NifH and NifM proteins interact as demonstrated by the yeast two-hybrid system

Biological nitrogen fixation is catalyzed by nitrogenase, a two-component enzyme consisting of the MoFe protein and the Fe protein. Two genes are involved in the formation of active Fe protein: nifH encodes the structural polypeptide, while nifM specifies a stabilizing and activation function by yet unknown mechanisms. Our studies were directed to clarify whether the NifM exerts its function through physical protein-protein interaction with NifH. To accomplish this, we used the yeast two-hybrid system. The simultaneous expression of the GAL4 binding domain-nifH fusion and GAL4 activation domain-nifM fusion resulted in the successful activation of GAL4-responsive HIS3, ADE2, and lacZ reporter genes in the two-hybrid system used. The system was also used to evidence the potential for in vivo NifH and NifM self-association. The results obtained suggest that NifH and NifM form homomers and also associate in between to form higher order complexes, which may be needed to exert the effect of NifM on Fe protein stability and activity.     

Conservation of structure and location of Rhizobium meliloti and Klebsiella pneumoniae nifB genes.

Using transposon Tn5-mediated mutagenesis, an essential Rhizobium meliloti nitrogen fixation (nif) gene was identified and located directly downstream of the regulatory gene nifA. Maxicell and DNA sequence analysis demonstrated that the new gene is transcribed in the same direction as nifA and codes for a 54-kilodalton protein. In Klebsiella pneumoniae, the nifBQ operon is located directly downstream of a gene which is structurally and functionally homologous to the R. meliloti nifA gene. The DNA sequences of the K. pneumoniae nifB and nifQ genes (which code for 51- and 20-kilodalton proteins, respectively) were determined. The DNA sequence of the newly identified R. meliloti gene was approximately 50% homologous to the K. pneumoniae nifB gene. R. meliloti does not contain a gene homologous to nifQ directly downstream of nifB. The R. meliloti nifB product shares approximately 40% amino acid homology with the K. pneumoniae nifB product, and 10 of the 12 cysteine residues of the R. meliloti nifB product are conserved with 10 of the 17 cysteine residues of the K. pneumoniae nifB product.     

Peptidyl-prolyl cis/trans isomerase-independent functional NifH mutant of Azotobacter vinelandii

Peptidyl-prolyl cis/trans isomerases (PPIases) play a pivotal role in catalyzing the correct folding of many prokaryotic and eukaryotic proteins that are implicated in a variety of biological functions, ranging from cell cycle regulation to bacterial infection. The nif accessory protein NifM, which is essential for the biogenesis of a functional NifH component of nitrogenase, is a PPIase. To understand the nature of the molecular signature that defines the NifM dependence of NifH, we screened a library of nifH mutants in the nitrogen-fixing bacterium Azotobacter vinelandii for mutants that acquired NifM independence. Here, we report that NifH can acquire NifM independence when the conserved Pro258 located in the C-terminal region of NifH, which wraps around the other subunit in the NifH dimer, is replaced by serine.     

Rhizobium meliloti nifN (fixF) gene is part of an operon regulated by a nifA-dependent promoter and codes for a polypeptide homologous to the nifK gene product.

An essential gene for symbiotic nitrogen fixation (fixF) is located near the common nodulation region of Rhizobium meliloti. A DNA fragment carrying fixF was characterized by hybridization with Klebsiella pneumoniae nif DNA and by nucleotide sequence analysis. The fixF gene was found to be related to K. pneumoniae nifN and was therefore renamed as the R. meliloti nifN gene. Upstream of the nifN coding region a second open reading frame was identified coding for a putative polypeptide of 110 amino acids (ORF110). By fragment-specific Tn5 mutagenesis it was shown that the nifN gene and ORF110 form an operon. The control region of this operon contains a nif promoter and also the putative nifA-binding sequence. For the deduced amino acid sequence of the nifN gene product a striking homology to the R. meliloti nifK protein was found. One cysteine residue and its adjacent amino acid sequence, which are highly conserved in the R. meliloti nifK, R. meliloti nifN, and K. pneumoniae nifN proteins, may play a role in binding the FeMo cofactor.     

Nitrogen fixation specific regulatory genes of Klebsiella pneumoniae and Rhizobium meliloti share homology with the general nitrogen regulatory gene ntrC of K. pneumoniae.

We have determined the complete nucleotide sequences of three functionally related nitrogen assimilation regulatory genes from Klebsiella pneumoniae and Rhizobium meliloti. These genes are: 1) The K. pneumoniae general nitrogen assimilation regulatory gene ntrC (formerly called glnG), 2) the K. pneumoniae nif-specific regulatory gene nifA, and 3) an R. meliloti nif-specific regulatory gene that appears to be functionally analogous to the K. pneumoniae nifA gene. In addition to the DNA sequence data, gel-purified K. pneumoniae nifA protein was used to determine the amino acid composition of the nifA protein. The K. pneumoniae ntrC and nifA genes code for proteins of 52,259 and 53,319 d respectively. The R. meliloti nifA gene codes for a 59,968 d protein. A central region within each polypeptide, consisting of approximately 200 amino acids, is between 52% and 58% conserved among the three proteins. Neither the amino termini nor the carboxy termini show any conserved sequences. Together with data that shows that the three regulatory proteins activate promoters that share a common consensus sequence in the -10 (5'-TTGCA-3') and -23 (5'-CTGG-3') regions, the sequence data presented here suggest a common evolutionary origin for the three regulatory genes.     

