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Isolation and Immobilization of Biosurfactant-Producing Bacteria Capable of Degrading Carbofuran Pesticide

Year 2024, Volume: 34 Issue: 3, 475 - 488, 30.09.2024
https://doi.org/10.29133/yyutbd.1352398

Abstract

Pesticide residue has been detected not only on agricultural lands but also in bodies of water such as rivers, lakes, and the sea. This study was aimed at exploring the potency of local bacterial isolates to degrade carbofuran, an active pesticide compound. Two biosurfactant-producing bacteria were isolated from hydrocarbon-compound-contaminated seas (NF9) and agricultural land with a long-term history of pesticide application (AB2). Bacteria were selected according to their ability to grow on a mineral medium, Bushnell Haas Agar, with the addition of 41.86 ppm of carbofuran pesticide as the sole carbon source. Their growth was characterized morphologically, biochemically, and molecularly based on their 16S rRNA genes. All isolates were Gram+ and indicated as Bacillus thuringiensis KD168 for isolate NF9 and Bacillus paranthracis C9 for isolate AB2. Both of the isolates were immobilized in sodium alginate and polyurethane matrixes. Both B. thuringiensis NF9 and B. paranthracis AB2 were able to degrade carbofuran, as indicated by the presence of carbofuran residue that ranged from 1.03 to 1.89 ppm; however, the residue was undetected after 15 days of incubation. We also confirmed that bacterial cells were immobilized and retained in polyurethane as well as in the sodium alginate matrix. The immobilization of the bacterial cells showed the abilities of the cells to degrade pesticides and their potential to be developed as bioremediation agents in polluted areas.

