European Journal of Experimental Biology Open Access

Keywords

Biodegradation, Cypermethrin, Scale up technique, Pseudomonas aeruginosa, COD GC-ECD, GC-MS, Pathalic acid, Proponic acid. Fish tolerance

Introduction

The first organic synthetic pesticide potassium dinitro-cryslate was used as insecticide The term pesticides covers a wide range of compounds like insecticides, fungicides, herbicides, rodenticides, molluscides, nematicides, plant growth regulators and heavy metals like copper, zinc, arsenic, lead, cadmium and mercury (Hayes, 1975). Among these, organo-chlorine (OC) insecticides which were used to control insects attack were banned or restricted after the 1960s in most of the technologically advanced countries because of its hazardous effect on environment. Thereafter introduction of other synthetic insecticides like organophosphate (OP) in the 1960s, carbamates in 1970s and pyrethroids in 1980s, herbicides and fungicides in the year 1970s-1980s contributed greatly in pest control and agricultural output. Ideally a pesticides must be lethal to the targeted pests but not to non-target organism including man. Unfortunately controversy and abuse use of pesticides soil surface was contaminated. The rampant use of these chemicals, under the adage, “if little is good, a lot more will be better” has played havoc with chronic health problems of humans and other life forms along with soil and environment pollution.

There were enormous studies conducted for degradation of such harmful pesticides. The potential of microorganisms to degrade and remove pesticide from soil has also been successes fully attempted (Doris et al., 1990). Therefore the present study is based on the degradation of pesticides by using biological source such as soil microorganisms. There are many microorganisms present in the soil but only few microorganisms have the potential for pesticides degradation. Isolation of these microorganisms was carried out from the cotton, Brinjal and wheat cultivated soil by enrichment soil methods in laboratory with addition of pesticides. Three different pesticides belonging to insecticide, fungicide and herbicide group were selected and used for microbial degradation. The technical grade Cypermethrin-25EC, Bavistin and 2, 4-D were selected for the degradation because these pesticides are widely used for controlling the different pest on crop in India.

In cypermethrin-25 EC belonging to pyrethroide family used as insecticide in large scale commercial agriculture applications as well as consumer products for domestic purpose. It was synthesized in 1974 and firstly marketed in the year 1977. Pyrethroide have four major a generation among which Cypermethrin belongs to fourth generation (Casida, 1980). The synthetic pyrethroid insecticides are analogs of naturally occurring pyrethrins as per botanical origin (Elliott, 1980) and derived from dry flower of Chrysanthemum cinerariaefolium plant which have been known since the nineteenth century (Grant et al, 2001). It is unlikely to contaminate the ground water because it binds tightly to soil particles. The huge amount of pesticide application causes desired side effects on population and activity of beneficial microorganisms in soil (Pandey and Singh, 2004). Soil microbes showed different response against different types of insecticides. Cypermethrin and monocrotophos had adverse effects on the total number of soil bacteria in the soil while fenvalerate had very low effect on the soil microbes (Rangaswamy and Venkateswarlu, 1992; Ajaz et al., 2005). Therefore soil fertility is decreased and due to which crop production is also affected. Among the different genera of microorganisms for degradation of pesticides, genus Pseudomonas has a special status, as the strain of P. cepacia are known to metabolize broad range of organic compounds and utilizes more than 100 different substrates as the sole source of carbon, nitrogen, sulfur (Dagley, 1986). Many efforts have been undertaken to isolate bacteria, capable of biodegradation of synthetic pyrethroid insecticides and a lot of pyrethroiddegrading microorganisms have been isolated from polluted soil and water (Sakata et al.,1992; Maloeny et al., 1993; Halden et al.,1999; Nirmali et al., 2005; Jilani and Khan, 2006; Tallur et al., 2008; Murugesan et al., 2010a). In vitro studies have shown that microorganisms have capacity to degrade cypermethrin mainly Pseudomonas aeruginosa more efficacious than other microorganisms (Murugesan, et al., 2010a and 2010b; Jilani and Khan, 2006). These microorganisms were isolated from soil of the pre treated Cypermethrin cotton and Brinjal crop field (Murugesan, et al., 2010b). In vitro study showed two soil bacteria that are able to degrade cypermethrin insecticide; they are the member of the genera Pseudomonas and Serratia (Grant, 2001).

