Harnessing the Potential of Native Microbial Communities for Bioremediation of Oil Spills in the Iberian Peninsula NW Coast

Bôto, Maria Luis de Vilar Correia Brito; Magalhães, Catarina; Perdigão, Rafaela; Alexandrino, Diogo A. M.; Fernandes, Joana P.; Bernabéu, Ana M.; Ramos, Sandra; Carvalho, Maria F.; Semedo, Miguel; LaRoche, Julie; Almeida, C. Marisa R.; Mucha, Ana P.

doi:10.3389/fmicb.2021.633659

Cited by 28 publications

(21 citation statements)

References 78 publications

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“…Oceanobacter -related bacteria (ORB) are clearly an ecologically important microbial clade in marine environments and are particularly involved in hydrocarbon metabolism. Notably, Thalassolituus and Oleibacter frequently occurred as predominant members in hydrocarbon-spiking microcosms of temperate seawater and sediment ( Yakimov et al, 2005 ; McKew et al, 2007 ; Tremblay et al, 2017 ; Lofthus et al, 2018 ; Bôto et al, 2021 ), tropical seawater ( Teramoto et al, 2009 ), oil plumes and seawater collected from the vicinity of the Deepwater Horizon blowout site ( Hazen et al, 2010 ; Liu et al, 2017 ), Arctic and subarctic seawater ( Dong et al, 2014 ; Suja et al, 2017 ; Shtratnikova et al, 2018 ) and sediment ( Murphy et al, 2021 ), as well as in the in situ sediment after oil-spills ( Lee et al, 2017 ; Thomas et al, 2020 ). Recently, they were identified as key hydrocarbon degraders not only in the ocean sunlight zone ( Love et al, 2021 ) but also in the dark hadal zone ( Liu et al, 2019 ; Jian et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Genome-based taxonomic rearrangement of Oceanobacter-related bacteria including the description of Thalassolituus hydrocarbonoclasticus sp. nov. and Thalassolituus pacificus sp. nov. and emended description of the genus Thalassolituus

et al. 2022

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Oceanobacter-related bacteria (ORB) are a group of oligotrophic marine bacteria play an underappreciated role in carbon cycling. They have been frequently described as one of the dominant bacterial groups with a wide distribution in coastal and deep seawater of global oceans. To clarify their taxonomic affiliation in relation to alkane utilization, phylogenomic and comparative genomics analyses were performed based on currently available genomes from GenBank and four newly isolated strains, in addition to phenotypic and chemotaxonomic characteristics. Consistently, phylogenomic analysis robustly separated them into two groups, which are accordingly hydrocarbon-degrading (HD, Thalassolituus and Oleibacter) and non-HD (NHD, Oceanobacter). In addition, the two groups can also be readily distinguished by several polyphasic taxonomic characteristics. Furthermore, both AAI and POCP genomic indices within the HD group support the conclusion that the members of the genus Oleibacter should be transferred into the genus Thalassolituus. Moreover, HD and NHD bacteria differed significantly in terms of genome size, G + C content and genes involved in alkane utilization. All HD bacteria contain the key gene alkB encoding an alkane monooxygenase, which can be used as a marker gene to distinguish the members of closely related genera Oceanobacter and Thalassolituus. Pangenome analysis revealed that the larger accessory genome may endow Thalassolituus with the flexibility to cope with the dynamics of marine environments and thrive therein, although they possess smaller pan, core- and unique-genomes than Oceanobacter. Within the HD group, twelve species were clearly distinguished from each other by both dDDH and ANI genomic indices, including two novel species represented by the newly isolated strains alknpb1M-1T and 59MF3M-4T, for which the names Thalassolituus hydrocarbonoclasticus sp. nov. and Thalassolituus pacificus sp. nov. are proposed. Collectively, these findings build a phylogenetic framework for the ORB and contribute to understanding of their role in marine carbon cycling.