References

  • ACECHEM, (2022). Open up the Indonesian agrochemical market with branded innovative products, technologies and services from a differentiated way of thinking and practicing. AgNews. May 2nd 2022. https://news.agropages.com/News/NewsDetail---42067.htm. September 21th 2022.
  • Alp, Y., & Şensoy, S. (2023). The Effects of Different Fertilizer Applications on Some Morphological Traits in Fresh Bean. Yuzuncu Yil University Journal of Agricultural Sciences, 33(1), 100-110.
  • Arifin, F., & Sukirah, A. R. (2020). Biodegradation of Carbofuran: a Review. Journal of Environmental Microbiology and Toxicology, 8(1), 50-57.
  • Bano, N., & Musarrat, J. (2004). Characterization of a novel carbofuran degrading Pseudomonas sp. with collateral biocontrol and plant growth promoting potential. FEMS Microbiol Lett., 231(1), 13-17.
  • Bertolote, J. M., Fleischmann ,A., Eddleston, M., & Gunnell, D. (2006). Deaths from pesticide poisoning: a global response. Br. J. Psychiatry, 189(3), 201-203.
  • Buque, E. M., Chin-Joe, I., & Straathof, A. J. J. (2002). Immobilization affects the rate and enantioselectivity of 3-oxo-ester reduction by baker's yeast. Enzyme Microb. Technol., 31, 656-664.
  • Cheah, U-B., Kirkwood, R. C., & Lum, K-Y. (1997). Adsorption, desorption and mobility of four commonly used pesticides in Malaysian agricultural soils. Pestic. Sci., 50(1), 53-63.
  • Cycon, M., Mrozik, A., & Piotrowska-Seget, Z. (2017). Bioaugmentation as a strategy for the remediation of pesticide-polluted soil: A review. Chemosphere, 172(1), 52-71.
  • Damayanti, A. C. K. A, Kumoro, A. C., & Bahlawan, Z. A. S. (2021). Review Calcium Alginate Beads as Immobilizing Matrix of Functional Cells: Extrusion Dripping Method, Characteristic and Applications. IOP Conf. Ser.: Mater. Sci. Eng. October 6th -7th Semarang, Indonesia. 1053 012017.
  • Das, A. C., Chakravarty, A., Sen, G., Sukul, P., & Mukherjee, D. (2005). A comparative study on the dissipation and microbial metabolism of organophosphate and carbamate insecticides in orchaqualf and fluvaquent soils of West Bengal. Chemosphere, 58(5), 579-584.
  • De Ory, I., Cabrera, G., Ramirez, M., & Blandino, A. (2020). Immobilization of Cells on Polyurethane Foam. In: Guisan, J., Bolivar, J., López-Gallego, F., Rocha-Martín, J. (eds) Immobilization of Enzymes and Cells. Methods in Molecular Biology, vol 2100. Humana, New York, NY.
  • Duc, H. D. (2022). Enhancement of carbofuran degradation by immobilized Bacillus sp. Strain DT1. Environmental Engineering Research, 27(4),1-23.
  • Eras-Muñoz, E., Abel F., Antoni S., Xavier F., & Teresa, G. (2022). Microbial biosurfactants: a review of recent environmental applications. Bioengineered, 13(5),12365–12391.
  • Fareed, A., Sania, R., Ismat, N., Mazhar, I., Raza, A., Jamshaid, H., Azhar, H., Azhar, R. & Tatheer, A.N. (2019). Immobilized cells of a novel bacterium increased the degradation of N-methylated carbamates under low temperature conditions, Heliyon, 5(11),1-8.
  • Feng, X., Ou, L-T., & Ogram, A. (1997). Plasmid-mediated mineralization of carbofuran by Sphingomonas sp. strain CF06. Appl Environ Microbiol, 63(4),1332–1337.
  • Fravel, D.R., Lumsden, R.D., & Connick, W. J. Jr. (1985). Encapsulation of potential biocontrol agent in alginate –clay matrix. Phytopathology, 76, 774 – 777.
  • Gupta, M., Mathur, S., Sharma, T. K., Rana, M., Gairola, A., Navani, N. K., & Pathania, R. (2016). A study on metabolic prowess of Pseudomonas sp. RPT 52 to degrade imidacloprid, endosulfan and coragen. Journal of Hazardous Materials, 301, 250-258.
  • Gupta, J., Rathour, R., Singh, R., & Thakur, I.S. (2019). Production and characterization of extracellular polymeric substances (EPS) generated by a carbofuran degrading strain Cupriavidus sp. ISTL7. Bioresource Technology, 282, 417–424.
  • Hu, B., & Chen, S. (2007). Pretreatment of methanogenic granules for immobilized hydrogen fermentation, Int. J. Hydrogen Energy, 32(15), 3266–3273.
