molybdenum-cofactor and tungstate

We have investigated the final steps of complex iron-sulfur molybdoenzyme (CISM) maturation using Escherichia coli DMSO reductase (DmsABC) as a model system. The catalytic subunit of this enzyme, DmsA, contains an iron-sulfur cluster (FS0) and a molybdo-bis(pyranopterin guanine dinucleotide) cofactor (Mo-bisPGD). We have identified a variant of DmsA (Cys59Ser) that renders enzyme maturation sensitive to molybdenum cofactor availability. DmsA-Cys59 is a ligand to the FS0 [4Fe-4S] cluster. In the presence of trace amounts of molybdate, the Cys59Ser variant assembles normally to the cytoplasmic membrane and supports respiratory growth on DMSO, although the ground state of FS0 as determined by EPR is converted from high-spin (S=3/2) to low-spin (S=1/2). In the presence of the molybdenum antagonist tungstate, wild-type DmsABC lacks Mo-bisPGD, but is translocated via the Tat translocon and assembles on the periplasmic side of the membrane as an apoenzyme. The Cys59Ser variant cannot overcome the dual insults of amino acid substitution plus lack of Mo-bisPGD, leading to degradation of the DmsABC subunits. This indicates that the cofactor can serve as a chemical chaperone to mitigate the destabilizing effects of alteration of the FS0 cluster. These results provide insights into the role of the Mo-bisPGD-protein interaction in stabilizing the tertiary structure of DmsA during enzyme maturation.

Topics: Coenzymes; Dimethyl Sulfoxide; Electron Spin Resonance Spectroscopy; Escherichia coli; Iron-Sulfur Proteins; Metalloproteins; Molybdenum Cofactors; Oxidoreductases; Pteridines; Tungsten Compounds

Molybdenum insertion into the dithiolene group on the 6-alkyl side-chain of molybdopterin is a highly specific process that is catalysed by the MoeA and MogA proteins in Escherichia coli. Ligation of molybdate to molybdopterin generates the molybdenum cofactor, which can be inserted directly into molybdoenzymes binding the molybdopterin form of the molybdenum cofactor, or is further modified in bacteria to form the dinucleotide form of the molybdenum cofactor. The ability of various metals to bind tightly to sulfur-rich sites raised the question of whether other metal ions could be inserted in place of molybdenum at the dithiolene moiety of molybdopterin in molybdoenzymes. We used the heterologous expression systems of human sulfite oxidase and Rhodobacter sphaeroides dimethylsulfoxide reductase in E. coli to study the incorporation of different metal ions into the molybdopterin site of these enzymes. From the added metal-containing compounds Na(2)MoO(4), Na(2)WO(4), NaVO(3), Cu(NO(3))(2), CdSO(4) and NaAsO(2) during the growth of E. coli, only molybdate and tungstate were specifically inserted into sulfite oxidase and dimethylsulfoxide reductase. Other metals, such as copper, cadmium and arsenite, were nonspecifically inserted into sulfite oxidase, but not into dimethylsulfoxide reductase. We showed that metal insertion into molybdopterin occurs beyond the step of molybdopterin synthase and is independent of MoeA and MogA proteins. Our study shows that the activity of molybdoenzymes, such as sulfite oxidase, is inhibited by high concentrations of heavy metals in the cell, which will help to further the understanding of metal toxicity in E. coli.

Topics: Binding Sites; Coenzymes; Escherichia coli; Humans; Iron-Sulfur Proteins; Metalloproteins; Metals, Heavy; Molybdenum; Molybdenum Cofactors; Oxidoreductases; Pteridines; Rhodobacter sphaeroides; Sulfite Oxidase; Sulfurtransferases; Tungsten Compounds

Selenite reduction in Rhodobacter sphaeroides f. sp. denitrificans was observed under photosynthetic conditions, following a 100-h lag period. This adaptation period was suppressed if the medium was inoculated with a culture previously grown in the presence of selenite, suggesting that selenite reduction involves an inducible enzymatic pathway. A transposon library was screened to isolate mutants affected in selenite reduction. Of the eight mutants isolated, two were affected in molybdenum cofactor synthesis. These moaA and mogA mutants showed an increased duration of the lag phase and a decreased rate of selenite reduction. When grown in the presence of tungstate, a well-known molybdenum-dependent enzyme (molybdoenzyme) inhibitor, the wild-type strain displayed the same phenotype. The addition of tungstate in the medium or the inactivation of the molybdocofactor synthesis induced a decrease of 40% in the rate of selenite reduction. These results suggest that several pathways are involved and that one of them involves a molybdoenzyme. Although addition of nitrate or dimethyl sulfoxide (DMSO) to the medium increased the selenite reduction activity of the culture, neither the periplasmic nitrate reductase NAP nor the DMSO reductase is the implicated molybdoenzyme, since the napA and dmsA mutants, with expression of nitrate reductase and DMSO reductase, respectively, eliminated, were not affected by selenite reduction. A role for the biotine sulfoxide reductase, another characterized molybdoenzyme, is unlikely, since its overexpression in a defective strain did not restore the selenite reduction activity.

