Metrika

  • citati u SCIndeksu: 0
  • citati u CrossRef-u:0
  • citati u Google Scholaru:[]
  • posete u poslednjih 30 dana:3
  • preuzimanja u poslednjih 30 dana:2

Sadržaj

članak: 5 od 20  
Back povratak na rezultate
Zaštita materijala
2019, vol. 60, br. 2, str. 152-156
Ispitivanje mikrobnog diverziteta zemljišta tretiranog nikosulfuronom
Sunulahpašić Amera, Hamidović Saudb, Mitrić Sinišac, Gavrić Teofilb, Haseljić Sanelb, Lalević Blažod ORCID
aMinistry of agriculture, water management and forestry, Travnik, Bosnia and Herzegovina
bUniverzitet u Sarajevu, Poljoprivredno-prehrambeni fakultet, Federacija BiH
cUniverzitet u Banjoj Luci, Poljoprivredni fakultet, Republika Srpska, BiH
dUniverzitet u Beogradu, Poljoprivredni fakultet, Srbija

e-adresablazol@agrif.bg.ac.rs
Projekat:
Biodiverzitet kao potencijal u ekoremedijacionim tehnologijama oštećenih ekosistema (MPNTR - 31080)

Sažetak
Nikosulfuron pripada grupi pesticide sulfonil urea, koji imaju široku primenu u uništavanju korova. Iako je njegova primena korisna sa aspekta uspešne biljne proizvodnje, njegova višegodišnja upotreba može imati toksične efekte za živi svet, uključujući i mikroorganizme. Cilj ovog rada bio je ispitivanje uticaja nikosulfurona na mikrobni diverzitet zemljišta. Uzorkovanje zemljišta (0-20 i 20-40 cm) tretiranog nikosulfuronom na području sela Trenica (Opština Novi Travnik, Bosna i Hercegovina) obavljeno je u jesen 2017. godine. Određivanje mikrobnog diverziteta (ukupnog broja bakterija, amonifikatora, gljiva I aktinomiceta) izvršeno je korišćenjem standardnih metoda, dok su bakterije tolerantne na prisustvo nikosulfurona određene metodom obogaćenja. Kontrolu je predstavljalo zemljište koje nije tretirano nikosulfuronom. Rezultati ukazuju da su bakterije bile najbrojnija populacija mikroorganizama. U svim varijantama ogleda konstatovana je redukcija mikrobnog diverziteta u zemljištu koje je tretirano nikosulfuronom u odnosu na kontrolni uzorak. Stepen redukcije bio je najveći kod gljiva, čija je brojnost redukovana za 38-60% u odnosu na kontrolu. Nekoliko izolata bakterija tolerantnih na prisustvo nikosulfurona je izolovano iz uzoraka zemljišta metodom obogaćenja. Mikroskopskim ispitivanjem I pomoću API i APIWEB metode, izolati 17cs, odnosno 22wl i 5wl, su identifikovani kao Pseudomonas fluorescens, odnosno Bacillus subtilis. Ovi bakterijski izolati bi mogli da imaju potencijalnu primenu u remedijaciji ekosistema kontaminiranih nikosulfuronom.
Reference

Bhattarai, A., Bhattarai, B., Pandey, S. (2015) Variation of soil microbial population in different soil horizons. Journal of Microbiology & Experimentation, 2, 00044

Carles, L., Joly, M., Bonnemoy, F., Leremboure, M., Batisson, I., Besse-Hoggan, P. (2017) Identification of sulfonylurea biodegradation pathways enabled by a novel nicosulfuron-transforming strain Pseudomonas fluorescens SG-1: Toxicity assessment and effect of formulation. Journal of Hazardous Materials, 324: 184-193

Deslippe, A.J.J.R. (2013) Soil microbes and their contribution to soil services. u: Ecosystem services in New Zealand: Conditions and trends, Lincoln, New Zealand: Manaaki Whenua Press

