Detoxification Esterase StrH Initiates Strobilurin Fungicide Degradation in Hyphomicrobium sp. Strain DY-1.

Strobilurin fungicides are widely used in agricultural production due to their broad-spectrum and fungal mitochondrial inhibitory activities. However, their massive application has restrained the growth of eukaryotic algae and increased collateral damage in freshwater systems, notably harmful cyanobacterial blooms (HCBs). In this study, a strobilurin fungicide-degrading strain, Hyphomicrobium sp. strain DY-1, was isolated and characterized successfully. Moreover, a novel esterase gene, strH, responsible for the de-esterification of strobilurin fungicides, was cloned, and the enzymatic properties of StrH were studied. For trifloxystrobin, StrH displayed maximum activity at 50°C and pH 7.0. The catalytic efficiencies (kcat/Km ) of StrH for different strobilurin fungicides were 196.32 ± 2.30 µM-1 · s-1 (trifloxystrobin), 4.64 ± 0.05 µM-1 · s-1 (picoxystrobin), 2.94 ± 0.02 µM-1 · s-1 (pyraclostrobin), and (2.41 ± 0.19)×10-2 µM-1 · s-1 (azoxystrobin). StrH catalyzed the de-esterification of a variety of strobilurin fungicides, generating the corresponding parent acid to achieve the detoxification of strobilurin fungicides and relieve strobilurin fungicide growth inhibition of Chlorella This research will provide insight into the microbial remediation of strobilurin fungicide-contaminated environments.IMPORTANCE Strobilurin fungicides have been widely acknowledged as an essential group of pesticides worldwide. So far, their residues and toxic effects on aquatic organisms have been reported in different parts of the world. Microbial degradation can eliminate xenobiotics from the environment. Therefore, the degradation of strobilurin fungicides by microorganisms has also been reported. However, little is known about the involvement of enzymes or genes in strobilurin fungicide degradation. In this study, a novel esterase gene responsible for the detoxification of strobilurin fungicides, strH, was cloned in the newly isolated strain Hyphomicrobium sp. DY-1. This degradation process detoxifies the strobilurin fungicides and relieves their growth inhibition of Chlorella.

Structural and spectroscopic characterization of a HdrA-like subunit from Hyphomicrobium denitrificans.

Many bacteria and archaea employ a novel pathway of sulfur oxidation involving an enzyme complex that is related to the heterodisulfide reductase (Hdr or HdrABC) of methanogens. As a first step in the biochemical characterization of Hdr-like proteins from sulfur oxidizers (sHdr), we structurally analyzed the recombinant sHdrA protein from the Alphaproteobacterium Hyphomicrobium denitrificans at 1.4 Å resolution. The sHdrA core structure is similar to that of methanogenic HdrA (mHdrA) which binds the electron-bifurcating flavin adenine dinucleotide (FAD), the heart of the HdrABC-[NiFe]-hydrogenase catalyzed reaction. Each sHdrA homodimer carries two FADs and two [4Fe-4S] clusters being linked by electron conductivity. Redox titrations monitored by electron paramagnetic resonance and visible spectroscopy revealed a redox potential between -203 and -188 mV for the [4Fe-4S] center. The potentials for the FADH•/FADH- and FAD/FADH• pairs reside between -174 and -156 mV and between -81 and -19 mV, respectively. The resulting stable semiquinone FADH• species already detectable in the visible and electron paramagnetic resonance spectra of the as-isolated state of sHdrA is incompatible with basic principles of flavin-based electron bifurcation such that the sHdr complex does not apply this new mode of energy coupling. The inverted one-electron FAD redox potentials of sHdr and mHdr are clearly reflected in the different FAD-polypeptide interactions. According to this finding and the assumption that the sHdr complex forms an asymmetric HdrAA'B1C1B2C2 hexamer, we tentatively propose a mechanism that links protein-bound sulfane oxidation to sulfite on HdrB1 with NAD+ reduction via lipoamide disulfide reduction on HdrB2. The FAD of HdrA thereby serves as an electron storage unit. DATABASE: Structural data are available in PDB database under the accession number 6TJR.