Topics: Coenzymes; Culture Media; Dimethyl Sulfoxide; Metalloproteins; Molybdenum Cofactors; Nitrates; Oxidation-Reduction; Oxidoreductases; Oxidoreductases Acting on Sulfur Group Donors; Pteridines; Rhodobacter sphaeroides; Sodium Selenite; Tungsten Compounds

The periplasmic nitrate reductase, NapA, from Escherichia coli was identified as a 90 kDa molybdoprotein which comigrated during polyacrylamide gel electrophoresis with the di-haem c-type cytochrome, NapB. The DNA sequence of the 5' end of the napA gene and the N-terminal amino acid sequences of both NapA and NapB were determined. The 36 residue leader peptide for NapA includes the double-arginine motif typical of proteins to which complex redox cofactors are attached in the cytoplasm prior to targeting to the periplasm. The pre-NapA leader sequence is both unexpectedly long and, unless two successive proteolysis steps are involved, is cleaved at the unprecedented sequence G-Q-Q-. Nap activity was suppressed during growth in the presence of tungstate and was absent from a mutant unable to synthesise the molybdopterin cofactor.

Topics: Amino Acid Sequence; Arginine; Base Sequence; Coenzymes; Cytochrome c Group; Dimerization; Escherichia coli; Metalloproteins; Molecular Sequence Data; Molybdenum; Molybdenum Cofactors; Nitrate Reductases; Periplasm; Protein Precursors; Protein Sorting Signals; Pteridines; Tungsten Compounds

In Chlamydomonas reinhardtii, molybdopterin cofactor (MoCo) able to reconstitute active nitrate reductase (NR) with apoenzyme from the Neurospora crassa mutant nit-1 was found mostly bound to a carrier protein (CP). This protein is scarce in the algal free extracts and has been purified 520-fold. MoCoCP is a protein of 64 kDa with subunits of 16.5 kDa and an isoelectric point of 4.5. In contrast to free MoCo, MoCo bound to CP was remarkably protected against inactivation under both aerobic conditions and basic pH. MocoCP transferred active MoCo to apoNR in vitro without addition of molybdate, though reconstituted activity was 20% higher in the presence of molybdate. Incubation with tungstate specifically inhibited MoCoCP activity but had no effect on the activity of free MoCo released from milk xanthine oxidase. MoCoCP did not charge molybdate unless in the presence of N. crassa extracts. Our data support that MoCoCP stabilizes MoCo in an active form charged with molybdate to provide MoCo to apomolybdoenzymes.

Topics: Animals; Carrier Proteins; Chlamydomonas reinhardtii; Coenzymes; Metalloproteins; Molybdenum; Molybdenum Cofactors; Pteridines; Tungsten Compounds

The molybdenum-containing iron-sulfur flavoprotein CO dehydrogenase is expressed in a catalytically fully competent form during heterotrophic growth of the aerobic bacterium Hydrogenophaga pseudoflava with pyruvate plus CO. We have adopted these conditions for studying the effect of molybdate (Mo) and tungstate (W) on the biosynthesis of CO dehydrogenase and its molybdopterin (MPT) cytosine-dinucleotide-(MCD)-type molybdenum cofactor. W was taken up by the Mo transport system and, therefore, interfered with Mo transport in an antagonistic way. Depletion of Mo from the growth medium as well as inclusion of excess W both resulted in the absence of intracellular Mo and led to the biosynthesis of CO dehydrogenase species of proper L2M2S2 subunit structure that carried the two 2Fe:2S type-I and type-II centers and two FAD molecules. EPR, ultraviolet/visible and CD spectroscopies established the full functionality of the cofactors. Due to the absence of the Mo-MCD cofactor, the enzyme species were catalytically inactive. Unexpectedly, the following cytidine nucleotides were present in inactive CO dehydrogenase: CDP, dCDP, CMP, dCMP, CTP or dCTP. The sum of cytidine nucleotides was two/mol enzyme. The binding specificities of inactive CO dehydrogenase for cytidine nucleotides (oxy > deoxy; diphosphate > monophosphate > triphosphate), and the absence of MPT suggest that, in active CO dehydrogenase, the cytidine diphosphate moiety of Mo-MCD provides the strongest interactions with the protein and determines the specificity for the type of nucleotide. In H. pseudoflava, the biosynthesis of MPT (identified as form A) was independent of Mo. Mo was, however, strictly required for the conversion of MPT to MCD (identified as form-A-CMP) as well as the insertion of Mo-MCD into CO dehydrogenase. These data support a model for the involvement of Mo in the biosynthesis of the Mo-MCD cofactor and of fully functional CO dehydrogenase in which the synthesis and insertion of Mo-MCD require Mo, and protein synthesis including integration of the FeS-centers and FAD are independent of Mo.

