Biogenesis of molybdenum cofactors

The History of the Molybdenum Cofactor—A Personal View

The transition element molybdenum (Mo) is an essential micronutrient for plants, animals, and microorganisms, where it forms part of the active center of Mo enzymes. To gain biological activity in the cell, Mo has to be complexed by a pterin scaffold to form the molybdenum cofactor (Moco). Mo enzymes and Moco are found in all kingdoms of life, where they perform vital transformations in the metabolism of nitrogen, sulfur, and carbon compounds. In this review, I recall the history of Moco in a personal view, starting with the genetics of Moco in the 1960s and 1970s, followed by Moco biochemistry and the description of its chemical structure in the 1980s. When I review the elucidation of Moco biosynthesis in the 1990s and the early 2000s, I do it mainly for eukaryotes, as I worked with plants, human cells, and filamentous fungi. Finally, I briefly touch upon human Moco deficiency and whether there is life without Moco.

Molybdopterin biosynthesis pathway contributes to the regulation of SaeRS two-component system by ClpP in Staphylococcus aureus

In Staphylococcus aureus, the SaeRS two-component system is essential for the bacterium’s hemolytic activity and virulence. The Newman strain of S. aureus contains a variant of SaeS sensor kinase, SaeS L18P. Previously, we showed that, in the strain Newman, SaeS L18P is degraded by the membrane-bound protease FtsH. Intriguingly, the knockout mutation of clpP, encoding the cytoplasmic protease ClpP, greatly reduces the expression of SaeS L18P. Here, we report that, in the strain Newman, the positive regulatory role of ClpP on the SaeS L18P expression is due to its destabilizing effect on FtsH and degradation of MoeA, a molybdopterin biosynthesis protein. Although the transcription of ftsH was not affected by ClpP, the expression level of FtsH was increased in the clpP mutant. The destabilizing effect appears to be indirect because ClpXP did not directly degrade FtsH in an in vitro assay. Through transposon mutagenesis, we found out that the moeA gene, encoding the molybdopterin biosynthesis protein A, suppresses the hemolytic activity of S. aureus along with the transcription and expression of SaeS L18P. In a proteolysis assay, ClpXP directly degraded MoeA, demonstrating that MoeA is a substrate of the protease. In a murine bloodstream infection model, the moeA mutant displayed reduced virulence and lower survival compared with the WT strain. Based on these results, we concluded that ClpP positively controls the expression of SaeS L18P in an FtsH and MoeA-dependent manner, and the physiological role of MoeA outweighs its suppressive effect on the SaeRS TCS during infection.

Comparative Genomics and Evolution of Molybdenum Utilization

The trace element molybdenum (Mo) is the catalytic component of important enzymes involved in global nitrogen, sulfur, and carbon metabolism in both prokaryotes and eukaryotes. With the exception of nitrogenase, Mo is complexed by a pterin compound thus forming the biologically active molybdenum cofactor (Moco) at the catalytic sites of molybdoenzymes. The physiological roles and biochemical functions of many molybdoenzymes have been characterized. However, our understanding of the occurrence and evolution of Mo utilization is limited. This article focuses on recent advances in comparative genomics of Mo utilization in the three domains of life. We begin with a brief introduction of Mo transport systems, the Moco biosynthesis pathway, the role of posttranslational modifications, and enzymes that utilize Mo. Then, we proceed to recent computational and comparative genomics studies of Mo utilization, including a discussion on novel Moco-binding proteins that contain the C-terminal domain of the Moco sulfurase and that are suggested to represent a new family of molybdoenzymes. As most molybdoenzymes need additional cofactors for their catalytic activity, we also discuss interactions between Mo metabolism and other trace elements and finish with an analysis of factors that may influence evolution of Mo utilization.

Occurrence of Nitrate Reductase and Molybdopterin in Xanthomonas maltophilia

Fifteen of 23 ATCC strains and 2 of 9 clinical isolates of Xanthomonas maltophilia, all of which grew aerobically on ammonia, but not nitrate, as a sole nitrogen source, reduced nitrate to nitrite. X. maltophilia failed to grow anaerobically on complex medium with or without nitrate, so it is considered an obligate aerobe. Nitrate-reducing strains contained reduced methyl viologen nitrate reductase (MVH-NR) with specific activities ranging from 49.2 to 192 U mg of protein. Strain ATCC 17666 doubled its cell mass after 3 h of growth on nitrate broth under low aeration, possessed maximal MVH-NR activity, and converted the added nitrate to nitrite, which accumulated. Dissolved oxygen above 15% saturation greatly suppressed nitrite formation. All strains, except ATCC 14535, possessed between 0.25 and 5.05 pmol of molybdopterin mg of protein as measured by the Neurospora crassa nit-1 assay. The molybdopterin activity in the soluble fraction sedimented as a single symmetrical peak with an s(20,w) of 5.1. Studies identified MVH-NR in selected strains as a membrane-bound protein. The deoxycholate-solubilized MVH-NR sedimented as a single peak in sucrose density gradients with an s(20,w) of 8.8. The MVH-NR of X. maltophilia has the physical characteristics of a respiratory nitrate reductase and may enable cells to use nitrate as an electron sink under semiaerobic conditions.