The roles of the nifW, nifZ and nifM genes of Klebsiella pneumoniae in nitrogenase biosynthesis

Active Fe protein of nitrogenase was synthesised in a non-nitrogen fixing organism when Escherichia coli was transformed with a plasmid encoding only two nif-specific genes, nifH and nifM of Klebsiella pneumoniae. Hence proteins NifH and NifM are sufficient to produce active Fe protein in E. coli. K. pneumoniae strains carrying chromosomal nifW- and nifZ- mutations were constructed and shown to be significant C2H2-reducing activity and to grow on N-free plates. Nevertheless, derepressing cultures of the mutant strains had reduced levels of MoFe protein activity, and consequently significantly lower levels of nitrogenase activity, than the nif+ parent strain. NifW and NifZ therefore appear to be involved in the formation or accumulation of active MoFe protein, but are not essential for nitrogen fixation in K. pneumoniae under the conditions tested.     

Genes required for formation of the apoMoFe protein of Klebsiella pneumoniae nitrogenase in Escherichia coli

A binary plasmid system was used to produce nitrogenase components in Escherichia coli and subsequently to define a minimum set of nitrogen fixation (nif) genes required for the production of the iron-molybdenum cofactor (FeMoco) reactivatable apomolybdenum-iron (apoMoFe) protein of nitrogenase. The active MoFe protein is an alpha 2 beta 2 tetramer containing two FeMoco clusters and 4 Fe4S4 P centers (for review see, Orme-Johnson, W.H. (1985) Annu. Rev. Biophys. Biophys. Chem. 14, 419-459). The plasmid pVL15, carrying a tac-promoted nifA activator gene, was coharbored in E. coli with the plasmid pGH1 which contained nifHDKTYENXUSVWZMF' derived from the chromosome of the nitrogen fixing bacterium Klebsiella pneumoniae. The apoMoFe protein produced in E. coli by pGH1 + VL15 was identical to the apoprotein in derepressed cells of the nifB- mutant of K. pneumoniae (UN106) in its electrophoretic properties on nondenaturing polyacrylamide gels as well as in its ability to be activated by FeMoco. The constituent peptides migrated identically to those from purified MoFe protein during electrophoresis on denaturing gels. The concentrations of apoMoFe protein produced in nif-transformed strains of E. coli were greater than 50% of the levels of MoFe protein observed in derepressed wild-type K. pneumoniae. Systematic deletion of individual nif genes carried by pGH1 has established the requirements for the maximal production of the FeMoco-reactivatable apoMoFe protein to be the following gene products, NifHDKTYUSWZM+A. It appears that several of the genes (nifT, Y, U, W, and Z) are only required for maximal production of the apoMoFe protein, while others (nifH, D, K, and S) are absolutely required for synthesis of this protein in E. coli. One curious result is that the nifH gene product, the peptide of the Fe protein, but not active Fe protein itself, is required for formation of the apoMoFe protein. This suggests the possibility of a ternary complex of the NifH, D, and K peptides as the substrate for the processing to form the apoMoFe protein. We also find that nifM, the gene which processes the nifH protein into Fe protein (Howard, K.S., McLean, P.A., Hansen, F. B., Lemley, P.V., Kobla, K.S. & Orme-Johnson, W.H. (1986) J. Biol. Chem. 261, 772-778) can, under certain circumstances, partially replace other processing genes (i.e. nifTYU and/or WZ) although it is not essential for apoMoFe protein formation. It also appears that nifS and nifU, reported to play a role in Fe protein production in Azotobacter vinelandii, play no such role in K. pneumoniae, although these genes are involved in apoMoFe formation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Use of synthetic biology tools to optimize the production of active nitrogenase Fe protein in chloroplasts of tobacco leaf cells

The generation of nitrogen fixing crops is considered a challenge that could lead to a new agricultural ‘green’ revolution. Here, we report the use of synthetic biology tools to achieve and optimize the production of active nitrogenase Fe protein (NifH) in the chloroplasts of tobacco plants. Azotobacter vinelandii nitrogen fixation genes, nifH, M, U and S, were re‐designed for protein accumulation in tobacco cells. Targeting to the chloroplast was optimized by screening and identifying minimal length transit peptides performing properly for each specific Nif protein. Putative peptidyl‐prolyl cis‐trans isomerase NifM proved necessary for NifH solubility in the stroma. Purified NifU, a protein involved in the biogenesis of NifH [4Fe‐4S] cluster, was found functional in NifH reconstitution assays. Importantly, NifH purified from tobacco chloroplasts was active in the reduction of acetylene to ethylene, with the requirement of nifU and nifS co‐expression. These results support the suitability of chloroplasts to host functional nitrogenase proteins, paving the way for future studies in the engineering of nitrogen fixation in higher plant plastids and describing an optimization pipeline that could also be used in other organisms and in the engineering of new metabolic pathways in plastids.     

