Distinction of cnxH cofactor gene-specified protomers with monoclonal antibodies to Aspergillus nitrate reductase

The nitrate reductase (NADPH) (EC 1.6.6.3) from Aspergillus nidulans is influenced directly by mutations in the structural gene (niaD) for the major subunit of the enzyme and indirectly by mutation in any of several molybdenum cofactor loci (cnx). The cnxE-14 and the cnxH-3 mutants have been noted to contain the enzyme in two distinct forms following induction with nitrate. With the cnxH-3 as a prototype cnxH mutant, 10 other cnxH were found to be devoid of the assembled (dimeric) form of the enzyme. Two monoclonal antibodies specific for the native enzyme of the wild type (biA-1) recognized an epitope on the enzyme from the cnxE-14 and cnxH-3 mutants that was common to both and another that was unique to the cnxH gene specified protomer. Another monoclonal antibody recognized an epitope that occurs only in the assembled dimerio form of the enzyme from the wild type or the cnxE-14 mutant. The experiments further substantiate the cnxH phenotype as one involving unassembled protomers of the nitrate reductase in Aspergillus.     

Access to the active site of periplasmic nitrate reductase: insights from site-directed mutagenesis and zinc inhibition studies

The periplasmic nitrate reductase (NapAB), a member of the DMSO reductase superfamily, catalyzes the first step of the denitrification process in bacteria. In this heterodimer, a di-heme NapB subunit is associated to the catalytic NapA subunit that binds a [4Fe-4S] cluster and a bis(molybdopterin guanine dinucleotide) cofactor. Here, we report the kinetic characterization of purified mutated heterodimers from Rhodobacter sphaeroides. By combining site-directed mutagenesis, redox potentiometry, EPR spectroscopy, and enzymatic characterization, we investigate the catalytic role of two conserved residues (M153 and R392) located in the vicinity of the molybdenum active site. We demonstrate that M153 and R392 are involved in nitrate binding: the Vm measured on the M153A and R392A mutants are similar to that measured on the wild-type enzyme, whereas the Km for nitrate is increased 10-fold and 200-fold, respectively. The use of an alternative enzymatic assay led us to discover that NapAB is uncompetitively inhibited by Zn2+ ions (Ki' = 1 microM). We used this property to further probe the active site access in the mutant enzymes. It is proposed that R392 acts as a filter by preventing a direct reduction of the Mo atom by small reducing molecules and partially protecting the active site against zinc inhibition. In addition, we show that M153 is a key residue mediating this inhibition likely by coordinating Zn2+ ions via its sulfur atom. This residue is not conserved in the DMSO reductase superfamily while it is conserved in the periplasmic nitrate reductase family. Zinc inhibition is therefore likely to be specific and restricted to periplasmic nitrate reductases.     

Heavy metal ions inhibit molybdoenzyme activity by binding to the dithiolene moiety of molybdopterin in Escherichia coli

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.     

Comparison of the sequences of the Aspergillus nidulans hxB and Drosophila melanogaster ma-l genes with nifS from Azotobacter vinelandii suggests a mechanism for the insertion of the terminal sulphur atom in the molybdopterin cofactor

The molybdopterin cofactor (MoCF) is required for the activity of a variety of oxidoreductases. The xanthine oxidase class of molybdoenzymes requires the MoCF to have a terminal, cyanolysable sulphur ligand. In the sulphite oxidase/nitrate reductase class, an oxygen is present in the same position. Mutations in both the ma-l gene of Drosophila melanogaster and the hxB gene of Aspergillus nidulans result in loss of activities of all molybdoenzymes that necessitate a cyanolysable sulphur in the active centre. The ma-l and hxB genes encode highly similar proteins containing domains common to pyridoxal phosphate-dependent cysteine transulphurases, including the cofactor binding site and a conserved cysteine, which is the putative sulphur donor. Key similarities were found with NifS, the enzyme involved in the generation of the iron-sulphur centres in nitrogenase. These similarities suggest an analogous mechanism for the generation of the terminal molybdenum-bound sulphur ligand. We have identified putative homologues of these genes in a variety of organisms, including humans. The human homologue is located in chromosome 18.q12.     