Materials and Methods

Chemicals:

Cypermethrin-25EC.

The Cypermethrin-25 EC (BASF India Lid.) was purchased locally from Mondha market, Agriculture Shop, Aurangabad.

Composition:

Cypermethrin-25 EC Technical: (70% basis) 36% w/w, Surfactants- Cresilax AE1, AE2, AE3, (Calcium salt of Alkyl benzene sulphonate, Alkyl phenol Ethoxylate, Tri glyceride Ethoxylate): 10.00% w/w., Solvent- C-IX :54.00 w/w, Total 100.00% w/w.

Chemical formula: C₂₂H₁₉O₃NCl₂

Cypermethrin IUPAC Name: [(RS)-α-cyano-3-phenoxybenzyl (1RS)-cis-trans-3-(2,2-dichlorovinyl)-1,1- dimethyl-cyclopropanecarboxylate.]

Collection of soil samples:

The soil samples were collected from the different sites of Cotton, Brinjal and wheat cultivated field from Belora Dist. Jalna (M.S) India. These fields were already sprayed with Pesticides mainly Cypermethrin-25 EC, Carbendazim and 2, 4-D for past few years. The soil samples were collected in sterile polythene bags for further study.

Soil enrichment Technique for isolation of Pesticides degrading bacteria:

Soils samples collected from the top 0-15 cm of field plots and were air dried and maintain 20% (w/w) moisture content. Fifty grams of each sample was placed in six glass plates and covered to maintain moisture conditions. The soil samples were treated with mix aqueous solution of Cypermethrin-25 EC, Carbendazim and 2, 4-D to get final concentration 1000 ppm by mixing gently and incubated at room temperature for two weeks. The moisture content was maintained using distilled water. The pesticides treatment was repeated three times for every two week of time interval.

Isolation of Pesticides degrading microorganisms:

The enriched culture method was used to isolate the Pesticides degrading microorganisms from soil. Enrichment of pesticides degraders were carried out in 150 ml minimal minerals salt medium in 250 ml conical flask. The medium was sterilized at 121°C for 30 min. Followed by addition of 1% (w/v) of pesticides separately as a sole source of carbon and energy. Consequently, second enrichment was carried out by transferring 1 ml of from first enriched flask culture into freshly prepared and sterilized 50 ml of minimal minerals salt medium and was incubated for same growth conditions. Isolation was done on sterile minimal minerals salt agar media plates with 0.25% pesticides. After 3 days incubation different types of colony were observed and pick up isolated colonies and maintain on slants for further study.

Minimal minerals salt nutrient culture medium (Bactria):

The medium FTW media (Herman and Frankerberger, 1999) comprised of K₂HPO₄- 0.255, KH₂PO₄-0.255, (NH₄)₂SO₄-0.255, MgSO₄.7H₂O-0.05, CaCO₃-0.00₅ and FeCl₂.4H₂O-0.005 was blended with 1 ml of trace elements solution (Focht. 1994). The Focht trace element solution contained (in mg/l): MgSO₄.H₂O-169, ZnSO₄.7H₂O-288, CuSO₄.5H₂O-250, NiSO₄.6H₂O-26, CoSO₄-28, and Na₂MoO₄.2H₂O-24; all in gm/l ratio. The PH was adjusted at 7 and media were sterilized at 121°C for 15 minutes.

Minimal minerals salt nutrient culture medium (Fungi):

A synthetic medium was used containing (NH₄)₂SO₄-2 g, KH₂PO₄-3g, MgSO₄. 7H₂O- 0.5g, glucose- 3g, microelements minerals solution -2 ml (Cooney and Levine, 1972) and distilled water 1 liter. The PHwas adjusted at 7 and media was sterilized at 121°C for 15 minutes.

Identification of Microorganism:

Several microorganisms were isolated and identified but only those microorganisms which showed high growth rate were used for further pesticides degradation study. Particularly four bacteria and four fungi were selected for the Pesticides degradation. The fungi were identified in Department of Botany, Research laboratory, Government institute of science, Aurangabad (MS) India, using manual of soil fungi - Joseph C. Gilman. A total of four bacteria capable of fast growing in the presence of pesticides using them source of carbon and energy were identify on the basis of 16s rDNA sequencing using universal primers. The molecular identification of bacterial isolates was done by National center for cell science (NCCS) Pune.