Rhizobium meliloti ntrA (rpoN) gene is required for diverse metabolic functions.

We report the identification and cloning of an ntrA-like (glnF rpoN) gene of Rhizobium meliloti and show that the R. meliloti ntrA product (NtrA) is required for C4-dicarboxylate transport as well as for nitrate assimilation and symbiotic nitrogen fixation. DNA sequence analysis showed that R. meliloti NtrA is 38% homologous with Klebsiella pneumoniae NtrA. Subcloning and complementation analysis suggested that the R. meliloti ntrA promoter lies within 125 base pairs of the initiation codon and may be constitutively expressed.     

Expression of nitrogen fixation genes in foreign hosts. Assembly of nitrogenase Fe protein in Escherichia coli and in yeast

In Klebsiella pneumoniae, the nifH gene encodes the Fe protein (Kp2) polypeptide that is assembled into a homodimer responsible for the reduction of nitrogenase. Escherichia coli or the yeast Saccharomyces cerevisiae, transformed with the K. pneumoniae nifH gene in suitable expression vectors, synthesize the Fe protein polypeptide. This study examines the assembly of the nifH gene product into its characteristic dimeric structure in E. coli and in yeast. Immunoblotting methods, as well as 55Fe2- labeling of K. pneumoniae were employed to detect native nitrogenase components in cell lysates. E. coli and yeast transformants contained a protein similar to native Kp2 in its immunoreactivity, apparent molecular weight, and lability in the presence of oxygen or MgATP. While in E. coli the co-introduction of nifH and nifM resulted in enhanced levels of the nifH product, it appears that the nifH gene product alone is sufficient for the assembly of an Fe protein-like structure in foreign prokaryotic and eukaryotic hosts.     

Heterologous hybridization of Frankia DNA to Rhizobium meliloti and Klebsiella pneumoniae nif genes

A nif gene probe from Rhizobium meliloti was used to isolate a recombinant bacteriophage from a Frankia sp. ArI3 gene bank. There is a large homology between nif D and nif H genes of R. meliloti or Klebsiella pneumoniae and Frankia DNA sequences. Approximately 4.5 kb to the right of nif K, we have localized a DNA region hybridizing to a R. meliloti probe containing nif A and nif B genes. The extent of the homology was greater for nif B than for nif A.     

Functional divergence outlines the evolution of novel protein function in NifH/BchL protein family

Biological nitrogen fixation is accomplished by prokaryotes through the catalytic action of complex metalloenzyme, nitrogenase. Nitrogenase is a two-protein component system comprising MoFe protein (NifD&K) and Fe protein (NifH). NifH shares structural and mechanistic similarities as well as evolutionary relationships with light-independent protochlorophyllide reductase (BchL), a photosynthesis-related metalloenzyme belonging to the same protein family. We performed a comprehensive bioinformatics analysis of the NifH/BchL family in order to elucidate the intrinsic functional diversity and the underlying evolutionary mechanism among the members. To analyse functional divergence in the NifH/BchL family, we have conducted pair-wise estimation in altered evolutionary rates between the member proteins. We identified a number of vital amino acid sites which contribute to predicted functional diversity. We have also made use of the maximum likelihood tests for detection of positive selection at the amino acid level followed by the structure-based phylogenetic approach to draw conclusion on the ancient lineage and novel characterization of the NifH/BchL protein family. Our investigation provides ample support to the fact that NifH protein and BchL share robust structural similarities and have probably deviated from a common ancestor followed by divergence in functional properties possibly due to gene duplication     

In vitro biosynthesis of iron-molybdenum cofactor and maturation of the nif-encoded apodinitrogenase. Effect of substitution for NifH with site-specifically altered forms of NifH.

NifH has three different roles in the nitrogenase enzyme system. Apart from serving as the physiological electron donor to dinitrogenase, NifH is involved in iron-molybdenum cofactor (FeMo-co) biosynthesis and in maturation of the FeMo-co-deficient form of apodinitrogenase to a FeMo-co-activable form (apodinitrogenase maturation). The exact roles of NifH in these processes are not well understood. In the present study, the features of NifH required for the aforementioned processes have been investigated by the use of site-specifically altered forms of the enzyme. The ability of six altered forms of NifH inactive in substrate reduction (K15R, D39N, D43N, L127Delta, D129E, and F135Y) to function in in vitro FeMo-co synthesis and apodinitrogenase maturation reactions was investigated. We report that the ability of NifH to bind and not hydrolyze MgATP is required for it to function in these processes. We also present evidence that the ability of NifH to function in these processes is not dictated by the properties known to be required for its function in electron transfer to dinitrogenase. Evidence toward the existence of separate, overlapping sites on NifH for each of its functions (substrate reduction, FeMo-co biosynthesis, and apodinitrogenase maturation) is presented.