Diversity of nitrite reductase (nirK and nirS) gene fragments in forested upland and wetland soils

The genetic heterogeneity of nitrite reductase gene (nirK and nirS) fragments from denitrifying prokaryotes in forested upland and marsh soil was investigated using molecular methods. nirK gene fragments could be amplified from both soils, whereas nirS gene fragments could be amplified only from the marsh soil. PCR products were cloned and screened by restriction fragment length polymorphism (RFLP), and representative fragments were sequenced. The diversity of nirK clones was lower than the diversity of nirS clones. Among the 54 distinct nirK RFLP patterns identified in the two soils, only one pattern was found in both soils and in each soil two dominant groups comprised >35% of all clones. No dominance and few redundant patterns were seen among the nirS clones. Phylogenetic analysis of deduced amino acids grouped the nirK sequences into five major clusters, with one cluster encompassing most marsh clones and all upland clones. Only a few of the nirK clone sequences branched with those of known denitrifying bacteria. The nirS clones formed two major clusters with several subclusters, but all nirS clones showed less than 80% identity to nirS sequences from known denitrifying bacteria. Overall, the data indicated that the denitrifying communities in the two soils have many members and that the soils have a high richness of different nir genes, especially of the nirS gene, most of which have not yet been found in cultivated denitrifiers.     

奇古菌亚硝酸盐还原酶基因相似基因的多样性

摘要:【目的】氨氧化古菌(Ammonia-oxidizing archaea,AOA)是奇古菌门中的唯一类群,广泛分布于各个生态系统中,对氮素生物地球化学循环起着重要作用。亚硝酸还原酶是反硝化作用的关键酶,目前关于AOA反硝化作用的研究较少,对AOA 亚硝酸盐还原酶基因多样性的研究有利于揭示AOA在反硝化中的作用。【方法】本研究以水体、沉积物和土壤为研究对象,构建了奇古菌样的nirK基因克隆文库,研究了这些环境中nirK相似基因的多样性。【结果】对奇古菌样的nirK基因文库及其序列分析表明:湖水及其沉积物的 nirK基因克隆文库得到10个OTUs,菜田土壤和水样则有8个OTUs;系统发育进化树表明这些nirK氨基酸序列和Candidatus Nitrosopumilus koreensis AR1,Nitrosopumilus maritimus SCM1最为相似,但相似度较低(53%－68%)。克隆文库多样性指数分析表明:所有样品都存在不同类型的nirK基因,水体样品nirK基因类型的多样性和均匀度高于土壤样品,菜田土壤的nirK基因类型多样性最高,分布最均匀。【结论】本研究表明土壤和淡水环境中奇古菌门nirK基因也具有较高的多样性,并且这些基因型与海洋样品差异非常大,这些基因编码的亚硝酸盐还原酶可能对这些环境中的反硝化作用有重要意义。     

Diversity,abundance and expression of nitrite reductase (nirK)-like genes in marine thaumarchaea

Ammonia-oxidizing archaea (AOA) are widespread and abundant in aquatic and terrestrial habitats and appear to have a significant impact on the global nitrogen cycle. Like the ammonia-oxidizing bacteria, AOA encode a gene homologous to copper-containing nitrite reductases (nirK), which has been studied very little to date. In this study, the diversity, abundance and expression of thaumarchaeal nirK genes from coastal and marine environments were investigated using two mutually excluding primer pairs, which amplify the nirK variants designated as AnirKa and AnirKb. Only the AnirKa variant could be detected in sediment samples from San Francisco Bay and these sequences grouped with the nirK from Candidatus Nitrosopumilus maritimus and Candidatus Nitrosoarchaeum limnia. The two nirK variants had contrasting distributions in the water column in Monterey Bay and the California Current. AnirKa was more abundant in the epi- to mesopelagic Monterey Bay water column, whereas AnirKb was more abundant in the meso- to bathypelagic California Current water. The abundance and community composition of AnirKb, but not AnirKa, followed that of thaumarchaeal amoA, suggesting that either AnirKa is not exclusively associated with AOA or that commonly used amoA primers may be missing a significant fraction of AOA diversity in the epipelagic. Interestingly, thaumarchaeal nirK was expressed 10–100-fold more than amoA in Monterey Bay. Overall, this study provides valuable new insights into the distribution, diversity, abundance and expression of this alternative molecular marker for AOA in the ocean.     

