fe protein, is also required for both FeMo-cofactor formation and the conversion of an immature form of P-clusters to the mature species. This latter process involves several assembly factors, NafH, NifW, and NifZ, and precedes FeMo-cofactor insertion. Here, using various protein affinity-based purification methods as well as in vivo , EPR spectroscopy, and MALDI measurements, we show that several MoFe protein species accumulate in a NifZ-deficient background of the nitrogen-fixing microbe Azotobacter vinelandii These included fully active MoFe protein replete with FeMo-cofactor and mature P-cluster, inactive MoFe protein having no FeMo-cofactor and only immature P-cluster, and partially active MoFe protein having one αβ-unit with a FeMo-cofactor and mature P-cluster and the other αβ-unit with no FeMo-cofactor and immature P-cluster. Also, NifW could associate with MoFe protein having immature P-clusters and became dissociated upon P-cluster maturation. Furthermore, both P-clusters could mature in vitro without NifZ. These findings indicate that NifZ has an equivalent, although not essential, function in the maturation of both P-clusters contained within the MoFe protein., Competing Interests: The authors declare that they have no conflicts of interest with the contents of this article., (© 2019 Jimenez-Vicente et al.)

Published

2019

49. The ammonium transporter AmtB and the PII signal transduction protein GlnZ are required to inhibit DraG in Azospirillum brasilense.

Author

Moure VR, Siöberg CLB, Valdameri G, Nji E, Oliveira MAS, Gerdhardt ECM, Pedrosa FO, Mitchell DA, Seefeldt LC, Huergo LF, Högbom M, Nordlund S, and Souza EM

Subjects

ADP Ribose Transferases genetics, Azospirillum brasilense genetics, Azospirillum brasilense growth & development, Bacterial Proteins chemistry, Bacterial Proteins genetics, Cation Transport Proteins genetics, Gene Expression Regulation, Bacterial, N-Glycosyl Hydrolases chemistry, N-Glycosyl Hydrolases genetics, PII Nitrogen Regulatory Proteins genetics, Protein Binding, Protein Conformation, Signal Transduction, ADP Ribose Transferases metabolism, Ammonium Compounds metabolism, Azospirillum brasilense metabolism, Bacterial Proteins metabolism, Cation Transport Proteins metabolism, N-Glycosyl Hydrolases metabolism, PII Nitrogen Regulatory Proteins metabolism

Abstract

The ammonium-dependent posttranslational regulation of nitrogenase activity in Azospirillum brasilense requires dinitrogenase reductase ADP-ribosyl transferase (DraT) and dinitrogenase reductase ADP-glycohydrolase (DraG). These enzymes are reciprocally regulated by interaction with the PII proteins, GlnB and GlnZ. In this study, purified ADP-ribosylated Fe-protein was used as substrate to study the mechanism involved in the regulation of A. brasilense DraG in vitro. The data show that DraG is partially inhibited by GlnZ and that DraG inhibition is further enhanced by the simultaneous presence of GlnZ and AmtB. These results are the first to demonstrate experimentally that DraG inactivation requires the formation of a ternary DraG-GlnZ-AmtB complex in vitro. Previous structural data have revealed that when the DraG-GlnZ complex associates with AmtB, the flexible T-loops of the trimeric GlnZ bind to AmtB and become rigid; these molecular events stabilize the DraG-GlnZ complex, resulting in DraG inactivation. To determine whether restraining the flexibility of the GlnZ T-loops is a limiting factor in DraG inhibition, we used a GlnZ variant that carries a partial deletion of the T-loop (GlnZΔ42-54). However, although the GlnZΔ42-54 variant was more effective in inhibiting DraG in vitro, it bound to DraG with a slightly lower affinity than does wild-type GlnZ and was not competent to completely inhibit DraG activity either in vitro or in vivo. We, therefore, conclude that the formation of a ternary complex between DraG-GlnZ-AmtB is necessary for the inactivation of DraG., (© 2019 Federation of European Biochemical Societies.)

Published

2019

50. Control of electron transfer in nitrogenase.

Author

Seefeldt LC, Peters JW, Beratan DN, Bothner B, Minteer SD, Raugei S, and Hoffman BM

Subjects

Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Bacteria enzymology, Electron Transport, Hydrolysis, Models, Biological, Models, Chemical, Nitrogen chemistry, Nitrogen metabolism, Oxidation-Reduction, Nitrogenase chemistry, Nitrogenase metabolism

Abstract

The bacterial enzyme nitrogenase achieves the reduction of dinitrogen (N 2 ) to ammonia (NH 3 ) utilizing electrons, protons, and energy from the hydrolysis of ATP. Building on earlier foundational knowledge, recent studies provide molecular-level details on how the energy of ATP hydrolysis is utilized, the sequencing of multiple electron transfer events, and the nature of energy transduction across this large protein complex. Here, we review the state of knowledge about energy transduction in nitrogenase., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018