Mcp1 encodes the molybdenum cofactor carrier protein in Chlamydomonas reinhardtii and participates in protection, binding, and storage functions of the cofactor

The molybdenum cofactor (Moco) is essential for the activity of all molybdoenzymes except nitrogenase. The cDNA for the Moco carrier protein (MocoCP) of Chlamydomonas reinhardtii has been cloned by reverse transcription PCR approaches with primers designed from microsequenced peptides of this protein. The C. reinhardtii MocoCP has been expressed in Escherichia coli. The recombinant protein has been purified to electrophoretic homogeneity and is found assembled into a homotetramer when Moco is not present under native conditions. Recombinant MocoCP has the same biochemical characteristics as MocoCP from C. reinhardtii, as it bound Moco from milk xanthine oxidase with high affinity, prevented Moco inactivation by oxygen, and transferred Moco efficiently to aponitrate reductase from the Neurospora crassa nit1 mutant. The genomic DNA sequence corresponding to the Chlamydomonas MocoCP gene, CrMcp1, also was isolated. This gene contained three introns in the coding region. The deduced amino acid sequence of CrMcp1 did not show a significant identity to functionally known proteins in the GenBank data base, although a significant conservation was found with bacterial proteins of unknown function. The results suggest that proteins having a Moco binding function probably exist in other organisms.

A chemical approach to systematically designate the pyranopterin centers of molybdenum and tungsten enzymes and synthetic models

The recent growth in the chemistry of the oxo-molybdenum enzymes has demonstrated the need for developing systematic methods for naming and abbreviating the novel pterin cofactors that bind to the metal ion via the sulfur atoms of an ene-1,2-dithiolate moiety. Historically, the term "molybdopterin" was coined to designate a special pterin that binds molybdenum and the molybdenum-bound form was termed the "molybdenum cofactor". However, recent studies have demonstrated that this novel pterin also binds tungsten. Furthermore, considerable variation has been found in the pterin entity itself. Taken together, these facts show that molybdenum- and tungsten-containing enzymes possess a family of cofactors rather than a single "molybdenum cofactor". This article proposes a unified methodology for describing these cofactors and their metal-free pterin units in light of recent results from protein crystallography. The various numbering schemes that have been used for this heterocycle are considered, as well as the IUPAC rules which are currently being used for related tricyclic compounds. A unified methodology for uniquely designating and abbreviating each cofactor is proposed. The available chemical and spectroscopic information on the pyranopterin entities that are present in the molybdenum and tungsten enzymes, the precursors to these centers, and synthetic pyranopterins are in part the basis of the systematic names and simplifying abbreviations.

The Aspergillus nidulans cnxF gene and its involvement in molybdopterin biosynthesis. Molecular characterization and analysis of in vivo generated mutants

The product of the Aspergillus nidulans cnxF gene was found by biochemical analysis of cnxF mutants to be involved in the conversion of precursor Z to molybdopterin. Mutants cnxF1242 and cnxF8 accumulate precursor Z, while the level of molybdopterin is undetectable. The DNA sequence of the cnxF gene was determined, and the inferred protein of 560 amino acids was found to contain a central region (residues around 157 to 396) similar in sequence to the prokaryotic proteins MoeB, which is thought to encode molybdopterin synthase sulfurylase, ThiF, required for thiamine biosynthesis, and HesA, involved in heterocyst formation, as well as eukaryotic ubiquitin-activating protein E1. Based on these similarities, a possible mechanism of action is discussed. Sequence comparisons indicate the presence of one and possibly two nucleotide binding motifs, Gly-X-Gly-X-X-Gly, as well as two metal binding Cys-X-X-Cys motifs in this central region of the CnxF protein. Seven in vivo generated A. nidulans cnxF mutants were found to have amino acid substitutions of conserved residues within this central region of similarity to molybdopterin synthase sulfurylase, indicating that these seven amino acids are essential and that this domain is crucial for function. Of these seven, the cnxF1285 mutation results in the replacement of Gly-178, the last glycine residue of the N-proximal Gly-X-Gly-X-X-Gly motif, indicating that this motif is essential. Mutation of the conserved Arg-208, also probably involved in nucleotide binding, leads to a loss-of-function phenotype in cnxF200. Alteration of Cys-263, the only conserved Cys residue (apart from the metal binding motifs), in cnxF472 suggests this residue as a candidate for thioester formation between molybdopterin synthase and the sulfurylase. Substitution of Gly-160 in two independently isolated mutants, cnxF21 and cnxF24, results in temperature-sensitive phenotypes and indicates that this residue is important in protein conformation. The C-terminal CnxF stretch (residues 397-560) shows substantial sequence conservation to a yeast hypothetical protein, Yhr1, such conservation between species suggesting that this region has function. Not inconsistent with this proposition is the observation that mutant cnxF8 results from loss of the 34 C-terminal residues of CnxF. There is no obvious similarity of the CnxF C-terminal region with other proteins of known function. Two cnxF transcripts are found in low abundance and similar levels were observed in nitrate- or ammonium-grown cells.

