Introduction

Atmospheric concentration of nitrous oxide (N2O), the most radiative greenhouse gas for global warming, has been increasing constantly since 1980 and reached 319 10−9 mol mol−1 in global air by 20051. Agriculture accounts for about 60% of the global anthropogenic N2O emission, with rice paddies being a major contributor2,3,4. Total N2O emission from China’s rice paddies was estimated at 29.0 Gg N2O per year, contributing by 7–11% to the nation’s total greenhouse gas emission from agriculture4.

The activity of denitrification, a rate-limiting process of N2O production in soil, could be inhibited by elevated soil metal concentration. Lab incubation study showed that metal addition of Cd, Cu or Zn up to 500 mg kg−1 significantly decreased denitrification in wetland sediment, being greatest by Cd followed by Zn and Cu5. Similarly, metal loading such as Zn up to 200 mg kg−1 reduced the activity of denitrifying enzyme in rice soils across a wide range of soil parent materials6. Likewise, in pasture soil, soil denitrification activity was negatively affected by heavy metal7, in a proportional response to gradient addition of Cu, Cr and As concentrations over 50–1300 mg kg−1. Moreover, potential denitrification activity was observed significantly reduced with Cu concentration up to 1300 mg kg−1, whereas gene abundance of nirK community was unchanged in metal polluted rice paddies from South China8. Different soil microbial communities were involved in multiple steps in the reduction of nitrate to nitrogen (N2) and a process-specific microbial community could differ from another in heavy metal tolerance9 and thus, any selective inhibition of N2O reductase by heavy metals could enhance N2O release in soil.

Release of N2O from denitrification in soil was largely determined by N2O production and the subsequent N2O reduction. As a preceding process of N2O production, the reduction of nitrite (NO2) to nitric oxide (NO) is catalyzed by nitrite reductases (NirK and NirS) mediated by denitrifiers, which had been well known distinguishable from nitrate respiring bacteria10. NirK is a member of the multi-copper oxidase metalloprotein family, whereas NirS contains a cytochrome cd1 active site. The nitrite reductase encoded by nirK or nirS gene was related with Cu and Fe, respectively. The N2O reduction, the final step in the denitrification, was catalyzed by nitrous oxide reductase (N2OR), which was encoded by gene nosZ but not present in all denitrifiers enzymes11. While both Nir and N2OR enzymes were known sensitive to environmental stresses12 and the study of changes in denitrifier communities with functional genes (nirS/nirK and nosZ) were intensively reported in rice paddies13, upland croplands14 and forest soils15. The effects of heavy metal on abundance of nirK and/or nosZ gene in soils had been studied generally in laboratory with spiked metals16,17,18. Such studies, however, were not directed to predicting the long-term effects of soil metal contamination as microbial community could have different adaption to pollutants and soil chemical immobilization reactions in field soils19,20. Yet, the changes in abundance and composition of denitrifier communities to long term heavy metal pollution in rice paddies are still unclear.

In China, large areas of rice paddies had been under pollution stresses by multiple heavy metals in the Yangtze River delta21,22, in the Pearl River delta23 and in the Jiangxi province24. Different pedogenesis and soil properties could mask microbial community changes and biogeochemical functioning in long-term heavy metal contaminated rice paddies25. In this study, two paddy soils contaminated with multiple heavy metals were studied in comparison to their unpolluted background soils. The purpose of present study was to characterize changes with metal pollution in abundances and community compositions of denitrifiers by molecular techniques (real-time PCR, denaturing gradient gel electrophoresis (DGGE), cloning and sequencing) with nirK and nosZ genes as the molecular markers and to evaluate potential impacts by metal pollution on their N2O production and reduction rates of rice paddy soils.

Results

Soil properties and heavy metal pollution

As shown in Table 1, there were hardly differences in soil properties between polluted and background soils in a single site. Soil organic carbon (SOC) and total nitrogen (TN) was in a range of 20.40 g kg−1 to 28.77 g kg−1 and of 1.97 g kg−1 to 2.66 g kg−1 for the two soils, respectively. Both SOC and TN of the Yixing site were higher than that of the Dayu site. Soil pH of the Yixing (pH 6.16) was also higher than that of the Dayu site (pH 5.01), again without visible difference between polluted and background soil in a single site. As listed in Table 2, there were consistent differences in the total contents and available pools of Cd, Pb, Cu and Zn between polluted and background soils in a single site though the contents of a single heavy metal element varied by site. While the total Zn content in polluted soil was approximately 2 times higher from Dayu site than from Yixing site, the total Cd, Pb and Cu contents of polluted soils were similar between the two sites. Nemerow pollution index was estimated as 16.22 for Yixing and 24.95 for Dayu, clearly indicating a difference in pollution intensity between Dayu site and Yixing site.