Topics: Aldehyde Oxidoreductases; Circular Dichroism; Coenzymes; Cytosine Nucleotides; Metalloproteins; Molybdenum; Molybdenum Cofactors; Multienzyme Complexes; Oxidation-Reduction; Pseudomonas; Pteridines; Pterins; Tungsten Compounds

Selection for chlorate resistance yields mol (formerly chl) mutants with defects in molybdenum cofactor synthesis. Complementation and genetic mapping analyses indicated that the Klebsiella pneumoniae mol genes are functionally homologous to those of Escherichia coli and occupy analogous genetic map positions. Hypoxanthine utilization in other organisms requires molybdenum cofactor as a component of xanthine dehydrogenase, and thus most chlorate-resistant mutants cannot use hypoxanthine as a sole source of nitrogen. Surprisingly, the K. pneumoniae mol mutants and the mol+ parent grew equally well with hypoxanthine as the sole nitrogen source, suggesting that K. pneumoniae has a molybdenum cofactor-independent pathway for hypoxanthine utilization.

Topics: Chromosome Mapping; Coenzymes; Gene Expression Regulation, Bacterial; Genetic Complementation Test; Hypoxanthine; Hypoxanthines; Klebsiella pneumoniae; Metalloproteins; Molybdenum; Molybdenum Cofactors; Mutagenesis; Nitrate Reductase; Nitrate Reductases; Nitrogen; Pteridines; Transduction, Genetic; Tungsten; Tungsten Compounds

The apo-nitrate reductase precursor in an Escherichia coli chlB mutant preparation obtained following growth in the presence of tungstate is activated by incubation with protein FA and a heat-treated preparation from an E. coli crude extract. We show that the requirement for heat-treated E. coli crude extract can be fulfilled by material obtained from either of two heat-denatured purified E. coli molybdoenzymes, namely nitrate reductase or trimethylamine N-oxide reductase. Apo-trimethylamine N-oxide reductase precursor in the tungstate-grown chlB preparation can be activated in a similar manner with material from either heat-denatured molybdoenzyme. The active component in the denatured molybdoenzyme preparations is shown to be the molybdenum cofactor by Neurospora crassa nit1 molybdenum cofactor assay, size estimation and fluorimetric analysis. The direct demonstration of the requirement for molybdenum cofactor in the E. coli tungstate-grown chlB complementation system is an important step towards the molecular definition of the activation process and an understanding of the mechanism of cofactor acquisition during molybdoenzyme biosynthesis.

Topics: Coenzymes; Enzyme Activation; Escherichia coli; Genetic Complementation Test; Hot Temperature; Metalloproteins; Molybdenum Cofactors; NADH, NADPH Oxidoreductases; Neurospora crassa; Nitrate Reductases; Oxidoreductases Acting on CH-NH Group Donors; Pteridines; Spectrometry, Fluorescence; Tungsten; Tungsten Compounds

The inducible trimethylamine-N-oxide reductase which migrates on non-denaturing polyacrylamide gels with an RF of 0.22, has been purified from the soluble fraction of wild-type E. coli K12. The molecular weight of the purified enzyme estimated by molecular-sieve chromatography is about 230,000. It is composed of two subunits of molecular weight 110,000. Antiserum specific for the enzyme has been produced. Gel filtration on Sephadex G-200 of the soluble fraction gave two peaks of trimethylamine-N-oxide reductase, one with an Mr of 230,000 and an RF of 0.22, and another with an Mr of 120,000 and an RF of 0.36. Since the anti-trimethylamine-N-oxide reductase serum recognises the two forms and shows a single subunit with an Mr of 110,000, we conclude that in E. coli there is a single inducible trimethylamine-N-oxide reductase which can exist as a dimer or a monomer. Other immunological studies with anti-trimethylamine-N-oxide reductase serum on crude extracts prepared from cells grown in the absence of inducer showed that the constitutive trimethylamine-N-oxide reductase was not recognised by the antiserum. The same analyses carried out on a tor mutant (defective in the structural gene of the inducible enzyme) confirmed without ambiguity that the constitutive enzyme is immunologically distinct from the inducible enzyme. In the same way, using the anti-trimethylamine-N-oxide reductase serum, rocket immunoelectrophoresis analyses were able to show that the inducible apoenzyme is not regulated by the fnr gene product and that molybdate does not seem necessary for the synthesis or stabilisation of this enzyme.

Topics: Aerobiosis; Antibodies, Bacterial; Bacterial Proteins; Coenzymes; Enzyme Induction; Escherichia coli; Metalloproteins; Molecular Weight; Molybdenum Cofactors; NADH, NADPH Oxidoreductases; Nitrates; Oxidoreductases Acting on CH-NH Group Donors; Oxygen; Pteridines; Tungsten; Tungsten Compounds