1 Introduction

Carbendazim (MBC) is one of the most effective compounds of benzimidazole fungicide applied in preventing fungal plant diseases in crops[1,2]. Moreover, it is also the degradation product of the other benzimidazole fungicides such as benomyl or thiophanatemethyl[3]. However, MBC is a stable compound with a long half-life period in natural conditions141. The residue in soil is destructive for soil microbial diversity, and the disrupted microbial content will induce the soil-borne disease or other plant diseases[5]. What's worse, the MBC residue in underground water or crop surface is threatening to human health, for MBC was toxic for mammalian liver and endocrine[6]. Thus, growing concern about the toxicity of MBC had led to the need for new methods on MBC degradation to eliminate MBC contamination in soil, underground water and food surface.

Microbial degradation of MBC has drawn extensive attention due to the effectiveness. Some bacteria such as Nocardioides sp. and Ralstonia sp. had been obtained for MBC degradation17,81. The isolation and screening of efficient MBC-degrading microorganisms is available in bioremediation of MBC-contaminated soil, and the addition of microorganisms in soil is favorable for soil microbial diversity and soil improvement. However, the MBC-degrading microorganisms were unable to detoxify MBC-contaminated water and food. In contrast, enzymatic bioremediation method is promising due to the high affinity to substrate and the safety to the environment. MBC hydrolyzing enzyme MheI from Microbacterium sp. had been reported for MBC degradation and several mutations had been researched for higher activity[9]. Nevertheless, the bioremediation on MBC contaminated water and food was not conducted. Futhermore, the safety of the bacteria isolated in the previous work was unknown, thus they were unable to be directly utilized in soil bioremediation. Thus, food-grade or agricultural used microorganism is needed for soil bioremediation, and a novel hydrolase is essential to detoxify MBC-contaminated food.

Based on the above considerations, this work aim to isolate novel agricultural used bacteria for MBC degradation, and try to obtain the safe bacteria for degrading MBC in soil and increase soil probiotic diversity at the same time. More importantly, after characterization of the MBC-degrading bacteria, we also purpose to PCR amplify a novel hydrolase coding gene for enzymatic detoxification of MBC contamination (Figure 1).

2 Materials and methods

2.1 Isolation and identification of MBC-degrading strain

The soil which had been treated with MBC for 5 months at the time of sampling was collected from Pinggu District, Beijing, China. To isolate MBC-degrading bacteria, continuous culture was carried out. The MBC-degrading medium content was as following, g/L: K2HPO4 0.5, KH2PO4 0.15, MgSO4 0.3, CaCO3 0.1, MBC 0.1. Soil sample (0.1 g/L) was added in in the first time of cultivation. The 250 mL shake flask was used and 100 mL medium was added. The shake flask was incubated in 30°C and agitated at 150 r/min. After incubation for 3 d, 1 mL aliquot from each conical flask was transferred to a new flask containing fresh medium containing only inorganic salts, then was still incubated at 30°C with shaking. This process was repeated five times before the final culture was diluted onto solid medium. The solid medium was the same with the enrichment medium except that 15 g/L agar powder was added. All plates were incubated at 30°C for bacterial isolation. After continuous isolation for more than 5 generations, the pure bacterial cultures that could grow with MBC as carbon source were selected. Then the strain was transferred onto Luria-Bertani (LB) solid medium (NaCl, 1%; peptone, 1%; yeast extract, 0.5%, ager powder, 1.5%) for preservation. Subsequently, 16S rDNA sequencing was conducted with two universal primers 27F and 1492R. DNA sequencing was accomplished in Biomed company Beijing, and the phylogenetic tree was constructed by MEGA 5.0 system.