Table 1 Soil physicochemical properties of the studied soil samples.
Full size table
Table 2 Total and available heavy metal contents (mg kg−1) and Nemerow pollution index (Means ± S.D.) of the soils studied.
Full size table

Soil potential denitrifying activity

The changes in potential denitrifying activity with metal pollution of the two studied paddies is shown in Fig. 1, which varied between the two sites. Compared to the unpolluted background soils, the total denitrifying activity was significantly reduced by over 84% in polluted soils for both sites; The N2O producing rate (Fig. 1B) was seen slightly decreased but the N2O reducing rate unchanged (Fig. 1C) in the polluted paddies of both sites.

Figure 1
figure 1

The total denitrifying activity (A) and the N2O production rate (B) and N2O reduction rate (C) in the background and polluted soils of Yixing and Dayu.

Full size image

Abundances of denitrifiers

As shown in Table 3, copy numbers of nirK gene of the two soils ranged from 2.86 × 108 to 5.2 × 109 g−1 dry soil and were similar with those of nosZ genes, which ranged from 3.99 × 108 to 4.29 × 109 g−1 dry soil. Compared to background soil, copy numbers of nirK and nosZ gene were reduced in polluted soils by 47% and 39% at Yixing site and by 73% and 48% at Dayu, respectively, corresponding to their soil metal pollution intensity. Accordingly, the ratio of nirK to nosZ, ranging from 0.8 to 1.2 across all samples, decreased in polluted soils over background soils at both sites.

Table 3 Denitrifier (nirK and nosZ) gene abundance (copy numbers g−1 dry soil) and the relative ratios (Means ± S.D.) of the soils studied.
Full size table

Community composition and phylogenetic analysis of denitrifiers

The principal component analysis (PCA) was used to group sampled soils based on similarity in relative band intensity and position of DGGE profiles. PCA analysis of nirK and nosZ DGGE profiles at Yixing and Dayu sites yielded good summaries of data, as 95% and 76% for nirK and 96% and 90% for nosZ of the total variability was explained by the first two components (Figs 2 and 3), respectively. The nirK community profiles showed a well separation between polluted and background soils at each site, on PC2 at Yixing and on PC1 and PC2 at Dayu site (Fig. 2B). Compared to the corresponding background soils, the composition of nosZ community shifted significantly along PC2 at Yixing and along PC1 at Dayu site. Using redundancy analysis, we identified the factors which can best explained denitrifier community at the two sites (Fig. S1). In RDA bi-plot, axis1 and axis2 values explained 72% and 68% of the variability in nirK and nosZ profiles, respectively. Metals most important in explained nirK community structure were the Zn, Cd contents and Nemerow index, which were strongly related to the first axis while soil pH, TN and SOC were most important soil factors in determining nosZ community structure.

Figure 2
figure 2

DGGE profiles (A) and principal component analysis (B) of nirK gene fragment from the background and polluted soils in Yixing and Dayu. M: 100 bp Marker. Arrows indicate the excised bands (K1–K13) for sequencing. Similar symbols in PCA plot indicate the triplicate samples.

Full size image
Figure 3
figure 3

DGGE profiles (A) and principal component analysis (B) of nosZ gene fragment from the background and polluted soils in Yixing and Dayu. M: 100 bp Marker. Arrows indicate the excised bands (Z1–Z15) for sequencing. Similar symbols in PCA plot indicate the replicate samples.

Full size image

There were some similar DNA bands with different intensities in the DGGE profiles between polluted and background soils in a single site. Selected bands from the DGGE profiles were sequenced to identify the predominant taxa associated with these bands and to trace the change in specific taxa with metal pollution (Figs 4 and 5). In the phylogenetic tree of nirK constructed (Fig. 4), none of the sequences from the different soils were affiliated with neither α-proteobacteria nor β-proteobacteria. Considering the two sites as a whole, sequences from the background and polluted soils did not separate from each other clearly. However, in a single site, most of the clones in the polluted soils were grouped differently from those of the corresponding background soils. The phylogenetic analysis showed that most of the nosZ sequences belonged to α-proteobacteria, only one clone in the polluted soil of the Dayu site was grouped into γ-proteobacteria, whereas the other 2 clones of the Dayu soils was not belonging to the known clusters (Fig. 5). Therefore, most of the species from the polluted and background soils in a single site were separated from the other site.