Analysis of nitrite reductase (nirK and nirS) genes and cultivation reveal depauperate community of denitrifying bacteria in the Black Sea suboxic zone

Chemical profiles of the Black Sea suboxic zone show a distribution of nitrogen species which is traditionally associated with denitrification, i.e. a secondary nitrite maximum associated with nitrate depletion and a N(2) gas peak. To better understand the distribution and diversity of the denitrifier community in the Black Sea suboxic zone, we combined a cultivation approach with cloning and sequencing of PCR-amplified nitrite reductase (nirS and nirK) genes. The Black Sea suboxic zone appears to harbour a homogeneous community of denitrifiers. For nirK, over 94% of the sequences fell into only three distinct phylogenetic clusters, and for nirS, a single closely related sequence type accounted for 91% of the sequences retrieved. Both nirS and nirK genes showed a dramatic shift in community composition at the bottom of the suboxic zone, but overall, nirK-based community composition showed much greater variation across depths compared with the highly uniform distribution of nirS sequences throughout the suboxic zone. The dominant nirK and nirS sequences differed at the amino acid level by at least 17% and 8%, respectively, from their nearest database matches. Denitrifying isolates recovered from the suboxic zone shared 97% 16S rRNA gene sequence similarity with Marinobacter maritimus. Analysis of the recently discovered nirS gene from the anammox bacterium Candidatus'Kuenenia stuttgartiensis' revealed that mismatches with commonly used primers may have prevented the previous detection of this divergent sequence.     

Molecular diversity and characterization of nitrite reductase gene fragments (nirK and nirS) from nitrate- and uranium-contaminated groundwater

Nitrate-contaminated groundwater samples were analysed for nirK and nirS gene diversity. The samples differed with respect to nitrate, uranium, heavy metals, organic carbon content, pH and dissolved oxygen levels. A total of 958 nirK and 1162 nirS clones were screened by restriction fragment length polymorphism (RFLP) analysis: 48 and 143 distinct nirK and nirS clones, respectively, were obtained. A single dominant nirK restriction pattern was observed for all six samples and was 83% identical to the Hyphomicrobium zavarzinii nirK gene. A dominant nirS pattern was observed for four of the samples, including the background sample, and was 95% identical to the nirS of Alcaligenes faecalis. Diversity indices for nirK and nirS sequences were not related to any single geochemical characteristic, but results suggested that the diversity of nirK genes was inversely proportional to the diversity of nirS. Principal component analysis (PCA) of the sites based on geochemistry grouped the samples by low, moderate and high nitrate but PCA of the unique operational taxonomic units (OTUs) distributions grouped the samples differently. Many of the sequences were not closely related to previously observed genes and some phylogenetically related sequences were obtained from similar samples. The results indicated that the contaminated groundwater contained novel nirK and nirS sequences, functional diversity of both genes changed in relation to the contaminant gradient, but the nirK and nirS functional diversity was affected differently.     

Phylogeny of nitrite reductase (nirK) and nitric oxide reductase (norB) genes from Nitrosospira species isolated from soil

Ammonia-oxidizing bacteria are believed to be an important source of the climatically important trace gas nitrous oxide (N(2)O). The genes for nitrite reductase (nirK) and nitric oxide reductase (norB), putatively responsible for nitrous oxide production, have been identified in several ammonia-oxidizing bacteria, but not in Nitrosospira strains that may dominate ammonia-oxidizing communities in soil. In this study, sequences from nirK and norB genes were detected in several cultured Nitrosospira species and the diversity and phylogeny of these genes were compared with those in other ammoniaoxidizing bacteria and in classical denitrifiers. The nirK and norB gene sequences obtained from Nitrosospira spp. were diverse and appeared to be less conserved than 16S rRNA genes and functional ammonia monooxygenase (amoA) genes. The nirK and norB genes from some Nitrosospira spp. were not phylogenetically distinct from those of denitrifiers, and phylogenetic analysis suggests that the nirK and norB genes in ammonia-oxidizing bacteria have been subject to lateral transfer.     

