Simultaneous biodegradation of phenol and cyanide present in coke-oven effluent using immobilized <i>Pseudomonas putida</i> and <i>Pseudomonas stutzeri</i>

Singh, Utkarsh; Arora, Naveen Kumar; Sachan, Preeti

doi:10.1016/j.bjm.2016.12.013

ABSTRACT

Discharge of coke-oven wastewater to the environment may cause severe contamination to it and also threaten the flora and fauna, including human beings. Hence before dumping it is necessary to treat this dangerous effluent in order to minimize the damage to the environment. Conventional technologies have inherent drawbacks however, biological treatment is an advantageous alternative method. In the present study, bacteria were isolated from the soil collected from the sites contaminated by coke-oven effluent rich in phenol and cyanide. Nucleotides sequence alignment and phylogenetic analysis showed the identity of the selected phenol and cyanide degrading isolates NAUN-16 and NAUN-1B as Pseudomonas putida and Pseudomonas stutzeri, respectively. These two isolates tolerated phenol up to 1800 mg L^-1 and cyanide up to 340 mg L^-1 concentrations. The isolates were immobilized on activated charcoal, saw dust and fly ash. The effluent was passed through the column packed with immobilized cells with a flow rate of 5 mL min^-1. The isolates showed degradation of phenol up to 80.5% and cyanide up to 80.6% and also had the ability to reduce biological oxygen demand, chemical oxygen demand and lower the pH of effluent from alkaline to near neutral. The study suggests the utilization of such potential bacterial strains in treating industrial effluent containing phenol and cyanide, before being thrown in any ecosystem.

Keywords:
16S rRNA; Biodegradation; Immobilization; Pseudomonas; Saw dust

Introduction

A wide variety of synthetic chemicals have found their way into the ecosystem as a consequence of industrial activities, agricultural applications and use in domestic purposes. The rate of discharge of these materials into the ecosystem is more than that of their degradation by natural processes, resulting in the accumulation of such substances in the environment.¹1 Chandra R, Yadav S, Mohan D. Effect of distillery sludge on seed germination and growth parameters of green gram (Phaseolus mungo L.). J Hazard Mater. 2008;152:431-439. The toxic pollutants phenol and cyanide are amongst the most common, potentially dangerous substances that are appearing in nature due to industrialization.²2 Banerjee D, Niyogi BK, Mandal S. Biodegradation of phenol using soil bacteria. Environ Ecol. 2002;20:259-264. Coke-oven based industries and steel plants release phenol and cyanide simultaneously (in the effluent discharged) thus causing a threat to the ecosystem. Coke-oven process wastewater contains phenol (150-2000 mg L^-1) and cyanide (0.1-0.6 kg ton^-1 of coke) at high levels far exceeding the normal limits.³3 EPA. Process Design Manual for Nitrogen Control. Washington, DC: US EPA; 1975.

Phenol present in effluent from coke-oven units is a hazardous pollutant, which is poisonous to animals and toxic to soil microbes and some aquatic species at concentrations in the low mg L^-1 range.⁴4 Rittmann BE, McCarty PL. Environmental Biotechnology, in Series Water Resources and Environmental Engineering. Mc Graw Hill; 2001:261-306.^,⁵5 Wu PX, Liao ZW, Zhang HF, Guo JG. Adsorption of phenol on inorganic-organic pillared montmorillonite in polluted water. Environ Int. 2001;26:401-407. Furthermore, phenol has an impact on human health and it is recommended that human exposure should not exceed 20 mg on an average working day.⁶6 Hannaford AM, Kuek C. Aerobic batch degradation of phenol using immobilized Pseudomonas putida. J Ind Microbiol Biotechnol. 1999;22:121-126. Phenol is placed in the list of priority contaminants by the U.S. Environmental Protection Agency.⁷7 Karigar C, Mahesh A, Nagenahalli M, Yun DJ. Phenol degradation by immobilized cells of Arthrobacter citreus. Biodegradation. 2006;17:47-55. The coke-oven effluent also contains an unacceptably high level of cyanide (a potent inhibitor of respiration due to its extreme toxicity towards cytochrome oxidase). Therefore, to protect the environment from such toxic materials, the wastewater and industrial effluents must be suitably treated before discharge for sustainable environment and agriculture.⁸8 Tewari L, Malviya P. Biodegradation of catechol by fluorescent pseudomonas for sustainable environment. J Sci Ind Res. 2002;61:70-74.^,⁹9 Zhuang X, Chen J, Shim H, Bae Z. New advances in plant growth promoting rhizobacteria for bioremediation. Environ Int. 2007;33:406-413.

