Energy Transduction in Nitrogenase

Energy Transduction in Nitrogenase

Conspectus Nitrogenase is a complicated two-component enzyme system that uses ATP binding and hydrolysis energy to achieve one of the most difficult chemical reactions in nature, the reduction of N2 to NH3. One component of the Mo-based nitrogenase system, Fe protein, delivers electrons one at a tim...

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Veröffentlicht in:Accounts of chemical research 2018-09, Vol.51 (9), p.2179-2186
Hauptverfasser: Seefeldt, Lance C, Hoffman, Brian M, Peters, John W, Raugei, Simone, Beratan, David N, Antony, Edwin, Dean, Dennis R
Format: Artikel
Sprache:eng
Schlagworte:
Adenosine Triphosphate - chemistry
Catalysis
Charge transfer
Electron transfer
Electrons
Hydrolysis
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Iron - chemistry
Kinetic parameters
Kinetics
Metal organic frameworks
Molybdoferredoxin - chemistry
Nitrogenase
Nitrogenase - chemistry
Oxidation-Reduction
Peptides and proteins
Protein Conformation
Thermodynamics
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Beschreibung
Zusammenfassung:Conspectus Nitrogenase is a complicated two-component enzyme system that uses ATP binding and hydrolysis energy to achieve one of the most difficult chemical reactions in nature, the reduction of N2 to NH3. One component of the Mo-based nitrogenase system, Fe protein, delivers electrons one at a time to the second component, the catalytic MoFe protein. This process occurs through a series of synchronized events collectively called the “Fe protein cycle”. Elucidating details of the events associated with this cycle has constituted an important challenge in understanding the nitrogenase mechanism. Electron delivery is a multistep process involving three metal clusters with intra- and interprotein events. It is proposed that the first electron transfer event is a gated intraprotein transfer of one electron from the MoFe protein P-cluster to the FeMo cofactor. Measurement of the effect of osmotic pressure on the rate of this electron transfer process revealed that it is gated by protein conformational changes. This first electron transfer is activated by binding of the Fe protein containing two bound ATP molecules. The mechanism of how this protein–protein association triggers electron transfer remains unknown. The second electron transfer event is proposed to be a rapid interprotein “backfill” with transfer of one electron from the reduced Fe protein 4Fe–4S cluster to the oxidized P-cluster. In this way, electron delivery can be viewed as a case of “deficit spending”. Such a deficit-spending electron transfer process can be envisioned as a way to achieve one-direction electron flow, limiting the potential for back electron flow. Hydrolysis of two ATP molecules associated with the Fe protein occurs after the electron transfer and therefore is not used to directly drive the electron transfer. Rather, ATP hydrolysis is proposed to contribute to relaxation of the “activated” conformational state associated with the ATP form of the complex, with the free energy from ATP hydrolysis being used to pay back energy associated with component protein association and electron transfer. Release of inorganic phosphate (Pi) and protein–protein dissociation follow electron transfer and ATP hydrolysis. The rate-limiting step for the Fe protein cycle is not dissociation of the two proteins, as previously believed, but rather is release of Pi after ATP hydrolysis, which is then followed by rapid protein–protein complex dissociation. Nitrogenase is composed of two catalytic halve
ISSN:0001-4842
1520-4898
DOI:10.1021/acs.accounts.8b00112