Characterization of a spontaneous mutant of Azotobacter vinelandii in which vanadium-dependent nitrogen fixation is not inhibited by molybdenum

A spontaneous mutant derivative of Azotobacter vinelandii CA12 (delta nif HDK), which vanadium-dependent nitrogen fixation is not inhibited by molybdenum (A. vinelandii CARR), grows profusely on BNF-agar containing 1 microM Na2MoO4, alone or supplemented with 1 microM V2O5. The expression of A. vinelandii vnfH::lacZ and vnfA::lacZ fusions in A. vinelandii CARR was not inhibited by 1 mM Na2MoO4, whereas molybdenum at much lower concentration inhibited the expression of vnfH::lacZ and vnfA::lacZ fusions in A. vinlandii CA12. The mutant also exhibited normal acetylene reduction activity in the presence of 1 microM Na2MoO4. The expression of A. vinelandii nifH::lacZ fusion in A. vinelandii CARR was low even though the cells were cultured under non-repressing conditions with urea as nitrogen source in the presence of Na2MoO4. The molybdenum content of A. vinelandii CARR cells was found to be about one-fourth that of A. vinelandii CA12. No nitrate reductase activity could be detected in A. vinelandii CARR when the cells were cultured in the presence of 10 microM Na2MoO4, whereas A. vinelandii CA12 exhibited some activity even with 100 pM Na2MoO4.

The molybdenum cofactor of Escherichia coli nitrate reductase A (NarGHI). Effect of a mobAB mutation and interactions with [Fe-S] clusters

We have studied the effect of a mobAB mutation and tungstate on molybdo-molybdopterin-guanine dinucleotide (Mo-MGD) insertion into Escherichia coli nitrate reductase (NarGHI). Preparation of fluorescent oxidized derivatives of MGD (Form A and Form B) indicates that in a mobAB mutant there is essentially no detectable cofactor present in either the membrane-bound (NarGHI) or purified soluble (NarGH) forms of the enzyme. Electron paramagnetic resonance characterization of membrane-bound cofactor-deficient NarGHI suggests that it has altered electrochemistry with respect to the dithionite reducibility of the [Fe-S] clusters of NarH. Potentiometric titrations of membrane-bound NarGHI indicate that the NarH [Fe-S] clusters have midpoint potentials at pH 8.0 (Em,8.0 values) of +180 mV ([3Fe-4S] cluster), +130, -55, and -420 mV ([4Fe-4S] clusters) in a wild-type background and +180, +80, -35, and -420 mV in a mobAB mutant background. These data support the following conclusions: (i) a model for Mo-MGD biosynthesis and assembly into NarGHI in which both metal chelation and nucleotide addition to molybdopterin precede cofactor insertion; and (ii) the absence of Mo-MGD significantly affects Em,8.0 of the highest potential [4Fe-4S] cluster.

Physiological and genetic analyses leading to identification of a biochemical role for the moeA (molybdate metabolism) gene product in Escherichia coli

A unique class of chlorate-resistant mutants of Escherichia coli which produced formate hydrogenlyase and nitrate reductase activities only when grown in medium with limiting amounts of sulfur compounds was isolated. These mutants failed to produce the two molybdoenzyme activities when cultured in rich medium or glucose-minimal medium. The mutations in these mutants were localized in the moeA gene. Mutant strains with polar mutations in moeA which are also moeB did not produce active molybdoenzymes in any of the media tested. moeA mutants with a second mutation in either cysDNCJI or cysH gene lost the ability to produce active molybdoenzyme even when grown in medium limiting in sulfur compounds. The CysDNCJIH proteins along with CysG catalyze the conversion of sulfate to sulfide. Addition of sulfide to the growth medium of moeA cys double mutants suppressed the MoeA- phenotype. These results suggest that in the absence of MoeA protein, the sulfide produced by the sulfate activation/reduction pathway combines with molybdate in the production of activated molybdenum. Since hydrogen sulfide is known to interact with molybdate in the production of thiomolybdate, it is possible that the MoeA-catalyzed activated molybdenum is a form of thiomolybdenum species which is used in the synthesis of molybdenum cofactor from Mo-free molybdopterin.

Cell biology and molecular basis of denitrification

Denitrification is a distinct means of energy conservation, making use of N oxides as terminal electron acceptors for cellular bioenergetics under anaerobic, microaerophilic, and occasionally aerobic conditions. The process is an essential branch of the global N cycle, reversing dinitrogen fixation, and is associated with chemolithotrophic, phototrophic, diazotrophic, or organotrophic metabolism but generally not with obligately anaerobic life. Discovered more than a century ago and believed to be exclusively a bacterial trait, denitrification has now been found in halophilic and hyperthermophilic archaea and in the mitochondria of fungi, raising evolutionarily intriguing vistas. Important advances in the biochemical characterization of denitrification and the underlying genetics have been achieved with Pseudomonas stutzeri, Pseudomonas aeruginosa, Paracoccus denitrificans, Ralstonia eutropha, and Rhodobacter sphaeroides. Pseudomonads represent one of the largest assemblies of the denitrifying bacteria within a single genus, favoring their use as model organisms. Around 50 genes are required within a single bacterium to encode the core structures of the denitrification apparatus. Much of the denitrification process of gram-negative bacteria has been found confined to the periplasm, whereas the topology and enzymology of the gram-positive bacteria are less well established. The activation and enzymatic transformation of N oxides is based on the redox chemistry of Fe, Cu, and Mo. Biochemical breakthroughs have included the X-ray structures of the two types of respiratory nitrite reductases and the isolation of the novel enzymes nitric oxide reductase and nitrous oxide reductase, as well as their structural characterization by indirect spectroscopic means. This revealed unexpected relationships among denitrification enzymes and respiratory oxygen reductases. Denitrification is intimately related to fundamental cellular processes that include primary and secondary transport, protein translocation, cytochrome c biogenesis, anaerobic gene regulation, metalloprotein assembly, and the biosynthesis of the cofactors molybdopterin and heme D1. An important class of regulators for the anaerobic expression of the denitrification apparatus are transcription factors of the greater FNR family. Nitrate and nitric oxide, in addition to being respiratory substrates, have been identified as signaling molecules for the induction of distinct N oxide-metabolizing enzymes.

