Gene Structure and Expression Profile of Cytochrome bc Nitric Oxide Reductase from Hydrogenobacter thermophilus TK-6

The genes for a nitric oxide reductase-like cytochrome bc complex were cloned from a thermophilic, chemolithoautotrophic hydrogen-oxidizing bacterium, Hydrogenobacter thermophilus TK-6. The structural genes norC and norB, which encode cytochrome c and cytochrome b subunits of the complex respectively, are probably transcribed as a tricistronic operon with a following gene encoding a putative membrane protein. NorC has, unusually, two hydrophobic transmembrane spans in its N-terminus. Immunoblot analysis showed that expression of NorC was induced by nitrate, nitrite, or sodium nitropurusside, suggesting that the norCB gene product is a denitrification enzyme, nitric oxide reductase. The consensus sequences for the DNR/NnrR-type or the NorR/FhpR-type nitric oxide-sensing regulators of proteobacteria were not found in the norC promoter region, but consensus ?35 and ?10 sequences were found in this region. These results indicate that strain TK-6 has a nitrogen oxide-sensing regulatory system that differs from proteobacterial systems.     

Nitrosylation of c heme in cd1-nitrite reductase is enhanced during catalysis

The reduction of nitrite into nitric oxide (NO) in denitrifying bacteria is catalyzed by nitrite reductase. In several species, this enzyme is a heme-containing protein with one c heme and one d₁ heme per monomer (cd₁NiR), encoded by the nirS gene.     

Isolation,sequencing and mutational analysis of a gene cluster involved in nitrite reduction inParacoccus denitrificans

By using the gene encoding the C-terminal part of thecd ₁-type nitrite reductase ofPseudomonas stutzeri JM300 as a heterologous probe, the corresponding gene fromParacoccus denitrificans was isolated. This gene,nirS, codes for a mature protein of 63144 Da having high homology withcd ₁-type nitrite reductases from other bacteria. Directly downstream fromnirS, three othernir genes were found in the ordernirECF. The organization of thenir gene cluster inPa. denitrificans is different from the organization ofnir clusters in some Pseudomonads.nirE has high homology with a S-adenosyl-L-methionine:uroporphyrinogen III methyltransferase (uro'gen III methylase). This methylase is most likely involved in the hemed ₁ biosynthesis inPa. denitrificans. The third gene,nirC, codes for a small cytochromec of 9.3 kDa having high homology with cytochromec _55X ofPs. stutzeri ZoBell. The 4th gene,nirF, has no homology with other genes in the sequence databases and has no relevant motifs. Inactivation of either of these 4 genes resulted in the loss of nitrite and nitric oxide reductase activities but not of nitrous oxide reductase activity.nirS mutants lack thecd ₁-type nitrite reductase whilenirE, nirC andnirF mutants produce a small amount ofcd ₁-type nitrite reductase, inactive due to the absence of hemed ₁. Upstream from thenirS gene the start of a gene was identified which has limited homology withnosR, a putative regulatory gene involved in nitrous oxide reduction. A potential FNR box was identified between this gene andnirS.Abbreviations SDS sodium dodecyl sulfate - NBT nitroblue tetrazolium - PAGE polyacrylamide gel electrophoresis     

Parallel Pathways for Nitrite Reduction during Anaerobic Growth in Thermus thermophilus

Respiratory reduction of nitrate and nitrite is encoded in Thermus thermophilus by the respective transferable gene clusters. Nitrate is reduced by a heterotetrameric nitrate reductase (Nar) encoded along transporters and regulatory signal transduction systems within the nitrate respiration conjugative element (NCE). The nitrite respiration cluster (nic) encodes homologues of nitrite reductase (Nir) and nitric oxide reductase (Nor). The expression and role of the nirSJM genes in nitrite respiration were analyzed. The three genes are expressed from two promoters, one (nirSp) producing a tricistronic mRNA under aerobic and anaerobic conditions and the other (nirJp) producing a bicistronic mRNA only under conditions of anoxia plus a nitrogen oxide. As for its nitrite reductase homologues, NirS is expressed in the periplasm, has a covalently bound heme c, and conserves the heme d₁ binding pocket. NirJ is a cytoplasmic protein likely required for heme d₁ synthesis and NirS maturation. NirM is a soluble periplasmic homologue of cytochrome c₅₅₂. Mutants defective in nirS show normal anaerobic growth with nitrite and nitrate, supporting the existence of an alternative Nir in the cells. Gene knockout analysis of different candidate genes did not allow us to identify this alternative Nir protein but revealed the requirement for Nar in NirS-dependent and NirS-independent nitrite reduction. As the likely role for Nar in the process is in electron transport through its additional cytochrome c periplasmic subunit (NarC), we concluded all the Nir activity takes place in the periplasm by parallel pathways.     