  • Ishag, A. E., Abdelbagi, A. O., Hammad, A. M., Elsheikh, E. A., Elsaid, O. E., Hur, J. H., & Laing, M. D. (2016). Biodegradation of Chlorpyrifos, Malathion, and Dimethoate by Three Strains of Bacteria Isolated from Pesticide-Polluted Soils in Sudan. Journal of Agricultural and Food Chemistry, 64(45), 8491-8498.
  • Islam, F., Wang, J., Farooq, M.A., Khan, M.S.S., Xu, L., & Zhu, J. (2018). Potential impact of the herbicide 2,4-dichlorophenoxyacetic acid on human and ecosystems. Environ Int, 111, 332–351.
  • Jeon, Y., Bissesur A., & Singh, P. (2019). Novel immbolization techniques of Acinobacter (V2) and Paenibacillus (D9) bacterial strains for waste oil degradation. Biotechnology & Biotechnological Equipment, 33(1), 911-920.
  • Kamboj, A., Kiran, R., & Sandhir, R. (2005). Isolation and characterization of carbofuran degrading bacteria from soil. Asian J Microbiol Biotechnol Environ Sci, 7(3), 355–358.
  • Karns, J.S., Mulbry, W.W., Nelson, J.O., & Kearney, P.C. (1986). Metabolism of carbofuran by a pure bacterial culture. Pestic Biochem Physiol, 25(2), 211–217.
  • Kar, S., & Ray, R.C. (2008). Statistical optimization of á-amylase production by Streptomyces erumpens MTCC 7317 cells in calcium alginate beads using response surface methodology. Pol J Microbiol, 57(1), 49-57.
  • Li, D.S., Junqiao, F., Yi-Fan, L., Lei, Z., Jin-Feng, L., Ji-Dong, G., Bo-Zhong, M., & Shi-Zhong, Y. (2020). Enrichment and immobilization of oil-degrading microbial consortium on different sorbents for bioremediation testing under simulated aquatic and soil conditions. Applied Environmental Biotechnolog, 5(1), 1-11.
  • Lima, D., Viana, P., André, S., Chelinho, S., Costa, C., & Ribeiro R. (2009). Evaluating a bioremediation tool for atrazine contaminated soils in open soil microcosms: The effectiveness of bioaugmentation and biostimulation approaches. Chemosphere, 74(2), 187–192.
  • Lu, J., & Toy, P.H. (2009). Organic polymer supports for synthesis and for reagent and catalyst immobilization. Chem Rev, 109(2), 815-838.
  • Matshui, T., & Tomohiko, N. (2017). Degradation of Alkana by bacteria immobilized in polyurethane foam. Journal of The Japan Petroleum Institute, 60(3), 154-157.
  • Mishra, S., Wenping, Z., Ziqiu, L., Shimei, P., Yaohua, H., Pankaj, B., & Shaohua, C. (2020). Carbofuran toxicity and its microbial degradation in contaminated environments, Chemosphere, 259(6), 1-15.
  • Moon, H., Suhyeok, K., Byung, H.J., & Hyung, J.C. (2020). Immobilization of genetically engineered whole-cell biocatalysts with periplasmic carbonic anhydrase in polyurethane foam for enzymatic CO2 capture and utilization. Journal of CO2 Utilization, 39, 1-7.
  • Morel, C. C., Parekh, N. R., Pautrel, D., & Fournier, J C. (1996). Cross-enhancement of karbofuran biodegradation in soil samples previously treated with carbamate pesticides. Soil Biol Biochem, 28(12), 1767–76.
  • Nabhan, K.J., Khalik, W.M.A.W.M., Abdullah, M.P., Othman, M.R., Isahak, A., & Zulkepli, S.A. (2018). Assessment of multiresidue pesticides in agricultural soils from ledang, Malaysia and related potential health risks. Nat Environ Pollut Technol, 17(1), 99–106.
  • Nemati, M. & Webb, C. (2019). Comprehensive Biotechnology, Third Edition Vol. 6. Environmental and Related Biotechnologies. Editor-in-Chief: Murray Moo-Young, University of Waterloo, Waterloo, ON, Canada. ISBN 987-0-444-64047-5.
  • PAN Asia Pacific, (2022). Malaysia commended for banned on chlorpyrifos and carbofuran August 23, 2022.https://panap.net/2022/08/malaysia-commended-for-ban-on-chlorpyrifos-and-carbofuran/ September 21th 2022.
  • Pandey, G., Dorrian, S. J., Russell, R. J., Brearley, C., Kotsonis, S., & Oakeshott, J. G. (2010). Cloning and biochemical characterization of a novel carbendazim (methyl-1H-benzimidazol-2-ylcarbamate)-hydrolyzing esterase from the newly isolated Nocardioides sp. strain SG-4G and its potential for use in enzymatic bioremediation. Applied and Environmental Microbiology, 76(9), 2940-2945.
  • Parekh, N.R., Suett, D.L., Roberts, S.J., McKeown, T., Shaw, E.D., & Jukes, A.A. (1994). Carbofuran‐degrading bacteria from previously treated field soils Get access Arrow. Journal of Applied Bacteriology, 76(6), 559–567.