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.     

nit 7: A New Locus for Molybdopterin Cofactor Biosynthesis in the Green Alga Chlamydomonas reinhardtii

Two new nitrate reductase-deficient mutants from Chlamydomonas reinhardtii have been genetically and biochemically characterized. Both H1 and F23 mutants carry single recessive allelic mutations that map at a new locus designated nit-7. This locus is unlinked to the other six nit loci related to the nitrate assimilation pathway in C. reinhardtii. Both mutant alleles H1 and F23 lack an active molybdopterin cofactor, the activity of which is restored neither in vitro nor in vivo by high concentrations of molybdate. Nitrate reductase subunits in these mutants seem to assemble, although not in a stable form, in a high molecular weight complex and, as in other molybdenum cofactor-defective mutants of C. reinhardtii, they cannot reconstitute nitrate reductase activity with an active molybdenum cofactor source from extracts of ammonium-grown cells. The results suggest that nit-7 mutants are defective in molybdopterin biosynthesis. They do produce some precursor(s) that are capable of binding to nitrate reductase subunits.     

Nitrate reductase of Neurospora crassa: the functional role of individual amino acids in the heme domain as examined by site-directed mutagenesis

The enzyme nitrate reductase, which catalyzes the reduction of nitrate to nitrite, is a multi-redox center homodimeric protein. Each polypeptide subunit is approximately 100 kDa in size and contains three separate domains, one each for a flavin, a heme-iron, and a molybdopterin cofactor. The heme-iron domain of nitrate reductase has homology with the simple redox protein, cytochrome b5, whose crystal structure was used to predict a three-dimensional structure for the heme domain. Two histidine residues have been identified that appear to coordinate the iron of the heme moiety, while other residues may be important in the folding or the function of the heme pocket. Site-directed mutagenesis was employed to obtain mutants that encode nitrate reductase derivatives with eight different single amino acid substitutions within the heme domain, including the two central histidine residues. Replacement of one of these histidines by alanine resulted in a completely nonfunctional enzyme whereas replacement of the other histidine resulted in a stable and functional enzyme with a lower affinity for heme. Certain amino acid substitutions appeared to cause a rapid turnover of the heme domain, whereas other substitutions were tolerated and yielded a stable and fully active enzyme. Three different single amino acid replacements within the heme domain led to a dramatic change in regulation of nitrate reductase synthesis, with significant expression of the enzyme even in the absence of nitrate induction.     

Nitrate reductase of Neurospora crassa: the functional role of individual amino acids in the heme domain as examined by site-directed mutagenesis

The enzyme nitrate reductase, which catalyzes the reduction of nitrate to nitrite, is a multi-redox center homodimeric protein. Each polypeptide subunit is approximately 100 kDa in size and contains three separate domains, one each for a flavin, a heme-iron, and a molybdopterin cofactor. The heme-iron domain of nitrate reductase has homology with the simple redox protein, cytochrome b5, whose crystal structure was used to predict a three-dimensional structure for the heme domain. Two histidine residues have been identified that appear to coordinate the iron of the heme moiety, while other residues may be important in the folding or the function of the heme pocket. Site-directed mutagenesis was employed to obtain mutants that encode nitrate reductase derivatives with eight different single amino acid substitutions within the heme domain, including the two central histidine residues. Replacement of one of these histidines by alanine resulted in a completely nonfunctional enzyme whereas replacement of the other histidine resulted in a stable and functional enzyme with a lower affinity for heme. Certain amino acid substitutions appeared to cause a rapid turnover of the heme domain, whereas other substitutions were tolerated and yielded a stable and fully active enzyme. Three different single amino acid replacements within the heme domain led to a dramatic change in regulation of nitrate reductase synthesis, with significant expression of the enzyme even in the absence of nitrate induction.     

chlC (nar) operon of Escherichia coli includes structural genes for alpha and beta subunits of nitrate reductase.