2.2 Microbial MBC degradation analysis

To research MBC degradation ability of the isolated strain Car4, the strain was pre-cultured in LB liquid medium for enrichment. The cultivation was carried out in 250 mL shake flask containing 100 mL medium. The temperature was set at 37°C and the agitation was set at 200 r/min. After the OD600 value of the medium reached 1.0, 2 mL of the medium was taken out and the bacteria cell was centrifugally obtained. After washing with sterile ddH2O for 2 times, the bacteria cell was then incubated into 100 mL liquid MBC-degrading medium in 250 mL shake flask, and MBC concentration was set at 30 mg/L. The cultivation was located in 30 °C and shaken at 200 r/min. Samples were taken every 24 h to determine MBC concentration. Each 1 mL of the medium was taken out and centrifuged at 12 000 r/min for 10 min, and the supernate was filtered through 0.22 pL membrane before injected into HPLC for analysis.

2.3 Enzymatic MBC degradation analysis

For enzymatic degradation analysis, cell free extract of E. coli overexpressing hy-1 and the purified hydrolase HY-1 were applied to identify MBC degradation. E. coli (pET-hy-1) was cultured in 100 mL LB medium containing 5 pg/mL kanamycin to keep the plasmid. After cultivation at 37°C 200 r/min for 12 h, 1 mmol/L isopropyl ß-D-thiogalactoside (IPTG) was added into the medium and the temperature was set at 30°C. Then the shake flask was cultivated for another 3 h for protein expression. Cell was harvested by centrifugation at 12 000 r/min for 10 min, then 20 mM potassium phosphate buffer (pH=7.0) was added for resolution of the cell. Ultrasonic disruption of the bacteria was conducted at 100 W for 5 min (work 3 s, stop 2 s). Subsequently, 0.1 mL of cell free extract was used for protein determination with Coomassie Bright Blue, and another 0.1 mL was applied for enzymatic activity analysis or MBC degradation experiment. Cell free extract or purified protein was added into 20 mM potassium phosphate buffer (pH=7.0) with 5 mg/L MBC. The reaction mixture was incubated at 37°C for 1 h. The remaining MBC was evaluated by HPLC.

2.4 Soil bioremediation

Then MBC degradation in soil was conducted by using the soil collected from the experimental plot of Beijing Union University. The soil was pre-cultured for 3 d in the incubator to adapt the environment of the incubator. The temperature and the humidity were set at 26°C and 60%, respectively. Then difficult concentrations of MBC (20-100 pg/g soil) were added and thoroughly mixed into the soil. Samples were taken every 24 h to identify MBC degradation. To determine the residual MBC in the soil, samples were collected and then dried in the dryer oven for 1 h 80°C. Then 0.1 g dried soil was dissolved in 500 pL ddH2O. After dissolution and vortex oscillation, the mixer was filtered through 0.22 pm membrane before injection into HPLC for MBC concentration analysis. Enzymatic remediation of MBC in soil was carried out in the similar way. In total 10 mg E. coli (pET-hy-1) cell was ultrasonic disrupted and the cell free extract was mixed with 1 g soil at 30 °C. After cultivation, the remaining MBC in the soil was measured according to the method above.

2.5 Fruits bio remediation

To research the application of the MBC hydrolase in detoxifying MBC contaminated fruits, cucumbers were used as MBC contaminated fruit by pre-cultivation of cucumbers and MBC solution. Cucumbers were firstly cut into 3 cm length fragments before they were incubated in 10 mg/L MBC for 3 min. Then the cucumbers were stewed at room temperature for 3 h to evaporate water, and the surface of dried cucumbers was filled with MBC. Subsequently, enzymatic remediation was conducted and 1 mg/L purified protein HY-1 was splashed onto experiment group. In parallel, the same volume of sterilized ddH2O was added to the control group. To determine MBC residue on the surface of cucumber, the experimental group and the control group were immersed into 200 mL water for 10 min separately for completely MBC dissolution (dissolution equilibrium was reached within 6 min), and the MBC in water was determined. The initial MBC concentration on surface of cucumbers was set as 100%. All the experiments were conducted for 3 times to calculate the standard deviation. The MBC concentrations in this study were measured by HPLC.

