Redox-Dependent Structural Changes in the Nitrogenase P-Cluster ,

et al. 2006

163

FeMo cofactor (FeMoco) biosynthesis is one of the most complicated processes in metalloprotein biochemistry. Here we show that Mo and homocitrate are incorporated into the Fe͞S core of the FeMoco precursor while it is bound to NifEN and that the resulting fully complemented, FeMoco-like cluster is transformed into a mature FeMoco upon transfer from NifEN to MoFe protein through direct protein-protein interaction. Our findings not only clarify the process of FeMoco maturation, but also provide useful insights into the other facets of nitrogenase chemistry. (9), which is located at the ␣␤-interface and ligated to six protein residues; and the [Mo-7Fe-9S-X-homocitrate] (the identity of X is unknown but is considered to be C, O, or N; ref. 10) FeMo cofactor (FeMoco), which is situated within the ␣-subunit and bound to only two protein residues and an exogenous homocitrate ligand. Both P-cluster and FeMoco are composed of smaller substructures: the P-cluster comprises two subclusters that share a 6 -sulfide (9) and FeMoco consists of [Mo-3Fe-3S] and [4Fe-3S] subcubanes that are bridged by three 2 -sulfides and share a central 6 -light atom (10). These metal clusters are essential for nitrogenase reaction, a process that involves ATP-dependent electron transfer from the [4Fe-

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confidence: 99%

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confidence: 99%

FeMo cofactor maturation on NifEN

Corbett

et al. 2006

163

“…The homodimeric Fe protein has one ATP binding site per subunit and a single [4Fe-4S] cluster bridged in between the subunits, whereas the ␣ 2 ␤ 2 -tetrameric MoFe protein (Fig. 1A) contains two unique clusters per ␣␤-subunit pair: the [8Fe-7S] P-cluster (6), which is located at the ␣␤-subunit interface, and the [Mo-7Fe-9S-X-homocitrate] † iron-molybdenum cofactor (FeMoco) (7), which is positioned within the ␣-subunit. Nitrogenase catalysis involves a series of complex formation and dissociation between the Fe protein and the MoFe protein, during which process the electrons are sequentially transferred from the [4Fe-4S] cluster of the Fe protein, through the P-cluster, to the FeMoco within the MoFe protein, where substrate reduction eventually occurs.…”

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confidence: 99%

“…Catalytically, it serves as a ''hub'' that mediates the shuffling of electrons between the metal centers of the Fe protein and the MoFe protein. Structurally, it represents a high-nuclearity, Fe/ S-only cluster that can be viewed as two [4Fe-4S] subclusters sharing a 6 -sulfide. Such a ''modular'' composition suggests that the P-cluster is formed through the fusion of its substructural units, a reaction mechanism that is well established in synthetic inorganic chemistry (8) and further supported by recent advances toward successful synthesis of P-cluster topologs (9)(10)(11)(12).…”

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confidence: 99%

P-cluster maturation on nitrogenase MoFe protein

Lee

et al. 2007

Biosynthesis of nitrogenase P-cluster has attracted considerable attention because it is biologically important and chemically unprecedented. Previous studies suggest that P-cluster is formed from a precursor consisting of paired [4Fe-4S]-like clusters and that P-cluster is assembled stepwise on MoFe protein, i.e., one cluster is assembled before the other. Here, we specifically tackle the assembly of the second P-cluster by combined biochemical and spectroscopic approaches. By using a P-cluster maturation assay that is based on purified components, we show that the maturation of the second P-cluster requires the concerted action of NifZ, Fe protein, and MgATP and that the action of NifZ is required before that of Fe protein/MgATP, suggesting that NifZ may act as a chaperone that facilitates the subsequent action of Fe protein/ MgATP. Furthermore, we provide spectroscopic evidence that the [4Fe-4S] cluster-like fragments can be converted to P-clusters, thereby firmly establishing the physiological relevance of the previously identified P-cluster precursor. (Fig. 1A) contains two unique clusters per ␣␤-subunit pair: the [8Fe-7S] P-cluster (6), which is located at the ␣␤-subunit interface, and the [Mo-7Fe-9S-X-homocitrate] † iron-molybdenum cofactor (FeMoco) (7), which is positioned within the ␣-subunit. Nitrogenase catalysis involves a series of complex formation and dissociation between the Fe protein and the MoFe protein, during which process the electrons are sequentially transferred from the [4Fe-4S] cluster of the Fe protein, through the P-cluster, to the FeMoco within the MoFe protein, where substrate reduction eventually occurs. The complexity of nitrogenase reaction mechanism is undoubtedly associated with the presence of complex metalloclusters in the enzyme, namely, the P-cluster and FeMoco, the structure and function of which have served as one of the central topics in nitrogenase research for decades.The P-cluster holds a unique place in nitrogenase chemistry. Catalytically, it serves as a ''hub'' that mediates the shuffling of electrons between the metal centers of the Fe protein and the MoFe protein. Structurally, it represents a high-nuclearity, Fe/ S-only cluster that can be viewed as two [4Fe-4S] subclusters sharing a 6 -sulfide. Such a ''modular'' composition suggests that the P-cluster is formed through the fusion of its substructural units, a reaction mechanism that is well established in synthetic inorganic chemistry (8) and further supported by recent advances toward successful synthesis of P-cluster topologs (9-12). Biological evidence of such a fusion mechanism came from studies of three FeMoco-deficient forms of A. vinelandii MoFe protein (Fig. 1B) that allowed analysis of P-cluster species without the interference of FeMoco. One of these MoFe proteins, designated Av1 ⌬nifH (Fig. 1B, I), was obtained by deleting nifH, the gene encoding the subunit of Fe protein (13-16), whereas another of them, designated Av1 ⌬nifB (Fig. 1B, III), was obtained by deleting nifB, the gene specifically invo...