Alternative pathways of nitric oxide formation in Lactobacilli: Evidence for nitric oxide synthase activity by EPR

The study of the ability of Lactobacillus plantarum 8P-A3 to synthesize nitric oxide (NO) showed that this strain lacks nitrite reductase. However, analysis by the EPR method revealed the presence of nitric oxide synthase activity in this strain. Like mammalian nitric oxide synthase, lactobacillar NO synthase is involved in the formation of nitric oxide from L-arginine. L. plantarum 8P-A3 does not produce NO in the denitrification process. The regulatory role of NO in symbiotic bacteria is emphasixed.     

Pseudomonas aeruginosa and Achromobacter sp.: nitrifying aerobic denitrifiers have a plasmid encoding for denitrifying functional genes

In the present work, novel heterotrophic nitrifying and aerobic denitrifying bacteria have been isolated from greenwater system of coastal aquaculture. Based on the 16S rRNA gene, FAME analysis and biochemical test, the isolates have been identified as Pseudomonas aeruginosa and Achromobacter sp. These have been named as P. aeruginosa strain DBT1BNH3 and Achromobacter sp. strain DBTN3. Denitrifying functional genes such as nitrite reductase (nirS), nitric oxide reductase (qnorB) and nitrous oxide reductase (nosZ) genes have been identified. These strains found to have a 27 kb plasmid coding for nirS and nosZ. The possibility of horizontal transfer of plasmid among Pseudomonadaceae and Alcaligenaceae families in coastal aquaculture has been explored. Further, we have studied combined nitrification and oxygen tolerant denitrification potential in the same isolates.     

Nitric oxide reduction, the last step in denitrification by Fusarium oxysporum, is obligatorily mediated by cytochrome P450nor

The involvement of cytochrome P450nor (P450nor) is the most striking feature of the fungal denitrifying system, and has never been shown in bacterial systems. To establish the physiological significance of the P450nor, we constructed and investigated mutants of Fusarium oxysporum that lacked the gene for P450nor. We mutated the gene by targeted integration of a disrupted gene into the chromosome of F. oxysporum. The mutants were shown to contain neither P450nor protein nor nitric oxide (NO) reductase (Nor) activity, implying that they are indeed deficient in P450nor. These mutants had apparently lost the denitrifying activity and failed to evolve nitrous oxide (N₂O) upon incubation under oxygen-limiting conditions in the presence of nitrate. Their mycelia exhibited normal levels of dissimilatory nitrite reductase (Nir) activity and were able to evolve NO under these conditions. The promoter region of the P450nor gene was fused to lacZ and introduced into the wild-type strain of F. oxysporum. The transformed strain produced β-galactosidase under denitrifying conditions as efficiently as the wild type does P450nor. These results represent unequivocal genetic evidence that P450nor is essential for the reduction of NO to N₂O, the last step in denitrification by F. oxysporum. Received: 28 June 1999 / Accepted: 22 December 1999     

Defects in cytochrome cd 1-dependent nitrite respiration of transposon Tn5-induced mutants from Pseudomonas stutzeri

Mutants with defective respiratory nitrite utilization (Nir^- phenotype) were obtained by transposon Tn5 insertion into genomic DNA of the ZoBell strain of Pseudomonas stutzeri. Three representative mutants were characterized with respect to their activities of nitrite and nitric oxide reduction, cytochrome cd ₁ content, and pattern of soluble c-type cytochromes. Mutant strain MK201 over-produced cytochrome c ₅₅₂ about fourfold by comparison with the wild type, but possessed an in vitro functional cytochrome cd ₁. Mutant strain MK202 lacked cytochrome cd ₁ and, simultaneously, had low amounts of cytochrome c ₅₅₂ and the split -peak c-type cytochrome. Strain MK203 synthesized nitrite reductase defective in the heme d ₁ prosthetic group. Irrespective of these biochemically distinct Nir^- phenotypes, all mutants preserved the nitric oxidereducing capability of the wild type. The mutant characteristics demonstrate that cytochrome cd ₁ is essential for nitrite respiration of P. stutzeri and establish the presence of a nitric oxide-reducing system distinct from cytochrome cd ₁. They also indicate the functional or regulatory interdependence of c-type cytochromes.     