Crystal structure of the dimethylsulfide monooxygenase DmoA from Hyphomicrobium sulfonivorans.

DmoA is a monooxygenase which uses dioxygen (O2) and reduced flavin mononucleotide (FMNH2) to catalyze the oxidation of dimethylsulfide (DMS). Although it has been characterized, the structure of DmoA remains unknown. Here, the crystal structure of DmoA was determined to a resolution of 2.28 Šand was compared with those of its homologues LadA and BdsA. The results showed that their overall structures are similar: they all share a conserved TIM-barrel fold which is composed of eight α-helices and eight ß-strands. In addition, they all have five additional insertions. Detailed comparison showed that the structures have notable differences despite their high sequence similarity. The substrate-binding pocket of DmoA is smaller compared with those of LadA and BdsA.

Lipoate-binding proteins and specific lipoate-protein ligases in microbial sulfur oxidation reveal an atpyical role for an old cofactor.

Many Bacteria and Archaea employ the heterodisulfide reductase (Hdr)-like sulfur oxidation pathway. The relevant genes are inevitably associated with genes encoding lipoate-binding proteins (LbpA). Here, deletion of the gene identified LbpA as an essential component of the Hdr-like sulfur-oxidizing system in the Alphaproteobacterium Hyphomicrobium denitrificans. Thus, a biological function was established for the universally conserved cofactor lipoate that is markedly different from its canonical roles in central metabolism. LbpAs likely function as sulfur-binding entities presenting substrate to different catalytic sites of the Hdr-like complex, similar to the substrate-channeling function of lipoate in carbon-metabolizing multienzyme complexes, for example pyruvate dehydrogenase. LbpAs serve a specific function in sulfur oxidation, cannot functionally replace the related GcvH protein in Bacillus subtilis and are not modified by the canonical E. coli and B. subtilis lipoyl attachment machineries. Instead, LplA-like lipoate-protein ligases encoded in or in immediate vicinity of hdr-lpbA gene clusters act specifically on these proteins.

Bacterial SBP56 identified as a Cu-dependent methanethiol oxidase widely distributed in the biosphere.

Oxidation of methanethiol (MT) is a significant step in the sulfur cycle. MT is an intermediate of metabolism of globally significant organosulfur compounds including dimethylsulfoniopropionate (DMSP) and dimethylsulfide (DMS), which have key roles in marine carbon and sulfur cycling. In aerobic bacteria, MT is degraded by a MT oxidase (MTO). The enzymatic and genetic basis of MT oxidation have remained poorly characterized. Here, we identify for the first time the MTO enzyme and its encoding gene (mtoX) in the DMS-degrading bacterium Hyphomicrobium sp. VS. We show that MTO is a homotetrameric metalloenzyme that requires Cu for enzyme activity. MTO is predicted to be a soluble periplasmic enzyme and a member of a distinct clade of the Selenium-binding protein (SBP56) family for which no function has been reported. Genes orthologous to mtoX exist in many bacteria able to degrade DMS, other one-carbon compounds or DMSP, notably in the marine model organism Ruegeria pomeroyi DSS-3, a member of the Rhodobacteraceae family that is abundant in marine environments. Marker exchange mutagenesis of mtoX disrupted the ability of R. pomeroyi to metabolize MT confirming its function in this DMSP-degrading bacterium. In R. pomeroyi, transcription of mtoX was enhanced by DMSP, methylmercaptopropionate and MT. Rates of MT degradation increased after pre-incubation of the wild-type strain with MT. The detection of mtoX orthologs in diverse bacteria, environmental samples and its abundance in a range of metagenomic data sets point to this enzyme being widely distributed in the environment and having a key role in global sulfur cycling.