Scale-up technique:

1ml of 24 hours old four bacterial sub cultured suspension inoculated in separate 250ml Erlenmeyer flasks containing bacterial nutrient culture media with 50 mg/L concentration of Cypermethrin and control was served without bacteria suspension and 1ml four days old four fungus mycelia/spore suspension was inoculated into separate 250ml Erlenmeyer flasks containing fungal nutrient culture media with 50 mg/L concentration of Cypermethrin and control was served without fungus spore suspension. The microbial culture inoculated flasks were kept in orbital shaker at 30ºC with 160 rpm (rotation per minute) for 14 days. After 14 days of incubation period, 1 ml of these 14 days old Cypermethrin degraded culture media and 100 mg/L of Cypermethrin concentration was added into another 250 ml of Erlenmeyer flasks containing nutrient culture medium and control was served without microorganism. The flasks were again kept on orbital shaker at 30ºC with 160 rpm for another 14 days incubation period. Likewise, the microbial culture was sub cultured into other nutrient culture media containing Erlenmeyer flasks with Cypermethrtin concentration of 150 mg/L and was kept on orbital shaker at 30 ºC with 160 rpm for increasing a total incubation period of 42 days. At this stage, the isolated microorganisms were found adapted to Cypermethrin-25 EC and by assessing the Cypermethrin as a sole source of carbon for growth and maintenance.

Chemical oxygen demand (COD):

COD was determined as the oxygen required for chemical oxidation of organic matter with the help of strong chemical oxidant. (Reflex condensation with k₂cr₂o₇ methods using manual of water and waste water analysis, NEERI). COD was determining by refluxing sufficient diluted culture filtrate of microorganisms for 2 hours, in the presence of HgSo₄ and Ag₂So₄ in concentrated H2So4. After refluxing residual K₂Cr₂O₇ was estimated by titrating content with .01N ferrous ammonium sulphate using a ferroin as indicator with wine red color which was the end point.

Residual quantification analysis of Cypermethrin by Gas Chromatography with electronic capture detector (GC-ECD):

After every 14 day’s interval the final concentration of cypermithrin was determined by GC-ECD methods. The solution mixture was extracted with dichloromethane; the organic layer was obtained and it was dried and re dissolved in n-hexane. The GC conditions were as follows: electron capture detector with SPB-5 capillary column, injector/interface temperature 260°C, oven temperature 240°C, detector temperature-300°C, and N2 carrier gas 1 ml/min.

Detection of cypermethrin metabolites by Gas chromatography and Mass spectroscopy (GC-MS):

Culture filtrate of medium containing cypermethrin was extracted with dichloromethane. The dichloromethane extract was evaporated and the residue was dissolved in acetone. The extracts were analyzed by GC-MS (Doctors Analytical laboratory Pvt. Ltd. Pune). The GC–MS analysis was performed in electron ionization (EI) mode (70 eV) with an Agilent gas chromatograph equipped with an MS detector. A HP-1701 capillary column (30 m length × 0.25 mm id × 0.25 ìm film thickness) was used with a initial temperature program of 80 °C for 1 min; increased up to 200 °C at 8 °C/min and held for 2 min. and finally increased up to 260 °C at 15°C/min and held at 260 °C for 10 min. Nitrogen was used as the carrier gas at a constant flow of 1.0 ml/min. The samples were analyzed in split mode (1:20) at an injection temperature of 260 °C and an EI source temperature of 230 °C and scanned in the mass range from 50 m/z to 450 m/z.

Fish Assay:

Healthy (10±0.5 g) were brought to the laboratory from the freshwater pond of the Harsool Lake, Aurangabad. The fish were acclimatized to the laboratory environment for about 5 days. They were regularly fed with commercial food pellets and given aeration. Feeding was stopped before 24 hours of the commencement of the test. After 24 hours a pair of fish was added into aquaria. Only healthy fish were used in the experiments. Fish were exposed in one liter glass aquaria containing 100 mg/L of pesticides and in other aquaria containing pesticides residue (1:1). Regular feed was given fishes and oxygen supply was maintained with mini aerator pumps. The behavior of fishes was observed closely for the first five hours and later extended up to 3 hours with intervals observations. This finding test gave an idea to bring about mortality and tolerance in the test species of fishes.