New technologies for waste disposal that use high-temperature incineration and chemical decomposition (e.g., base-catalyzed dechlorination, UV oxidation) have evolved. Although they can be very effective at reducing contaminants but at the same time have several drawbacks. These methods are complex, uneconomical and lack public acceptance because of the formation of toxic intermediates, cost ineffectiveness and associated hazards. The associated deficiencies in these methods have focused efforts toward harnessing modern-day bioremediation process as a suitable alternative.¹⁰10 Karigar CS, Rao SS. Role of microbial enzymes in the bioremediation of pollutants: a review. Enzyme Res. 2011;:11.^,¹¹11 Marihal AK, Jagadeesh KS. Plant-microbe interaction: a potential tool for enhanced bioremediation. In: Arora NK, ed. Plant Microbe Symbiosis: Fundamentals and Advances. India: Springer; 2013:395-410. Bioremediation, especially associated with microorganisms, used for the cleanup of contaminated waters and soils is receiving most attention because of its environmental friendly approach and its ability to completely mineralize toxic organic compounds.¹²12 Raghav N, Srivastava JN. Toxic pollution in river water and bacterial remediation: an overview. Int J Curr Microbiol Appl Sci. 2016;5(4):244-266.^,¹³13 Kumar A, Bisht BS, Joshi VD, Dhewa T. Review on bioremediation of polluted environment: a management tool. Int J Environ Sci. 2011;1(6):1079-1093. It is also a cost-effective strategy.¹⁴14 Clarkson A, Abubakar SI. Bioremediation and biodegradation of hydrocarbon contaminated soils: a review. IOSR J Environ Sci Toxicol Food Technol. 2015;9(11):38-45.^,¹⁵15 Shukla KP, Singh NK, Sharma S. Bioremediation: developments, current practices and perspectives. Genet Eng Biotechnol J. 2010;3:1-20. Besides cost-effectiveness, it is a permanent solution, which may lead to complete mineralization of the pollutant. Furthermore, it is a non-invasive technique, leaving the ecosystem intact.¹⁶16 Perelo LW. Review: in situ and bioremediation of organic pollutants in aquatic sediments. J Hazard Mater. 2010;177:81-89.

The purpose of the study was to find bacterial strains that can be used as alternatives to conventional technologies to treat coke-oven wastewater with the simultaneous biodegradation of phenol and cyanide present in coke-oven effluent.

Materials and methods

Organism source and culture conditions

Soil samples were collected in pre sterilized bottles from contaminated site in district Haridwar, Uttarakhand, India (29.9°N and 78.17°E), where coke-oven effluent was being dumped since several years. For isolation of bacteria, one gram of soil suspension was serially diluted in sterile test tubes containing sterile distilled water. The contents were spread out on nutrient agar (NA) plates and incubated at 28 °C for 24 h.¹⁷17 APHA. Standard Methods for the Examination of Water and Wastewaters. 21st ed. Washington, DC: APHA, AWWA, WPCF; 2005. Colonies that grew on plates were selected for further studies.

Growth studies in presence of phenol and cyanide

The isolates were grown in nutrient broth (NB) medium and NB-containing phenol (Phenol GR, Merck) (0-2000 mg L^-1) and cyanide (KCN, Merck) (0-400 mg L^-1) in a batch culture. The bacteria were grown at 160 rpm, incubation temperature 28 °C and pH 7.0. After inoculation, the growth mass was measured as OD₆₁₀ (UV-VIS Spectrophotometer Genesys 6) at 2 h-intervals, up to 48 h.¹⁸18 Mamma D, Kalogeris E, Papadopoulos N, Hatzinikolaou DG, Christrakopoulos P, Kekos D. Biodegradation of phenol by acclimatized Pseudomonas putida cells using glucose as an added growth substrate. J Environ Sci Health. 2004;39:2039-2104. The isolates were screened for further studies on the basis of their tolerance to phenol and cyanide.

Identification of bacteria

The selected isolates were microscopically checked for their morphological characteristics. Their biochemical identities were elucidated by various tests according to Bergey's Manual of Systematic Bacteriology.¹⁹19 Brenner DJ, Krieg NR, Staley JT. Bergey's Manual of Systematic Bacteriology. 2nd ed. Springer; 2005. Selected isolates (NAUN-16 and NAUN-1B) on the basis of tolerance towards phenol and cyanide were further identified by 16S rRNA gene sequencing. For this, bacterial DNA was isolated²⁰20 Baele M, Baele P, Vaneechoutte M, et al. Application of tRNA intergenic spacer PCR for identification of Enterococcus species. J Clin Microbiol. 2000;38:4201-4207. and evaluated on 1.2% agarose gel.²¹21 Marmur J. A procedure for the isolation of deoxyribo-nucleic acid from micro-organisms. J Mol Biol. 1961;3:208-218. For sequence analysis of ∼1.5 kb 16S rRNA gene fragment, consensus universal forward and reverse primers fD1 and rP2 respectively were used and amplification performed by Taq DNA Polymerase. Reaction Mixture components for 50 µL final volume is reaction buffer (10X): 5.0 µL, dNTPs mix (10 mM): 5.0 µL, MgCl₂ (25 mM): 3.0 µL, forward primer (10 pmol/µL): 1.5 µL, reverse primer (10 pmol/µL): 1.5 µL, template DNA: 5.0 µL, Taq DNA polymerase (5 U/µL): 0.5 µL and MQ water: 28.5 µL. The PCR product was bi-directionally sequenced using the forward and reverse primer under the conditions: Initial denaturation (95 °C) for 2 min, denaturation (95 °C) for 1 min, annealing (48 °C) for 1 min, elongation (72 °C) for 1 min, repetition from step 2 to 4 for 29 cycles and finally elongation (72 °C) for 5 min. The 16S rDNA gene sequence was used to carry out BLAST²²22 Altschul SF, Madden TL, Scaffer AA, et al. Gapped BLAST and PSI-BLAST: a new generation of protein database search program. Nucleic Acids Res. 1997;25:3389-3402. with the NCBI GenBank database.²³23 Maidak BL, Cole JR, Lilburn TG, et al. The RDP (Ribosomal database Project) continues. Nucleic Acids Res. 2000;28:173-174. First ten sequences were aligned using Clustal W. Distance matrix was generated using RDP database²⁴24 Maidak BL, Olsen GL, Larsen N, Overbeek R, Mc Caughey MJ, Woese CR. The ribosomal database project. Nucleic Acids Res. 1997;24:82-85. and the phylogenetic tree was constructed in MEGA 4 software²⁵25 Tamura K, Dudley J, Nei M, Kumar S. MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol. 2007;16:111-120. using Neighbor Joining method²⁶26 Saitou N, Nei M. The neighbour-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol. 1987;4:406-425. for identification of bacterial isolates.