Use of a Green Fluorescent Protein-Based Reporter Fusion for Detection of Nitric Oxide Produced by Denitrifiers

To determine if green fluorescent protein could be used as a reporter for detecting nitric oxide production, gfp was fused to nnrS from Rhodobacter sphaeroides 2.4.3. nnrS was chosen because its expression requires nitric oxide. The presence of the fusion in R. sphaeroides 2.4.3 resulted in a significant increase in fluorescent intensity of the cells, but only when nitrite reductase was active. Cells lacking nitrite reductase activity and consequently the ability to generate nitric oxide were only weakly fluorescent when grown under denitrification-inducing conditions. One of the R. sphaeroides strains unable to generate nitric oxide endogenously was used as a reporter to detect exogenously produced nitric oxide. Incubation of this strain with sodium nitroprusside, a nitric oxide generator, significantly increased its fluorescence intensity. Mixing of known denitrifiers with the reporter strain also led to significant increases in fluorescence intensity, although the level varied depending on the denitrifier used. The reporter was tested on unknown isolates capable of growing anaerobically in the presence of nitrate, and one of these was able to induce expression of the fusion. Analysis of the 16S rRNA gene sequence of this isolate placed it within the Thauera aromatica subgroup, which is known to contain denitrifiers. These experiments demonstrate that this green fluorescent protein-based assay provides a useful method for assessing the ability of bacteria to produce nitric oxide.     

Higher diversity and abundance of denitrifying microorganisms in environments than considered previously

Denitrification is an important process in the global nitrogen cycle. The genes encoding NirK and NirS (nirK and nirS), which catalyze the reduction of nitrite to nitric oxide, have been used as marker genes to study the ecological behavior of denitrifiers in environments. However, conventional polymerase chain reaction (PCR) primers can only detect a limited range of the phylogenetically diverse nirK and nirS. Thus, we developed new PCR primers covering the diverse nirK and nirS. Clone library and qPCR analysis using the primers showed that nirK and nirS in terrestrial environments are more phylogenetically diverse and 2–6 times more abundant than those revealed with the conventional primers. RNA- and culture-based analyses using a cropland soil also suggested that microorganisms with previously unconsidered nirK or nirS are responsible for denitrification in the soil. PCR techniques still have a greater capacity for the deep analysis of target genes than PCR-independent methods including metagenome analysis, although efforts are needed to minimize the PCR biases. The methodology and the insights obtained here should allow us to achieve a more precise understanding of the ecological behavior of denitrifiers and facilitate more precise estimate of denitrification in environments.     

Close linkage in Pseudomonas stutzeri of the structural genes for respiratory nitrite reductase and nitrous oxide reductase, and other essential genes for denitrification

Summary The structural gene, nirS, for the respiratory nitrite reductase (cytochrome cd ₁) from Pseudomonas stutzeri was identified by (i) sequencing of the N-terminus of the purified protein and partial sequencing of the cloned gene, (ii) immunoscreening of clones from a lambda gt11 expression library, (iii) mapping of the transposon Tn5 insertion site in the nirS mutant strain MK202, and (iv) complementation of strain MK202 with a plasmid carrying the insert from an immunopositive lambda clone. A mutation causing overproduction of cytochrome c ₅₅₂ mapped on the same 8.6 kb EcoRI fragment within 1.7 kb of the mutation affecting nirS. Two mutations affecting nirD, which cause the synthesis of an inactive cytochrome cd ₁ lacking heme d ₁, mapped 1.1 kb apart within a 10.5 kb EcoRI fragment contiguous with the fragment carrying nirS. Nir^– mutants of another type that had low level synthesis of cytochrome cd ₁, had Tn5 insertions within an 11 kb EcoRI fragment unlinked to the nirS ⁺ and nirD ⁺ fragments. Cosmid mapping provided evidence that nirS and nirD, and the previously identified gene cluster for nitrous oxide respiration are closely linked. The nirS gene and the structural gene for nitrous oxide reductase, nosZ, are transcribed in the same direction and are separated by approximately 14 kb. Several genes for copper processing are located within the intervening region.     

