Mechanisms of gating nucleotide-driven electron transfer in nitrogenase
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Date
2020
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Montana State University - Bozeman, College of Letters & Science
Abstract
The Mo-nitrogenase from Azotobacter vinelandii reduces N 2 to ammonia in an ATP-dependent process. It has two-components, the MoFe protein (MoFe) with the active site for N 2 reduction, and the Fe protein (FeP) that delivers electrons to MoFe. The less efficient alternative nitrogenases (Fe- and V-nitrogenases) have FeFe and VFe proteins with an additional subunit, termed gamma, whose role is unknown. Electron delivery to MoFe occurs through the Fe protein cycle (FeP cycle). This involves association between the FeP(MgATP 2) and MoFe, followed by electron transfer, ATP hydrolysis, release of P i, and dissociation of the FeP(MgADP 2) from MoFe. A study of the Fe protein cycle with the physiological electron donor flavodoxin (Fld), changed the rate-limiting step for nitrogenase catalysis, highlighting the important role of physiological protein donors in nitrogenase catalysis. However, it is unknown if Fld interacts with the MgADP or MgATP-bound state of the FeP. Insights from ClusPro 2.0 in silico docking models, time-resolved limited proteolysis and chemical cross-linking coupled with LC-MS and MALDI-TOF MS analysis show that the FeP(MgADP 2) forms a more productive complex with Fld, reducing competition between Fld and MoFe for the FeP(MgATP 2) to drive catalysis. To confirm our model, MicroScale Thermophoresis (MST) was developed to measure binding affinity between the FeP and nucleotides which agreed with previous measurements from isothermal calorimetry, confirming its application for nitrogenase. In silico docking models with ClusPro 2.0 and HADDOCK 2.2 identified structural differences between the Mo-nitrogenase and the alternative V- and Fe-nitrogenases that allow discrimination of protein-protein interactions that enable complex formation. The gamma subunit of the V- and Fe-nitrogenases mediates interactions between the nitrogenases, preventing competition between the least efficient Fe-nitrogenase and the Mo-nitrogenase. Finally, a pipeline was developed for homology modeling of potential physiological donor ferredoxin proteins (VnfF, FdxN, FixFd) associated with expression of the Mo-, V- or Fe-nitrogenases. Insights from in silico docking and assessment with the PRODIGY server were used to identify structural features that differentiate how these ferredoxins interact with the FePs of the three nitrogenases. Ultimately, nucleotide-dependent control of protein-protein interactions is necessary to support N 2 reduction and funnel electrons to the most efficient Mo-nitrogenase.