Results

On the basis of morphological characterization the four fungal cultures were identified as Trichoderma viride, Trichoderma koningii, Penicillium chrysogenum and Rhizopus stolanifer and bacteria were identified through 16s rDNA sequencing as Alcaligenes faecalis (Accession No. HQ202537.1), Pseudomonas aeruginosa (Accession No. JF708942.1. Strain IRMD-2010), Pseudomonas fluorescens (Accession No. AF094731.1. strain ATCC 17574) and Bacillus cereus. (Accession No. HM752769.1. Strain IMAUB1022 CS-2010). The identified Fungi and bacteria were used further for biodegradation of Cypermethrin-25 EC.

Chemical Oxygen Demand:

During the experiment, a good correlation was established between Chemical Oxygen Demand removal and Cypermethrin degradation rates. It was observed that microorganisms showed degradation of Cypermethrin at different concentrations of 50mg/l, 100mg/l and 150mg/lin minimal minerals salt medium at 3^rd, 7^th, 11^th and 14^th day’s intervals. The percentage decreased during the biodegradation Cypermethrin following result was obtained.

A) Bacteria:- P. auroginosa recorded maximum degradation at 50mg/l concentrations as 14.80%, 32.80%, 71.20% and 90.33%, at 100 mg/l concentration 14.16%, 28.21%, 73.89% and 76.39% removal of Cypermethrin was recorded, at 150 mg/l 16.57%, 28.24%, 32.55%, and 50.23% respectively. Followed by P. fluorescens at 50 mg/l as 13.89%, 30.28%, 56.03% and 84.37%, in 100 mg/l 11.53%, 20.94%, 70.64%, and 72.37%, at 150 mg/l as 09.66%, 27.55%, 32.09 % and 48.48% and in B. cereus at 50 mg/l 11.17%, 28.39%, 71.20% and 72.00% respectively, at 100 mg/l 10.31%, 23.98%, 67.57% and 72.02% respectively and in 150 mg/l 15.99%, 28.58%, 30.69% and 44.39% respectively while A. faecalis at 50 mg/l 9.36%, 27.44%, 53.03% and 69.00% , at 100 mg/l 11.53%, 13.84%, 62.97% and 66.78% respectively and at 150 mg/l concentration it showed the lowest removal of Cypermethrin with COD as 07.40%, 24.56%, 33.95% and 38.55% degradation was observed and recorded.(Table no. 1)

B) Fungi:- The four fungi selected for degradation study as T. viride, T. koningii, P. chrysogenum and R. stolaniferous among the T. viride had recorded maximum degradation potential at 50 mg/l 14.34%, 30.59%, 56.03% and 78.00%, at 100 mg/l 9.613%, 18.91%, 48.80% and 61.08% and at 150 mg/l 13.00%, 23.65%, 32.44% and 32.47% respectively. In T. koningii at 50mg/l it was 12.98%, 26.17%, 54.80% and 77.00%, at 100 mg/l 12.40%, 18.91%, 49.49% and 60.31% respectively and lastly at 150 mg/l 09.32%, 23.65%, 31.51% and 41.23% respectively. In P. chrysogenum at 50 mg/l 11.62%, 26.50%, 47.98% and 70.67%, at 100 mg/l 10.13%, 18.58%, 48.12% and 60.84% and at 150 mg/l 11.39%, 29.91%, 32.79% and 41.47%. Finally R. stolaniferus at 50 mg/l 11.17%, 29.96%, 43.96% and 67.34% respectively, at 100 mg/l it was showed 0.173%, 15.54%, 39.42% and 59.61% respectively and at 150 mg/l showed very less degradation was recorded 06.42%, 20.32%, 30.23% and 32.59% respectively. (Table no. 1)

Cypermethrin detection by GC-ECD:

The Bactria of P. aeruginosa, P. fluorescens, B. cereus and A. faecalis and fungi T. viride, T. koningii, P. chrysogenum and R. stolaniferous were enriched and adapted by scale up process in minimal salt medium (MSM) containing Cypermethrin as a sole source of carbon and energy at varying concentration as 50mg/l, 100mg/l and 150mg/l respectively. The scale up process was carried out with successive frequent microbial sub-cultures from lower concentration to higher concentration of Cypermethrin after 14 days time interval under continuous incubation at 30o C with 160 rpm shaking speed.

