Evaluation of Physico-Chemical and Fungal Species Associated with Oil Contaminated Soil from Selected Automobile Garage in Sokoto Metropolis
This study was conducted with a view to evaluating the physicochemical and mycological properties of different oil contaminated soils collected from three different automobile garages in Sokoto Metropolis, and uncontaminated soil from the temporary site, Usmanu Danfodiyo University, Sokoto (UDUS) was used as the control. The pH was determined using pH meter model Hanna (H1991301), quantity of mineral elements was evaluated in accordance with Murphy and Fungi were isolated from the three oil contaminated samples (A, B. and C) and the uncontaminated (sample D) as control, this was done by standard procedure using the method of P. Ren, T. Jankun & B. Leaderer. The physical, chemical, and mineral elements from the oil-contaminated soils of the three automobile garages and control. The results of particle soil analysis revealed the high content of sandy soil (96.2 to 87.3) and silt is the lowest with (2.5–0.6). Magnesium had the highest concentration of studied minerals, ranging from 193 to 649.2 mg/kg. while PH result revealed that the soil samples were pH value ranged from (16.85–16.20) in oil Contaminated samples, while the control had 15.90, and electrical conductivity ranged from 12.8–13.8 % and 28 % in control, four fungal isolates Aspergillus sp., Penicillum sp., Mucor sp. and Sporobolomyces sp. were identified based on colonial, sexual and morphological characteristics. These fungal strains can be used in bioremediation process and oil pollution reduction in aquatic ecosystems.
1. Abdus-Salam, N. (2009). Assessment of Heavy Metals Pollution in Dumpsites in Ilorin Metropolis. Ethiopian Journal of Environmental Studies and Management, 2(2).
2. Akpoveta, O., Osakwe, S., Okoh, B., & Otuya, B. (2011). Physicochemical Characteristics and Levels of Some Heavy Metals in Soils around Metal Scrap Dumps in Some Parts of Delta State, Nigeria. Journal of Applied Sciences and Environmental Management, 14(4).
3. Al-Wasify, R. S., & Hamed, S. R. (2014). Bacterial Biodegradation of Crude Oil Using Local Isolates. International Journal of Bacteriology, 2014, 1–8.
4. Chukwura, E. I., Ojiegbu, N. M., & Nwankwegu, A. S. (2016). Hydrocarbon degradation potentials of fungi associated with oil-contaminated soil from selected mechanic workshops in Awka, Anambra State, Nigeria. Frontiers in Environmental Microbiology, 2, 38–44.
5. Coleman, D. C., Callaham, M. A., & Crossley Jr, D. (2017). Fundamentals of soil ecology. Amsterdam: Academic press.
6. Eldor, P. A. (2015). Soil microbiology, ecology and biochemistry. Amsterdam: Academic press.
7. EL-Morsy, E.-S. M. (2005). Evaluation of microfunghi for the bioremediation of diesel oil in Egypt. Land Contamination & Reclamation, 13(2), 147–159.
8. Eze, V., Omeh, Y., & Ugweje, C. (2013). Microbiological and Physicochemical Assessment of Soil Contaminated with Lairage Effluent in Umuahia, Abia State, Nigeria. Journal of Pharmacy and Biological Sciences, 8(2), 50–56.
9. Fuentes, S., Méndez, V., Aguila, P., & Seeger, M. (2014). Bioremediation of petroleum hydrocarbons: catabolic genes, microbial communities, and applications. Applied Microbiology and Biotechnology, 98(11), 4781–4794.
10. Gbadebo, A., Taiwo, A., & Eghele, U. (2010). Environmental impacts of drilling mud and cutting wastes from the Igbokoda onshore oil wells, Southwestern Nigeria. Indian Journal of Science and Technology, 3(5), 504–510.
11. Hibbett, D. S., Binder, M., Bischoff, J. F., Blackwell, M., Cannon, P. F., Eriksson, O. E., … Lücking, R. (2007). A higher-level phylogenetic classification of the Fungi. Mycological Research, 111(5), 509–547.