PCR detection of nitrite reductase genes (nirK and nirS) and use of active consortia of constructed ternary adherent staphylococcal cultures via mixture design for a denitrification process

In this study, three adherent Staphylococcus strains able to use nitrate as electron acceptor were isolated from textile wastewater activated sludge. Based on the biochemical profiles, bacterial strains were identified as Staphylococcus lentus, Staphylococcus warneri and Staphylococcus epidermidis the PCR amplification of the nir genes reveal that S. lentus and S. epidermidis were nirK positive and that S. epidermidis was nirS positive. The three strains were also icaA/icaD positive. To obtain the optimal formulation of pure cultures of the staphylococci, the influence of the different mixtures of organisms was studied using mixture design. The regression model of microorganism composition and main metabolites was established. The most predictable reduction of nitrate was 87.2 and 12% of COD consumption. The results suggested that the predictable production of nitrite would reach a minimum of 6.1 mg/l. Based on this, the response values that satisfied all expectations were optimized using MINITAB^® 14 analysis software. The most optimal proportion combination was 49.75% of S. lentus (curve value), 36.85% of S. warneri (curve value) and 13.39% S. epidermidis (curve value).     

Diversity of Nitrite Reductase (nirK and nirS) Gene Fragments in Forested Upland and Wetland Soils

The genetic heterogeneity of nitrite reductase gene (nirK and nirS) fragments from denitrifying prokaryotes in forested upland and marsh soil was investigated using molecular methods. nirK gene fragments could be amplified from both soils, whereas nirS gene fragments could be amplified only from the marsh soil. PCR products were cloned and screened by restriction fragment length polymorphism (RFLP), and representative fragments were sequenced. The diversity of nirK clones was lower than the diversity of nirS clones. Among the 54 distinct nirK RFLP patterns identified in the two soils, only one pattern was found in both soils and in each soil two dominant groups comprised >35% of all clones. No dominance and few redundant patterns were seen among the nirS clones. Phylogenetic analysis of deduced amino acids grouped the nirK sequences into five major clusters, with one cluster encompassing most marsh clones and all upland clones. Only a few of the nirK clone sequences branched with those of known denitrifying bacteria. The nirS clones formed two major clusters with several subclusters, but all nirS clones showed less than 80% identity to nirS sequences from known denitrifying bacteria. Overall, the data indicated that the denitrifying communities in the two soils have many members and that the soils have a high richness of different nir genes, especially of the nirS gene, most of which have not yet been found in cultivated denitrifiers.     

Nitrite reductase genes (nirK and nirS) as functional markers to investigate diversity of denitrifying bacteria in pacific northwest marine sediment communities

