To engineer Mo-dependent nitrogenase function in plants, expression of the structural proteins NifD and NifK will be an absolute requirement. Although mitochondria have been established as a suitable eukaryotic environment for biosynthesis of oxygen-sensitive enzymes such as NifH, expression of NifD in this organelle has proven difficult due to cryptic NifD degradation. Here, we describe a solution to this problem. Using molecular and proteomic methods, we found NifD degradation to be a consequence of mitochondrial endoprotease activity at a specific motif within NifD. Focusing on this functionally sensitive region, we designed NifD variants comprising between one and three amino acid substitutions and distinguished several that were resistant to degradation when expressed in both plant and yeast mitochondria. Nitrogenase activity assays of these resistant variants in Escherichia coli identified a subset that retained function, including a single amino acid variant (Y100Q). We found that other naturally occurring NifD proteins containing alternate amino acids at the Y100 position were also less susceptible to degradation. The Y100Q variant also enabled expression of a NifD(Y100Q)–linker–NifK translational polyprotein in plant mitochondria, confirmed by identification of the polyprotein in the soluble fraction of plant extracts. The NifD(Y100Q)–linker–NifK retained function in bacterial nitrogenase assays, demonstrating that this polyprotein permits expression of NifD and NifK in a defined stoichiometry supportive of activity. Our results exemplify how protein design can overcome impediments encountered when expressing synthetic proteins in novel environments. Specifically, these findings outline our progress toward the assembly of the catalytic unit of nitrogenase within mitochondria.
There is a growing interest in using ammonia as a liquid carrier of hydrogen for energy applications. Currently, ammonia is produced industrially by the Haber-Bosch process, which requires high temperature and high pressure. In contrast, bacteria have naturally evolved an enzyme known as nitrogenase, that is capable of producing ammonia and hydrogen at ambient temperature and pressure. Therefore, nitrogenases are attractive as a potentially more efficient means to produce ammonia via harnessing the unique properties of this enzyme. In recent years, exciting progress has been made in bioelectrocatalysis using nitrogenases to produce ammonia. Here, the prospects for developing biological ammonia production are outlined, key advances in bioelectrocatalysis by nitrogenases are highlighted, and possible solutions to the obstacles faced in realising this goal are discussed.
Acetyl-CoA synthase (ACS) catalyzes the reversible condensation of CO, CoA, and a methyl-cation to form acetyl-CoA at a unique Ni,Ni-[4Fe4S] cluster (the A-cluster). However, it was unknown which proteins support the assembly of the A-cluster. We analyzed the product of a gene from the cluster containing the ACS gene, cooC2 from Carboxydothermus hydrogenoformans, named AcsF Ch , and showed that it acts as a maturation factor of ACS. AcsF Ch and inactive ACS form a stable 2:1 complex that binds two nickel ions with higher affinity than the individual components. The nickel-bound ACS-AcsF Ch complex remains inactive until MgATP is added, thereby converting inactive to active ACS. AcsF Ch is a MinD-type ATPase and belongs to the CooC protein family, which can be divided into homologous subgroups. We propose that proteins of one subgroup are responsible for assembling the Ni,Ni-[4Fe4S] cluster of ACS, whereas proteins of a second subgroup mature the [Ni4Fe4S] cluster of carbon monoxide dehydrogenases.The cellular maturation of metalloenzymes, previously considered a spontaneous process in vivo, typically depends on a machinery of uptake, storage, processing, and delivery factors (1). How metalloenzymes mature has been investigated for some systems, revealing surprisingly complex maturation pathways (2-8). Enzymes containing nickel, although still relatively small in number, play critical roles in archaea, bacteria, and eukarya, through which they impact the global hydrogen (Ni,Fe-hydrogenase), nitrogen (urease), and carbon (acetylCoA synthase, carbon monoxide dehydrogenase, and methylCoM reductase) cycles (9). For most of these enzymes, we now have a good understanding of how nickel is incorporated into the active site (8, 10).The nickel-enzymes acetyl-CoA synthase (ACS) 2 and carbon monoxide dehydrogenase (CODH) are found in a variety of anaerobic microbes, including bacterial sulfate reducers, acetogens, and hydrogenogens, as well as archaeal methanogens and sulfate reducers, where they act as the prime CO 2 and CO converter (11)(12)(13)(14). ACS and CODH can be found as independent monofunctional enzymes in Carboxydothermus hydrogenoformans (15) but are typically found in other microorganisms as protein complexes: in acetogens ACS and CODH form a bifunctional (␣) 2 complex, whereas in methanogens they are part of a large (␣␥␦⑀) 8 multienzyme complex (11,13,15,16). CODHs catalyze the reversible reduction of CO 2 to CO at the C-cluster, in which a single nickel ion, embedded within a 3Fe-4S scaffold with an additional iron in exo, binds and activates CO and CO 2 for turnover (17)(18)(19). ACS catalyzes the reversible condensation of CO, CoA, and a methyl-cation donated by the methylated corrinoid iron-sulfur protein to form acetyl-CoA (13). ACS depends on a Ni,Ni-[4Fe4S] cluster (also called A-cluster) for activity, in which the two nickel ions have distinct coordinations: the nickel ion distal to the [4Fe4S] cluster (Ni d ) is coordinated by two amide nitrogen atoms and two cysteine thiolates within a Cys-X-Cys ...