Purification and characterization of dimethylsulfide monooxygenase from Hyphomicrobium sulfonivorans.

Dimethylsulfide (DMS) is a volatile organosulfur compound which has been implicated in the biogeochemical cycling of sulfur and in climate control. Microbial degradation is a major sink for DMS. DMS metabolism in some bacteria involves its oxidation by a DMS monooxygenase in the first step of the degradation pathway; however, this enzyme has remained uncharacterized until now. We have purified a DMS monooxygenase from Hyphomicrobium sulfonivorans, which was previously isolated from garden soil. The enzyme is a member of the flavin-linked monooxygenases of the luciferase family and is most closely related to nitrilotriacetate monooxygenases. It consists of two subunits: DmoA, a 53-kDa FMNH2-dependent monooxygenase, and DmoB, a 19-kDa NAD(P)H-dependent flavin oxidoreductase. Enzyme kinetics were investigated with a range of substrates and inhibitors. The enzyme had a K(m) of 17.2 (± 0.48) µM for DMS (k(cat) = 5.45 s⁻¹) and a V(max) of 1.25 (± 0.01) µmol NADH oxidized min⁻¹ (mg protein⁻¹). It was inhibited by umbelliferone, 8-anilinonaphthalenesulfonate, a range of metal-chelating agents, and Hg²(+), Cd²(+), and Pb²(+) ions. The purified enzyme had no activity with the substrates of related enzymes, including alkanesulfonates, aldehydes, nitrilotriacetate, or dibenzothiophenesulfone. The gene encoding the 53-kDa enzyme subunit has been cloned and matched to the enzyme subunit by mass spectrometry. DMS monooxygenase represents a new class of FMNH2-dependent monooxygenases, based on its specificity for dimethylsulfide and the molecular phylogeny of its predicted amino acid sequence. The gene encoding the large subunit of DMS monooxygenase is colocated with genes encoding putative flavin reductases, homologues of enzymes of inorganic and organic sulfur compound metabolism, and enzymes involved in riboflavin synthesis.

Degradation of methamidophos by Hyphomicrobium species MAP-1 and the biochemical degradation pathway.

Methamidophos is one of the most widely used organophosphorus insecticides usually detectable in the environment. A facultative methylotroph, Hyphomicrobium sp. MAP-1, capable of high efficiently degrading methamidophos, was isolated from methamidophos-contaminated soil in China. It was found that the addition of methanol significantly promoted the growth of strain MAP-1 and enhanced its degradation of methamidophos. Further, this strain could utilize methamidophos as its sole carbon, nitrogen and phosphorus source for growth and could completely degrade 3,000 mg l(-1) methamidophos in 84 h under optimal conditions (pH 7.0, 30 degrees C). The enzyme responsible for methamidophos degradation was mainly located on the cell inner membrane (90.4%). During methamidophos degradation, three metabolites were detected and identified based on tandem mass spectrometry (MS/MS) and gas chromatography-mass spectrometry (GC-MS) analysis. Using this information, a biochemical degradation pathway of methamidophos by Hyphomicrobium sp. MAP-1 was proposed for the first time. Methamidophos is first cleaved at the P-N bond to form O,S-dimethyl hydrogen thiophosphate and NH(3). Subsequently, O,S-dimethyl hydrogen thiophosphate is hydrolyzed at the P-O bond to release -OCH(3) and form S-methyl dihydrogen thiophosphate. O,S-dimethyl hydrogen thiophosphate can also be hydrolyzed at the P-S bond to release -SCH(3) and form methyl dihydrogen phosphate. Finally, S-methyl dihydrogen thiophosphate and methyl dihydrogen phosphate are likely transformed into phosphoric acid.

Identification and cloning of a gene encoding dichloromethane dehalogenase from a methylotrophic bacterium, Bacillus circulans WZ-12 CCTCC M 207006.