Treatment of effluent by immobilized cells

Activated charcoal (Merck), saw dust (of Sesamum indicum obtained from local saw mill) and fly ash (collected from thermal power plant) were procured to use as carrier material for immobilization of bacterial cells.

To determine pH, 10 g solid carrier was mixed with 90 mL of distilled water with thorough stirring and pH of mixture was determined.²⁷27 Somasegaran P, Hoben HJ. Handbook for Rhizobia: Methods in Legume-Rhizobium Technology. New York: Springer-Verlag; 1994. The moisture content of each carrier was determined on a wet and dry weight basis. Water-holding capacity of each carrier was determined by adding 100 g oven-dried carrier material in a 500 mL size beaker containing appropriate amount of water for dipping the material. Saturated material was decanted on gauze to remove extra water and weighed.²⁷27 Somasegaran P, Hoben HJ. Handbook for Rhizobia: Methods in Legume-Rhizobium Technology. New York: Springer-Verlag; 1994.

The bacterial suspension used for immobilization contained 12 h grown cells of the screened bacteria incubated at 28 °C in the nutrient broth. Broth cultures were added separately to each carrier in the ratio 1:3 and thoroughly mixed to obtain a homogeneous carrier-inoculum mixture. This mixture was spread in the trays and kept for 48 h curing at room temperature.²⁷27 Somasegaran P, Hoben HJ. Handbook for Rhizobia: Methods in Legume-Rhizobium Technology. New York: Springer-Verlag; 1994. Carrier with un-inoculated broth served as control. Each inoculated and uninoculated carrier was filled up to 1/3 in 60 cm glass columns (Borosil). The column diameter used was 7 cm so as to allow the effluent run at an optimum flow rate of 5 mL min^-1.²⁸28 Misson M, Razali F. Immobilization of phenol degrader Pseudomonas sp. in repeated batch culture using bioceramic and sponge as support materials. J Teknol. 2007;46:51-59.

Physico-chemical analysis of treated and untreated effluent

The physico-chemical experiments were conducted taking the untreated and treated effluent samples. Biological oxygen demand (BOD), chemical oxygen demand (COD) and pH levels were estimated before and after the treatment. Phenol in the effluent sample was estimated colorimetrically using 4-aminoantipyrine method. In this method phenol reacts with 4-aminoantipyrine in the presence of potassium ferricyanide to form a colored antipyrine dye. Chloroform was used to extract the dye from aqueous solution. The absorbance of the extract was read at 460 nm using Genesys 6 spectrophotometer. Cyanide in the effluent sample was estimated by pyridine barbituric acid colorimetric method (575 nm) after distillation. The procedures adopted for analyses were according to the American Public Health Association Manual.¹⁷17 APHA. Standard Methods for the Examination of Water and Wastewaters. 21st ed. Washington, DC: APHA, AWWA, WPCF; 2005.

Survival of immobilized cells

Pseudomonas putida (NAUN-16) and Pseudomonas stutzeri (NAUN-1B), selected for the study, were marked with antibiotic resistance genes so as to easily isolate and count them from mixed culture. P. putida NAUN-16^strep+ was indigenously resistant to streptomycin (50 mg L^-1). The plasmid vector pBC16 was used to engineer tetracycline-resistance (200 mg L^-1) taking donor Bacillus cereus strain GP7 (pBC16), as described by Bernhard et al.²⁹29 Bernhard K, Schrempf H, Goebel W. Bacteriocin and antibiotic plasmids in Bacillus cereus and Bacillus subtilis. J Bacteriol. 1978;:897-903. While P. stutzeri NAUN-1B^amp+ indigenously resistant to ampicillin (50 mg L^-1) was engineered using Tn5 delivery suicide vector pGS9 to cause streptomycin-resistance (100 mg L^-1) taking donor Escherichia coli strain WA803 (pGS9), as described by Kumar et al.³⁰30 Kumar A, Vij N, Randhawa GS. Isolation and symbiotic characterization of transposon Tn5 induced arginine auxotrophs of Sinorhizobium meliloti. Ind J Exp Biol. 2003;41:1198-1204. Subsequently the strains were designated P. putida NAUN-16^strep+tet+ and P. stutzeri NAUN-1B^amp+strep+.

Carrier-inoculum mixtures were stored separately at room temperature (25 ± 5 °C) conditions. After every 30 days, the stored samples were analyzed to determine the number of viable cells up to six months (180 days). Population density was also monitored before and after the treatment process. The colony forming units (cfu) were measured taking 1 g of carrier (with immobilized cells) from the columns which was run for 7 days. The carrier taken from the column was re-suspended in 10 mL sterile normal saline and left to rehydrate for 2 min. Subsequently, each suspension was agitated vigorously on a vortex mixture for 10 min to suspend the adhered cells. Aliquots containing 0.1 mL were plated on nutrient agar supplemented with streptomycin (50 mg L^-1) and tetracycline (200 mg L^-1) for P. putida NAUN-16^strep+tet+ and with ampicillin (50 mg L^-1) and streptomycin (100 mg L^-1) for P. stutzeri NAUN-1B^amp+strep+ and incubated at 28 °C for 48 h before final counts were taken.³¹31 Obuekwe CO, Al-Muttawa EM. Self-immobilized bacterial cultures with potential for application as ready-to-use seeds for petroleum bioremediation. Biotechnol Lett. 2001;23:1025-1032.