Ding, F., Liu, W., Li, N., Zhang, L., Sun, Y. (2010) Complex of nicosulfuron with human serum albumin: A biophysical study. Journal of Molecular Structure, 975(1), 256-264

Eilers, K.G., Debenport, S., Anderson, S., Fierer, N. (2012) Digging deeper to find unique microbial communities: the strong effect of depth on the structure of bacterial and archaeal communities in soil. Soil Biology and Biochemistry, 50, 58-65

Huang, X., He, J., Sun, J.Q., Pan, J.J., Sun, X.F., Li, S.P. (2007) Isolation and characterization of a metsulfuron-methyl degrading bacterium Methylopila sp. S113. International Biodeterioration and Biodegradation, 60, 152-158

Hussain, S., Siddique, T., Saleem, M., Arshad, M., Khalid, A. (2009) Impact of pesticides on soil microbial diversity, enzymes, and biochemical reactions. Advances in Agronomy, 102: 159-200

Igbinosa, E.O. (2015) Effect of cassava mill effluent on biological activity of soil microbial community. Environmental Monitoring and Assessment, 187, 418

Joly, P., Bonnemoy, F., Charvy, J.C., Bohatier, J., Mallet, C. (2013) Toxicity assessment of the maize herbicides S-metolachlor, benoxacor, mesotrione and nicosulfuron, and their corresponding commercial formulations, alone and in mixtures, using the Microtox(®) test. Chemosphere, 93(10), 2444-2450

Kang, Z.H., Dong, J.G., Zhang, J.L. (2012) Optimization and characterization of nicosulfuron-degrading enzyme from Bacillus subtilis strain YB1. Journal of Integrative Agriculture, 11(9), 1485-1492

Kingsbury, J.M., Yang, Z., Ganous, T.M., Cox, G.M., McCusker, J.H. (2004) Cryptococcus neoformans llv2p confers resistance to sulfometuron methyl and is required for survival at 37°C and in vivo. Microbiology, 150(5): 1547-1558

Lafontaine, Y., Beauvais, C., Cessna, A.J., Gagnon, P., Hudon, C., Poissant, L. (2014) Sulfonylurea herbicides in an agricultural catchment basin and its adjacent wetland in the St. Lawrence River basin. Science of Total Environment, 479-480, 1-10

Leboulanger, C., Rimet, F., de Lacotte, M., Berard, A. (2001) Effects of atrazine and nicosulfuron on freshwater microalgae. Environmental International, 26, 131-135

Lu, X.H., Kang, Z.H., Tao, B., Wang, Y.N., Dong, J.G., Zhang, J.L. (2012) Degradation of nicosulfuron by Bacillus subtilis YB1 and Aspergillus Niger YF1. Applied Biochemistry and Microbiology / Priklad Biokhimii i Mikrobiologii, 48(5): 460-466

Mallek, A.Y., Moharram, A.M., Abdel-Kader, M.I., Omar, S.A. (1994) Effect of soil treatment with the organophosphorus insecticide profenofos on the fungal flora and some microbial activities. Microbiology Research, 149: 167-171

Pampulha, M.E., Oliveira, A. (2006) Impact of an herbicide combination of bromoxynil and on soil microorganisms. Current Microbiology, 53, 238-243

Pardo, T., Clemente, R., Epelde, L., Garbisu, C., Bernal, M.P. (2014) Evaluation of the phytostabilisation efficiency in a trace elements contaminated soil using soil health indicators. Journal of Hazardous Materials, 268, 68-76

5

Peper, I.L., Gerba, C.P., Brendencke, J.W. (1995) Environmental microbiology. San Diego, CA: Academic Press, p. 11-33

Petric, I., Karpouzas, D.G., Bru, D., Udikovic-Kolic, N., Kandeler, E., Djuric, S., Martin-Laurent, F. (2016) Nicosulfuron application in agricultural soils drives the selection towards NS-tolerant microorganisms harboring various levels of sensitivity to nicosulfuron. Environmental Science and Pollution Research, 23(5): 4320-4333

