Reduction of N by nitrogenases occurs at an organometallic iron cofactor that commonly also contains either molybdenum or vanadium. The well-characterized resting state of the cofactor does not bind substrate, so its mode of action remains enigmatic. Carbon monoxide was recently found to replace a bridging sulfide, but the mechanistic relevance was unclear. Here we report the structural analysis of vanadium nitrogenase with a bound intermediate, interpreted as a μ-bridging, protonated nitrogen that implies the site and mode of substrate binding to the cofactor. Binding results in a flip of amino acid glutamine 176, which hydrogen-bonds the ligand and creates a holding position for the displaced sulfide. The intermediate likely represents state E or E of the Thorneley-Lowe model and provides clues to the remainder of the catalytic cycle.
Three genetically distinct, but structurally similar, isozymes of nitrogenase catalyze biological N2 reduction to 2NH3: Mo-, V-, and Fe-nitrogenase, named respectively for the metal (M) in their active site metallocofactors (metal-ion composition, MFe7). Studies of the Mo-enzyme have revealed key aspects of its mechanism for N2 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 E4(4H) (“Janus”) state. N2 binding/reduction in this state is coupled to reductive elimination (re) of the two hydrides as H2, 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 N2/D2. Kinetic analysis revealed that Mo- and Fe-nitrogenases show similar rate constants for hydrogenase-like H2 formation by hydride protonolysis (k HP) but significant differences in the rate constant for H2 re with N2 binding/reduction (k re ). We now report that V-nitrogenase also exhibits HD formation during N2/D2 turnover (and H2 inhibition of N2 reduction), thereby establishing the re/oa equilibrium as a universal mechanism for N2 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 H2 production by the hydrogenase-like side reaction but directly arise from the differences in the rate constant (k re ) for the re of H2 coupled to N2 binding/reduction, which decreases in the order Mo > V > Fe.
The reaction catalyzed by the nitrogenase enzyme involves breaking the stable triple bond of the dinitrogen molecule and is consequently considered among the most challenging reactions in biology. While many aspects regarding its atomic mechanism remain to be elucidated, a kinetic scheme established by David Lowe and Roger Thorneley has remained a gold standard for functional studies of the enzyme for more than 30 years. Recent three-dimensional structures of ligand-bound states of molybdenum- and vanadium-dependent nitrogenases have revealed the actual site of substrate binding on the large active site cofactors of this class of enzymes. The binding mode of an inhibitor and a reaction intermediate further substantiate a hypothesis by Seefeldt, Hoffman, and Dean that the activation of N is made possible by a reductive elimination of H that leaves the cofactor in a super-reduced state that can bind and reduce the inert N molecule. Here we discuss the immediate implications of the structurally observed mode of binding of small molecules to the enzyme with respect to the early stages of the Thorneley-Lowe mechanism of nitrogenase. Four consecutive single-electron reductions give rise to two bridging hydrides at the cluster surface that can recombine to eliminate H and enable the reduced cluster to bind its substrate in a bridging mode.
The copper-containing enzyme nitrous oxide reductase (NOR) catalyzes the transformation of nitrous oxide (NO) to dinitrogen (N) in microbial denitrification. Several accessory factors are essential for assembling the two copper sites Cu and Cu, and for maintaining the activity. In particular, the deletion of either the transmembrane iron-sulfur flavoprotein NosR or the periplasmic protein NosX, a member of the ApbE family, abolishes NO respiration. Here we demonstrate through biochemical and structural studies that the ApbE protein from Pseudomonas stutzeri, where the nosX gene is absent, is a monomeric FAD-binding protein that can serve as the flavin donor for NosR maturation via covalent flavinylation of a threonine residue. The flavin transfer reaction proceeds both in vivo and in vitro to generate post-translationally modified NosR with covalently bound FMN. Only FAD can act as substrate and the reaction requires a divalent cation, preferably Mg that was also present in the crystal structure. In addition, the reaction is species-specific to a certain extent.
The alternative, vanadium-dependent nitrogenase is employed by Azotobacter vinelandii for the fixation of atmospheric N under conditions of molybdenum starvation. While overall similar in architecture and functionality to the common Mo-nitrogenase, the V-dependent enzyme exhibits a series of unique features that on one hand are of high interest for biotechnological applications. As its catalytic properties differ from Mo-nitrogenase, it may on the other hand also provide invaluable clues regarding the molecular mechanism of biological nitrogen fixation that remains scarcely understood to date. Earlier studies on vanadium nitrogenase were almost exclusively based on a ΔnifHDK strain of A. vinelandii, later also in a version with a hexahistidine affinity tag on the enzyme. As structural analyses remained unsuccessful with such preparations we have developed protocols to isolate unmodified vanadium nitrogenase from molybdenum-depleted, actively nitrogen-fixing A. vinelandii wild-type cells. The procedure provides pure protein at high yields whose spectroscopic properties strongly resemble data presented earlier. Analytical size-exclusion chromatography shows this preparation to be a VnfDKG heterohexamer.
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