Genetic heterogeneity of denitrifying bacteria in sediment samples from Puget Sound and two sites on the Washington continental margin was studied by PCR approaches amplifying nirK and nirS genes. These structurally different but functionally equivalent single-copy genes coding for nitrite reductases, a key enzyme of the denitrification process, were used as a molecular marker for denitrifying bacteria. nirS sequences could be amplified from samples of both sampling sites, whereas nirK sequences were detected only in samples from the Washington margin. To assess the underlying nir gene structure, PCR products of both genes were cloned and screened by restriction fragment length polymorphism (RFLP). Rarefraction analysis revealed a high level of diversity especially for nirS clones from Puget Sound and a slightly lower level of diversity for nirK and nirS clones from the Washington margin. One group dominated within nirK clones, but no dominance and only a few redundant clones were seen between sediment samples for nirS clones in both habitats. Hybridization and sequencing confirmed that all but one of the 228 putative nirS clones were nirS with levels of nucleotide identities as low as 45.3%. Phylogenetic analysis grouped nirS clones into three distinct subclusters within the nirS gene tree which corresponded to the two habitats from which they were obtained. These sequences had little relationship to any strain with known nirS sequences or to isolates (mostly close relatives of Pseudomonas stutzeri) from the Washington margin sediment samples. nirK clones were more closely related to each other than were the nirS clones, with 78.6% and higher nucleotide identities; clones showing only weak hybridization signals were not related to known nirK sequences. All nirK clones were also grouped into a distinct cluster which could not be placed with any strain with known nirK sequences. These findings show a very high diversity of nir sequences within small samples and that these novel nir clusters, some very divergent from known sequences, are not known in cultivated denitrifiers.     

Diversity of the nitrite reductase gene nirS in the sediment of a free-water surface constructed wetland.

The diversity of the nitrite reductase gene nirS was studied in the bulk sediment of a free-water surface constructed wetland (FWS-CW) located next to the Empuriabrava wastewater treatment plant (WWTP), in Castelló d'Empúries (Girona, NE Spain). The study period extended from the inception of the treatment wetland, in June 1998, until March 1999 and comprised periods of relatively high nitrate and ammonium concentrations at the influent and low nitrate-removal efficiencies. To evaluate nirS diversity, partial gene sequences were obtained by cloning of the respective PCR products. Rarefaction curves based on DOTUR analyses of the deduced amino-acid sequences predicted a greater diversity of nirS genes in samples containing higher ammonium concentrations. Estimated Shannon-Weaver indices of the four cloned samples showed a positive relationship with the N-NH4 +/N-NO3 - ratios measured at the FWS-CW inlet. Identities between the deduced amino-acid sequences and those previously deposited in public databases ranged from 72 to 97%. Phylogenetic analysis based on these deduced sequences grouped 165 nirS clones in seven main clusters according to high similarity indices. Up to 60% of the clones clustered together in a highly homogeneous group with little homologies to any sequence retrieved from cultured representatives. Moreover, prevailing environmental conditions appeared to select for particular denitrifying populations, e.g., with respect to ammonium load and nitrogen removal efficiencies. This observation is of particular interest for the management of treatment wetlands, in which only slight variations in the theoretical denitrification potential of the system can occur.     

Transcriptome of a Nitrosomonas europaea mutant with a disrupted nitrite reductase gene (nirK)

Global gene expression was compared between the Nitrosomonas europaea wild type and a nitrite reductase-deficient mutant using a genomic microarray. Forty-one genes were differentially regulated between the wild type and the nirK mutant, including the nirK operon, genes for cytochrome c oxidase, and seven iron uptake genes. Relationships of differentially regulated genes to the nirK mutant phenotype are discussed.     

Nitrite Reductase Genes (nirK and nirS) as Functional Markers To Investigate Diversity of Denitrifying Bacteria in Pacific Northwest Marine Sediment Communities

Genetic heterogeneity of denitrifying bacteria in sediment samples from Puget Sound and two sites on the Washington continental margin was studied by PCR approaches amplifying nirK and nirS genes. These structurally different but functionally equivalent single-copy genes coding for nitrite reductases, a key enzyme of the denitrification process, were used as a molecular marker for denitrifying bacteria. nirS sequences could be amplified from samples of both sampling sites, whereas nirK sequences were detected only in samples from the Washington margin. To assess the underlying nir gene structure, PCR products of both genes were cloned and screened by restriction fragment length polymorphism (RFLP). Rarefraction analysis revealed a high level of diversity especially for nirS clones from Puget Sound and a slightly lower level of diversity for nirK and nirS clones from the Washington margin. One group dominated within nirK clones, but no dominance and only a few redundant clones were seen between sediment samples for nirS clones in both habitats. Hybridization and sequencing confirmed that all but one of the 228 putative nirS clones were nirS with levels of nucleotide identities as low as 45.3%. Phylogenetic analysis grouped nirS clones into three distinct subclusters within the nirS gene tree which corresponded to the two habitats from which they were obtained. These sequences had little relationship to any strain with known nirS sequences or to isolates (mostly close relatives of Pseudomonas stutzeri) from the Washington margin sediment samples. nirK clones were more closely related to each other than were the nirS clones, with 78.6% and higher nucleotide identities; clones showing only weak hybridization signals were not related to known nirK sequences. All nirK clones were also grouped into a distinct cluster which could not be placed with any strain with known nirK sequences. These findings show a very high diversity of nir sequences within small samples and that these novel nir clusters, some very divergent from known sequences, are not known in cultivated denitrifiers.     