2.6 Gene cloning and protein purification

The coding sequence of the MBC hydrolase derived from the strain Car4 was amplified by PCR. The genomic DNA of strain Car4 was used as the PCR template. The 16S rDNA alignment suggested that Car4 was mostly similar to Bacillus amyloliquefaciens, thus the PCR primers were designed based on the DNA sequence of possible hydrolase gene BSF20_12070. The sequences of the primers were: hy-1 -F: (5' ATGTGGANTTGGANAGCNGA 3') and hy-1-R: (5' TCAANTATACTGNTCTGTAA 3'). The PCR was performed as the following program: 94°C for 1 min, 30 cycles of 94°C for 15 s, 55°C for 20 s, 72°C for 40 s. The PCR product was separated by gel electrophoresis. The band with the expected size was cut and purified. Then the fragment was ligated into expression vector pET-28a with BamHI and HindIII sites, and the recombinant plasmid was transformed into E. coli BL21 (DE3). The recombinant strain was named E. coli (pET-hy-1).

For HY-1 purification, the recombinant strain E. coli (pET-hy-1) cultured in 4 mL LB medium supplemented with 20 pg/mL kanamycin, at 37°C overnight. Cultured E. coli (pET-hy-1) was then transferred into fresh 20 mL LB medium at the ratio of 1:100 and cultured for another 2 h at 37°C, followed by another 3 h at 30°C with 0.5 mM IPTG added. Next, cells were centrifuged and washed for 3 times before they were ultrasonic disrupted according to the method above. Cell lysis solution was then centrifuged and the supernatant was used for protein purification. Protein in the supernatant was purified using Nickel chromatographic column of Protein Purification Kit of Beyotime according to the steps. SDS-PAGE was conducted in 12% polyacrylamide gel, and protein ruler was obtained from TAKARA.

2.7 Enzyme activity assay

The enzymatic activity of hydrolase was determined by hydrolyzing MBC at 30°C within 1 h. The reaction mixer was 20 mM potassium phosphate buffer (pH = 7.0) and 25 ^M MBC. The reaction was initiated by adding the enzyme into the mixturre, and was terminated by incubating in 100°C water for 10 min. The remaining MBC was measured by HPLC. One units of enzyme activity was defined as the enzyme required for 1 yM MBC degradation in 1 h.

2.8 Analytical methods

MBC concentration was measured in a SHIMADZU LC-20A HPLC system equipped with a 300 mm C18 column. The mobile phase was consisted by methanol/water/phosphoric acid and the volume ratio was 15:85:0.025. The column temperature was set at 30°C and the flow rate was 0.8 mL/min. The wavelength of the UV detector was set at 280 nm. Metabolites of MBC degradation were detected MS system. Samples were thawed and centrifuged to remove insoluble particles. The supernatants were dried in nitrogen condition and the residues were dissolved in methanol. MS analysis was performed on an API 4000 mass spectrometer under positive-ion turbo ion spray ionization mode.

3Results and discussion

3.1 Isolation and characterization of MBC-degrading strain

Bacterial single colony that could grow with MBC as the sole carbon source was obtained after continuous purification. The 16S rDNA sequencing result suggested that the strain belonged to Bacillus genus and it was mostly closed to Bacillus amyloliquefaciens strain YH-5. The strain was named as Car4. The phylogenetic tree was constructed based on 16S rDNA alignment and it was displayed in Figure 2a. It can be inferred that strain Car4 and other B. amyloliquefaciens strains were characterized into different types by the analysis of phylogenetic relationships. In previous researches, MBC-degrading strains were isolated such as Microbacterium and Ralstonia. In contrast, there is only a few literatures reported the MBC-degrading strain that belongs to Bacillus genus[10,11]. The advantage of using B. amyloliquefaciens over the other strains was that B. amyloliquefaciens was a defined agricultural probiotic, meaning that it can be used directly in soil bioremediation[12, 13].