Molybdenum-cofactor-containing enzymes: structure and mechanism

Molybdenum-containing enzymes catalyze basic metabolic reactions in the nitrogen, sulfur, and carbon cycles. With the exception of the nitrogenase cofactor, molybdenum is incorporated into proteins as the molybdenum cofactor that contains a mononuclear molybdenum atom coordinated to the sulfur atoms of a pterin derivative named molybdopterin. Certain microorganisms can also utilize tungsten in a similar fashion. Molybdenum-cofactor-containing enzymes catalyze the transfer of an oxygen atom, ultimately derived from or incorporated into water, to or from a substrate in a two-electron redox reaction. On the basis of sequence alignments and spectroscopic properties, four families of molybdenum-cofactor-containing enzymes have been identified. The available crystallographic structures for members of these families are discussed within the framework of the active site structure and catalytic mechanisms of molybdenum-cofactor-containing enzymes. Although the function of the molybdopterin ligand has not yet been conclusively established, interactions of this ligand with the coordinated metal are sensitive to the oxidation state, indicating that the molybdopterin may be directly involved in the enzymatic mechanism.

Nitrate reductase activity and heterocyst suppression on nitrate in Anabaena sp. strain PCC 7120 require moeA

Mutants of Anabaena sp. strain PCC 7120 that form heterocysts when grown on nitrate-containing media were isolated following nitrosoguanidine mutagenesis. Six independent mutants were isolated, and the characterization of one mutant, strain AMC260, which forms 6 to 8% heterocysts in the presence of nitrate, is presented. A 1.8-kb chromosomal fragment that complemented the AMC260 mutant was sequenced, and a 1.2-kb open reading frame, named moeA, was identified. The deduced amino acid sequence of the predicted Anabaena sp. strain PCC 7120 MoeA polypeptide shows 37% identity to MoeA from Escherichia coli, which is required for the synthesis of molybdopterin cofactor. Molybdopterin is required by various molybdoenzymes, such as nitrate reductase. Interruption of the moeA gene in Anabaena sp. strain PCC 7120 resulted in a strain, AMC364, that showed a phenotype similar to that of AMC260. We show that AMC260 and AMC364 lack methyl viologen-supported nitrate reductase activity. We conclude that the inability of the moeA mutants to metabolize nitrate results in heterocyst formation on nitrate-containing media. Northern (RNA) analysis detected a 1.5-kb moeA transcript in wild-type cells grown in the presence or absence of a combined nitrogen source.

Molybdenum cofactor biosynthesis in Escherichia coli mod and mog mutants

The molybdopterin content of Escherichia coli mod and mog mutants was estimated by conversion to the form A derivative. The results are in accord with complete phenotypic repair of mod, and incomplete repair of mog, by culture in high concentrations of molybdate. A possible role for Mog as a molybdochelatase is discussed.

Repression of the Escherichia coli modABCD (molybdate transport) operon by ModE

The modABC gene products constitute the molybdate-specific transport system in Escherichia coli. Another operon coding for two proteins which diverges from the modABCD operon has been identified. The first gene of this operon codes for a 262-amino-acid protein, designated ModE (28 kDa), and the second genes codes for a 490-amino-acid protein. ModF (54 kDa). The role of ModF has not yet been determined; however, mutations in modE depressed modABCD transcription even in the presence of molybdate, suggesting that ModE is a repressor. ModE, in the presence of 1 mM molybdate, repressed the production of plasmid-encoded ModA and ModB' proteins in an in vitro transcription-translation system. DNA mobility shift experiments confirmed that ModE binds to an oligonucleotide derived from the operator region of the modABCD operon. Further experimentation indicated that ModE binding to target DNA minimally requires an 8-bp inverted-repeat sequence, TAAC GITA. A highly conserved amino acid sequence, TSARNOXXG (amino acids 125 to 133), was identified in ModE and homologs from Azotobacter vinelandii, Haemophilus influenzae, Rhodobacter capsulatus, and Clostridium pasterianum. Mutants with mutations in either T or G of this amino acid sequence were isolated as "superrepressor" mutants. These mutant proteins repressed modABCD transcription even in the absence of molybdate, which implies that this stretch of amino acids is essential for the binding of molybdate by the ModE protein. These results show that molybdate transport in E. coli is regulated by ModE, which acts as a repressor when bound to molybdate.