Structural gene (nirS) for the cytochrome cd1 nitrite reductase of Alcaligenes eutrophus H16.

Denitrification by Alcaligenes eutrophus H16 is genetically linked to megaplasmid pHG1. Unexpectedly, the gene encoding the nitrite reductase (nirS) was identified on chromosomal DNA. The nirS product showed extensive homology with periplasmic nitrite reductases of the heme cd1-type. Disruption of nirS abolished nitrite-reducing ability, indicating that NirS is the enzyme essential for denitrification in A.eutrophus.     

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.     

Effect of Sulfadiazine on Abundance and Diversity of Denitrifying Bacteria by Determining nirK and nirS Genes in Two Arable Soils

Sulfadiazine (SDZ) is an antibiotic frequently used in agricultural husbandry. Via manuring of excrements of medicated animals, the drug reaches the soil and might impair important biochemical transformation processes performed by microbes, e.g., the nitrogen turnover. We studied the effect of pig manure and SDZ-spiked pig manure on denitrifying bacteria by quantifying nirK and nirS nitrite reductase genes in two arable soils. Addition of manure entailed mainly an increase of nirK-harboring denitrifiers in both soils, whereas in the SDZ-amended treatments, primarily the nirS denitrifiers increased in abundance after the bioavailable SDZ had declined. However, the community composition of nirS nitrite reducers investigated by denaturing gradient gel electrophoresis did not change despite the observed alterations in abundance.     

固氮施氏假单胞菌亚硝酸盐还原酶基因nirS转录特性及功能鉴定

【目的】研究固氮施氏假单胞菌(Pseudomonas stutzeri)A1501亚硝酸盐还原酶结构基因nir S的转录调控机制及其在反硝化过程中的功能。【方法】构建nir S-lac Z融合载体,利用三亲本结合法将其导入野生型A1501,通过β-半乳糖苷酶活性的测定,分析不同供氧状况、不同浓度的硝酸盐、亚硝酸盐对nir S基因表达的影响;同时将该载体导入rpo N突变株中,研究氮代谢调控因子Rpo N对nir S基因转录影响。通过同源重组方法构建nir S突变株,通过生化表型测定明确nir S在反硝化过程中的功能。【结果】启动子活性测定表明,nir S基因厌氧条件下高水平表达,是好氧条件下表达水平的4倍;nir S的表达受硝酸盐诱导,但不受亚硝酸盐的诱导;Rpo N突变株中,nir S的表达活性为野生型的1/4,nir S启动子未发现Rpo N的保守结合位点,表明nir S的表达受Rpo N间接调控。表型测定显示以硝酸盐为电子受体时Δnir S的反硝化能力降低了约20%;以亚硝酸盐为电子受体时Δnir S仅有微弱的反硝化能力,并且nir S的突变使得菌体在反硝化条件下利用亚硝酸盐的能力显著减弱。nir S突变提高了菌体在亚硝酸为电子受体的反硝化条件下的固氮酶活。【结论】A1501中nir S基因的转录受外界氧及硝酸盐的影响,同时受氮代谢Sigma因子Rpo N的调控。nir S在A1501菌反硝化过程中起关键作用,参与了亚硝酸盐的转化。