The result of MBC degradation by Car4 was displayed in Figure 2b. It can be inferred that Car4 is able to survive by using MBC as the sole carbon source. After 7 d cultivation, the OD600 of Car4 reached 0.14 (0.04 g/L cell dry weight), and 30 mg/L of MBC was consumed in total. The average degradation rate was 4.3mg/(L-d), which is faster than the previously isolated Rhodococcus erythropolis and slower than Ralstonia[7,14]. Advantageously, the cultivation cost of Car4 is cheaper than that of the other genus for Bacillus was easier for biomass accumulation with broad substrate utilization spectrum[15,16].

3.2Cloning, expression and purification of HY-1

The primers used for cloning the hydrolase coding sequence in Car4 were designed according to the sequence from B. amyloliquefaciens after gene alignment. The coding sequence was obtained by PCR amplification by using genomic DNA of Car4 and the gene was named as hy-1. DNA gel electrophoresis of the PCR product identified that the length of hy-1 gene was about 800 bp (Figure 3a). The sequencing result showed that the hy-1 coding sequence had 99% similarity to the phospholipase coding gene (CP018152.1) from Bacillus amyloliquefaciens strain S499. Subsequently, the hydrolase HY-1 encoded by gene hy-1 was obtained by overexpression. The coding sequence of hy-1 was ligated with expression vector pET-28a (+) with a C-terminal 6·His tag. The expression vector was electro-transformed into E. coli BL21 (DE3), and the resulting strain was named as E-HY1. The recombinant E-HY1 strain was cultivated with the induction of 0.5 mM IPTG for 5 h, and a clear IPTG induced band was observed in SDS-PAGE analysis (Figure 3b). The molecular mass of HY-1 was almost 30 KDa, which is identical to the calculation based on hy-1 gene sequence. The molecular mass of HY-1 was similar to the other reported MBC-degradation enzymes, belonging to hydrolase family[8,9]. Then the HY-1 was purified by Ni-NTA agarose gel and the result was displayed in Figure 3c. The purified HY-1 was successfully obtained through freeze drying.

3.3Metabolite characterization and enzyme assay

To characterize the biodegradation product of HY-1, HPLC and MS analysis were conducted based on the hydrolyzing reaction. The results were displayed in Figure 4. The HPLC analysis of MBC hydrolysis products in Figure 4a indicated that MBC was catalyzed into a novel compound that was eluted at 9.2 min, while the remaining MBC in the reaction mixer was eluted at 13.2 min. The main peaks of the 2 compounds were both at the same position compared to the standard substances. Moreover, the MS data confirmed the exact molecular weights of the products in Figure 4b. The fragment ion peaks at m/z 134 and m/z 192 were identified as 2-aminobenzimidazole (2-AB) and MBC, respectively. The HPLC and MS results showed that HY-1 catalyzed MBC into 2-AB successfully.

The enzymatic activity of HY-1 on MBC was then determined. HPLC data showed that 5 umol/L MBC in 100 mL PBS buffer was completely hydrolyzed within 24 h when 1 mg cell free extract of E-HY1 was added at 37°C. When 0.05 mg/L of the purified HY-1 was added into the same solution, the MBC was completely degraded in 150 min. The relative enzymatic activities of E-HY1 cell free extract and purified HY-1 were 0.021 U/mg and 40 U/mg, respectively. The enzymatic activity of HY-1 was slightly higher than the previous reports[9,17]. In total, the hydrolyzing results certified that MBC was degraded by HY-1, and enzymatic assay suggested that HY-1 is a proper protein for restoration of MBC-contaminated soil and food.