  • Partovinia, A. & Rasekh, B. (2018). Review of Immobilized microbial cell system for bioremediation of petroleum hydrocarbon polluted environment. Critical Review in Environmental Science and Technology, 48(1), 1-38.
  • Pathak, V.M., Verma, V.K., Rawat, B.S., Kaur, B., Babu, N., Sharma, A., Dewali, S., Yadav, M., Kumari, R., Singh, S., Mohapatra, A., Pandey. V., Rana, N., & Cunill, J.M. (2022). Current status of pesticide effects on environment, human health and it’s eco-friendly management as bioremediation. Front Microbiol, 17(13), 1-29.
  • Plangklang, P., & Reungsang, A. (2011). Bioaugmentation of carbofuran residues in soil by Burkholderia cepacia PCL3: A small-scale field study. Int Biodeterior Biodegrad, 65(6), 902–905.
  • Racke, K.D., & Coats, J.R. (1988). Comparative Degradation of Organophosphorus Insecticides in Soil: Specificity of Enhanced Microbial Degradation. J Agric Food Chem, 36(1), 193–199.
  • Rahimi, A., Gitari, H., Lyons, G., Heydarzadeh, S., Tuncturk, M., & Tuncturk, R. (2023). Effects of Vermicompost, Compost and Animal Manure on Vegetative Growth, Physiological and Antioxidant Activity Characteristics of Thymus vulgaris L. under Water Stress. Yuzuncu Yil University Journal of Agricultural Sciences, 33(1), 40-53.
  • Sarkar, S. (2021). The use of pesticide in developing countries and their impact on health and theright to food. Policy Department for External Relations. Directorate General fo External Policy of the Union. PE. 653-652.
  • Sarwar, A., Günter, B., Erika, C., Gajendar, A., Muhammad, A., Angela, S., & Fauzia, Y.H. (2018). Qualitative analysis of biosurfactants from Bacillus species exhibiting antifungal activity. PLoS One, 13(6), 1-15.
  • Schoebitz, M., Ceballos, C., & Ciampi, L. (2013). Effect of immobilized phosphate solubilizing bacteria on wheat growth and phosphate uptake. Journal of Soil Science and Plant Nutrition, 13(1), 1-10.
  • Sharip, Z., Hashim, N., & Suratman, S. (2017). Occurrence of organochlorine pesticides in a tropical lake basin. Environ Monit Assess, 189(11), 560.
  • Shin, D-H., Kim, D-U., Seong, C-N., Song, H-G. & Ka J-O. (2012). Genetic and phenotypic diversity of carbofuran-degrading bacteria isolated from agricultural soils. J Microbiol Biotechnol, 22(4), 448–456.
  • Slaoui, M., Ouhssine, M., Berny, E., & Elyachioui, M. (2007). Biodegradation of the carbofuran by a fungus isolated from treated soil. Afr J Biotechnol, 6(4), 419–423.
  • Soo, C-L., Chen-Ann, C., Othman, B., & Yii-Siang, H. (2017). Feasibility of marine microalga immobilization in alginate beads for marine water treatment: Bead stability,cell growth and ammonia removal. International Journal of Polymer Science, 1, 1 – 7.
  • Talwar, M. P., Mulla, S. I., & Ninnekar, H. Z. (2014). Biodegradation of organophosphate pesticide quinalphos by Ochrobactrum sp. strain HZM. Journal of Applied Microbiology, 117(5), 1283-1292.
  • Tomasek, P.H., & Karns, J.S. (1989). Cloning of a carbofuran hydrolase gene from Achromobacter sp. strain WM111 and its expression in gram-negative bacteria. J Bacteriol, 71(7), 4038–4044.
  • Utami, R.R., Gertjan, W. G., Indah R. S. S., & Suprihanto, N. (2020). Agricultural Pesticide Use In The Upper Citarum River Basin: Basic D Basin: Basic Data For Model-Based Risk M A For Model-Based Risk Management. Journal of Environmental Science and Sustainable Development, 3(2), 235-260.
  • Wu, X., Yin, Y., Wang, S., & Yu, Y. (2014). Accumulation of chlorothalonil and its metabolite,4-hydroxychlorothalonil, in soil after repeated applications and its effects on soil microbial activities undegreenhouse conditions. Environmental Science and Pollution Research, 21(5), 3452-3459.
  • Xu, J., Hong, Q., Wu, J., Yan, Q., & Li, S. (2009). Cloning of a gene related to carbofuran hydrolyzing from Sphingomonas agrestisCDS-1 by transposon rescue. Chin J Appl Environ Biol, 15(5), 677–681.
  • Yan, Q.X., Hong, Q., Han, P., Dong, X.J., Shen, Y.J., & Li, S.P. (2007). Isolation and chacterization of a carbofuran-degading strain Novisphingobium sp. FND. 3. FEMS Microbiol Lett, 271(2), 207-213.
Year 2024, Volume: 34 Issue: 3, 475 - 488, 30.09.2024
https://doi.org/10.29133/yyutbd.1352398