Results and discussion

Phenol and cyanide resistant isolates

Microorganisms have the ability to adapt to a variety of environmental conditions. The microorganisms able to use the pollutants as a nutrient source can efficiently degrade the target compounds.³²32 Ayangbenro AS, Babalola OO. A new strategy for heavy metal polluted environments: a review of microbial biosorbants. Int J Environ Res Pub Health. 2017;14:94-110. In total 15 bacterial strains were isolated from the contaminated soil on NA medium. Two bacterial isolates designated NAUN-16 and NAUN-1B were selected on the basis of their growth in the presence of phenol and cyanide in vitro conditions. The isolate NAUN-16 was Gram negative, motile, rod, endospore-forming and catalase positive and glucose fermenting bacteria. Isolate NAUN-1B was Gram negative, rod, gelatinase, oxidase and catalase positive, and denitrifying bacteria. On the basis of 16S rRNA gene sequence (1.5 kb) analysis isolates NAUN-16 and NAUN-1B were identified as P. putida and P. stutzeri respectively.

Influence of phenol and cyanide on growth of isolates

P. putida NAUN-16 tolerated phenol up to 1500 mg L^-1 and cyanide up to 340 mg L^-1 while P. stutzeri NAUN-1B tolerated phenol up to 1800 mg L^-1 and cyanide up to 300 mg L^-1 concentrations (Figs. 1 and 2). Although many reports on individual degradation of phenol and cyanide are available,¹⁸18 Mamma D, Kalogeris E, Papadopoulos N, Hatzinikolaou DG, Christrakopoulos P, Kekos D. Biodegradation of phenol by acclimatized Pseudomonas putida cells using glucose as an added growth substrate. J Environ Sci Health. 2004;39:2039-2104.^,³³33 Suh YJ, Park JM, Yang JW. Biodegradation of cyanide compounds by Pseudomonas fluorescens immobilized on zeolite. Enzyme Microb Technol. 1993;16:529-553.

34 Farag AM, Abd-Elnaby HA. Degradation of phenol by a new-degradable marine halophilic fungus Fennellia flavipes isolated from mangrove sediments. Life Sci J. 2014;11(9):837-845.

35 Wang Y, Song J, Zhao W. In situ degradation of phenol and promotion of plant growth in contaminated environments by a single strain. J Hazard Mater. 2011;192:354-360.

36 Djokic L, Narancic T, Nikodinovic-Runic J, Savic M, Vasiljevic B. Isolation and characterization of four novel Gram positive bacteria associated with the rhizo-sphere of two endemorelict plants capable of degrading broad range of aromatic substrates. Appl Microbiol Biotechnol. 2011;91(4):1227-1238.^-³⁷37 Parmar P, Soni A, Vyas K, Desai PV. Enzymatic study of cyanide utilizing Pseudomonas species isolated from contaminated soil. J Sci Innov Res. 2013;2(6):1058-1066. but there are negligible reports on the simultaneous degradation of both phenol and cyanide at such high concentrations.

Fig. 1
Growth in presence of phenol. (a) NAUN-16. (b) NAUN 1B.

Fig. 2
Growth in presence of cyanide. (a) NAUN-16. (b) NAUN-1B.

Effect of immobilized cells on effluent

Saw dust had the maximum inherent moisture content and water-holding capacity of 16.41% and 354% respectively, followed by activated charcoal (7.02% and 246%) and fly ash (0.3% and 200%). All the carriers were near neutral in pH. The pH values of all the three solid carriers were in between 6.8 and 7.9 (saw dust, pH = 6.84; charcoal, pH = 7.76; fly ash, pH = 7.1).

P. putida NAUN-16 immobilized on fly ash degraded 56.8% phenol and 76.9% cyanide from the effluent. It reduced BOD and COD by 41% and 42% respectively. When immobilized on charcoal it reduced phenol concentration by almost 60.8% and cyanide by 80.6% and reduced BOD and COD by 53% and 46% respectively. When immobilized on saw dust it reduced phenol by 64.8% and cyanide by 85.7%.and BOD and COD by 48% and 51% respectively. P. stutzeri NAUN-1B when immobilized on fly ash degraded 78.8% phenol and 57.6% cyanide from the effluent. It reduced BOD and COD by 26% and 23% respectively. When immobilized on charcoal it reduced phenol concentration by almost 80.5% and cyanide by 60% and reduced BOD and COD by 58% and 50% respectively. When immobilized on saw dust it reduced phenol by 84.9% and cyanide by 63% and BOD and COD by 55% and 46% respectively (Table 1).

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Table 1
Composition of coke-oven effluent treated with two screened bacterial isolates as compared to untreated effluent.

The microorganisms were resistant to washout and toxicity because they were held on a stationary carrier surface. It has been shown that high cell concentration results in a high degradation rate of toxic compounds.³⁸38 Lee K, Hui K, Tan W, Lim T. Klebsiella bacterium: a report of 101 cases from National University Hospital, Singapore. J Hosp Infect. 1994;27:299-305.

39 Marrot B, Barrios-Martinez A, Moulin P, Roche N. Biodegradation of high phenol concentration by activated sludge in an immersed membrane bioreactor. Biochem Eng J. 2006;30:174-183.^-⁴⁰40 Tallur PN, Megadi VB, Ninnekar HZ. Biodegradation of p-cresol by immobilized cells of Bacillus sp. Strain PHN 1. Biodegradation. 2009;20:79-83. It is probably due to accelerated reaction rates caused by high local cell density in or on the immobilized matrix.⁴¹41 Cassidy MB, Lee H, Trevors JT. Environmental applications of immobilized microbial cells: a review. J Ind Microbiol. 1996;16:79-101. Immobilized cells offer the possibility of degrading higher concentrations of toxic pollutants than can be achieved with free cells.⁴²42 Cai T, Chen L, Ren Q, Cai S, Zhang J. The biodegradation pathway of triethylamine and its biodegradation by immobilized Arthrobacter protophormiae cells. J Hazard Mater. 2011;186:59-66.^,⁴³43 Liu H, Guo L, Liao S, Wang G. Reutilization of immobilized fungus Rhizopus sp. LG04 to reduce toxic chromate. J Appl Microbiol. 2012;112:651-659.