3.4Soil restoration

To evaluate the feasibility of strain Car4 and enzyme HY-1 for soil bioremediation, MBC degradation in soil was carried out with either Car4 or cell free extract of E-HY1 added. The degradation results with different original MBC concentrations were displayed in Figure 5. It can be drawn that MBC degradation ratios were all accelerated with Car4 or HY-1 crude extract added under various MBC concentrations. When MBC concentrations were 20 ug/g and 50 ug/g in soil, the addition of Car4 and HY-1 crude extract had similar effect on MBC degradation ratio. In the primary stage within 4 d, the addition of HY-1 crude extract led to the faster degradation of MBC than the addition of bacteria, for the enzyme catalyzed reaction was easier initiated than the bacteria catalyzed reaction. However, the remaining MBC when Car4 added in the following days was lower than HY-1 crude extract added. This indicated that the strain Car4 played an important role in MBC degradation after the adaption to the soil environment. In contrast, the enzyme HY-1 was easily degraded in soil, thus led to the faster degradation within 4 d and lower degradation after 4 d. Car4 and HY-1 played distinct roles in MBC degradation for bacterial remediation and enzymatic remediation experiments. In all, MBC degradation ratios were both accelerated compared to the control. 20 ug/g and 50 ug/g MBC were completely degraded in 10 d and 12 d, respectively, while the same effects were reached at 14 d and 16 d without Car4 or HY-1 crude extract added.

When the MBC concentrations were 80 ug/g and 100 ug/g in soil, Car4 and HY-1 were more effective in accelerating MBC degradation. The addition of Car4 accelerated MBC degradation obviously, and the remaining MBC was 10% lower than the control from 8 day to the end. It can be drawn that the optimum effect by Car4 in soil bioremediation was reached at 80 ug/g MBC concentration, and only 6.19 ug/g was left in the soil at 16 day. When 100 ug/g MBC was added, 36.1 ug/g MBC was remained in the soil. This was probably due to the bactericidal effect of MBC against Car4 when MBC concentration was 100 ug/g, and the cell death of Car4 led to decreased MBC degradation ratio. The addition of HY-1 crude extract also increased MBC degradation ratio, but the accelerated consumption of MBC was mainly focused on the primary stage before 6 d. Enzymatic remediation was better than bacterial remediation when MBC concentrations were lower. However, the half-life period of enzyme HY-1 was much shorter than Car4, thus led to the faster degradation ratio before 6 d and slower degradation ratio after 6 d. When 80 ug/g and 100 ug/g of MBC was provided, MBC was completely consumed at 17th day and 21th day, respectively, which were both faster than the control (20th day and 26th day). This result indicated that enzymatic remediation is feasible for rapid elimination MBC residue in low-microbe conditions, while bacterial method is suitable for soil remediation because Car4 was able to survive in soil with MBC as carbon source.

3.5Food restoration

The cell crude extract of E-HY1 was able to accelerate MBC degradation in soil, thus purified HY-1 was used for bioremediation of MBC-contaminated cucumber. The MBC pre-treated cucumber was applied for remediation, and the results were displayed in Figure 6a. It can be inferred that MBC degradation ratio was increased to a large scale compared to the control. In the end of the experiment, 41.8% of the original MBC was catalyzed by HY-1, while only 30.5% of MBC was naturally catalyzed. Enzymatic remediation was certified available in cleaning MBC residual in food surface, which expanded the enzymatic bioremediation of pesticide contaminations[23]. It can be drawn that the most obvious difference between experimental group and the control group was located in the initial stage of bioremediation, meaning that MBC degradation was accelerated greatly from the 1st day to the 4 th day. However, from the 4th day to the end, the MBC degradation ratios of the 2 groups were tend to be similar. The reason was mainly resulted by the natural degradation of HY-1. In all, the purified HY-1 efficiently accelerated the degradation of MBC in the surface of fruit especially in the initial 4 d, and this is the first report on enzymatic bioremediation of MBC-contaminated food.