The gene dehalA encoding a novel dichloromethane dehalogenases (DehalA), has been cloned from Bacillus circulans WZ-12 CCTCC M 207006. The open reading frame of dehalA, spanning 864 bp, encoded a 288-amino acid protein that showed 85.76% identity to the dichloromethane dehalogenases of Hyphomicrobium sp. GJ21 with several commonly conserved sequences. These sequences could not be found in putative dichloromethane (DCM) dehalogenases reported from other bacteria and fungi. DehalA was expressed in Escherichia coli BL21 (DE3) from a pET28b(+) expression system and purified. The subunit molecular mass of the recombinant DehalA as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis was approximately 33 kDa. Subsequent enzymatic characterization revealed that DehalA was most active in a acidic pH range at 30 degrees , which was quite different from that observed from a facultative bacterium dichloromethane dehalogenases of Methylophilus sp. strain DM11. The Michaelis-Menten constant of DCM dehalogenase was markedly lower than that of standard DCM dehalogenases.

Detection of a gem-diamine and a stable quinonoid intermediate in the reaction catalyzed by serine-glyoxylate aminotransferase from Hyphomicrobium methylovorum.

BACKGROUND: The enzyme L-serine-glyoxylate aminotransferase (SGAT) from Hyphomicrobium methylovorum is a PLP-containing enzyme that catalyzes the conversion of L-serine and glyoxylate to hydroxypyruvate and glycine. The cloned enzyme expressed in Escherichia coli is isolated as a mixture of the E:PLP and E:PMP forms. The PLP form of the enzyme has a maximum absorbance at 413 nm. METHODS: Uv-visible spectra of SGAT were obtained using an HP-8453 diode array spectrophotometer in the absence and presence of substrates and substrate analogs. Pre-steady state kinetic studies were carried out using an OLIS rapid scanning spectrophotometer in the rapid scanning mode. RESULTS: Incubation of the enzyme with a saturating concentration D-serine leads to a shift in the 413 nm peak to 421 nm that is ascribed to the external aldimine. The reverse stereochemistry of D-serine does not allow for abstraction of the C alpha proton by the epsilon-amine of the active site lysine residue leading to an abortive external aldimine intermediate. Pre-steady state studies pushing SGAT against D-serine leads to a rapid decrease in the 413 nm peak and an increase at approximately 330 nm with an associated rate constant of 47 s(-1) at pH 7.6. This is followed by a slower decrease (0.26 s(-1)) at 330 nm and an increase and shift of the 413 nm peak to 421 nm. The intermediate species that absorbs at approximately 330 nm is attributed to the gem-diamine intermediate. The rate of the fast phase increases with pH and increase in rate is likely due to the deprotonation of an enzymatic group that accepts a proton from the alpha-amine of D-serine. In the presence of hydroxypyruvate and ammonia the enzyme spectra display an increase in absorbance at 521 nm that occurs on the order of minutes. The shape and position of the 521 nm species is consistent with a quinonoid intermediate. GENERAL SIGNIFICANCE: The data suggest a non-enzymatic reaction between hydroxypyruvate and ammonia to form an imine which will be in equilibrium with the enamine. A mechanism is proposed by which the enamine reacts with the PLP form of SGAT to generate the stable highly conjugated quinonoid intermediate.

Crystallization and preliminary X-ray diffraction analysis of a complex between the electron-transfer partners hexameric Cu-containing nitrite reductase and pseudoazurin.

The complex between Cu-containing nitrite reductase (HdNIR) and its electron-donor protein pseudoazurin (HdPAz) from Hyphomicrobium denitrificans has been crystallized. The crystals were obtained from a mixture of the two proteins using the hanging-drop vapour-diffusion method in the presence of polyethylene glycol (PEG) and 2-methyl-2,4-pentanediol (MPD) as precipitants. SDS-PAGE analysis demonstrated that the crystals contained both proteins. The X-ray diffraction experiment was carried out at SPring-8 and diffraction data were collected to 3.3 A resolution. The crystals were tetragonal (space group P4(1)2(1)2), with unit-cell parameters a = b = 130.39, c = 505.55 A. Preliminary analysis indicated that there was one HdNIR and at least two HdPAz molecules in the asymmetric unit of the crystal.

