Multispecies Diesel Fuel Biodegradation and Niche Formation Are Ignited by Pioneer Hydrocarbon-Utilizing Proteobacteria in a Soil Bacterial Consortium

Multispecies Diesel Fuel Biodegradation and Niche Formation Are Ignited by Pioneer Hydrocarbon-Utilizing Proteobacteria in a Soil Bacterial Consortium

A soil bacterial consortium that was grown on diesel fuel and consisted of more than 10 members from different genera was maintained through repetitive subculturing and was utilized as a practical model to investigate a bacterial community that was continuously exposed to petroleum hydrocarbons. Thr...

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Bibliographic Details
Published in:Applied and environmental microbiology Vol. 87; no. 1; pp. 1 - 19
Main Authors: Mori, Jiro F, Kanaly, Robert A
Format: Journal Article
Language:English
Published: United States American Society for Microbiology 17-12-2020
Subjects:
Achromobacter
Bacteria
Biodegradation
Biodegradation, Environmental
Biotransformation
Community structure
Consortia
Diesel
Diesel fuels
Ecological effects
Ecological niches
Gasoline
Hydrocarbons
Hydrocarbons - metabolism
Metabolism
Metabolites
Metagenomics
Microbial Consortia
Niches
Petroleum hydrocarbons
Pollutants
Proteobacteria - metabolism
Pseudomonas
Soil Microbiology
Soil microorganisms
Soils
Sphingobium
Survival
soil bacterial community
diesel fuel biodegradation
metagenomics
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Summary:A soil bacterial consortium that was grown on diesel fuel and consisted of more than 10 members from different genera was maintained through repetitive subculturing and was utilized as a practical model to investigate a bacterial community that was continuously exposed to petroleum hydrocarbons. Through metagenomics analyses, consortium member isolation, growth assays, and metabolite identification which supported the linkage of genomic data and functionality, two pioneering genera, and , whose catabolic capabilities were differentiated, were found to be responsible for the creation of specialized ecological niches that were apparently occupied by other bacterial members for survival within the consortium. Coexisting genera and maintained their existence in the consortium through metabolic dependencies by utilizing hydrocarbon biotransformation products of pioneer metabolism, which was confirmed through growth tests and identification of biotransformation products of the isolated strains. Pioneering and s spp. utilized relatively water-insoluble hydrocarbon parent compounds and facilitated the development of a consortium community structure that resulted in the creation of niches in response to diesel fuel exposure which were created through the production of more-water-soluble biotransformation products available to cocolonizers. That these and other organisms were still present in the consortium after multiple transfers spanning 15 years provided evidence for these ecological niches. Member survival through occupation of these niches led to robustness of each group within the multispecies bacterial community. Overall, these results contribute to our understanding of the complex ecological relationships that may evolve during prokaryotic hydrocarbon pollutant biodegradation. There are few metagenome studies that have explored soil consortia maintained on a complex hydrocarbon substrate after the community interrelationships were formed. A soil bacterial consortium maintained on diesel fuel was utilized as a practical model to investigate bacterial community relationships through metagenomics analyses, consortium member isolation, growth assays, and metabolite identification, which supported the linkage of genomic data and functionality. Two pioneering genera were responsible for the biodegradation of aromatics and alkanes by initiating biotransformation and thereby created specialized niches that were populated by other members. A model that represents these relationships was constructed, which contributes to our understanding of the complex ecological relationships that evolve during prokaryotic hydrocarbon pollutant biodegradation.
Bibliography:Citation Mori JF, Kanaly RA. 2021. Multispecies diesel fuel biodegradation and niche formation are ignited by pioneer hydrocarbon-utilizing proteobacteria in a soil bacterial consortium. Appl Environ Microbiol 87:e02268-20. https://doi.org/10.1128/AEM.02268-20.
ISSN:0099-2240
1098-5336
DOI:10.1128/aem.02268-20