Biological treatment of hydrocarbons contaminated soil by Serratia ficaria

Nahla Shadeed Ajeel; Ahmed Jasim Mohammed

doi:10.53730/ijhs.v6nS9.12415

Authors

Nahla Shadeed Ajeel
nahla_bio2007@yahoo.com
Envioromental engineering department, College of engineering / University of Baghdad, Iraq
Ahmed Jasim Mohammed Biology department, College of sciences / University of Baghdad, Iraq

Keywords:

biological treatment, bioremediation, contaminated soil, hydrocarbons, Serratia ficaria

Abstract

Petroleum is one of the most important substances consumed by man at present times, a major energy source in this century, petroleum oils can cause environmental pollution during various stages of production, transportation, refining and use, petroleum hydrocarbons pollutions ranging from soil, ground water to marine environment, become an inevitable problem in the modern life, current study focused on bioremediation process of hydrocarbons contaminants that remaining in the bottom of gas cylinders and discharged to the soil. Twenty-four bacterial isolates were isolated from contaminated soils all of them gram negative bacteria, bacterial isolates screening to investigate the ability of biodegradation of hydrocarbons, these isolates inoculated with modified mineral salt media containing 1% hydrocarbons for five days in shaking incubator 150 rpm at 30^oC. Then measured optical density by a spectrophotometer (UV–9200) at waves length 540nm, biomass, where three isolates appeared highest ability to growth than others isolates. These three bacterial isolates were diagnosed by morphological features, gram stain, microscopically examination, biochemical tests, as well as by using VITEK 2 Compact device. One of three isolates was selected and result of identification of this bacterium showed that belonged to Serretia ficaria.

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References

A. Al-Zahrani, and M. Gaber, Biological Treatment of Hydrocarbon ontaminants:Petroleum Hydrocarbon uptake by Pseudomonas alkanolytica. JKAU: Eng. Sci., 21(1), 39-53, 2010.

AlMashhadani HA, Saleh KA. Electrochemical Deposition of Hydroxyapatite Co-Substituted By Sr/Mg Coating on Ti-6Al-4V ELI Dental Alloy Post-MAO as Anti-Corrosion. Iraqi Journal of Science. 2020 Nov 28:2751-61.

AlMashhadani HA. Corrosion protection of pure titanium implant in artificial saliva by electro-polymerization of poly eugenol. Egyptian Journal of Chemistry. 2020 Aug 1;63(8):2803-11.

Arora, S., Kumar, D., Akram, W., Alam, S., Bhati, K., Kumari, A., & Sharma, V. (2022). Novel treatment strategies and involvement of international agencies for the control of asthma. International Journal of Health Sciences, 6(S1), 11025–11050. https://doi.org/10.53730/ijhs.v6nS1.7651

Ayodele R. Ipeaiyeda, Gloria O. Nwauzor, and Samuel O. Akporido, Biodegradation of Polycyclic Aromatic Hydrocarbons in Agricultural Soil Contaminated with Crude Oil from nigeria refinery using leurotus sajor-caju. Journal of Bioremediation & Biodegradation, 2015, 2015.

C. Calvo, M. Manzanera, G. Silva, I. Uad, and J. Gonzalez, Application of bioemulsifiers in soil oil bioremediation processes. Future prospects. Science of The Total Environmen, 407(12), 3634-3640, 2009.

Chang YH, Han J, Chun J, Lee KC, Rhee MS, Kim YB, Baae KS. Comamonas koreensis sp., a non-motile species from wetland in woopo, korea. Int.j. syst. Evol. Microbial, 52, 2002, 377-318.

Christian O. Nweke1 Gideon C. Okpokwasil, Inhibition of dehydrogenase activity in petroleum refinery wastewater bacteria by phenolic compounds, Taubate, 5(1), 2010, 6-16.

Ha, H., Olson, J., Bian, L., Rogerson, P.A. Analysis of heavy metal sources in soil using kriging interpolation on principal components. Environ. Sci. Technol. 48, 2014, 4999-5007.