Strategy for the isolation of native dehydrogenases with potential for biosensor development from the organism Hyphomicrobium zavarzinii ZV580.

Dehydrogenases are interesting candidates for the development of electrochemical biosensors. Most dehydrogenases are characterised by a comparatively broad substrate spectrum, yet highly specific enzymes exist as well. A specific formaldehyde dehydrogenase has, e.g., been described for the organism Hyphomicrobium zavarzinii ZV580. Isolation of enzymes from their natural source instead of a recombinant expression renders the isolation more challenging, as common tools such as affinity tags are no longer available. In this contribution, we develop chromatographic procedures for such isolation tasks. The previously described formaldehyde dehydrogenase was isolated by two procedures, one based on affinity chromatography, the other on hydroxyapatite. Neither procedure yielded an active enzyme. In addition two dehydrogenases, a formaldehyde and a methylamine dehydrogenase, were found in the cell free extract, which had not been described previously. Both enzymes could be isolated to near purity by a sequence of hydroxyapatite and anion exchange chromatography. The new formaldehyde dehydrogenase requires reconstitution with calcium and pyrroloquinoline quinone in order to become active. The enzyme shows no cross-reactivity with methylamine or methanol. The methylamine dehydrogenase catalyses the conversion of methylamine into formaldehyde, hence it could become a technical catalyst for the inverse reaction. This enzyme consists of two types of subunit and may be one of the rare alpha,beta-methylamine dehydrogenases.

Direct detection of formaldehyde in air by a novel NAD+- and glutathione-independent formaldehyde dehydrogenase-based biosensor.

An amperometric enzyme-based sensor-system for the direct detection of formaldehyde in air is under investigation. The biosensor is based on a native bacterial NAD(+)- and glutathione-independent formaldehyde dehydrogenase as biorecognition element. The enzyme was isolated from Hyphomicrobium zavarzinii strain ZV 580, grown on methylamine hydrochloride in a fed-batch process. The sensor depends on the enzymatic conversion of the analyte to formic acid. Released electrons are detected in an amperometric measurement at 0.2V vs. Ag/AgCl reference electrode by means of a redox-mediator. To optimize the sensing device, Ca(2+) and pyrroloquinoline quinone (PQQ) were added to the buffer solution as reconstitutional substances. At this stage, the sensor shows linear response in the tested ppm-range with a sensitivity of 0.39 microA/ppm. The signal is highly reproducible with respect to sensitivity and base line signal. Reproducibility of sensitivity is more than 90% within the same bacterial batch and even when enzyme of different bacterial batches is used.

A fast method for the quantification of methylamine in fermentation broths by gas chromatography.

The objective of this study was to develop a method for the quantitative analysis of the methylamine concentration in fermentation broths of Hyphomicrobium zavarzinii ZV 580 cultures. For this purpose an established method for the quantification of free amino acids in such matrices was adapted and validated. The detection limit was 10 microM, the calibration curve showed good linearity (R2=0.9998) in the concentration range between 0.1 and 8 mM. The standard deviation of the injection-to-injection reproducibility (n=10) of the retention coefficient was <1%, that of the peak area<5%. In case of the sample-to-sample reproducibility (n=8), the standard deviation was <5% for the retention coefficient and <10% for the peak area. The validated method was successfully applied for monitoring a fed-batch bioprocess (starting volume: 8L, initial methylamine hydrochloride concentration: 10 mM) producing a dye-linked formaldehyde dehydrogenase in H. zavarzinii ZV 580.

Development of a fed-batch process for the production of a dye-linked formaldehyde dehydrogenase in Hyphomicrobium zavarzinii ZV 580.