The synthesis of the alpha and beta subunits of nitrate reductase by 20 chlC::Tn5 insertion mutants of Escherichia coli was determined by immune precipitation of the subunits from fractions of cell extracts. Only two of the mutants produced either subunit in detectable amounts; these two accumulated the alpha subunit, but no beta subunit. In both cases the alpha subunit was present in the cytosolic fraction, in contrast to wild-type cells, in which both subunits are present mainly in the membrane fraction. EcoRI restriction fragments containing the Tn5 inserts from five of the mutants were cloned into pBR322. The insertions were localized on two contiguous EcoRI fragments spanning a 5.6-kilobase region that overlapped the contiguous ends of the two fragments. An insertion that permitted alpha subunit formation defined one end of the 5.6-kilobase region. The results indicated that the genes encoding the alpha and beta subunits of nitrate reductase were part of a chlC (nar) operon that is transcribed in the direction alpha leads to beta.     

Involvement of the narJ and mob gene products in distinct steps in the biosynthesis of the molybdoenzyme nitrate reductase in Escherichia coli

The Escherichia coli mob locus is required for synthesis of active molybdenum cofactor, molybdopterin guanine dinucleotide. The mobB gene is not essential for molybdenum cofactor biosynthesis because a deletion of both mob genes can be fully complemented by just mobA. Inactive nitrate reductase, purified from a mob strain, can be activated in vitro by incubation with protein FA (the mobA gene product), GTP, MgCl₂, and a further protein fraction, factor X. Factor X activity is present in strains that lack MobB, indicating that it is not an essential component of factor X, but over-expression of MobB increases the level of factor X. MobB, therefore, can participate in nitrate reductase activation. The narJ protein is not a component of mature nitrate reductase but narJ mutants cannot express active nitrate reductase A. Extracts from narJ strains are unable to support the in vitro activation of purified mob nitrate reductase: they lack factor X activity. Although the mob gene products are necessary for the biosynthesis of all E. coli molybdoenzymes as a result of their requirement for molybdopterin guanine dinucleotide, NarJ action is specific for nitrate reductase A. The inactive nitrate reductase A derivative in a narJ strain can be activated in vitro following incubation with cell extracts containing the narJ protein. NarJ acts to activate nitrate reductase after molybdenum cofactor biosynthesis is complete.     

Nitrate reductase activity is required for nitrate uptake into fungal but not plant cells

The ability to transport net nitrate was conferred upon transformant cells of the non-nitrate-assimilating yeast Pichia pastoris after the introduction of two genes, one encoding nitrate reductase and the other nitrate transport. It was observed that cells of this lower eukaryote transformed with the nitrate transporter gene alone failed to display net nitrate transport despite having the ability to produce the protein. In addition, loss-of-function nitrate reductase mutants isolated from several nitrate-assimilating fungi appeared to be unable to accumulate nitrate. Uptake assays using the tracer (13)NO(3)(-) showed that nitrate influx is negligible in cells of a nitrate reductase null mutant. In parallel studies using a higher eukaryotic plant, Arabidopsis thaliana, loss-of-function nitrate reductase strains homozygous for both NIA1 insertion and NIA2 deletion were found to have no detectable nitrate reductase mRNA or nitrate reductase activity but retained the ability to transport nitrate. The reasons for these fundamental differences in nitrate transport into the cells of representative members of these two eukaryotic kingdoms are discussed.     

Synthesis of nitrate reductase components in chlorate-resistant mutants of Escherichia coli.

Specific antibody to purified nitrate reductase from Escherichia coli was used to identify enzyme components present in mutants which lack functional nitrate reductase. chlA and B mutants contained all three subunits present in the wild-type enzyme. Different peptides with a broad range of molecular weights could be precipitated from chlCmutants, and chlE mutants contained either slightly degraded enzyme subunits or no precipitable protein. No mutants produced significant amounts of cytoplasmic enzyme. The chlA and B loci are suggested to function in the synthesis and attachment of a molybdenum-containing factor. The chlC locus is suggested to be the structural gene for nitrate reductase subunit A and chlE is suggested to be involved in the synthesis of the cytochrome b1 apoprotein.     

Effects of site-directed mutations on processing and activities of penicillin G acylase from Escherichia coli ATCC 11105.