Singh, J.S., Abhilash, P.C., Singh, H.B., Singh, R.P., Singh, D.P. (2011) Genetically engineered bacteria: An emerging tool for environmental remediation and future research perspectives. Gene, 480(1-2): 1-9

Sutton, N.B., Maphosa, F., Morillo, J.A., Abu, A.W., Langenhoff, A.A., Grotenhuis, T., Rijnaarts, H.H., Smidt, H. (2013) Impact of long-term diesel contamination on soil microbial community structure. Applied and Environmental Microbiology, 79, 619-630

Šantrić, Lj., Radivojević, Lj., Gajić-Umiljendić, J., Sarić-Krsmanović, M., Đurović-Pejčev, R. (2018) The effects of nicosulfuron and glyphosate on microbial activity of different soils. Planta Daninha, v36, e018159989

1

Šantrić, L., Radivojević, L., Gajić-Umiljendić, J., Đurović-Pejčev, R., Sarić-Krsmanović, M. (2014) Assessment of microbial activity and biomass in different soils exposed to nicosulfuron. Pesticidi i fitomedicina, vol. 29, br. 3, str. 213-219

1

Talaie, A.R., Jafaarzadeh, N., Talaie, M., Beheshti, M. (2010) Biodegradation of aromatic compounds in crude oil by isolated microorganisms from environment. Scientific Journal of Zanjan University of Medical Sciences and Health Services, 18(70), 68-80

Tang, Q., Zhao, Z., Liu, Y., Wang, N., Wang, B., Wang, Y., Zhou, N., Liu, S. (2012) Augmentation of tribenuron methyl removal from polluted soil with Bacillus sp. strain BS2 and indigenous earthworms. Journal of Environmental Sciences, 24(8): 1492-1497

Ventorino, V., Sannino, F., Piccolo, A., Cafaro, V., Carotenuto, R., Pepe, O. (2014) Methylobacterium populi VP2: Plant growth-promoting bacterium isolated from a highly polluted environment for polycyclic aromatic hydrocarbon (PAH) biodegradation. Scientific World Journal, 2014, 93793

Ventorino, V., Pascale, A., Adamo, P., Rocco, C., Fiorentino, N., Mori, M., Faraco, V., Pepe, O., Pepe, M. (2018) Comparative assessment of autochthonous bacterial and fungal communities and microbial biomarkers of polluted agricultural soils of the Terra dei Fuochi. Scientific Reports, 8, 14281

Wasi, S., Tabrez, S., Ahmad, M. (2013) Use of Pseudomonas spp. for the bioremediation of environmental pollutants: A review. Environmental Monitoring and Assessment, 185(10): 8147-8155

Xu, J., Li, X.S., Xu, Y.J., Qiu, L.H., Pan, C.P. (2009) Biodegradation of pyrazosulfuron-ethyl by three strains of bacteria isolated from contaminated soils. Chemosphere, 74, 682-687

Zhao, H., Zhu, J., Liu, S., Zhou, X. (2018) Kinetic study of nicosulfuron degradation by a Pseudomonas nitroreducens strain NSA02. Biodegradation, 29, 271-283

Zhao, H., Zhu, J., Liu, S., Zhou, X. (2018) Kinetics study of nicosulfuron degradation by a Pseudomonas nitroreducens strain NSA02. Biodegradation, 29(3): 271-283

Zhou, Y., Liu, W., Ye, H. (2006) Effects of pesticides metolachlor and S-metolachlor on soil microorganisms in aquisols: Soil respiration. Ying Yong Sheng Tai Xue Bao, II, 17: 1305-1309
   

O članku

jezik rada: engleski
vrsta rada: naučni članak
DOI: 10.5937/zasmat1902152S
objavljen u SCIndeksu: 14.06.2019.
Creative Commons License 4.0

Povezani članci

Nema povezanih članaka