The dye-linked formaldehyde dehydrogenase (dlFalDH) from Hyphomicrobium zavarzinii ZV 580 processes formaldehyde in a highly selective manner and without need for NAD(P). The enzyme thus has considerable potential for technical applications if the difficulties associated with its efficient production can be resolved. In this contribution, a fed-batch bioprocess is developed, which improves both the biomass production of H. zavarzinii ZV 580 (from 0.6 to 2 g l(-1) dry mass) and the specific dlFalDH production (from 0.1 to 0.3 units g(-1) biomass), resulting in an overall improvement of the productivity by more than an order of magnitude compared to the previously reported process (Klein et al., Biochem J 301:289-295, 1994). In particular, the process uses an automated feeding strategy controlled via the dissolved oxygen concentration. In addition, our results show that the growth of H. zavarzinii ZV 580 is rather sensitive toward increasing salt concentration in the culture medium. Growth is also inhibited by the presence of surfactant-based antifoam reagents. Adjustment of the pH via the addition of methylamine instead of NaOH, on the other hand, leads to an increase in biomass yield.

Structure and function of a hexameric copper-containing nitrite reductase.

Dissimilatory nitrite reductase (NIR) is a key enzyme in denitrification, catalyzing the first step that leads to gaseous products (NO, N(2)O, and N(2)). We have determined the crystal structure of a Cu-containing NIR from a methylotrophic denitrifying bacterium, Hyphomicrobium denitrificans, at 2.2-A resolution. The overall structure of this H. denitrificans NIR reveals a trigonal prism-shaped molecule in which a monomer consisting of 447 residues and three Cu atoms is organized into a unique hexamer (i.e., a tightly associated dimer of trimers). Each monomer is composed of an N-terminal region containing a Greek key beta-barrel folding domain, cupredoxin domain I, and a C-terminal region containing cupredoxin domains II and III. Both cupredoxin domains I and II bind one type 1 Cu and are combined with a long loop comprising 31 amino acid residues. The type 2 Cu is ligated at the interface between domain II of one monomer and domain III of an adjacent monomer. Between the two trimeric C-terminal regions are three interfaces formed by an interaction between the domains I, and the type 1 Cu in the domain is required for dimerization of the trimer. The type 1 Cu in domain II functions as an electron acceptor from an electron donor protein and then transfers an electron to the type 2 Cu, binding the substrate to reduce nitrite to NO. The discussion of the intermolecular electron transfer process from cytochrome c(550) to the H. denitrificans NIR is based on x-ray crystallographic and kinetic results.

Crystal structures of cytochrome c(L) and methanol dehydrogenase from Hyphomicrobium denitrificans: structural and mechanistic insights into interactions between the two proteins.

Methanol dehydrogenase (Hd-MDH) and its physiological electron acceptor, cytochrome c(L) (Hd-Cyt c(L)), isolated from a methylotrophic denitrifying bacterium, Hyphomicrobium denitrificans A3151, have been kinetically and structurally characterized; the X-ray structures of Hd-MDH and Hd-Cyt c(L) have been determined using molecular replacement at 2.5 and 2.0 A resolution, respectively. To explain the mechanism for electron transfer between these proteins, the dependence of MDH activity on the concentration of Hd-Cyt c(L) has been investigated at pH 4.5-7.0. The Michaelis constant for Hd-Cyt c(L) shows the smallest value (approximately 0.3 microM) at pH 5.5. The pseudo-first-order rate constant (k(obs)) of the reduction of Hd-Cyt c(L) exhibits a hyperbolic concentration dependence of Hd-MDH at pH 5.5, although k(obs) linearly increases at pH 6.5. These findings indicate formation of a transient complex between these proteins during an electron transfer event. Hd-MDH (148 kDa) is a large tetrameric protein with an alpha(2)beta(2) subunit composition, showing a high degree of structural similarity with other MDHs. Hd-Cyt c(L) (19 kDa) exhibiting the alpha-band at 550.7 nm has a unique C-terminal region involving a disulfide bond between Cys47 and Cys165. Moreover, there is a pair of Hd-Cyt c(L) monomers related with a pseudo-2-fold axis of symmetry in the asymmetric unit, and the two monomers tightly interact with each other through three hydrogen bonds. This configuration is the first example in the studies of cytochrome c as the physiological electron acceptor for MDH. The docking simulation between the coupled Hd-Cyt c(L) molecules and the heterotetrameric Hd-MDH molecule has been carried out.