4 Discussion

MBC contamination in soil and food is difficult to be cleaned because MBC was rarely soluble in water. Microbial and enzymatic remediation provided novel methods for MBC degradation and restoration. However, the efficiencies of these methods were restricted due to the low enzyme activity and microbial degradation rate. In contrast, the isolated Car4 in this work was able to efficiently degrade MBC. Moreover, Car4 belongs to Bacillus genus, which is also an agricultural probiotics used in promoting plant growth. More importantly, a newly isolated hydrolase HY-1 was obtained and heterogeneously expressed in E. coli, and HY-1 functioned efficiently in removing MBC residue in the surface of fruits and vegetables. Compared to the previous research, both the microbial method and enzymatic method were competent used in bioremediation of MBC contamination.

The maximum MBC degradation ratio of Car4 was 4.1 yug/(g-d). Compared to the other isolated bacteria such as Ralstonia and Altermria alternata[7,18], Car4 exhibited higher efficiency in MBC degradation in soil. Interestingly, when used for agricultural applications, Car4 was more suitable for soil bioremediation because bacteria that belong to Bacillus genus were safe to the environment1191. Some strains of Bacillus even facilitates as plant growth accelerant or antifungal biopesticide[20-22]. Therefore, the application of Car4 combined with several Bacillus strains is feasible in MBC degradation and probiotic enrichment[10,11]. However, MBC functions as an antibiotic in controlling plant disease, and bacterial bioremediation is invalid when MBC concentration is high. Thus, the enzymatic bioremediation is feasible for bioremediation with high MBC concentration when bacterial method is ineffective. Cell crude extract successfully accelerated MBC degradation in soil. More importantly, the industrial production of cell crude extract was economical viable. The main disadvantage for enzymatic bioremediation is the short half-life time of the enzyme in soil. In conclusion, the cooperation of enzymatic bioremediation and bacterial bioremediation methods are able to restore the MBC-contaminated soil under different MBC concentrations.

However, there still exist problems in enzymatic remediation by HY-1. Although MBC degradation was accelerated, 2-AB was still remained on the food surface. In Figure 6b, the relative 2-AB content in soil and food surface were displayed. The remaining 2-AB in soil was much lower than that on food surface. With the increased original MBC concentrations in soil, the relative 2-AB contents were also increased slightly. When 100 ug/g MBC was added, 10.2% of 2-AB was remained. However, the residual 2-AB on the cucumber surface at 6 days was 32.6%, which also led to serious food contamination because 2-AB was also toxic to human health. It can be deduced that 2-AB was easier consumed by soil microbes, leading to lower 2-AB residue. In comparison, the microbial diversity on food surface was much less than in the nutritious soil[24]. MBC on food surface was degraded by HY-1, but the catalytic product 2-AB was unable to be cleaned by the enzyme. Collectively, HY-1 was a novel enzyme for bioremediation that accelerated MBC degradation. On the other hand, a mixer of functional enzymes was feasible in bioremediation of MBC-contaminated food thoroughly.

5 Conclusions

In this work, a novel MBC-degrading bacterial Car4 which belongs to Bacillus genus was isolated. A MBC-hydrolyzing enzyme HY-1 from Car4 was obtained and characterized. MS data identified the catalyzing product of HY-1 as 2-AB. Then Car4 and HY-1 were applied for bioremediation of MBC contamination in soil and food surface. Soil MBC degradation was accelerated with either Car4 or cell crude extract of HY-1 added. Finally, purified HY-1 was applied to restore MBC-contaminated cucumber. In total 41.8% of the original MBC was degraded within 6 d experiment and more than 10% of the MBC residue on the food surface was degraded compared to the control. In all, this work provided a new bioremediation method on MBC or other pesticide contamination.

Acknowledgements

This work was financially supported by Joint Funding of Beijing Municipal Natural Science Foundation-Beijing Municipal Education Commission (KZ201911417049), National Key R&D Program of China (2017YFD0201105) and Premium Funding Project for Academic Human Resources Development in Beijing Union University (BPHR2017DZ07).