Figure 4
figure 4

Neighbor-joining phylogenetic tree of nirK sequences retrieved from the numbered DGGE bands of Fig. 2A.

Designation of the clones in bold includes the following information: excised DGGE band number, accession number in the parentheses, followed by the sampling plot the clone retrieved from. Bootstrap values (>50%) with 1000 replicates are indicated at branch points. Scale bar indicates 5 changes per 100 nucleotide positions.

Full size image
Figure 5
figure 5

Neighbor-joining phylogenetic tree of nosZ sequences retrieved from the numbered DGGE bands of Fig. 3A.

Designation of the clones in bold includes the following information: excised DGGE band number, accession number in the parentheses, followed by the sampling plot the clone retrieved from. Bootstrap values (>50%) with 1000 replicates are indicated at branch points. Scale bar indicates 5 changes per 100 nucleotide positions.

Full size image

Discussion

Our results showed a strong impact of heavy metal pollution on denitrifiers in the two different locations. The gene abundances of both nirK (2.8 × 108 ~ 5.2 × 109) and nosZ (4.0 × 108 ~ 4.3 × 109) in the sampled soils were both within the ranges reported in literature. Dandie, et al.26 reported an average abundances of nirK of 1.2 × 109 gene copies g−1 soil from agricultural zones of Thomas Brook Watershed, Canada. Chronakova, et al.27 gave a range of 9.1 × 107 ~ 7.5 × 109 copies g−1 soil of the nosZ gene copies in an upland pasture soil. The much lower copy numbers and activities of denitrifiers at Dayu than those at Yixing site, could be attributed to the lower soil pH of Dayu soil, since denitrification rate could be constrained decreased by acidic condition28 and denitrification enzymes activities had been commonly accepted as a sensitive indicator of acid soil reaction29,30.

Metal impact on denitrifier community abundance varied with elements. Reported by Magalhães, et al.16, copy numbers of both nirK and nosZ genes were decreased with exposure to Cu in 6-day lab incubation of an estuary sediment. However, such decreases could be recovered in prolonged incubation. For example, inhibition of N2O reduction with a mixture of Cd, Cu and Zn spiked in a sandy loam soil was recovered within two months of incubation9. In a study by Ruyters, et al.17, particularly, Zn-spiking (up to 5000 mg kg−1 dry soil) induced decrease in nosZ gene abundance, which was seen recoverable to the level value of the control in a grassland soil after 12 months incubation. In our case, the soils were contaminated by multiple metals at levels up to 400 mg kg−1 but with high Cd pollution intensity (12–25 folds). Sakadevan, et al.5 found a considerable inhibition of denitrification activity in a surface wetland sediment treated with multiple heavy metals and they argued that Cd was the most inhibitory element followed by Zn and Cu among the studied metals. This could help to account for the consistent decrease in the abundances of nirK and nosZ in polluted soils from the two different sites but with commonly high Cd pollution intensity.

Metal pollution could lead to substantial changes in nirK or nosZ communities in soils. For example, metal spiking both at low and high doses resulted in a shift of composition of nirK communities in a silt clay soil after 18-month treatment18. As reported by Ruyters, et al.17, the intensity of dominant bands in the original community profile of nosZ community was decreased while other bands became dominant after spiked Zn treatment for one year, indicating the presence of some tolerant species to Zn spiking. However, in this study, DGGE technique provided no phylogenetic information for microbial community. As much, data here did not allow to identify which group responsible for the change in denitrifier in the polluted soil. Based on DGGE combined with amplicon sequencing, we found that composition of nirK and nosZ denitrifier changed to an extent under metal pollution in the polluted soils at both sites (Figs 2 and 3). Here, both the nirK and nosZ phylogenetic analysis showed that clones of the polluted and the background soils were grouped into different branches, suggesting presence of species tolerant to metals in the polluted soil. However, it was unclear whether the metal tolerant species in these heavy metal polluted soils were intrinsically tolerant to pollution or whether tolerance had been conferred by horizontal gene transfer (HGT). As reported by Jones, et al.31, the phylogenic diversity of denitrifiers had been raised by HGT of denitrification genes including nirK, nirS and nosZ. Here, some clones of polluted soils were widespread among different clusters, probably indicating the presence of different metal tolerant species in the heavy metal polluted soils. Prasad32 reported that the metal resistance capabilities were widespread among different bacterial genera. Particularly, several Proteobacteria could survive in highly metal-contaminated environments33,34. In a study35, metal tolerant species possess multiple heavy metal tolerance mechanism at the community level and metal-exposed microorganisms were tolerance to several metals but not only to one in an agricultural soil.