An integrated network analysis reveals that nitric oxide reductase prevents metabolic cycling of nitric oxide by Pseudomonas aeruginosa

Nitric oxide (NO) is a chemical weapon within the arsenal of immune cells, but is also generated endogenously by different bacteria. Pseudomonas aeruginosa are pathogens that contain an NO-generating nitrite (NO₂⁻) reductase (NirS), and NO has been shown to influence their virulence. Interestingly, P. aeruginosa also contain NO dioxygenase (Fhp) and nitrate (NO₃⁻) reductases, which together with NirS provide the potential for NO to be metabolically cycled (NO→NO₃⁻→NO₂⁻→NO). Deeper understanding of NO metabolism in P. aeruginosa will increase knowledge of its pathogenesis, and computational models have proven to be useful tools for the quantitative dissection of NO biochemical networks. Here we developed such a model for P. aeruginosa and confirmed its predictive accuracy with measurements of NO, O₂, NO₂⁻, and NO₃⁻ in mutant cultures devoid of Fhp or NorCB (NO reductase) activity. Using the model, we assessed whether NO was metabolically cycled in aerobic P. aeruginosa cultures. Calculated fluxes indicated a bottleneck at NO₃⁻, which was relieved upon O₂ depletion. As cell growth depleted dissolved O₂ levels, NO₃⁻ was converted to NO₂⁻ at near-stoichiometric levels, whereas NO₂⁻ consumption did not coincide with NO or NO₃⁻ accumulation. Assimilatory NO₂⁻ reductase (NirBD) or NorCB activity could have prevented NO cycling, and experiments with ΔnirB, ΔnirS, and ΔnorC showed that NorCB was responsible for loss of flux from the cycle. Collectively, this work provides a computational tool to analyze NO metabolism in P. aeruginosa, and establishes that P. aeruginosa use NorCB to prevent metabolic cycling of NO.     

Selection and organisation of denitrifying electron-transfer pathways in Paracoccus denitrificans

(1) Under anaerobic conditions the respiratory chain in cells of Paracoccus denitrificans, from late exponential cultures grown anaerobically with nitrate as electron acceptor and succinate as carbon source, has been shown to reduce added nitrate via nitrite and nitrous oxide to nitrogen without any accumulation of these intermediates. (2) Addition of nitrous oxide to cells reducing nitrate strongly inhibited the latter reaction. The inhibition was reversed by preventing electron flow to nitrous oxide with either antimycin or acetylene. Electron flow to nitrous oxide thus resembles electron flow to oxygen in its inhibitory effect on nitrate reduction. In contrast, addition of nitrite to an anaerobic suspension of cells reducing nitrate resulted in a stimulation of nitrate reductase activity. Usually, addition of nitrite also partially overcame the inhibitory effect of nitrous oxide on nitrate reduction. The reason why added nitrous oxide, but not nitrite, inhibits nitrate reduction is suggested to be related to the higher reductase activity of the cells for nitrous oxide compared with nitrite. Explanations for the unexpected stimulation of nitrate reduction by nitrite in the presence or absence of added nitrous oxide are considered. (3) Nitrous oxide reductase was shown to be a periplasmic protein that competed with nitrite reductase for electrons from reduced cytochrome c. Added nitrous oxide strongly inhibited the reduction of added nitrite. (4) Nitrite reductase activity of cells was strongly inhibited by oxygen in the presence of physiological reductants, but nitrite reduction did occur in the presence of oxygen when isoascorbate plus N,N,N′,N′-tetramethyl-p-phenylenediamine was the reductant. It is concluded that competition for available electrons by two oxidases, cytochrome aa₃ and cytochrome o, severely restricted electron flow to the nitrite reductase (cytochrome cd). For this reason it is unlikely that the oxidase activity of this cytochrome is ever functional in cells. (5) The mechanism by which electron flow to oxygen or nitrous oxide inhibits nitrate reduction in cells has been investigated. It is argued that relatively small changes in the extent of reduction of ubiquinone, or of another component of the respiratory chain with similar redox potential, critically determine the capacity for reducing nitrate. The argument is based on: (i) the response of an anthroyloxystearic acid fluorescent probe that is sensitive to changes in the oxidation state of ubiquinone; (ii) consideration of the total rates of electron flow through ubiquinone both in the presence of oxygen and in the presence of nitrate under anaerobic conditions; (iii) use of relative extents of oxidation of b-type cytochromes as an indicator of ubiquinone redox state, especially the finding that b-type cytochrome of the antimycin-sensitive part of the respiratory chain is more oxidised in the presence of added nitrous oxide, which inhibits nitrate reduction, than in the presence of added nitrite which does not inhibit. Arguments against b- or c-type cytochromes themselves controlling nitrate reduction are given. (6) In principle, control on nitrate reduction could be exerted either upon electron flow or upon the movement of nitrate to the active site of its reductase. The observations that inverted membrane vesicles and detergent-treated cells reduced nitrate and oxygen simultaneously at a range of total rates of electron flow are taken to support the latter mechanism. The failure of an additional reductant, durohydroquinone, to activate nitrate reduction under aerobic conditions in the presence of succinate is also evidence that it is not an inadequate supply of electrons that prevents the functioning of nitrate reductase under aerobic conditions. (7) In inverted membrane vesicles the division of electron flow between nitrate and oxygen is determined by a competition mechanism, in contrast to cells. This change in behaviour upon converting cells to vesicles cannot be attributed to loss of cytochrome c, and therefore of oxidase activity, from the vesicles because a similar change in behaviour was seen with vesicles prepared from cells of a cytochrome c-deficient mutant.     