Abstract

References

  • ACECHEM, (2022). Open up the Indonesian agrochemical market with branded innovative products, technologies and services from a differentiated way of thinking and practicing. AgNews. May 2nd 2022. https://news.agropages.com/News/NewsDetail---42067.htm. September 21th 2022.
  • Alp, Y., & Şensoy, S. (2023). The Effects of Different Fertilizer Applications on Some Morphological Traits in Fresh Bean. Yuzuncu Yil University Journal of Agricultural Sciences, 33(1), 100-110.
  • Arifin, F., & Sukirah, A. R. (2020). Biodegradation of Carbofuran: a Review. Journal of Environmental Microbiology and Toxicology, 8(1), 50-57.
  • Bano, N., & Musarrat, J. (2004). Characterization of a novel carbofuran degrading Pseudomonas sp. with collateral biocontrol and plant growth promoting potential. FEMS Microbiol Lett., 231(1), 13-17.
  • Bertolote, J. M., Fleischmann ,A., Eddleston, M., & Gunnell, D. (2006). Deaths from pesticide poisoning: a global response. Br. J. Psychiatry, 189(3), 201-203.
  • Buque, E. M., Chin-Joe, I., & Straathof, A. J. J. (2002). Immobilization affects the rate and enantioselectivity of 3-oxo-ester reduction by baker's yeast. Enzyme Microb. Technol., 31, 656-664.
  • Cheah, U-B., Kirkwood, R. C., & Lum, K-Y. (1997). Adsorption, desorption and mobility of four commonly used pesticides in Malaysian agricultural soils. Pestic. Sci., 50(1), 53-63.
  • Cycon, M., Mrozik, A., & Piotrowska-Seget, Z. (2017). Bioaugmentation as a strategy for the remediation of pesticide-polluted soil: A review. Chemosphere, 172(1), 52-71.
  • Damayanti, A. C. K. A, Kumoro, A. C., & Bahlawan, Z. A. S. (2021). Review Calcium Alginate Beads as Immobilizing Matrix of Functional Cells: Extrusion Dripping Method, Characteristic and Applications. IOP Conf. Ser.: Mater. Sci. Eng. October 6th -7th Semarang, Indonesia. 1053 012017.
  • Das, A. C., Chakravarty, A., Sen, G., Sukul, P., & Mukherjee, D. (2005). A comparative study on the dissipation and microbial metabolism of organophosphate and carbamate insecticides in orchaqualf and fluvaquent soils of West Bengal. Chemosphere, 58(5), 579-584.
  • De Ory, I., Cabrera, G., Ramirez, M., & Blandino, A. (2020). Immobilization of Cells on Polyurethane Foam. In: Guisan, J., Bolivar, J., López-Gallego, F., Rocha-Martín, J. (eds) Immobilization of Enzymes and Cells. Methods in Molecular Biology, vol 2100. Humana, New York, NY.
  • Duc, H. D. (2022). Enhancement of carbofuran degradation by immobilized Bacillus sp. Strain DT1. Environmental Engineering Research, 27(4),1-23.
  • Eras-Muñoz, E., Abel F., Antoni S., Xavier F., & Teresa, G. (2022). Microbial biosurfactants: a review of recent environmental applications. Bioengineered, 13(5),12365–12391.
  • Fareed, A., Sania, R., Ismat, N., Mazhar, I., Raza, A., Jamshaid, H., Azhar, H., Azhar, R. & Tatheer, A.N. (2019). Immobilized cells of a novel bacterium increased the degradation of N-methylated carbamates under low temperature conditions, Heliyon, 5(11),1-8.
  • Feng, X., Ou, L-T., & Ogram, A. (1997). Plasmid-mediated mineralization of carbofuran by Sphingomonas sp. strain CF06. Appl Environ Microbiol, 63(4),1332–1337.
  • Fravel, D.R., Lumsden, R.D., & Connick, W. J. Jr. (1985). Encapsulation of potential biocontrol agent in alginate –clay matrix. Phytopathology, 76, 774 – 777.