Site-specific mutagenesis in Enterobacter agglomerans: construction of nif B mutants and analysis of the gene's structure and function

A novel technique was developed which may be generally well suited to the site-specific construction of mutations in Enterobacter agglomerans. The method is based on the observation that E. agglomerans can be cured of a plasmid of the incompatibility group IncQ by cultivation on citrate-containing medium. To test the applicability of this technique, we inserted a kanamycin cassette into the cloned nifB gene, transferred it into E. agglomerans, and selected for recombinants in which the wild-type nifB was replaced by the mutated gene by growing transformants on citrate medium with kanamycin. The nifB- mutants with the kanamycin cassette inserted in either orientation showed a nif- phenotype. Further, we determined the nucleotide sequence of nifB. A typical sigma 54-dependent promoter and a consensus NifA binding site were found upstream of nifB. Activation of this promoter by both heterologous and homologous NifA proteins was observed in vivo. The predicted amino acid sequence of the NifB protein showed strong similarity to the NifB sequences of other diazotrophic bacteria. The typical clustering of cysteine residues at the N-terminal end indicates its involvement in Fe-Mo cofactor biosynthesis.

Molecular analysis of the molybdate uptake operon, modABCD, of Escherichia coli and modR, a regulatory gene

The nucleotide sequence of a 6.8-kb chromosomal subfragment of plasmid pHW100 complementing an Escherichia coli modC (chlD) mutant has been determined. This DNA region encodes the genes of a high-affinity uptake system for molybdate arranged in an operon with the genes modABCD. Since the modA product has a signal peptide at the N-terminus it probably is the periplasmic binding-protein for molybdate. The products of modB (chlJ) and modC (chlD) have been described earlier as the inner membrane protein and the ATP-binding protein of the molybdate transport system, respectively. At present, there is no information on possible functions of the fourth gene of the operon, modD. Upstream of the mod operon, two other gene loci, termed modR and an open reading frame ORF6 could be identified. ModR shares homology with a molybdenum-pterin binding protein of Clostridium pasteurianum. ORF6 has extensive homology to ModC and other nucleotide-binding proteins of E. coli. Insertional inactivation of modR and ORF6 using a gentamicin resistance gene cartridge has no effect on molybdoenzyme activities, indicating that none of the two gene products is essential for molybdate uptake or molybdenum cofactor synthesis. However, by using a plasmid carrying a modA-lacZ gene fusion we observed that inactivation of modR releases repression of the mod operon independent of the molybdate concentration in the medium. This indicates that modR is a component of the mod operon regulation or the repressor itself.

Mutational analysis of genes of the mod locus involved in molybdenum transport, homeostasis, and processing in Azotobacter vinelandii

DNA sequencing of the region upstream from the Azotobacter vinelandii operon (modEABC) that contains genes for the molybdenum transport system revealed an open reading frame (modG) encoding a hypothetical 14-kDa protein. It consists of a tandem repeat of an approximately 65-amino-acid sequence that is homologous to Mop, a 7-kDa molybdopterin-binding protein of Clostridium pasteurianum. The tandem repeat is similar to the C-terminal half of the product of modE. The effects of mutations in the mod genes provide evidence for distinct high- and low-affinity Mo transport systems and for the involvement of the products of modE and modG in the processing of molybdate. modA, modB, and modC, which encode the component proteins of the high-affinity Mo transporter, are required for 99Mo accumulation and for the nitrate reductase activity of cells growing in medium with less than 10 microM Mo. The exchange of accumulated 99Mo with nonradioactive Mo depends on the presence of modA, which encodes the periplasmic molybdate-binding protein. 99Mo also exchanges with tungstate but not with vanadate or sulfate. modA, modB, and modC mutants exhibit nitrate reductase activity and 99Mo accumulation only when grown in more than 10 microM Mo, indicating that A. vinelandii also has a low-affinity Mo uptake system. The low-affinity system is not expressed in a modE mutant that synthesizes the high-affinity Mo transporter constitutively or in a spontaneous tungstate-tolerant mutant. Like the wild type, modG mutants only show nitrate reductase activity when grown in > 10 nM Mo. However, a modE modG double mutant exhibits maximal nitrate reductase activity at a 100-fold lower Mo concentration. This indicates that the products of both genes affect the supply of Mo but are not essential for nitrate reductase cofactor synthesis. However, nitrogenase-dependent growth in the presence or absence of Mo is severely impaired in the double mutant, indicating that the products of modE and modG may be involved in the early steps of nitrogenase cofactor biosynthesis in A. vinelandii.

Molybdate and regulation of mod (molybdate transport), fdhF, and hyc (formate hydrogenlyase) operons in Escherichia coli