Reaction of serine-glyoxylate aminotransferase with the alternative substrate ketomalonate indicates rate-limiting protonation of a quinonoid intermediate.

Serine-glyoxylate aminotransferase (SGAT) from Hyphomicrobium methylovorum is a pyridoxal 5'-phosphate (PLP) enzyme that catalyzes the interconversion of L-serine and glyoxylate to hydroxypyruvate and glycine. The primary deuterium isotope effect using L-serine 2-D is one on (V/K)serine and V in the steady state. Pre-steady-state experiments also indicate that there is no primary deuterium isotope effect with L-serine 2-D. The results suggest there is no rate limitation by abstraction of the alpha proton of L-serine in the SGAT reaction. In the steady-state a solvent deuterium isotope effect of about 2 was measured on (V/K)L-serine and (V/K)ketomalonate and about 5.5 on V. Similar solvent isotope effects were observed in the pre-steady-state for the natural substrates and the alternative substrate ketomalonate. In the pre-steady-state, no reaction intermediates typical of PLP enzymes were observed with the substrates L-serine, glyoxylate, and hydroxypyruvate. The data suggest that breakdown and formation of the ketimine intermediate is the primary rate-limiting step with the natural substrates. In contrast, using the alternative substrate ketomalonate, pre-steady-state experiments display the transient formation of a 490 nm absorbing species typical of a quinonoid intermediate. The solvent isotope effect results also suggest that with ketomalonate as substrate protonation at C(alpha) is the slowest step in the SGAT reaction. This is the first report of a rate-limiting protonation of a quinonoid at C(alpha) of the external Schiff base in an aminotransferase reaction.

Crystallization and preliminary X-ray crystallographic studies of dissimilatory nitrite reductase isolated from Hyphomicrobium denitrificans A3151.

Dissimilatory nitrite reductase isolated from Hyphomicrobium denitrificans A3151 (HdNIR) is a novel copper-containing nitrite reductase (CuNIR) composed of six identical subunits. One plastocyanin-like domain and one green CuNIR-like domain are connected to each other, suggesting that the HdNIR subunit structure resembles a complex of green CuNIR and pseudoazurin (or azurin). Recombinant HdNIR protein was crystallized using the hanging-drop vapour-diffusion method with PEG 4000 as the precipitant at pH 8.9. X-ray diffraction data were collected to 2.35 A resolution. The HdNIR crystal belonged to the tetragonal space group P4(1) (or P4(3)), with unit-cell parameters a = b = 221.9, c = 165.2 A, giving 12 molecules (two hexamers) per asymmetric unit and a solvent content of 64%. A mutant form of HdNIR, C260A, which lacks the type I copper ion in the CuNIR-like domain, was prepared and crystallized under wild-type HdNIR conditions. The C260A mutant crystal belonged to the cubic space group P4(3)32 (or P4(1)32), with unit-cell parameters a = b = c = 153.7 A, giving one molecule per asymmetric unit and a solvent content of 59%. X-ray diffraction data were collected to 3.5 A resolution. To solve the crystal structure of HdNIR, the multiwavelength anomalous dispersion (MAD) method and the molecular-replacement method are currently being used.

Characterization of two type 1 Cu sites of Hyphomicrobium denitrificans nitrite reductase: a new class of copper-containing nitrite reductases.