Bacteria integrate CO2 reduction and acetyl coenzyme-A (CoA) synthesis in the Wood-Ljungdal pathway. The acetyl-CoA synthase (ACS) active site is a [4Fe4S]-[NiNi] complex (A-cluster). The dinickel site structure (with proximal, p, and distal, d, ions) was studied by X-ray absorption spectroscopy in ACS variants comprising all three protein domains or only the C-terminal domain with the A-cluster. Both variants showed two square-planar Ni(II) sites and an OH- bound at Ni(II)p in oxidized enzyme and a H2O at Ni(I)p in reduced enzyme; a Ni(I)p-CO species was induced by CO incubation and a Ni(II)-CH3- species with an additional water ligand by a methyl group donor. These findings render a direct effect of the N-terminal and middle domains on the A-cluster structure unlikely.
To engineer Mo dependent nitrogenase function in plants expression of proteins NifD and NifK will be an absolute requirement. Although mitochondria have been established as a suitable eukaryotic environment for biosynthesis of oxygen-sensitive enzymes such as NifH, expression of NifD in this organelle has proven difficult due to cryptic NifD degradation. Here we describe a solution to this problem. Using molecular and proteomic methods, we found NifD degradation to be a consequence of mitochondrial endoprotease activity at a specific motif within NifD. Focusing on this functionally sensitive region, we designed NifD variants comprising between one and three amino acid substitutions and distinguished several that were resistant to degradation when expressed in both plant and yeast mitochondria. Nitrogenase activity assays of these resistant variants in E. coli identified a subset that retained function, including a single amino acid (Y100Q) variant. The Y100Q variant also enabled expression of a NifD(Y100Q)-linker-NifK translational polyprotein in plant mitochondria, confirmed by identification of the polyprotein in the soluble fraction of plant extracts. The NifD(Y100Q)-linker-NifK retained function in E. coli based nitrogenase assays, demonstrating this polyprotein permits expression of NifD and NifK in a defined stoichiometry supportive of activity. Our results exemplify how protein design can overcome impediments encountered when expressing synthetic proteins in novel environments. Specifically, these findings outline our progress toward the assembly of the catalytic unit of nitrogenase within mitochondria.
Industrial nitrogen fertilizer is intrinsic to modern agriculture yet expensive and environmentally harmful. We aim to reconstitute bacterial nitrogenase function within plant mitochondria to reduce nitrogen fertilizer usage. Many nitrogen fixation (Nif) proteins are required for biosynthesis and function of the mature nitrogenase enzyme, and these will need to be correctly processed and soluble within mitochondria as a pre-requisite for function. Here we present our workflow that assessed processing, solubility and relative abundance of 16 Klebsiella oxytoca Nif proteins targeted to the plant mitochondrial matrix using an Arabidopsis mitochondrial targeting peptide (MTP). The functional consequence of the N-terminal modifications required for mitochondrial targeting of Nif proteins was tested using bacterial nitrogenase assays. We found that despite the use of the same constitutive promoter and MTP, MTP::Nif processing and relative abundance in plant leaf varied considerably. Assessment of solubility for all MTP::Nif proteins found NifF, M, N, S, U, W, X, Y and Z were soluble, while NifB, E, H, J, K, Q and V were mostly insoluble. Although most Nif proteins tolerated the N-terminal extension as a consequence of mitochondrial processing, this extension in NifM reduced nitrogenase activity to 10% of controls. Using proteomics, we detected a ∼50-fold increase in the abundance of NifM when it contained the N-terminal MTP extension, which may account for this reduction seen in nitrogenase activity. Based on plant mitochondrial processing and solubility, and retention of function in a bacterial assay, our workflow has identified that NifF, N, S, U, W, Y and Z satisfied all these criteria. Future work can now focus on improving these parameters for the remaining Nif components to assemble a complete set of plant-ready Nif proteins for reconstituting nitrogen fixation in plant mitochondria.
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