There was also some reduction in phenol (8.3% in charcoal; 9.7% in saw dust; 4.1% in fly ash), cyanide (8.0% in charcoal; 9.6% in saw dust; 5.0% in fly ash), BOD (14.4% in charcoal; 19.2% in saw dust; 9.7% in fly ash) and COD (16.8% in charcoal; 21.2% in saw dust; 11.4% in fly ash) with un-inoculated carriers only (Table 1). As far as the carriers were concerned saw dust showed best results for both isolates. Kulandaivel et al.⁴⁴44 Kulandaivel S, Kaleeswari P, Mohanapriya P. Decolorization and adsorption of dyes by consortium of bacteria with agriculture waste. Int J Curr Microbiol Appl Sci. 2014;3(12):865-882. also reported saw dust as a very good carrier. Immobilization provides a kind of membrane stabilization, which may be responsible for the protection of cells and better degradation rates.⁴¹41 Cassidy MB, Lee H, Trevors JT. Environmental applications of immobilized microbial cells: a review. J Ind Microbiol. 1996;16:79-101.^,⁴⁵45 Kumar SK, Rajalakshmi AG, Balaganesh B, Manikandan P, Vinoth CV. Impact of biochar on soil health. Int J Agric Res. 2014;2(4):933-950.

Survival rate of immobilized cells with reference to storage time

The potential of immobilizing cells for treatment of industrial effluents is of great value.⁷7 Karigar C, Mahesh A, Nagenahalli M, Yun DJ. Phenol degradation by immobilized cells of Arthrobacter citreus. Biodegradation. 2006;17:47-55. The stability of the immobilized cells under storage was assessed by checking viability at different times when stored at room temperature (25 ± 5 °C). Fig. 3 shows the changes in the number of viable cells of P. putida NAUN-16^strep+tet+ and P. stutzeri NAUN-1B^amp+strep+. Charcoal and saw dust proved to be much better carriers. Arora et al.⁴⁶46 Arora NK, Khare E, Naraian R, Maheshwari DK. Sawdust as a superior carrier for production of multipurpose bioinoculant using plant growth promoting rhizobial and pseudomonad strains and their impact on productivity of Trifolium repense. Curr Sci. 2008;95:90-94. observed that carriers possessing high water-holding capacity and near neutral pH can support large populations.

Fig. 3
Population of isolates (a) NAUN-16 and (b) NAUN-1B in different carriers up to 06 months storage.

Charcoal and saw dust also supported almost similar number of bacterial cells before and after the seven days of treatment process. P. putida NAUN-16^strep+tet+ gave 8.49 log cfu g^-1 before and 8.45 log cfu g^-1 after treatment in charcoal, 8.47 log cfu g^-1 before and 8.44 log cfu g^-1 after treatment in saw dust and 8.31 log cfu g^-1 before and 8.25 log cfu g^-1 after treatment in fly ash. Likewise, P. stutzeri NAUN-1B^amp+strep+ gave 8.41 log cfu g^-1 before and 8.36 log cfu g^-1 after treatment in charcoal, 8.45 log cfu g^-1 before and 8.37 log cfu g^-1 after treatment in saw dust and 8.32 log cfu g^-1 before and 8.25 log cfu g^-1 after treatment in fly ash. The main advantage of using immobilized cells of microorganisms is their higher operational stability.⁴⁷47 Dash RR, Gaur A, Balomajumder C. Cyanide in industrial wastewaters and its removal: a review on biotreatment. J Hazard Mater. 2009;163:1-11. Immobilization of viable cells provides a better environment for reaction and alters physiological features in metabolism such as enhanced enzyme induction. Moreover, immobilization system also provides high biomass concentrations due to the formation of biofilm.²⁸28 Misson M, Razali F. Immobilization of phenol degrader Pseudomonas sp. in repeated batch culture using bioceramic and sponge as support materials. J Teknol. 2007;46:51-59.

Phenol and cyanide are present in effluents especially those produced by heavy industries using coke-ovens. The biological degradation of coke-oven effluent becomes much more difficult due to the presence of both of these toxic compounds.⁴⁸48 Staib C, Lant P. Thiocyanate degradation during activated sludge treatment of coke-ovens wastewater. Biochem Eng. 2007;J34:122-130. Both the bacterial strains not only showed the capacity to grow in presence of phenol and cyanide but also degrade them concurrently, which is supposed to be a novel finding of the study.

Conclusion

The microorganisms isolated from the coke-oven effluent contaminated sites had the ability to degrade and tolerate high phenol concentration up to 1800 mg L^-1 and cyanide up to 340 mg L^-1. Two of the most tolerant isolates were identified and characterized as P. putida and P. stutzeri. The study reported the simultaneous degradation of 720 mg L^-1 phenol and 37 mg L^-1 cyanide present in the effluent. Also, the BOD and COD were found to be reduced by more than 50%. Being highly tolerant of phenol and cyanide and also having a capacity to degrade phenol and cyanide in wastewater are features that make P. putida and P. stutzeri particularly useful for treatment of coke-oven effluent containing phenol and cyanide.