Holtan-Hartwig, et al.9 found a greater inhibition and thus a longer time required to recover, for N2O reduction than for N2O production, in a sandy loam spiked with metals regardless of a single or combination of them. Accordingly, they could conclude that heavy metal pollution could enhance N2O release from soil to the atmosphere. Whereas, De Brouwere, et al.36 reported a decline in prohibition by Zn on N2O reduction with prolonged incubation for up to one year while they did not detect any changes on N2O reduction activity in the field soils they sampled for lab experiment. In our study, both the total denitrifying activity and the N2O production rate were decreased under pollution in the two sites, but the N2O reduction rate was not affected by pollution (Fig. 1). Vásquez-Murrieta, et al.37 reported the production rate of N2O determined with the C2H2 inhibitor technique was significantly but negatively correlated with the concentrations of Pb, Cu and Zn in soils near a mine used for over 200 years in Mexico.

In addition to the effect of heavy metal pollution, denitrifier communities were also affected by soil properties. Soil inorganic N contents were decreased in polluted soils propably owing to inhibited decomposition rate38. Moreover, soil pH had been found to alter microbial composition directly by changes in functional microbial species39 and directly by changes in metal availablity40. Therefore, interactions of soil properties with metal pollution could alter the availability of metal in soils to microorganisms. However, there were different findings on the correlation of denitrification activity to abundance and/or community composition of denitrifiers among the studies. Henry, et al.41 and Miller, et al.42 reported a significantly increased denitrifying activity but a slight change in the denitrifier community with carbon additions. Ruyters, et al.17 reported different denitrifying activity but unchanged nosZ gene abundance between soils amended or not with hay. Attard, et al.43 reported a change in denitrifying activity after a shift in land uses, which was seen partly due to changes in denitrifier abundance but regardless of changes in the denitrifier community after a shift in land use. In this study, there were hardly difference in community structure of overall denitrifiers as there was no significant difference in copy number ratio of nirK to nosZ between the polluted and background soils at both sites (Table 3). This was, however, in disagreement with the change in N2O release with metal pollution. Yet, changes in N2O production and/or reduction activities under pollution were not consistent with that of nirK or nosZ abundances in a single site. Thus, the abundance of functional genes could be unlikely a predictor for the denitrifying activity in field soils with metal pollution, probably due to the presence of inactive microorganisms as well as to the presence of extracellular DNA in soil44. Alternatively, gene transcript numbers could be a better predictor since they reflect the active populations of the community. Therefore, more direct molecular measurements of shifts in microbial community gene expression patterns (for example, through environmental transcriptomics) is indeed highly desirable for future work.

In conclusion, as revealed with the principal component analysis of DGGE profiles and the phylogenetic analysis, community composition of both nirK and nosZ denitrifiers in rice paddies shifted to a certain extent under pollution from the two sites. The abundances of both nirK and nosZ genes were reduced significantly in the polluted soils. Being inconsistent with the changes in nirK/nosZ community composition or abundance, the total N2O denitrifying activity and the N2O production rate were reduced but the N2O reduction rate unchanged under pollution at both sites. Comparing to the N2O reduction, N2O production could be more sensitive to heavy metal pollution, which could potentially reduce the N2O release in the polluted rice paddies. This study indicates that metal pollution could potentially impact on soil N transformation process and thus on N2O emission from rice paddies. For heavy metal pollution had been already a critical issue for China’s sustainable agriculture, the potential impact of heavy metal pollution on soil nitrogen cycling would deserve an in-depth characterization, through environmental transcriptomics in the near future.