The GC-ECD data illustrates that, after a period of 14 days intervals at 50 mg/l, 100 mg/l and 150 mg/l. The P. aeruginosa had degraded Cypermethtrin up to 81.35%, 70.

and 53.32% respectively than control. Followed by P. fluorescens degraded Cypermethrin up to 79.28%, 66.97% and 52.66% respectively than control. The B. cereus showed 66.34%, 57.07% and 51.21% degradation of Cypermethrin respectively and A. faecalis showed 62.45%, 57.07% and 35.03% degradation respectively.

While fungi T. viride had maximum degradation up to 66.06%, 58.59 % and 41.01% respectively than the control. In T. koningii showed 61.81%, 56.01% and 36.36% degradation respectively. In P. chrysogenum recorded 55.01%, 54.69% and 35.80% degradation respectively and finally least degradation was by R. stolaniferous up to 47.89%, 35.00% and 13.63% at 50 mg/l, 100 mg/l and 150 mg/l concentration of cypermethrin respectively (Table No. 2). The COD, GC-ECD analysis data showed that the Bacteria P. aeruginosa had more potential for cypermethrin break down into simple compounds. While Bacteria A. faecalis and fungi R. stolanoferous had recorded minimum degradation of cypermethrin at all three selected concentrations. Therefore Bacteria P. aeruginosa had highest potential for removal of cyermethrine and less potential was recorded by the fungus R. stolanoferous in minimal minerals salt medium. The result indicates that as the concentration of Cypermethrin increased the percentage rate of degradation was decreased, indicating that higher concentration of Cypermethrin was harmful for the growth of microorganisms, but P. auroginosa showed significant degradation at higher concentration of Cypermethrin. Therefore the Bacteria P. auroginosa was the potent only potent microorganism for the Cypermethrin degradation than the other microorganism studied.

Detection metabolite of Cypermethrin-25 EC through Gas Chromatography and mass spectrometry (GCMS):

The GC-MS chromatogram revealed that primary metabolites of degraded cypermethrin were found as Phthalic acid -isobutyl 2-pentyl ester, Phthalic acid-butyl 4-octyl ester, 2-Propenic acid-3-(4- methoxyphenyl)-2-ethylhexyl ester, Azuleno(7,9- Dihydroxy-6,9a-dimethyl3-methylenedecarhydroazuleno[4,5-b]furan-29(3H)-one) and Cyclopropane carboxylic acid which were detected by the GC-MS analysis.

From these result it is concluded that the isolated microorganisms were effective for breakdown of toxic compound like cypermethrin especially P. aeruginosa which was more potent for cypermethrin degradation and obtained primary metabolites which were less hazardous to the environment than cypermethrin.

Fish assay against the Cypermethrin pure and Cypermethrin degraded microbial residue.

Tolerance and mortality of fish against Cypermethrin and their microbial residue was examined after one hour time intervals up to three hours time duration. In between one hour fish was feeling uncomfortable in Cypermethrin, mortality was increased and tried to reach the surface of water. One fish was dead after 35 minutes time duration in 100 mg/l Cypermethrin concentrated medium. At residue concentration (1:1 ratio) fish was very unstable and no movement was seen. After 120 minutes fish of residual solution was very uncomfortable and movement was increased while in Cypermethrin solution contain aquarium fish died after 60 and 65 minutes. After 180 minutes time duration residue contains aquarium fish movement was increased and fishes gathered near aerator, one was dead after 150 min and one resist up to 3 hours (Table No. 3). Result revealed that microbial degraded residue fishes showed tolerance and more time survival capacity than Cypermethrin solution and it had proved that degraded residue of Cypermethrin was not harmful for the aquatic life, therefore microbial degradation of Cypermethrin is eco-friendly and non toxic to the environment.