12. Hillel, D. (2013). Fundamentals of soil physics. Amsterdam: Academic press.
13. Hillel, D. (2013). Introduction to soil physics. Amsterdam: Academic press.
14. Imarhiagbe, E., Osarenotor, O., Obayagbona, O., Eghomwanre, A., & Nzeadibe, B. (2017). Evaluation of physicochemical, microbiological and polycyclic aromatic hydrocarbon content of top soils from Oka Market Waste Collection Site, Benin City, Nigeria. Journal of Applied Sciences and Environmental Management, 21(1), 112–117.
15. Isbell, F., Reich, P. B., Tilman, D., Hobbie, S. E., Polasky, S., & Binder, S. (2013). Nutrient enrichment, biodiversity loss, and consequent declines in ecosystem productivity. Proceedings of the National Academy of Sciences, 110(29), 11911–11916.
16. Lawal, M. O., Samuel, O. B., Mogekwu, T. O., & Bolaji, D. A. (2013). Toxicity of Two Household Liquid Soaps on Poecilia reticulata Peters, 1859. Brazilian Journal of Aquatic Science and Technology, 17(1), 35.
17. McNamara, N. P., Black, H. I. J., Beresford, N. A., & Parekh, N. R. (2003). Effects of acute gamma irradiation on chemical, physical and biological properties of soils. Applied Soil Ecology, 24(2), 117–132.
18. Murphy, H. F. (1929). Some effects of crude petroleum on nitrate production, seed germination, and growth. Soil Science, 27(2), 117–120.
19. Ngozi, V., Wirnkor, V., & Ebere, E. (2017). Pollution assessment models of surface soils in Port Harcourt city, Rivers State, Nigeria. World News of Natural Sciences, 12, 1–20.
20. Obayagbona, N. O., & Enabulele, O. I. (2013). Biodegradation potentials of automobile workshop soil mycoflora on flow station petroleum sludge with an extra carbon source. The Journal of Microbiology, Biotechnology and Food Sciences, 3(1), 19–25.
21. Obi, M. (2000). Soil physics: A compendium of lectures. Nsukka: Atlanto Publishers.
22. Odiba, J. O., Matthew, O. A., & Chrysanthus, A. (2017). Evaluation of the physicochemical and heavy metal content of ground water sources in Bantaji and Rafin-Kada settlements of Wukari Local Government Area, Taraba State, Nigeria. Journal of Environmental Chemistry and Ecotoxicology, 9(4), 43–53.
23. Ologbosere, O. A., Aluyi, H. S. A., Ogofure, A. G., Beshiru, A., & Omeje, F. I. (2016). Physico-chemical and microbiological profile of bacterial and fungal isolates of Ikpoba River in Benin City: Public health implications. African Journal of Environmental Science and Technology, 10(3), 67–76.
24. Parveen, S., Iqbal, M. Z., Shafiq, M., & Athar, M. (2014). Effect of automobile polluted soil on early seedling growth performance of Neem (Azadirachta indica A. Juss.). Advances in Environmental Research, 3(1), 1–9.
25. Rathi, S. (2006). Alternative approaches for better municipal solid waste management in Mumbai, India. Waste Management, 26(10), 1192–1200.
26. Ren, P., Jankun, T. M., & Leaderer, B. P. (1999). Comparisons of seasonal fungal prevalence in indoor and outdoor air and in house dusts of dwellings in one Northeast American county. Journal of Exposure Science & Environmental Epidemiology, 9(6), 560–568.
27. Sharholy, M., Ahmad, K., Mahmood, G., & Trivedi, R. C. (2008). Municipal solid waste management in Indian cities – A review. Waste Management, 28(2), 459–467.
28. Udo, E. J., & Fayemi, A. A. A. (1975). The Effect of Oil Pollution of Soil on Germination, Growth and Nutrient Uptake of Corn1. Journal of Environment Quality, 4(4), 537.
29. Watkar, A., & Barbate, M. (2012). Annual Changes in Physico-Chemical Parameters of the Effluents of Pulpand Paper Mill in Saoner Region. Bionano Frontier, 16(1), 41–43.
30. Zhai, Y., Cui, L., Zhou, X., Gao, Y., Fei, T., & Gao, W. (2013). Estimation of nitrogen, phosphorus, and potassium contents in the leaves of different plants using laboratory-based visible and near-infrared reflectance spectroscopy: comparison of partial least-square regression and support vector machine regression methods. International Journal of Remote Sensing, 34(7), 2502–2518.
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