Nitrite-reducing ability is related to growth inhibition by nitrite in Rhodobacter sphaeroides f. sp. denitrificans

Growth inhibition of Rhodobacter sphaeroides f. sp. denitrificans IL106 by nitrite under anaerobic-light conditions became less pronounced when the gene encoding nitrite reductase was deleted. Growth of another deletion mutant of the genes encoding nitric oxide reductase was severely suppressed by nitrite. Our results suggest that nitrite reductase increases the sensitivity to nitrite through the production of nitric oxide.     

Solubilization and resolution of the membrane-bound nitrite reductase from Paracoccus halodenitrificans into nitrite and nitric oxide reductases

Membranes prepared from Paracoccus halodenitrificans reduced nitrite or nitric oxide to nitrous oxide. Extraction of these membranes with the detergent CHAPSO [3-(3-cholamidopropyldimethylammonio)-1-(2-hydroxy-1-propanesulfonate)], followed by ammonium sulfate fractionation of the solubilized proteins, resulted in the separation of nitrite and nitric oxide reductase activities. The fraction containing nitrite reductase activity spectrally resembled a cd-type cytochrome. Several cytochromes were detected in the nitric oxide reductase fraction. Which, if any, of these cytochromes is associated with the reduction of nitric oxide is not clear at this time.Abbreviations PMS phenazine methosulfate - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - CHAPSO 3-(3-cholamidopropyl-dimethylammonio)-1-(2-hydroxy-1-propanesulfonate) - NH buffer 150 mM NaCl-50 mM - HEPES pH 7.5; octylglucoside, octyl--d glucopyranoside - NIR intrite reductase (nitrite to nitric oxide) - NOR nitric oxide reductase (nitric oxide to nitrous oxide)     

Presence of Two Different Active nirS Nitrite Reductase Genes in a Denitrifying Thauera sp. from a High-Nitrate-Removal-Rate Reactor

The nirS nitrite reductase genes were studied in two strains (strains 27 and 28) isolated from two denitrifying reactors and characterized as Thauera according to their 16S rRNA gene sequences. Strain 28 contains a single nirS sequence, which is related to the nirS of Thauera mechernichensis, and strain 27 contains two nirS sequences; one is similar to the nirS sequence from Thauera mechernichensis (gene 2), but the second one (gene 8) is from a separate clade with nirS from Pseudomonas stutzeri, Azoarcus species, Alcaligenes faecalis, and other Thauera species. Both genes were expressed, but gene 8 was constitutively expressed while gene 2 was positively regulated by nitrate.     

Role of norEF in Denitrification,Elucidated by Physiological Experiments with Rhodobacter sphaeroides

Many denitrifying organisms contain the norEF gene cluster, which codes for two proteins that are thought to be involved in denitrification because they are expressed during the reduction of nitrite and nitric oxide. The products of both genes are predicted to be membrane associated, and the norE product is a member of the cytochrome c oxidase subunit III family. However, the specific role of norEF is unknown. The denitrification phenotypes of Rhodobacter sphaeroides strains with and without norEF genes were studied, and it was found that loss of norEF lowered the rate of denitrification from nitrate and resulted in accumulation of micromolar concentrations of nitric oxide during denitrification from nitrite. norEF appears to have no direct role in the reduction of nitric oxide; however, since deletion of norEF in the wild-type 2.4.3 strain had essentially no influence on the kinetics of potential nitric oxide reduction (V_max and K_s), as measured by monitoring the depletion of a bolus of nitric oxide injected into anoxic cultures without any other electron acceptors. However, norEF-deficient cells that had undergone a more chronic exposure to micromolar concentrations of nitric oxide showed an ∼50% reduction in V_max but no change in apparent K_s. These results can explain the occurrence of norEF in the 2.4.3 strain of R. sphaeroides, which can reduce nitrate to nitrous oxide, and their absence from strains such as 2.4.1, which likely use nitric oxide reductase to mitigate stress due to episodic exposure to nitric oxide from exogenous sources.