Penicillin G acylase from Escherichia coli ATCC 11105 is synthesized from its precursor polypeptide into a catalytically active heterodimer via a complex posttranslational processing pathway. Substitutions in the pair of aminoacyl residues at the cleavage site for processing the small and large subunits were made. Their processing phenotypes and penicillin G acylase activities were analyzed. By the introduction of a prolyl residue at either position, the processing of the small subunit was blocked without a change in enzymatic activity. Four other substitutions had no effect. At the site for processing the large subunit, four substitutions out of the seven examined blocked processing. In general, penicillin G acylase activity seemed to be proportional to the efficiency of the large-subunit-processing step. Ser-290 is an amino acid critical for processing and also for the enzymatic activity of penicillin G acylase. In the mutant pAATC, in which Ser-290 is mutated to Cys, the precursor is processed, but there is no detectable enzymatic activity. This suggests that there is a difference in the structural requirements for the processing pathway and for enzymatic activity. Recombination analysis of several mutants demonstrated that the small subunit can be processed only when the large subunit is processed first. Some site-directed mutants from which signal peptides were removed showed partial processing phenotypes and reduced enzymatic activities. Their expression showed that the prerequisite for penicillin G acylase activity is the efficient processing of the large subunit and that the maturation of the small subunit does not affect the enzymatic activity.     

Amino acid substitutions in the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase that influence catalytic activity of the holoenzyme.

Four unique amino acid substitutions were introduced by site-directed mutagenesis into the third conserved region of the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO) from Anacystis nidulans (Synechococcus sp., PCC6301), resulting in the formation of four mutant enzymes, I87V, R88K, G91V, and F92L. Wild-type and mutant proteins were purified after synthesis in Escherichia coli. These single amino acid substitutions do not appear to perturb intersubunit interactions or induce any gross conformational changes; purified mutant proteins are stable, for the most part like the wild-type holoenzyme, and exhibit nearly identical CD spectra. Three of the four mutants, however, are severely deficient in carboxylase activity, with kcat less than or equal to 35% of the wild-type enzyme. While the substrate specificity factors were the same for the mutant and wild-type enzymes, significant alterations in some kinetic parameters were observed, particularly in the Michaelis constants for CO2, O2, and RuBP. All four mutant proteins exhibited lower KCO2 values, ranging from 37 to 88% of the wild-type enzyme. Two of the mutants, in addition, exhibited significantly lower KRuBP values, and one mutant showed a substantial decrease in KO2. The effects of the single-site mutations in rbcS of this study strengthen the hypothesis that small subunits may not contribute directly to substrate specificity; however, individual residues of the small subunit substantially influence catalysis by large subunits.     

Asymmetric distribution of nitrate reductase subunits in the cytoplasmic membrane of Escherichia coli: evidence derived from surface labeling studies with transglutaminase.

The enzyme transglutaminase has been used to label surface proteins of Escherichia coli cytoplasmic membranes by covalently attaching to them a small fluorescent primary amine, dansyl cadaverine. Spheroplasts lacking outer membrane, osmotically lysed vesicles from the spheroplasts, and vesicles made by breaking cells in a French pressure cell were each labeled with transglutaminase and dansyl cadaverine. When the total cytoplasmic membrane proteins of each were examined on sodium dodecyl sulfate gels, three rather different labeling patterns were obtained. Labeling of the respiratory enzyme, nitrate reductase, in the membranes of each of these preparations was also examined. Membrane-bound nitrate reductase contains three subunits: A, B, and C. Dansyl cadaverine labeling of nitrate reductase in the presence of Triton X-100 indicated that subunits A and C could be labeled. When nitrate reductase was isolated from dansyl cadaverine-labeled spheroplasts, none of the subunits was labeled. When nitrate reductase was isolated from French press vesicles, subunit A was labeled and labeling was enhanced by the presence of nitrate during labeling. When nitrate reductase from osmotic vesicles was examined, subunit A was labeled in the presence of nitrate but no labeled subunits appeared when the vesicles were labeled in the absence of nitrate. It was concluded that (i) nitrate reductase is buried in the membrane with subunit A exposed only on the inner surface of the membrane, (ii) subunit C is sufficiently buried within the membrane so that it is inaccessible to transglutaminase, (iii) subunit B is not labeled under any condition, so its location is not known, and (iv) large osmotic vesicles are probably mosaics in which some protein components have been reoriented.     