Escherichia coli mutants with defined mutations in specific mod genes that affect molybdate transport were isolated and analyzed for the effects of particular mutations on the regulation of the mod operon as well as the fdhF and hyc operons which code for the components of the formate hydrogenlyase (FHL) complex. phi (hyc'-'lacZ+) mod double mutants produced beta-galactosidase activity only when they were cultured in medium supplemented with molybdate. This requirement was specific for molybdate and was independent of the moa, mob, and moe gene products needed for molybdopterin guanine dinucleotide (MGD) synthesis, as well as Mog protein. The concentration of molybdate required for FHL production by mod mutants was dependent on medium composition. In low-sulfur medium, the amount of molybdate needed by mod mutants for the production of half-maximal FHL activity was increased approximately 20 times by the addition of 40 mM of sulfate, mod mutants growing in low-sulfur medium transported molybdate through the sulfate transport system, as seen by the requirement of the cysA gene product for this transport. In wild-type E. coli, the mod operon is expressed at very low levels, and a mod+ merodiploid E. coli carrying a modA-lacZ fusion produced less than 20 units of beta-galactosidase activity. This level was increased by over 175 times by a mutation in the modA, modB, or modC gene. The addition of molybdate to the growth medium of a mod mutant lowered phi (modA'-'lacZ+) expression. Repression of the mod operon was sensitive to molybdate but was insensitive to mutations in the MGD synthetic pathway. These physiological and genetic experiments show that molybdate can be transported by one of the following three anion transport system in E. coli: the native system, the sulfate transport system (cysTWA gene products), and an undefined transporter. Upon entering the cytoplasm, molybdate branches out to mod regulation, fdhF and hyc activation, and metabolic conversion, leading to MGD synthesis and active molybdoenzyme synthesis.

Genetic analysis of the modABCD (molybdate transport) operon of Escherichia coli

DNA sequence analysis of the modABCD operon of Escherichia coli revealed the presence of four open reading frames. The first gene, modA, codes for a 257-amino-acid periplasmic binding protein enunciated by the presence of a signal peptide-like sequence. The second gene (modB) encodes a 229-amino-acid protein with a potential membrane location, while the 352-amino-acid ModC protein (modC product) contains a nucleotide-binding motif. On the basis of sequence similarities with proteins from other transport systems and molybdate transport proteins from other organisms, these three proteins are proposed to constitute the molybdate transport system. The fourth open reading frame (modD) encodes a 231-amino-acid protein of unknown function. Plasmids containing different mod genes were used to map several molybdate-suppressible chlorate-resistant mutants; interestingly, none of the 40 mutants tested had a mutation in the modD gene. About 35% of these chlorate-resistant mutants were not complemented by mod operon DNA. These mutants, designated mol, contained mutations at unknown chromosomal location(s) and produced formate hydrogenlyase activity only when cultured in molybdate-supplemented glucose-minimal medium, not in L broth. This group of mol mutants constitutes a new class of molybdate utilization mutants distinct from other known mutants in molybdate metabolism. These results show that molybdate, after transport into cells by the ModABC proteins, is metabolized (activated?) by the products of the mol gene(s).

Association of molybdopterin guanine dinucleotide with Escherichia coli dimethyl sulfoxide reductase: effect of tungstate and a mob mutation

We have identified the organic component of the molybdenum cofactor in Escherichia coli dimethyl sulfoxide reductase (DmsABC) to be molybdopterin (MPT) guanine dinucleotide (MGD) and have studied the effects of tungstate and a mob mutation on cofactor (Mo-MGD) insertion. Tungstate severely inhibits anaerobic growth of E. coli on a glycerol-dimethyl sulfoxide minimal medium, and this inhibition is partially overcome by overexpression of DmsABC. Isolation and characterization of an oxidized derivative of MGD (form A) from DmsABC overexpressed in cells grown in the presence of molybdate or tungstate indicate that tungstate inhibits insertion of Mo-MGD. No electron paramagnetic resonance evidence for the assembly of tungsten into DmsABC was found between Eh = -450 mV and Eh = +200 mV. The E. coli mob locus is responsible for the addition of a guanine nucleotide to molybdo-MPT (Mo-MPT) to form Mo-MGD. DmsABC does not bind Mo-MPT or Mo-MGD in a mob mutant, indicating that nucleotide addition must precede cofactor insertion. No electron paramagnetic resonance evidence for the assembly of molybdenum into DmsABC in a mob mutant was found between Eh = -450 mV and Eh = +200 mV. These data support a model for Mo-MGD biosynthesis and assembly into DmsABC in which both metal chelation and nucleotide addition to MPT precede cofactor insertion.

Metabolic relationship between the CO dehydrogenase molybdenum cofactor and the excretion of urothione by Hydrogenophaga pseudoflava

Urothione was isolated as an excretion product of Hydrogenophaga pseudoflava and other bacteria at amounts approaching 253 micrograms/l of culture corresponding to 44 micrograms/g bacterial dry mass. The compound was identified as urothione by co-chromatography with urothione isolated from human urine, its characteristic ultraviolet and visible absorption spectra, oxidation to pterin-6-carboxylic-7-sulfonic acid by alkaline permanganate, 1H-NMR spectroscopy, double-quantum-filtered Fourier-transform 1H correlated spectroscopy, circular-dichroism spectroscopy and mass spectroscopy. A metabolic relationship between urothione and the carbon monoxide dehydrogenase molybdenum cofactor was suggested by a 1.1:0.5 molar ratio between urothione excreted and degradation of carbon monoxide dehydrogenase, a coincidence of urothione excretion and induction of carbon monoxide dehydrogenase with different species of carboxidotrophic bacteria, a structural relationship between molybdopterin cytosine dinucleotide of the carbon monoxide dehydrogenase molybdenum cofactor and urothione, and the demonstrated conversion of the carbon monoxide dehydrogenase molybdenum cofactor to urothione in vitro. A pathway for the conversion of the H. pseudoflava carbon monoxide dehydrogenase molybdenum cofactor to urothione has been proposed which involves molybdopterin cytosine dinucleotide, molybdopterin, phospho-norurothione and norurothione.