Discussion

During experimental study conducted in scale up process bacteria P. aeruginosa had retained their degradation capacity at wide range of PH 7.5 to 8.53. The chemical oxygen demand result showed that removal of organic load was proportional to the cypermethrin disappearance. The P. aeruginosa showed highest COD reduction (90.33%, 76.39% and 50.23%) at 50 mg/l, 100 mg/l and 150 mg/l respectively while fungi R. stolaniferous recorded minimum reduction of COD as 67.34%, 59.61% and 32.59% at 50 mg/l, 100 mg/l and 150 mg/l respectively. Similar correlation between COD removal and degradation was also observed by S. Jilani and M. Altaf Khan (2006) and Berchtold, et al. (1995), who noticed the same correlation between the COD removal and Biodegradation of increased concentrations of Cypermethrin from 20-125 mg/l gradually decreased the degradation performance of IES-PS-1 and 2, 4-DAT and also 2,4 and 2,6 diamino toluene degradation by acclimated Bacteria (Pesce and Wunderlin, 1997). The COD monitored during bioremediation showed that the reduction in COD concentration was directly proportional to the degradation of the parent compound into its intermediates or less harmful compounds with increasing period of time. Previous research studies also reported that COD is a direct indicator of bioremediation (Singh and Fulekar,2007).

The potential of microorganisms isolated from the cotton cultivated field to mineralize the cypermethrin into primary metabolites were evaluated by using GC- MS method. The finding of present study revealed that eight different microorganisms’ i.e. four fungal genera and four bacteria genera showed varied degradation abilities at several tested concentration of commercial based Cypermethrin. The bacterial growth density was calculated at optical density 600nm showed that the P. aeruginosa had faster growth than other Bacteria and in fungi the mycelial dry weight showed that the T. viride was more effective than other selected fungi. Similar findings were reported by Lee et al. 1998 that the genus Pseudomonas which was gram negative, rod shaped, highly oxidative and metabolically versatile due to which it was able to degrade aromatic hydrocarbons and pesticides and showed more growth than other microorganisms. At the higher concentration of cypermethrin the optical density of bacteria and dry weight of fungi decreased. As the Similar findings were reported by Jilani and Khan, 2006 that increasing in concentration of insecticide decreases the activity of microorganisms. However, at increased concentration of cypermethrin from 50ppm to 150ppm a marked negative effect on the rate of degradation was observed in higher concentration of cypermethrin. Several researchers also reported similar result of lower degradation at high concentration of hazardous organic compounds (Goudar and Strevett, 2000; Lee, et al., 1998; Pesce and Wunderlin, 1997; Smith and Adkins, 1996).

In Present work Trichoderma viride Pseudomonas fluorescens, Bacillus cereus and Alcaligenes faecalis grows at 50ppm, 100ppm more effectively but at 150ppm it had lost degradation capacity and Rhizopus stolanioferus recorded as less tolerance against Cypermethrin but Pseudomonas aeruginosa was very potent at 150ppm concentration. GC-ECD result evaluated that Pseudomonas aeruginosa showed more potential as 81.22%, 69.88% and 53.32% at 50 mg/l, 100 mg/l and 150 mg/l concentrations of Cypermethrin respectively (Table No. 10, Fig-). The various researchers also showed that Pseudomonas aeruginosa was more potent against the cypermethrin degradation (R.J. Grant, T.J. Daniell and W.B. Betts 2002, S.Jilani and M. Altaf Khan 2004, D. Malik, M. Singh, & P. Bhatia 2009, M.H. Fulekar 2009, A.G Murugesan et al 2010a). The P. aeruginosa and other bacteria was grown as shake culture in minimal mineral salt medium containing Cypermethrin as sole source of carbon and energy. Bacterial degradation of Cypermethrin in pure cultures has been reported by several researchers such as Maloney et al.1998; Lee et al. 1998 and Grant et al. 2002.

The susceptibility and resistance of fish were studied against 100 mg/l concentration alone Cypermethrin and degraded residue of Cypermethrin. Three fish were used for assessing fish against pesticides and their degraded residue. Fish resistance and susceptibility against pesticides and degraded residue was examined after 60 minutes, 120 minutes and 180 minutes time intervals. The result revealed that microbial degraded residue of Cypermethrin was eco-friendly and less toxic than pure Cypermethrin therefore the microbial degradation of Cypermethrin ecofriendly and there was no side effect on environment, aqueous life, soil.

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