Identification of an acetolactate synthase small subunit gene in two eukaryotes

Acetolactate synthase catalyses the first step in branched-chain amino acid biosynthesis. The bacterial enzyme contains two large and two small subunits but there is only limited and circumstantial evidence for a small subunit in the eukaryotic enzyme. Here this evidence is summarised and protein sequences of two putative eukaryotic small subunits, from a yeast and a red alga, are presented.     

Molybdenum cofactor biosynthesis in Escherichia coli. Requirement of the chlB gene product for the formation of molybdopterin guanine dinucleotide.

The chlorate-resistant mutants of Escherichia coli are affected in the biosynthesis of the molybdenum cofactor and show pleiotropic loss of the activities of those enzymes which require the cofactor. The molybdenum cofactor in all molybdoenzymes other than nitrogenase is a complex of the metal with a unique pterin termed molybdopterin. The molybdenum cofactor in a number of E. coli enzymes has been shown to contain GMP in addition to the metal-molybdopterin complex, with the GMP appended in pyrophosphate linkage to the terminal phosphate ester on the molybdopterin side chain. In this paper, we have examined the biochemistry of the chlB mutant and show that the gene product of the chlB locus is essential for the addition of the GMP moiety to form molybdopterin guanine dinucleotide, a step which occurs late in the cofactor biosynthetic pathway in E. coli. Sensitive techniques were developed for the identification of fluorescent derivatives of molybdopterin and of molybdopterin guanine dinucleotide in extracts of E. coli cells. Wild type cells were shown to contain both molybdopterin and molybdopterin guanine dinucleotide, while cells of chlB mutants were found to contain elevated levels of molybdopterin but no detectable molybdopterin guanine dinucleotide.     

Crystal structure of molybdopterin synthase and its evolutionary relationship to ubiquitin activation

Molybdenum cofactor (Moco) biosynthesis is an evolutionarily conserved pathway present in eubacteria, archaea and eukaryotes, including humans. Genetic deficiencies of enzymes involved in Moco biosynthesis in humans lead to a severe and usually fatal disease. Moco contains a tricyclic pyranopterin, termed molybdopterin (MPT), that bears the cis-dithiolene group responsible for molybdenum ligation. The dithiolene group of MPT is generated by MPT synthase, which consists of a large and small subunits. The 1.45 A resolution crystal structure of MPT synthase reveals a heterotetrameric protein in which the C-terminus of each small subunit is inserted into a large subunit to form the active site. In the activated form of the enzyme this C-terminus is present as a thiocarboxylate. In the structure of a covalent complex of MPT synthase, an isopeptide bond is present between the C-terminus of the small subunit and a Lys side chain in the large subunit. The strong structural similarity between the small subunit of MPT synthase and ubiquitin provides evidence for the evolutionary antecedence of the Moco biosynthetic pathway to the ubiquitin dependent protein degradation pathway.     

Synthesis and degradation of nitrate reductase in Escherichia coli.

The biosynthesis, insertion, and in vivo stability of nitrate reductase were examined by following the amount of labeled enzyme present in both membranes and cytoplasm at varying times after a short pulse of radioactive sulfate. Nitrate reductase levels were measured by autoradiography of immunoprecipitated material after fractionation on sodium dodecyl sulfate-polyacrylamide gels. These experiments demonstrated that subunits A and B were synthesized in the cytoplasm and subsequently inserted into membranes. The insertion of these subunits was dependent upon the synthesis of another protein, and the rate of synthesis of this protein determined the rate of insertion of subunits A and B. The nitrate reductase produced by the chlA mutant was inserted into membranes in the normal fashion, whereas the nitrate reductase produced by the chlC and chlE mutants was poorly incorporated. The nitrate reductase in the wild type was completely stable in vivo under inducing or noninducing conditions, whereas in the chlC and chlE mutants nitrate reductase was degraded extensively in both the cytoplasm and membranes, even under inducing conditions. Under similar conditions, nitrate reductase was stable in the chlA mutant.