Anaerobic degradation of nitrilotriacetate (NTA) in a denitrifying bacterium: purification and characterization of the NTA dehydrogenase-nitrate reductase enzyme complex

The initial step in the anoxic metabolism of nitrilotriacetate (NTA) was investigated in a denitrifying member of the gamma subgroup of the Proteobacteria. In membrane-free cell extracts, the first step of NTA oxidation was catalyzed by a protein complex consisting of two enzymes, NTA dehydrogenase (NTADH) and nitrate reductase (NtR). The products formed were iminodiacetate and glyoxylate. Electrons derived from the oxidation of NTA were transferred to nitrate only via the artificial dye phenazine methosulfate, and nitrate was stoichiometrically reduced to nitrite. NTADH activity could be measured only in the presence of NtrR and vice versa. The NTADH-NtrR enzyme complex was purified and characterized. NTADH and NtrR were both alpha 2 dimers and had molecular weights of 170,000 and 105,000, respectively. NTADH contained covalently bound flavin cofactor, and NtrR contained a type b cytochrome. Optimum NTA-oxidizing activity was achieved at a molar ratio of NTADH to NtrR of approximately 1:1. So far, NTA is the only known substrate for NTADH. This is the first report of a redox enzyme complex catalyzing the oxidation of a substrate and concomitantly reducing nitrate.

Structure of the nifQ gene from Enterobacter agglomerans 333 and its overexpression in Escherichia coli

The nifQ gene, involved in early stages of iron-molybdenum cofactor (FeMo-co) biosynthesis, was identified downstream of the nifB and nifF genes of Enterobacter agglomerans. This gene was cloned and its nucleotide sequence determined. The amino acid sequence, as deduced from the nucleotide sequence, revealed an accumulation of cysteine amino acid residues at the C-terminal end of the protein. The cysteine cluster showed the following consensus sequence Cys-X4-Cys-X2-Cys-X5-Cys, which is a typical characteristic of metal-binding proteins. Further, the nifQ gene was cloned downstream of strong transcriptional (bacteriophage lambda PLPR) and translational (atpE) signals of the expression vector pCYTEXP1 and expressed as an unfused, soluble protein in Escherichia coli. The molecular mass of 19 kDa, as deduced by SDS-PAGE, is in good agreement with the molecular mass deduced from the nucleotide sequence. The availability of high-level expression clones should facilitate purification of large quantities of the recombinant NifQ protein and elucidation of its properties.

Characterization of genes involved in molybdenum transport in Azotobacter vinelandii

Expression of alternative nitrogenases in Azotobacter vinelandii is repressed by molybdenum. Two strains with Tn5 insertion mutations showed alternative nitrogenase-dependent diazotrophic growth in the presence of Mo. The mutations were in a region which contained four open reading frames (ORFs 1-4). The genetic structure and predicted products of ORFs 2, 3 and 4 are typical of the membrane-associated elements of the ATP-binding cassette (ABC) superfamily of transport systems. The products of ORF3 and ORF4 are homologous with the products of the Escherichia coli genes chlD and the partially sequenced chlJ, respectively, both of which are implicated in molybdenum transport. ORF1, which is in the relative position of bacterial permease genes commonly specifying periplasmic binding proteins, encodes a 29 kDa protein with a novel primary structure. It lacks a potential signal sequence, and its C-terminal half consists of a tandem repeat of a segment which is homologous with the M(r) 7 kDa molybdenum-pterin binding protein Mop from Clostridium pasteurianum. This suggests that a substituted pterin may be involved in the initial capture or early metabolism of molybdenum.

Molybdoenzyme biosynthesis in Escherichia coli: in vitro activation of purified nitrate reductase from a chlB mutant

All molybdoenzyme activities are absent in chlB mutants because of their inability to synthesize molybdopterin guanine dinucleotide, which together with molybdate constitutes the molybdenum cofactor in Escherichia coli. The chlB mutants are able to synthesize molybdopterin. We have previously shown that the inactive nitrate reductase present in a chlB mutant can be activated in a process requiring protein FA and a heat-stable low-molecular-weight substance. We show here that purified nitrate reductase from the soluble fraction of a chlB mutant can be partially activated in a process that requires protein FA, GTP, and an additional protein termed factor X. It appears that the molybdopterin present in the nitrate reductase of a chlB mutant is converted to molybdopterin guanine dinucleotide during activation. The activation is absolutely dependent upon both protein FA and factor X. Factor X activity is present in chlA, chlB, chlE, and chlG mutants.