  • Gupta, M., Mathur, S., Sharma, T. K., Rana, M., Gairola, A., Navani, N. K., & Pathania, R. (2016). A study on metabolic prowess of Pseudomonas sp. RPT 52 to degrade imidacloprid, endosulfan and coragen. Journal of Hazardous Materials, 301, 250-258.
  • Gupta, J., Rathour, R., Singh, R., & Thakur, I.S. (2019). Production and characterization of extracellular polymeric substances (EPS) generated by a carbofuran degrading strain Cupriavidus sp. ISTL7. Bioresource Technology, 282, 417–424.
  • Hu, B., & Chen, S. (2007). Pretreatment of methanogenic granules for immobilized hydrogen fermentation, Int. J. Hydrogen Energy, 32(15), 3266–3273.
  • Ishag, A. E., Abdelbagi, A. O., Hammad, A. M., Elsheikh, E. A., Elsaid, O. E., Hur, J. H., & Laing, M. D. (2016). Biodegradation of Chlorpyrifos, Malathion, and Dimethoate by Three Strains of Bacteria Isolated from Pesticide-Polluted Soils in Sudan. Journal of Agricultural and Food Chemistry, 64(45), 8491-8498.
  • Islam, F., Wang, J., Farooq, M.A., Khan, M.S.S., Xu, L., & Zhu, J. (2018). Potential impact of the herbicide 2,4-dichlorophenoxyacetic acid on human and ecosystems. Environ Int, 111, 332–351.
  • Jeon, Y., Bissesur A., & Singh, P. (2019). Novel immbolization techniques of Acinobacter (V2) and Paenibacillus (D9) bacterial strains for waste oil degradation. Biotechnology & Biotechnological Equipment, 33(1), 911-920.
  • Kamboj, A., Kiran, R., & Sandhir, R. (2005). Isolation and characterization of carbofuran degrading bacteria from soil. Asian J Microbiol Biotechnol Environ Sci, 7(3), 355–358.
  • Karns, J.S., Mulbry, W.W., Nelson, J.O., & Kearney, P.C. (1986). Metabolism of carbofuran by a pure bacterial culture. Pestic Biochem Physiol, 25(2), 211–217.
  • Kar, S., & Ray, R.C. (2008). Statistical optimization of á-amylase production by Streptomyces erumpens MTCC 7317 cells in calcium alginate beads using response surface methodology. Pol J Microbiol, 57(1), 49-57.
  • Li, D.S., Junqiao, F., Yi-Fan, L., Lei, Z., Jin-Feng, L., Ji-Dong, G., Bo-Zhong, M., & Shi-Zhong, Y. (2020). Enrichment and immobilization of oil-degrading microbial consortium on different sorbents for bioremediation testing under simulated aquatic and soil conditions. Applied Environmental Biotechnolog, 5(1), 1-11.
  • Lima, D., Viana, P., André, S., Chelinho, S., Costa, C., & Ribeiro R. (2009). Evaluating a bioremediation tool for atrazine contaminated soils in open soil microcosms: The effectiveness of bioaugmentation and biostimulation approaches. Chemosphere, 74(2), 187–192.
  • Lu, J., & Toy, P.H. (2009). Organic polymer supports for synthesis and for reagent and catalyst immobilization. Chem Rev, 109(2), 815-838.
  • Matshui, T., & Tomohiko, N. (2017). Degradation of Alkana by bacteria immobilized in polyurethane foam. Journal of The Japan Petroleum Institute, 60(3), 154-157.
  • Mishra, S., Wenping, Z., Ziqiu, L., Shimei, P., Yaohua, H., Pankaj, B., & Shaohua, C. (2020). Carbofuran toxicity and its microbial degradation in contaminated environments, Chemosphere, 259(6), 1-15.
  • Moon, H., Suhyeok, K., Byung, H.J., & Hyung, J.C. (2020). Immobilization of genetically engineered whole-cell biocatalysts with periplasmic carbonic anhydrase in polyurethane foam for enzymatic CO2 capture and utilization. Journal of CO2 Utilization, 39, 1-7.