We report (1) the amino acid sequence of Hyphomicrobium denitrificans nitrite reductase (HdNIR), containing two type 1 Cu sites and one type 2 Cu site; (2) the expression and preparation of wild-type HdNIR and two mutants replacing the Cys ligand of each type 1 Cu with Ala; and (3) their spectroscopic and functional characterization. The open-reading frame of 50-kDa HdNIR is composed of the 15-kDa N-terminal domain having a type 1 Cu-binding motif like cupredoxins and the 35-kDa C-terminal domain having type 1 Cu-binding and type 2 Cu-binding motifs such as common nitrite reductases (NIRs). Moreover, the amino acid sequences of the N- and C-terminal domains are homologous to those of plastocyanins and NIRs, respectively. The point mutation of the Cys ligand of each type 1 Cu with Ala gives two mutants, C114A and C260A, possessing one type 1 Cu and one type 2 Cu. The spectroscopic data of C114A reveal that the C-terminal NIR-like domain has the green type 1 Cu (type 1 Cu(C)), showing two intense absorption peaks at 455 (epsilon = 2600 M(-1) cm(-1)) and 600 nm (epsilon = 2800 M(-1) cm(-1)) and a rhombic EPR signal like those of the green type 1 Cu of Achromobacter cycloclastes NIR (AcNlR). The spectroscopic data of C260A elucidate that the N-terminal Pc-like domain in HdNIR contains the blue type 1 Cu (type 1 Cu(N)), exhibiting an intense absorption band at 605 nm (epsilon = 2900 M(-1) cm(-1)) and an axial EPR signal like those of the blue type 1 Cu of Alcaligenes xylosoxidans NIR (AxNIR). The sum of the visible absorption or EPR spectra of C114A and C260A is almost equal to the corresponding spectrum of wild-type HdNIR. The spectroscopic characterization of the type 1 Cu indicates that the geometries of the type 1 Cu(N) and Cu(C) sites are slightly distorted tetrahedral (or axially elongated bipyramidal) and flattened tetrahedral, respectively. In the cyclic voltammograms, the midpoint potentials (E(1/2)), probably because of the type 1 Cu ions of C114A and C260A, are observed at +321 and +336 mV versus normal hydrogen electrode (NHE) at pH 7.0, respectively. These values, which are close to each other, are more positive than those ( approximately +0.24-0.28 V at pH 7.0) of the type 1 Cu sites of AcNIR and AxNIR. The electron-accepting capability of C114A from cytochrome c(550) is almost similar to that of wild-type HdNIR, whereas that of C260A is very low. This suggests that the type 1 Cu(C) in the C-terminal domain is essential for the enzyme functions of HdNIR.

Relations and functions of dye-linked formaldehyde dehydrogenase from Hyphomicrobium zavarzinii revealed by sequence determination and analysis.

faoA, the gene of the dye-linked NAD(P)-independent quinone-containing formaldehyde dehydrogenase of methylamine-grown Hyphomicrobium zavarzinii strain ZV 580 was sequenced and analyzed together with an apparent promoter region and adjoining genes in a 7.2-kb fragment of hyphomicrobial DNA. The formaldehyde dehydrogenase, identified as a periplasmic enzyme by its signal sequence, is distantly related to the soluble pyrroloquinoline-quinone-dependent glucose dehydrogenase of Acinetobacter calcoaceticus and to other predicted glucose dehydrogenase sequences. The promoter region, containing about 400 nucleotides upstream of faoA, comprised potential binding sites identical or highly similar to known consensus sequences of the sigma factors sigma(70) (housekeeping), sigma(H) (heat shock), sigma(F) (flagellar) and sigma(N) (nitrogen). The complex regulation of the transcription of faoA, which is suggested by this setting and emphasized by a possible heat-shock promoter, supports a hypothesis proposing an auxiliary role of the enzyme in lowering detrimental elevated concentrations of formaldehyde, which might arise in the course of stress or regulatory transitions disturbing balanced C(1) metabolism.