Mixed bacterial consortium can hamper the efficient degradation of crude oil hydrocarbons

Crude oil degradation efficiency can be improved because of co-metabolism that exists when bacterial consortium is applied. However, because of possible vulnerability to environmental conditions and/or antagonistic interactions among members of the consortium, the degradation efficiency can be hampe...

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Bibliographic Details
Published in:Archives of microbiology 2022-06, Vol.204 (6), p.306-306, Article 306
Main Authors: Nnabuife, Obianuju Obiajulu, Ogbonna, James Chukwuma, Anyanwu, Chukwudi, Ike, Anthony Chibuogwu, Eze, Chibuzor Nwadibe, Enemuor, Simeon Chukwuemeka
Format: Article
Language:English
Subjects:
Bacteria
Biochemistry
Biodegradation
Biodegradation, Environmental
Biomedical and Life Sciences
Bioremediation
Biotechnology
Cell Biology
Chromatography, Gas
Consortia
Crude oil
Ecology
Efficiency
Environmental changes
Environmental conditions
Gas chromatography
Germfree
Gravimetric analysis
Hydrocarbon-degrading bacteria
Hydrocarbons
Hydrocarbons - metabolism
Life Sciences
Metabolism
Microbial Ecology
Microbiology
Oil
Oil pollution
Original Paper
Petroleum - metabolism
Population decline
Pseudomonas aeruginosa
Serratia marcescens - metabolism
Spectrophotometry
Synergistic effect
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Summary:Crude oil degradation efficiency can be improved because of co-metabolism that exists when bacterial consortium is applied. However, because of possible vulnerability to environmental conditions and/or antagonistic interactions among members of the consortium, the degradation efficiency can be hampered. In this laboratory-based study, the biodegradation potentials of pure bacterial isolates namely Pseudomonas aeruginosa strain W15 (MW320658), Providencia vermicola strain W8 (MW320661) and Serratia marcescens strain W13 (MW320662) earlier isolated from crude oil-contaminated site and their consortium were evaluated using 3% crude oil-supplemented Bushnell Haas media. The efficiency was evaluated based on the viable cell count, biosurfactant analyses, percentage hydrocarbon degradation using gravimetric analysis and gas chromatography–mass spectrophotometry (GC–MS) analysis. There was decline in the population of W13 and predominance of W15 in the consortium as the incubation period progressed. Accelerated biodegradation of the crude oil hydrocarbons through co-metabolism was not achieved with the consortium; neither was there any improved resilience nor resistance to environmental changes of strain W13. The GC–MS analyses showed that the highest degradation was produced by W15 (48.23%) compared to W8 (46.04%), W13 (45.24%) and the Consortium (28.51%). The biodegradation of the crude oil hydrocarbons by W15, W8, W13 axenic cultures and their consortium treatments demonstrated that the bacterial constituent in a consortium can influence the synergistic effect that improves bioremediation. Future research that focuses on evaluating possible improvement in bioremediation through maintenance of diversity by continuous bioaugmentation using vulnerable but efficient degraders in a consortium is necessary to further understand the application of consortia for bioremediation improvement.
ISSN:0302-8933
1432-072X
DOI:10.1007/s00203-022-02915-9