Comparison of selenite (IV) and selenate (VI) effect on some oxidoreductive enzymes in soil contaminated with spent engine oilęk M., Telesiński A. (2016): Comparison of selenite (IV) and selenate (VI) effect on some oxidoreductive enzymes in soil contaminated with spent engine oil  . Plant Soil Environ., 62: 157-163.
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This paper assesses the impact of spent engine oil on activity of dehydrogenase, nitrate reductase, catalase and o-diphenol oxidase in sandy soil, and evaluates biostimulation with selenates in the restoration of homeostasis of soil with spent engine oil. The experiment was carried out on loamy sand samples with organic carbon content of 8.71 g/kg, with the following variable factors: dose of spent engine oil: 0, 2, 10, 50 g/kg dry matter (DM) of soil; selenate application: without selenate, selenite (IV) and selenate (VI) in the amount of 0.05 mmol/kg DM of soil; day of experiment: 1, 7, 14, 28, 56, 112. Obtained results showed that spent engine oil increased activity of dehydrogenase and catalase. Application of selenite (IV) and selenate (VI) to soil non-contaminated with spent engine oil stimulated activity of dehydrogenase and nitrate reductase and inhibited in o-diphenol oxidase. Among selenates tested regarding biostimulation of oxidoreductases in soil contained spent engine, selenate (VI) is more useful than selenite (IV).  
Achuba Fidelis Ifeakachuku, Okoh Patrick Nwanze (2014): Effect of Petroleum Products on Soil Catalase and Dehydrogenase Activities. Open Journal of Soil Science, 04, 399-406
Achuba F.I., Peretiemo-Clarke B.O. (2008): Effect of spent engine oil on soil catalase and dehydrogenase activities. International Agrophysics, 22: 1–4.
Abdelmagid H.M., Tabatabai M.A. (1987): Nitrate reductase activity of soils. Soil Biology and Biochemistry, 19, 421-427
Bach Christopher E., Warnock Daniel D., Van Horn David J., Weintraub Michael N., Sinsabaugh Robert L., Allison Steven D., German Donovan P. (2013): Measuring phenol oxidase and peroxidase activities with pyrogallol, l-DOPA, and ABTS: Effect of assay conditions and soil type. Soil Biology and Biochemistry, 67, 183-191
Cartes P, Gianfreda L, Paredes C, Mora M.L (2011): Selenium uptake and its antioxidant role in ryegrass cultivars as affected by selenite seed pelletization. Journal of soil science and plant nutrition, 11, 1-14
Fu Lian-Hai, Wang Xiao-Feng, Eyal Yoram, She Yi-Min, Donald Lynda J., Standing Kenneth G., Ben-Hayyim Gozal (2002): A Selenoprotein in the Plant Kingdom. Journal of Biological Chemistry, 277, 25983-25991
Hermosillo-Cereceres M.A., Sánchez E., Muñoz-Márquez E., Guevara-Aguilar A., García-Bañuelos M., Ojeda-Barrios D. (2014): Impact of selenium fertilization on the activity of detoxifying enzymes of H2O2 in bean plants. Fyton, 83: 347–352.
Johnson John L., Temple Kenneth L. (1964): Some Variables Affecting the Measurement of “Catalase Activity” in Soil1. Soil Science Society of America Journal, 28, 207-
Kaczyńska Grażyna, Borowik Agata, Wyszkowska Jadwiga (2015): Soil Dehydrogenases as an Indicator of Contamination of the Environment with Petroleum Products. Water, Air, & Soil Pollution, 226, -
LI Hui, ZHANG Ying, KRAVCHENKO Irina, XU Hui, ZHANG Cheng-gang (2007): Dynamic changes in microbial activity and community structure during biodegradation of petroleum compounds: A laboratory experiment. Journal of Environmental Sciences, 19, 1003-1013
Margesin R., Walder G., Schinner F. (2000): The impact of hydrocarbon remediation (diesel oil and polycyclic aromatic hydrocarbons) on enzyme activities and microbial properties of soil. Acta Biotechnologica, 20, 313-333
Nowak J., Kaklewski K., Klódka D. (2002): Influence of various concentrations of selenic acid (IV) on the activity of soil enzymes. Science of The Total Environment, 291, 105-110
Nowak Janina, Kaklewski Krzysztof, Ligocki Marek (2004): Influence of selenium on oxidoreductive enzymes activity in soil and in plants. Soil Biology and Biochemistry, 36, 1553-1558
Nwite J.N., Alu M.O. (2015): Effect of different levels of spent engine oil on soil properties, grain yield of maize and its heavy metal uptake in Abakaliki, Southeastern Nigeria. Journal of Soil Science and Environmental Management, 6: 44–51.
Perucci P, Casucci C, Dumontet S (2000): An improved method to evaluate the o-diphenol oxidase activity of soil. Soil Biology and Biochemistry, 32, 1927-1933
Pilon-Smits E.A.H., Quinn C.F. (2010): Selenium metabolism in plants. Cell Biology of Metals and Nutrients, 17: 225–241.
Ramadass Kavitha, Megharaj Mallavarapu, Venkateswarlu Kadiyala, Naidu Ravi (2015): Ecological implications of motor oil pollution: Earthworm survival and soil health. Soil Biology and Biochemistry, 85, 72-81
Rao M.A, Scelza R, Scotti R, Gianfreda L (2010): ROLE OF ENZYMES IN THE REMEDIATION OF POLLUTED ENVIRONMENTS. Journal of soil science and plant nutrition, 10, -
Stręk M., Telesiński A. (2015a): Change in oxidoreductase activity of selected microbial enzymes in gasoline-contaminated light soil in presence of selenium. Ochrona Środowiska, 37: 43–47. (In Polish)
Stręk M., Telesiński A. (2015b): Assessment of selenium compounds use in limitation of petroleum impact on antioxidant capacity in sandy soil. Environmental Protection and Natural Resources, 26: 6–11.
Thalmann A. (1968): Zur Methodik der Bestimmung der Dehydrogenaseaktivität im Boden mittels Triphenyltetrazoliumchlorid (TTC). Landwirtschaftliche Forschung, 21: 249–258.
Wang J., Jia C.R., Wong C.K., Wong P.K. (2000): Characterization of polycyclic aromatic hydrocarbons created in lubricating oils. Water, Air and Soil Pollution, 120: 381–396.
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