The study thus reports the isolation of some very important bacteria having the ability to simultaneously degrade phenol and cyanide present in coke-oven effluent. The ability to degrade improved with simple cell immobilization process. Such strains can be used in development of microbial technology for bioremediation of waste lands where industrial effluents rich in phenol and cyanide are dumped.

References

¹
Chandra R, Yadav S, Mohan D. Effect of distillery sludge on seed germination and growth parameters of green gram (Phaseolus mungo L.). J Hazard Mater 2008;152:431-439.
²
Banerjee D, Niyogi BK, Mandal S. Biodegradation of phenol using soil bacteria. Environ Ecol 2002;20:259-264.
³
EPA. Process Design Manual for Nitrogen Control Washington, DC: US EPA; 1975.
⁴
Rittmann BE, McCarty PL. Environmental Biotechnology, in Series Water Resources and Environmental Engineering Mc Graw Hill; 2001:261-306.
⁵
Wu PX, Liao ZW, Zhang HF, Guo JG. Adsorption of phenol on inorganic-organic pillared montmorillonite in polluted water. Environ Int 2001;26:401-407.
⁶
Hannaford AM, Kuek C. Aerobic batch degradation of phenol using immobilized Pseudomonas putida J Ind Microbiol Biotechnol 1999;22:121-126.
⁷
Karigar C, Mahesh A, Nagenahalli M, Yun DJ. Phenol degradation by immobilized cells of Arthrobacter citreus Biodegradation 2006;17:47-55.
⁸
Tewari L, Malviya P. Biodegradation of catechol by fluorescent pseudomonas for sustainable environment. J Sci Ind Res 2002;61:70-74.
⁹
Zhuang X, Chen J, Shim H, Bae Z. New advances in plant growth promoting rhizobacteria for bioremediation. Environ Int 2007;33:406-413.
¹⁰
Karigar CS, Rao SS. Role of microbial enzymes in the bioremediation of pollutants: a review. Enzyme Res 2011;:11.
¹¹
Marihal AK, Jagadeesh KS. Plant-microbe interaction: a potential tool for enhanced bioremediation. In: Arora NK, ed. Plant Microbe Symbiosis: Fundamentals and Advances India: Springer; 2013:395-410.
¹²
Raghav N, Srivastava JN. Toxic pollution in river water and bacterial remediation: an overview. Int J Curr Microbiol Appl Sci 2016;5(4):244-266.
¹³
Kumar A, Bisht BS, Joshi VD, Dhewa T. Review on bioremediation of polluted environment: a management tool. Int J Environ Sci 2011;1(6):1079-1093.
¹⁴
Clarkson A, Abubakar SI. Bioremediation and biodegradation of hydrocarbon contaminated soils: a review. IOSR J Environ Sci Toxicol Food Technol 2015;9(11):38-45.
¹⁵
Shukla KP, Singh NK, Sharma S. Bioremediation: developments, current practices and perspectives. Genet Eng Biotechnol J 2010;3:1-20.
¹⁶
Perelo LW. Review: in situ and bioremediation of organic pollutants in aquatic sediments. J Hazard Mater 2010;177:81-89.
¹⁷
APHA. Standard Methods for the Examination of Water and Wastewaters 21st ed. Washington, DC: APHA, AWWA, WPCF; 2005.
¹⁸
Mamma D, Kalogeris E, Papadopoulos N, Hatzinikolaou DG, Christrakopoulos P, Kekos D. Biodegradation of phenol by acclimatized Pseudomonas putida cells using glucose as an added growth substrate. J Environ Sci Health 2004;39:2039-2104.
¹⁹
Brenner DJ, Krieg NR, Staley JT. Bergey's Manual of Systematic Bacteriology 2nd ed. Springer; 2005.
²⁰
Baele M, Baele P, Vaneechoutte M, et al. Application of tRNA intergenic spacer PCR for identification of Enterococcus species. J Clin Microbiol 2000;38:4201-4207.
²¹
Marmur J. A procedure for the isolation of deoxyribo-nucleic acid from micro-organisms. J Mol Biol 1961;3:208-218.
²²
Altschul SF, Madden TL, Scaffer AA, et al. Gapped BLAST and PSI-BLAST: a new generation of protein database search program. Nucleic Acids Res 1997;25:3389-3402.
²³
Maidak BL, Cole JR, Lilburn TG, et al. The RDP (Ribosomal database Project) continues. Nucleic Acids Res 2000;28:173-174.
²⁴
Maidak BL, Olsen GL, Larsen N, Overbeek R, Mc Caughey MJ, Woese CR. The ribosomal database project. Nucleic Acids Res 1997;24:82-85.
²⁵
Tamura K, Dudley J, Nei M, Kumar S. MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol 2007;16:111-120.
²⁶
Saitou N, Nei M. The neighbour-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol 1987;4:406-425.
²⁷
Somasegaran P, Hoben HJ. Handbook for Rhizobia: Methods in Legume-Rhizobium Technology New York: Springer-Verlag; 1994.
²⁸
Misson M, Razali F. Immobilization of phenol degrader Pseudomonas sp. in repeated batch culture using bioceramic and sponge as support materials. J Teknol 2007;46:51-59.
²⁹
Bernhard K, Schrempf H, Goebel W. Bacteriocin and antibiotic plasmids in Bacillus cereus and Bacillus subtilis J Bacteriol 1978;:897-903.
³⁰
Kumar A, Vij N, Randhawa GS. Isolation and symbiotic characterization of transposon Tn5 induced arginine auxotrophs of Sinorhizobium meliloti Ind J Exp Biol 2003;41:1198-1204.
³¹
Obuekwe CO, Al-Muttawa EM. Self-immobilized bacterial cultures with potential for application as ready-to-use seeds for petroleum bioremediation. Biotechnol Lett 2001;23:1025-1032.
³²
Ayangbenro AS, Babalola OO. A new strategy for heavy metal polluted environments: a review of microbial biosorbants. Int J Environ Res Pub Health 2017;14:94-110.
³³
Suh YJ, Park JM, Yang JW. Biodegradation of cyanide compounds by Pseudomonas fluorescens immobilized on zeolite. Enzyme Microb Technol 1993;16:529-553.
³⁴
Farag AM, Abd-Elnaby HA. Degradation of phenol by a new-degradable marine halophilic fungus Fennellia flavipes isolated from mangrove sediments. Life Sci J 2014;11(9):837-845.
³⁵
Wang Y, Song J, Zhao W. In situ degradation of phenol and promotion of plant growth in contaminated environments by a single strain. J Hazard Mater 2011;192:354-360.
³⁶
Djokic L, Narancic T, Nikodinovic-Runic J, Savic M, Vasiljevic B. Isolation and characterization of four novel Gram positive bacteria associated with the rhizo-sphere of two endemorelict plants capable of degrading broad range of aromatic substrates. Appl Microbiol Biotechnol 2011;91(4):1227-1238.
³⁷
Parmar P, Soni A, Vyas K, Desai PV. Enzymatic study of cyanide utilizing Pseudomonas species isolated from contaminated soil. J Sci Innov Res 2013;2(6):1058-1066.
³⁸
Lee K, Hui K, Tan W, Lim T. Klebsiella bacterium: a report of 101 cases from National University Hospital, Singapore. J Hosp Infect 1994;27:299-305.
³⁹
Marrot B, Barrios-Martinez A, Moulin P, Roche N. Biodegradation of high phenol concentration by activated sludge in an immersed membrane bioreactor. Biochem Eng J 2006;30:174-183.
⁴⁰
Tallur PN, Megadi VB, Ninnekar HZ. Biodegradation of p-cresol by immobilized cells of Bacillus sp. Strain PHN 1. Biodegradation 2009;20:79-83.
⁴¹
Cassidy MB, Lee H, Trevors JT. Environmental applications of immobilized microbial cells: a review. J Ind Microbiol 1996;16:79-101.
⁴²
Cai T, Chen L, Ren Q, Cai S, Zhang J. The biodegradation pathway of triethylamine and its biodegradation by immobilized Arthrobacter protophormiae cells. J Hazard Mater 2011;186:59-66.
⁴³
Liu H, Guo L, Liao S, Wang G. Reutilization of immobilized fungus Rhizopus sp. LG04 to reduce toxic chromate. J Appl Microbiol 2012;112:651-659.
⁴⁴
Kulandaivel S, Kaleeswari P, Mohanapriya P. Decolorization and adsorption of dyes by consortium of bacteria with agriculture waste. Int J Curr Microbiol Appl Sci 2014;3(12):865-882.
⁴⁵
Kumar SK, Rajalakshmi AG, Balaganesh B, Manikandan P, Vinoth CV. Impact of biochar on soil health. Int J Agric Res 2014;2(4):933-950.
⁴⁶
Arora NK, Khare E, Naraian R, Maheshwari DK. Sawdust as a superior carrier for production of multipurpose bioinoculant using plant growth promoting rhizobial and pseudomonad strains and their impact on productivity of Trifolium repense Curr Sci 2008;95:90-94.
⁴⁷
Dash RR, Gaur A, Balomajumder C. Cyanide in industrial wastewaters and its removal: a review on biotreatment. J Hazard Mater 2009;163:1-11.
⁴⁸
Staib C, Lant P. Thiocyanate degradation during activated sludge treatment of coke-ovens wastewater. Biochem Eng 2007;J34:122-130.