  • Morel, C. C., Parekh, N. R., Pautrel, D., & Fournier, J C. (1996). Cross-enhancement of karbofuran biodegradation in soil samples previously treated with carbamate pesticides. Soil Biol Biochem, 28(12), 1767–76.
  • Nabhan, K.J., Khalik, W.M.A.W.M., Abdullah, M.P., Othman, M.R., Isahak, A., & Zulkepli, S.A. (2018). Assessment of multiresidue pesticides in agricultural soils from ledang, Malaysia and related potential health risks. Nat Environ Pollut Technol, 17(1), 99–106.
  • Nemati, M. & Webb, C. (2019). Comprehensive Biotechnology, Third Edition Vol. 6. Environmental and Related Biotechnologies. Editor-in-Chief: Murray Moo-Young, University of Waterloo, Waterloo, ON, Canada. ISBN 987-0-444-64047-5.
  • PAN Asia Pacific, (2022). Malaysia commended for banned on chlorpyrifos and carbofuran August 23, 2022.https://panap.net/2022/08/malaysia-commended-for-ban-on-chlorpyrifos-and-carbofuran/ September 21th 2022.
  • Pandey, G., Dorrian, S. J., Russell, R. J., Brearley, C., Kotsonis, S., & Oakeshott, J. G. (2010). Cloning and biochemical characterization of a novel carbendazim (methyl-1H-benzimidazol-2-ylcarbamate)-hydrolyzing esterase from the newly isolated Nocardioides sp. strain SG-4G and its potential for use in enzymatic bioremediation. Applied and Environmental Microbiology, 76(9), 2940-2945.
  • Parekh, N.R., Suett, D.L., Roberts, S.J., McKeown, T., Shaw, E.D., & Jukes, A.A. (1994). Carbofuran‐degrading bacteria from previously treated field soils Get access Arrow. Journal of Applied Bacteriology, 76(6), 559–567.
  • Partovinia, A. & Rasekh, B. (2018). Review of Immobilized microbial cell system for bioremediation of petroleum hydrocarbon polluted environment. Critical Review in Environmental Science and Technology, 48(1), 1-38.
  • Pathak, V.M., Verma, V.K., Rawat, B.S., Kaur, B., Babu, N., Sharma, A., Dewali, S., Yadav, M., Kumari, R., Singh, S., Mohapatra, A., Pandey. V., Rana, N., & Cunill, J.M. (2022). Current status of pesticide effects on environment, human health and it’s eco-friendly management as bioremediation. Front Microbiol, 17(13), 1-29.
  • Plangklang, P., & Reungsang, A. (2011). Bioaugmentation of carbofuran residues in soil by Burkholderia cepacia PCL3: A small-scale field study. Int Biodeterior Biodegrad, 65(6), 902–905.
  • Racke, K.D., & Coats, J.R. (1988). Comparative Degradation of Organophosphorus Insecticides in Soil: Specificity of Enhanced Microbial Degradation. J Agric Food Chem, 36(1), 193–199.
  • Rahimi, A., Gitari, H., Lyons, G., Heydarzadeh, S., Tuncturk, M., & Tuncturk, R. (2023). Effects of Vermicompost, Compost and Animal Manure on Vegetative Growth, Physiological and Antioxidant Activity Characteristics of Thymus vulgaris L. under Water Stress. Yuzuncu Yil University Journal of Agricultural Sciences, 33(1), 40-53.
  • Sarkar, S. (2021). The use of pesticide in developing countries and their impact on health and theright to food. Policy Department for External Relations. Directorate General fo External Policy of the Union. PE. 653-652.
  • Sarwar, A., Günter, B., Erika, C., Gajendar, A., Muhammad, A., Angela, S., & Fauzia, Y.H. (2018). Qualitative analysis of biosurfactants from Bacillus species exhibiting antifungal activity. PLoS One, 13(6), 1-15.