Methods

Site description

Two sites of rice fields with pollution were selected for this study. Site Yixing (31°24′N, 119°41′E, Yixing Municipality, Jiangsu) was located in a smelter area. Site Dayu (25°24′N, 114°18′E, Dayu County, Jiangxi) was situated in a zinc mining area. The polluted field at Yixing was polluted by waste discharge and atmospheric deposition from a metal smelter 0.5 km in distance down wind. Whereas, the polluted soil at Dayu site was polluted by irrigation with river water discharged from an upstream zinc mining ore. The smelter and mining activity had been taken place since late 1960’s in both sites. In each location, unpolluted rice paddies were selected in adjacent fields with same soil type but without distinct access to pollution by deposition or waste water irrigation. The soil at Yixing was derived from lacustrine deposit while the soil at Dayu from red earth on granite. Both sites were within the area controlled by a subtropical monsoon climate with a mean annual temperature ranging from 18 °C to 25 °C and mean annual rainfall ranging from 1200 mm to 1450 mm. The rice paddies were cultivated normally with either rice-wheat rotation or double-cropping of rice in a year.

Soil sampling

Soils were sampled before rice planting in spring 2009. Three composite samples were randomly collected from both polluted and background fields (0–15 cm), each of which contained 5 sub-samples collected in a “Z” shaped pattern with a distance of ~5 m from each other. The composite samples were mixed thoroughly and kept on ice until they were transported to the laboratory within two days after sampling. The gravel and visible plant detritus were removed and then soil samples were sieved (<2 mm). One portion of sieved soil was stored at −20 °C for DNA extraction and another portion was stored at 4 °C for measuring denitrifying activity. The remaining soil was air-dried at room temperature before being analyzed for soil chemical and physical properties as described below.

Measurements of soil properties and metal contents

Measurements of soil basic properties were conducted following the protocols described by Lu45. Briefly, soil pH was measured with a glass electrode using a 1/2.5 soil/water ratio. Soil organic carbon (SOC) was measured using wet digestion and oxidation with potassium dichromate. Total nitrogen (TN) was analyzed using the Kjeldahl method. Soil texture was determined with a hydrometer method after dispersion with 0.5 mol L−1 NaOH. Total heavy metal content was determined by digesting soil with a solution of HF/HClO4/HNO3 (10/2.5/2.5, v/v/v) followed by extraction with 1 M HCl. Cd content was determined with graphite furnace atomic absorption spectrometry (GFAAS, SpectrAA220Z, Varian, USA) while Pb, Cu and Zn contents were determined by flame atomic adsorption spectrophotometry (FAAS, TAS-986, China).

The Nemerow pollution index (Pn)46 was used to evaluate the overall extent of heavy metal pollution and was calculated by the following equation:

where, Pi is a single pollution intensity index of ith metal element with its measured concentration (Ci) divided by the guideline standard of environmental quality (RSi), MaxPi and AvePi is the maximum and average pollution intensity of the analyzed metals in a given soil, respectively.

DNA extraction and real time PCR assay

Total DNA was extracted from 0.25 g of fresh soil by the PowerSoil™ DNA Isolation Kit (Mo Bio Laboratories Inc., CA) according to the manufacturer’s protocol. The primers and thermal cycling procedures for real-time PCR are listed in Table 4. Each reaction was performed in a 25 μl volume containing 15 ng DNA, 1 μl 10 μM of each primer and 12.5 μl SYBR premix EX Taq TM (Takara Shuzo, Shiga, Japan). Melting curve analysis of PCR products was conducted following each assay to confirm that the fluorescence signal originated from the specific PCR products but not from primer-dimers or other artifacts. PCR products were checked for the correct size by comparing standardized molecular weight ladder by electrophoresis on 1.5% agarose gel. A plasmid standard containing the target region was generated for each primer set using total DNA extracted from soil. The amplified PCR products of nirK and nosZ genes were purified using PCR solution purification kit (Takara Shuzo, Shiga. Japan), ligated into pEASY-T3 cloning vector (Promega, Madison,WI) and cloned into Escherichia coli DH5α. Clones containing correct inserts were chosen as standards for real-time PCR. Standard curves were generated using triplicate 10-fold dilutions of plasmid DNA. High amplification efficiencies of nirK (102%) and nosZ (96%) were obtained for gene quantification, with R2 values being 0.995 and 0.991, respectively.