Edited by

Associate Editor: Cynthia Silva

Publication Dates

Publication in this collection
Jan-Mar 2018

History

Received
4 Jan 2016
Accepted
4 Dec 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

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Altschul SF, Madden TL, Scaffer AA, et al. Gapped BLAST and PSI-BLAST: a new generation of protein database search program. Nucleic Acids Res 1997;25:3389-3402.

[23] ²³
Maidak BL, Cole JR, Lilburn TG, et al. The RDP (Ribosomal database Project) continues. Nucleic Acids Res 2000;28:173-174.

[24] ²⁴
Maidak BL, Olsen GL, Larsen N, Overbeek R, Mc Caughey MJ, Woese CR. The ribosomal database project. Nucleic Acids Res 1997;24:82-85.

[25] ²⁵
Tamura K, Dudley J, Nei M, Kumar S. MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol 2007;16:111-120.

[26] ²⁶
Saitou N, Nei M. The neighbour-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol 1987;4:406-425.

[27] ²⁷
Somasegaran P, Hoben HJ. Handbook for Rhizobia: Methods in Legume-Rhizobium Technology New York: Springer-Verlag; 1994.

[28] ²⁸
Misson M, Razali F. Immobilization of phenol degrader Pseudomonas sp. in repeated batch culture using bioceramic and sponge as support materials. J Teknol 2007;46:51-59.

[29] ²⁹
Bernhard K, Schrempf H, Goebel W. Bacteriocin and antibiotic plasmids in Bacillus cereus and Bacillus subtilis J Bacteriol 1978;:897-903.

[30] ³⁰
Kumar A, Vij N, Randhawa GS. Isolation and symbiotic characterization of transposon Tn5 induced arginine auxotrophs of Sinorhizobium meliloti Ind J Exp Biol 2003;41:1198-1204.