Identification of a locus within the hydrogenase gene cluster involved in intracellular nickel metabolism in Bradyrhizobium japonicum

A 0.6-kb fragment of DNA involved in intracellular Ni metabolism was isolated and cloned from a cosmid containing 23.2 kb of hydrogenase-related genes of Bradyrhizobium japonicum. This locus is located 8.3 kb upstream of the hydrogenase structural genes. The hydrogenase activity of a mutant with a gene-directed mutation at this locus (strain JHK7) showed dependency on nickel provided during hydrogenase derepression. The hydrogenase activity was only 20% of that in the wild-type strain, JH, at a concentration of 0.5 microM NiCl2. The hydrogenase activity in JH reached its maximum at 3 microM NiCl2, whereas the mutant (JHK7) reached wild-type levels of hydrogenase activity when derepressed in 50 microM NiCl2. Studies with the hup-lacZ transcriptional fusion plasmid pSY7 in JHK7 showed that the mutant JHK7 expressed less promoter activity under low-nickel conditions than did strain JH. The mutant accumulated less nickel during a 45-h hydrogenase derepression period than did the wild type. However, both JHK7 and the JH wild-type strain had the same short-term Ni transport rates, and the KmS for Ni of both strains were about 62 microM. When incubated under non-hydrogenase-derepression conditions, the mutant accumulated Ni at the same rate as strain JH. However, this stored source of nickel was unable to restore hydrogenase expression ability of the mutant to wild-type levels during derepression without nickel. The results indicate that the locus identified in B. japonicum is not involved in nickel-specific transport; indeed, it was not at all homologous to the "nickel transporter" hoxN gene of Alcaligenes eutrophus.(ABSTRACT TRUNCATED AT 250 WORDS)

Molybdenum-dependent degradation of quinoline by Pseudomonas putida Chin IK and other aerobic bacteria

Eighteen different aerobic bacteria were isolated which utilized quinoline as sole source of carbon, nitrogen, and energy. Attempts were unsuccessful at isolating anaerobic quinoline-degrading bacteria. The optimal concentration of quinoline for growth was in the range of 2.5 to 5 mM. Some organisms excreted 2-hydroxyquinoline as the first intermediate. Hydroxylation of quinoline was catalyzed by a dehydrogenase which was induced in the presence of quinoline or 2-hydroxyquinoline. Quinoline dehydrogenase activity was dependent on the availability of molybdate in the growth medium. Growth on quinoline was inhibited by tungstate, an antagonist of molybdate. Partially purified quinoline dehydrogenase from Pseudomonas putida Chin IK indicated the presence of flavin, iron-sulfur centers, and molybdenum-binding pterin. Mr of quinoline dehydrogenase was about 300 kDa in all isolates investigated.

Xanthine dehydrogenase and 2-furoyl-coenzyme A dehydrogenase from Pseudomonas putida Fu1: two molybdenum-containing dehydrogenases of novel structural composition

The constitutive xanthine dehydrogenase and the inducible 2-furoyl-coenzyme A (CoA) dehydrogenase could be labeled with [185W]tungstate. This labeling was used as a reporter to purify both labile proteins. The radioactivity cochromatographed predominantly with the residual enzymatic activity of both enzymes during the first purification steps. Both radioactive proteins were separated and purified to homogeneity. Antibodies raised against the larger protein also exhibited cross-reactivity toward the second smaller protein and removed xanthine dehydrogenase and 2-furoyl-CoA dehydrogenase activity up to 80 and 60% from the supernatant of cell extracts, respectively. With use of cell extract, Western immunoblots showed only two bands which correlated exactly with the activity stains for both enzymes after native polyacrylamide gel electrophoresis. Molybdate was absolutely required for incorporation of 185W, formation of cross-reacting material, and enzymatic activity. The latter parameters showed a perfect correlation. This evidence proves that the radioactive proteins were actually xanthine dehydrogenase and 2-furoyl-CoA dehydrogenase. The apparent molecular weight of the native xanthine dehydrogenase was about 300,000, and that of 2-furoyl-CoA dehydrogenase was 150,000. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of both enzymes revealed two protein bands corresponding to molecular weights of 55,000 and 25,000. The xanthine dehydrogenase contained at least 1.6 mol of molybdenum, 0.9 ml of cytochrome b, 5.8 mol of iron, and 2.4 mol of labile sulfur per mol of enzyme. The composition of the 2-furoyl-CoA dehydrogenase seemed to be similar, although the stoichiometry was not determined. The oxidation of furfuryl alcohol to furfural and further to 2-furoic acid by Pseudomonas putida Fu1 was catalyzed by two different dehydrogenases.

Sequence of the Klebsiella aerogenes urease genes and evidence for accessory proteins facilitating nickel incorporation

A 4.8-kilobase-pair region of cloned DNA encoding the genes of the Klebsiella aerogenes urease operon has been sequenced. Six closely spaced open reading frames were found: ureA (encoding a peptide of 11.1 kilodaltons [kDa]), ureB (11.7-kDa peptide), ureC (60.3-kDa peptide), ureE (17.6-kDa peptide), ureF (25.2-kDa peptide), and ureG (21.9-kDa peptide). Immediately after the ureG gene is a putative rho-dependent transcription terminator. The three subunits of the nickel-containing enzyme are encoded by ureA, ureB, and ureC based on protein structural studies and sequence homology to jack bean urease. Potential roles for ureE, ureF, and ureG were explored by deleting these accessory genes from the operon. The deletion mutant produced inactive urease, which was partially purified and found to have the same subunit stoichiometry and native size as the active enzyme but which contained no significant levels of nickel. The three accessory genes were able to activate apo-urease in vivo when they were cloned into a compatible expression vector and cotransformed into cells carrying the plasmid containing ureA, ureB, and ureC. Thus, one or more of the ureE, ureF, or ureG gene products are involved in nickel incorporation into urease.