Hentati, R. Lachhab, M. Ayadi, M. Ksibi Toxicity assessment for petroleum-contaminated soil using terrestrial invertebrates and plant bioassays. Environ. Monit. Assess., 185 (2013) 2989-2998.

Isenberg, H. D. and Sundheim, L. H.23T (1958). Indole reactions in bacteria. J. Bacteriol. 75, 2010, 682–690.

J. Pichtel, Oil and gas production wastewater: Soil contamination and pollution prevention . Applied and environmental soil science, 2016, 1-24, 2016.

J. Tamames, J. Abellan, MP. ignatelli, A. Moya, Environmental distribution of prokaryotic taxa. BMC Microbiol,10, 2010.

L. Petersen, L. Tisa, Friend or foe? A review of the mechanisms that drive Serratia towards diverse lifestyles. Can J Microbiol. 59(9), 2013, 627-40.

Liu, C. W., Chang, W. N. and Liu, H. S. Bioremediation of n-alkanes and the formation of biofloccules by Rhodococcus erythropolis NTU-1 under various saline conditions and sea water, Biochemical Engineering Journal, 45. 2009, 69–75.

M. Abubakar Clarkson, S.Abubakar, Bioremediation and biodegradation of hydrocarbon contaminated soils: A review. IOSR Journal of environmental science, Toxicology and Food Technology (IOSR-JESTFT) , 9(11) , 2015, 38-45.

M. Alexander, Biodegradation and Bioremediation 2nd ed. Academic Press, New York, NY, 1999.

M. Padmapriya, and B. Williams, Purification and characterization of neutral protease enzyme from Bacillus subtilis. J. Microbiol. Biotech. Res., 2(4), 2012, 612- 618.

M. Peng, X. Zi, and Q. Wang, Bacterial Community Diversity of Oil-Contaminated Soils Assessed by High Throughput Sequencing of 16S rRNA Genes. International Journal of Environmental Research and Public Health, 12, 2015, 12002-12015.

Madsen, E. L. 1998b. Theoretical and applied aspects of bioremediation: The influence of microbiological processes on organic compounds in field sites, pp. 354-407. In: Burlage, R., R. Atlas, D. Stahl, G. Geesey, and G. Sayler (Eds.).

N. Das, P. Chandran, Microbial degradation of petroleum hydrocarbon contaminants: An overview. Biotech Res Inter. 2011, 2011, 1-13.

Perni, S.; Andrew, P. W. and Shama, G). Estimating the maximum growth rate from microbial growth curves: definition is everything. Food Microbiology, 22, 2005, 491-495.

Reddy, P. G.; Singh , H. D.; Roy, P. K. ; Barnah, J. N. Predominant role of hydrocarbon solubilization in microbial up take of hydrocarbons . Biotechnology and Bioengineering, 24, 1982, 1241 – 1269.

S. Rayu, D. Karpozaus, B. Singh, Emerging technologies in bioremediation: constraints and opportunities.Biodegradation, 23, 2012 ,917-926.

S. Wang, X. Wang, C. ZhangF. Li, and G. Guo, Bioremediation of oil sludge contaminated soil by landfarming with added cotton stalks. Int Biodeter Biodegr. 106, 2008, 150-156.

Satriana, I. M. W. C. (2018). Dilemma on medical treatments: rejection of medical treatments by patients and elements of neglect through perspective of article 304 of criminal law. International Journal of Social Sciences and Humanities, 2(3), 180–186. https://doi.org/10.29332/ijssh.v2n3.228

Suryasa, I. W., Rodríguez-Gámez, M., & Koldoris, T. (2021). Get vaccinated when it is your turn and follow the local guidelines. International Journal of Health Sciences, 5(3), x-xv. https://doi.org/10.53730/ijhs.v5n3.2938

T. Anahory, H. Darbas, O. Ongaro, H. Jean, P. Mion, Serratia ficaria: a misidentified or unidentified rare cause of human infections in fig tree culture zones, Journal of Clinical Microbiology, 36(11), 1998, 3266-3272.

Young, L. Y., and C. E. Cerniglia. 1995. Microbial Transformation and Degradation of Toxic Organic Chemicals. Wiley Liss, Inc., New York, NY.