[31] ³¹
Obuekwe CO, Al-Muttawa EM. Self-immobilized bacterial cultures with potential for application as ready-to-use seeds for petroleum bioremediation. Biotechnol Lett 2001;23:1025-1032.

[32] ³²
Ayangbenro AS, Babalola OO. A new strategy for heavy metal polluted environments: a review of microbial biosorbants. Int J Environ Res Pub Health 2017;14:94-110.

[33] ³³
Suh YJ, Park JM, Yang JW. Biodegradation of cyanide compounds by Pseudomonas fluorescens immobilized on zeolite. Enzyme Microb Technol 1993;16:529-553.

[34] ³⁴
Farag AM, Abd-Elnaby HA. Degradation of phenol by a new-degradable marine halophilic fungus Fennellia flavipes isolated from mangrove sediments. Life Sci J 2014;11(9):837-845.

[35] ³⁵
Wang Y, Song J, Zhao W. In situ degradation of phenol and promotion of plant growth in contaminated environments by a single strain. J Hazard Mater 2011;192:354-360.

[36] ³⁶
Djokic L, Narancic T, Nikodinovic-Runic J, Savic M, Vasiljevic B. Isolation and characterization of four novel Gram positive bacteria associated with the rhizo-sphere of two endemorelict plants capable of degrading broad range of aromatic substrates. Appl Microbiol Biotechnol 2011;91(4):1227-1238.

[37] ³⁷
Parmar P, Soni A, Vyas K, Desai PV. Enzymatic study of cyanide utilizing Pseudomonas species isolated from contaminated soil. J Sci Innov Res 2013;2(6):1058-1066.

[38] ³⁸
Lee K, Hui K, Tan W, Lim T. Klebsiella bacterium: a report of 101 cases from National University Hospital, Singapore. J Hosp Infect 1994;27:299-305.

[39] ³⁹
Marrot B, Barrios-Martinez A, Moulin P, Roche N. Biodegradation of high phenol concentration by activated sludge in an immersed membrane bioreactor. Biochem Eng J 2006;30:174-183.

[40] ⁴⁰
Tallur PN, Megadi VB, Ninnekar HZ. Biodegradation of p-cresol by immobilized cells of Bacillus sp. Strain PHN 1. Biodegradation 2009;20:79-83.

[41] ⁴¹
Cassidy MB, Lee H, Trevors JT. Environmental applications of immobilized microbial cells: a review. J Ind Microbiol 1996;16:79-101.

[42] ⁴²
Cai T, Chen L, Ren Q, Cai S, Zhang J. The biodegradation pathway of triethylamine and its biodegradation by immobilized Arthrobacter protophormiae cells. J Hazard Mater 2011;186:59-66.

[43] ⁴³
Liu H, Guo L, Liao S, Wang G. Reutilization of immobilized fungus Rhizopus sp. LG04 to reduce toxic chromate. J Appl Microbiol 2012;112:651-659.

[44] ⁴⁴
Kulandaivel S, Kaleeswari P, Mohanapriya P. Decolorization and adsorption of dyes by consortium of bacteria with agriculture waste. Int J Curr Microbiol Appl Sci 2014;3(12):865-882.

[45] ⁴⁵
Kumar SK, Rajalakshmi AG, Balaganesh B, Manikandan P, Vinoth CV. Impact of biochar on soil health. Int J Agric Res 2014;2(4):933-950.

[46] ⁴⁶
Arora NK, Khare E, Naraian R, Maheshwari DK. Sawdust as a superior carrier for production of multipurpose bioinoculant using plant growth promoting rhizobial and pseudomonad strains and their impact on productivity of Trifolium repense Curr Sci 2008;95:90-94.

[47] ⁴⁷
Dash RR, Gaur A, Balomajumder C. Cyanide in industrial wastewaters and its removal: a review on biotreatment. J Hazard Mater 2009;163:1-11.

[48] ⁴⁸
Staib C, Lant P. Thiocyanate degradation during activated sludge treatment of coke-ovens wastewater. Biochem Eng 2007;J34:122-130.

	Phenol (mg L^-1)	Cyanide (mg L^-1)	BOD (mg L^-1)	COD (mg L^-1)	pH
Effluent (Control)	720 ± 0.05	37.3 ± 0.01	541 ± 0.05	1790 ± 0.05	8.5
Uninoculated charcoal	660 ± 0.06	34.3 ± 0.01	463 ± 0.05	1507 ± 0.05	7.8
Uninoculated fly ash	690 ± 0.03	35.4 ± 0.02	488 ± 0.05	1410 ± 0.04	7.9
Uninoculated saw dust	650 ± 0.09	33.7 ± 0.02	473 ± 0.05	1410 ± 0.04	7.9
P. putida (Charcoal)	252 ± 0.02	7.2 ± 0.01	252 ± 0.04	966 ± 0.05	7.4
P. putida (Fly ash)	310 ± 0.04	8.6 ± 0.01	316 ± 0.03	1033 ± 0.05	7.5
P. putida (Saw dust)	253 ± 0.03	5.3 ± 0.01	278 ± 0.04	880 ± 0.03	7.5
P. stutzeri (Charcoal)	140 ± 0.09	14.9 ± 0.02	224 ± 0.03	878 ± 0.02	7.2
P. stutzeri (Fly ash)	152 ± 0.03	15.8 ± 0.01	398 ± 0.05	1350 ± 0.04	7.6
P. stutzeri (Saw dust)	108 ± 0.04	13.8 ± 0.01	240 ± 0.05	960 ± 0.02	7.2

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