  • Schoebitz, M., Ceballos, C., & Ciampi, L. (2013). Effect of immobilized phosphate solubilizing bacteria on wheat growth and phosphate uptake. Journal of Soil Science and Plant Nutrition, 13(1), 1-10.
  • Sharip, Z., Hashim, N., & Suratman, S. (2017). Occurrence of organochlorine pesticides in a tropical lake basin. Environ Monit Assess, 189(11), 560.
  • Shin, D-H., Kim, D-U., Seong, C-N., Song, H-G. & Ka J-O. (2012). Genetic and phenotypic diversity of carbofuran-degrading bacteria isolated from agricultural soils. J Microbiol Biotechnol, 22(4), 448–456.
  • Slaoui, M., Ouhssine, M., Berny, E., & Elyachioui, M. (2007). Biodegradation of the carbofuran by a fungus isolated from treated soil. Afr J Biotechnol, 6(4), 419–423.
  • Soo, C-L., Chen-Ann, C., Othman, B., & Yii-Siang, H. (2017). Feasibility of marine microalga immobilization in alginate beads for marine water treatment: Bead stability,cell growth and ammonia removal. International Journal of Polymer Science, 1, 1 – 7.
  • Talwar, M. P., Mulla, S. I., & Ninnekar, H. Z. (2014). Biodegradation of organophosphate pesticide quinalphos by Ochrobactrum sp. strain HZM. Journal of Applied Microbiology, 117(5), 1283-1292.
  • Tomasek, P.H., & Karns, J.S. (1989). Cloning of a carbofuran hydrolase gene from Achromobacter sp. strain WM111 and its expression in gram-negative bacteria. J Bacteriol, 71(7), 4038–4044.
  • Utami, R.R., Gertjan, W. G., Indah R. S. S., & Suprihanto, N. (2020). Agricultural Pesticide Use In The Upper Citarum River Basin: Basic D Basin: Basic Data For Model-Based Risk M A For Model-Based Risk Management. Journal of Environmental Science and Sustainable Development, 3(2), 235-260.
  • Wu, X., Yin, Y., Wang, S., & Yu, Y. (2014). Accumulation of chlorothalonil and its metabolite,4-hydroxychlorothalonil, in soil after repeated applications and its effects on soil microbial activities undegreenhouse conditions. Environmental Science and Pollution Research, 21(5), 3452-3459.
  • Xu, J., Hong, Q., Wu, J., Yan, Q., & Li, S. (2009). Cloning of a gene related to carbofuran hydrolyzing from Sphingomonas agrestisCDS-1 by transposon rescue. Chin J Appl Environ Biol, 15(5), 677–681.
  • Yan, Q.X., Hong, Q., Han, P., Dong, X.J., Shen, Y.J., & Li, S.P. (2007). Isolation and chacterization of a carbofuran-degading strain Novisphingobium sp. FND. 3. FEMS Microbiol Lett, 271(2), 207-213.
There are 55 citations in total.

Details

Primary Language English
Subjects Enzyme and Microbial Biotechnology in Agriculture
Journal Section Articles
Authors

Nunuk Priyani 0009-0008-1488-7382

Dwi Suryanto 0000-0003-0010-2958

Edison Purba 0000-0002-9366-2489

Erman Munır 0000-0003-2815-4856

Early Pub Date September 16, 2024
Publication Date September 30, 2024
Acceptance Date May 4, 2024
Published in Issue Year 2024 Volume: 34 Issue: 3

Cite

APA Priyani, N., Suryanto, D., Purba, E., Munır, E. (2024). Isolation and Immobilization of Biosurfactant-Producing Bacteria Capable of Degrading Carbofuran Pesticide. Yuzuncu Yıl University Journal of Agricultural Sciences, 34(3), 475-488. https://doi.org/10.29133/yyutbd.1352398
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Yuzuncu Yil University Journal of Agricultural Sciences by Van Yuzuncu Yil University Faculty of Agriculture is licensed under a Creative Commons Attribution 4.0 International License.