Table 4 Primer sets and thermal profiles used for qPCR (*) and DGGE (#) of the functional target genes.
Full size table

PCR-DGGE of nirK and nosZ containing community

Total extracted DNA from each soil sample was amplified with the nirK876-GC and nirK1040 primers47 and with the nosZ2F-GC and nosZ2R primers48 for the nirK and nosZ genes, respectively (Table 4). The GC clamp described by Muyzer, et al.49 was added to 5′ end of primer. PCR reaction was performed in an Eppendorf autothermer Cycler (Bio-Rad) using 25 μl reaction volume. The DNA concentration of each sample was adjusted to 10 ng μl−1 and used as template for PCR amplification. The reaction mixture contained 12.5 μl Go Taq® Green Master Mix (Promega, Madison,WI), 1 μl of 10 μM of each primer and 10 ng DNA template. For DGGE analysis, PCR products were separated on 8% (w/v) polyacrylamide gels (acrylamide-bisacrylamide [37.5:1]) with a 49% to 62% denaturing gradients for nirK and a 45% to 70% for nosZ using the D-Code universal mutation detection system (Bio-Rad Laboratories, Hercules, CA, USA), respectively. Denaturant was defined that containing 8% acrylamide with 7 M urea and 40% deionized formamide. Electrophoresis ran 5 min at 200 V at first and then 500 min at 140 V at a temperature of 60 °C in a DGGE chamber containing approximately of 1 × TAE buffer. Gels were silver stained and scanned using a gel document system (Bio-Rad, USA).

Sequencing and phylogenetic analysis

Dominant bands from DGGE gels were detected and numbered (K1-K13 and Z1-Z15) on the basis of their relative intensity or specific positions across all treatments. The numbered bands of DGGE gels were excised, transferred to clean Eppendorf tubes and smashed to release the DNA in to 25 μl of sterile water at 4 °C. The eluted DNA was reamplified as templates using primer sets described above but without GC clamp, purified and ligated with the p-EASY T3 cloning kits (Promega, Madison, WI) according to the protocol. The positive colonies were amplified again using the above primers with GC clamp and checked by DGGE. The correct one was finally selected for sequencing. The retrieved sequences were compared with GenBank data base sequences using BLAST (Basic Local Alignment Search Tool) (http://www.ncbi.nlm.nih/gov/blast/) to search for best matches. The sequences of DGGE bands have been deposited in GenBank under the accession numbers JF264814-JF264826 (nirK) and JF264756-JF264766 (nosZ). Phylogenetic analysis was performed using MEGA version 4.0 and the neighbor-joining trees were constructed using the p-distance model with bootstrap value of 1,000.

Measurement of potential denitrifying activity

The total denitrifying activity was determined by the acetylene (C2H2) inhibition method described by Tiedje, et al.50. 20 g moist soil at 60% WHC (water holding capacity) was placed in 250 mL glass bottles and treated with 20 mL of a substrate solution containing 1 mM glucose and 1 mM KNO3. Each soil sample was divided into two subsamples to be incubated with or without C2H2 (10% v/v). N2O evolved from the bottles was measured using a gas chromatograph (Agilent 7890D, Santa Clara, CA, USA) equipped with an electron capture detector (ECD). A mixture of argon and methane (5%) was used as the carrier gas. The oven temperature was controlled at 55 °C and the temperature of the ECD was set at 330 °C. Concentration of N2O was quantified by comparing the peak area with those of reference gas (Nanjing special gas factory). The linear rates of N2O production over time were observed within 6 h after initiating the incubations. In the treatment with C2H2, the net rate of N2O production was calculated as the N2O production rate. In the treatment without C2H2, the net rate of N2O production was calculated as the total denitrifying activity. The difference between the N2O production rate and total denitrifying activity was treated as the N2O reduction rate.

Data processing and statistical analysis

The data presentation and treatment was conducted using Microsoft Excel 2013. Results were expressed as means with one standard deviation. Digital DGGE images were analyzed with Quantity One image analysis software (Version 4.0, Bio-Rad, USA). This software identifies the bands occupying the same position in the different lanes of the gel and also measures the intensity of the identified bands. All statistical analyses were performed using the SPSS 16.0 for Windows. Principal component analysis (PCA) and redundancy analysis (RDA) of the DGGE profiles were conducted using the Canoco 4.5 software.

Additional Information

How to cite this article: Liu, Y. et al. Abundance, composition and activity of denitrifier communities in metal polluted paddy soils. Sci. Rep. 6, 19086; doi: 10.1038/srep19086 (2016).