“…f Although encoded by different structural genes, all three nitrogenases are comprised of two essential component metalloproteins, component 1 (MoFe, VFe, or FeFe protein) and component 2 (Fe protein). g The homodimeric Fe protein of the Mo-nitrogenase has one [4Fe-4S] cluster bridged between the two subunits, whereas the ␣ 2 ␤ 2 -tetrameric MoFe protein contains two unique metal clusters per ␣␤-subunit: the [8Fe-7S] P-cluster (14), which is located at the ␣␤-interface, and the [Mo-7Fe-9S-X-homocitrate] h FeMo cofactor (FeMoco), which is situated within the ␣-subunit. ATP-dependent electron transfer is believed to proceed from the [4Fe-4S] cluster of the Fe protein to the P-cluster of the MoFe protein and finally to FeMoco where substrate reduction takes place.…”

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confidence: 99%

Nitrogenase reactivity with P-cluster variants

Corbett

et al. 2005

Nitrogenase is a multicomponent metalloenzyme that catalyzes the conversion of atmospheric dinitrogen to ammonia. For decades, it has been generally believed that the [8Fe-7S] P-cluster of nitrogenase component 1 is indispensable for nitrogenase activity. In this study, we identified two catalytically active P-cluster variants by activity assays, metal analysis, and EPR spectroscopic studies. Further, we showed that both P-cluster variants resemble [4Fe-4S]-like centers based on x-ray absorption spectroscopic experiments. We believe that our findings challenge the dogma that the standard P-cluster is the only cluster species capable of supporting substrate reduction at the FeMo cofactor and provide important insights into the general mechanism of nitrogenase catalysis and assembly.MoFe protein ͉ VFe protein N itrogenase catalyzes one of the most remarkable chemical transformations in biological systems, the reduction of atmospheric dinitrogen to a bioavailable form, ammonia. Three classes of nitrogenase systems, namely, the Mo-, V-, and Fe-only nitrogenases, have been identified (for recent reviews see refs. 1-11). f Although encoded by different structural genes, all three nitrogenases are comprised of two essential component metalloproteins, component 1 (MoFe, VFe, or FeFe protein) and component 2 (Fe protein). g The homodimeric Fe protein of the Mo-nitrogenase has one [4Fe-4S] cluster bridged between the two subunits, whereas the ␣ 2 ␤ 2 -tetrameric MoFe protein contains two unique metal clusters per ␣␤-subunit: the [8Fe-7S] P-cluster (14), which is located at the ␣␤-interface, and the [Mo-7Fe-9S-X-homocitrate] h FeMo cofactor (FeMoco), which is situated within the ␣-subunit. ATP-dependent electron transfer is believed to proceed from the [4Fe-4S] cluster of the Fe protein to the P-cluster of the MoFe protein and finally to FeMoco where substrate reduction takes place. The Fe protein of the V-nitrogenase shares a high degree of homology with the Fe protein of the Mo-nitrogenase and, apart from the presence of an additional ␥-subunit, the VFe protein is also believed to be highly homologous to the MoFe protein with respect not only to the structural genes encoding the ␣-and ␤-subunits, but also to the redox centers contained within the protein, designated the P-cluster and the FeV cofactor (FeVco), respectively, in this case (4, 10, 16). The structurally homologous heterometal centers, i.e., FeMoco and FeVco, are also categorically termed cofactors.It is generally believed that the structural integrity of the P-cluster is indispensable for nitrogenase reactivity. However, the exact mechanism by which the P-cluster carries out its function in substrate reduction and, in particular, the oxidation states and structural conformations of the P-cluster involved in this process, remain largely a puzzle (17). Two types of cofactordeficient MoFe or VFe protein variants, generated by nifH or nifB deletion, i respectively, have been used to study the features of P-clusters without the interference of the cofactor centers...