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Section: Introductionmentioning

confidence: 99%

Genome-based taxonomic rearrangement of Oceanobacter-related bacteria including the description of Thalassolituus hydrocarbonoclasticus sp. nov. and Thalassolituus pacificus sp. nov. and emended description of the genus Thalassolituus

et al. 2022

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“…Except for the genus Shewanella , many bacteria, not being abundant in seawater, could be detected in the immobilized petroleum–degrading bacteria beads, which indicated that the immobilized petroleum–degrading bacteria beads provided shelter for these bacteria and improved their growth and reproduction. The genera Alcanivorax , Shewanella , Thalassospira , Alteromonas , Tenacibaculum , and Lutibacter , were abundant in the interior of the immobilized petroleum–degrading bacteria beads, and these bacteria were all petroleum–degrading bacteria [ 27 , 28 , 29 ]. Plenty of holes in the immobilized petroleum–degrading bacteria beads could absorb diesel (shown in Figure 2 c); thus, the immobilized petroleum–degrading bacteria beads attracted many petroleum–degrading bacteria to migrate into the interior of the immobilized petroleum–degrading bacteria beads [ 30 , 31 ].…”

Section: Resultsmentioning

confidence: 99%

Study on the Changes in Immobilized Petroleum–Degrading Bacteria Beads in a Continuous Bioreactor Related to Physicochemical Performance, Degradation Ability, and Microbial Community

Liu

Qiao

et al. 2022

IJERPH

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Continuous bioreactors for petroleum degradation and the effect factors of these bioreactors have rarely been mentioned in studies. In addition, indigenous bacteria living in seawater could influence the performance of continuous bioreactors with respect to petroleum degradation in practice. In this paper, a bioreactor fitted with immobilized petroleum–degrading bacteria beads was designed for further research. The results indicated that the diesel degradation rate of the bioreactor could remain above 50% over 27 days, while degradation performance decreased with bioremediation time. Intriguingly, the diameters of immobilized petroleum–degrading bacteria beads were reduced by 32.49% after 45 days remediation compared with the initial size of the immobilized petroleum–degrading bacteria beads. Change in immobilized petroleum–degrading bacteria beads was considered to correlate remarkably with reduced degradation efficiency. Therefore, this paper will be helpful for further study and improvement of bioreactors in the practical context of oil-spill accident recovery.

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“…Enumeration of bacterial population was performed by plating 0.1 ml of serially diluted soil sample on nutrient agar. Diesel degrading bacterial strains were screened by streaking them over Bushnell Haas (BH) Agar supplemented with 1% (v/v) filter sterilized diesel as carbon source using the standard methods (14,17,18). The soil samples after physical and analytical characterization were subjected to the microbiological analysis.…”

Section: Microbiological Characterization Of Hydrocarbon Degrading Mi...mentioning

confidence: 99%

“…In order to find out the microbial isolates possessing hydrocarbon degrading capabilities (13,19). Primary and secondary screenings (17,18,20) of hydrocarbon degrading microbes were performed. Soil suspension was made by mixing with 1 g soil in 10 ml Bushnell and Hass Broth (BH broth) conditioned with 1% (v/v) filter-sterilized diesel as the sole source of carbon.…”

Section: Microbiological Characterization Of Hydrocarbon Degrading Mi...mentioning

confidence: 99%

“…After 48 hrs of incubation of pure single isolates, colonies were subjected to microbiological identification (cultural, microscopic and biochemi-cal characterization) of all the gram positive and gramnegative isolates. All the identified microbial isolates were transferred to agar slants and glycerol stocks for further use (2,13,14,18). Primary screening, soil suspension was inoculated in Bushnell Hass broth supplemented with 1% filter sterilized diesel incubated on orbital shaker incubator for 24 hrs.…”

Section: Primary and Secondary Screening (Liquid-liquid Extraction)mentioning

confidence: 99%

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Exploiting bacterial isolates for diesel degrading potential under in vitro conditions

Taskar

Gupta

2022

Plant Sci. Today

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Hydrocarbon contaminated oil-spilled areas and oil-products have caused serious harm with increasing attention for development, implementation and removal of these contaminants. Bacterial diversity on succession at the petroleum hydrocarbon contaminated environment can give answer the problem. Such lands have serious problems as totally barren or with rare plantation. Bacteria can thereby be exploited for the mitigation of hydrocarbon to enhance the nutrient availability for vegetation. Present study involves collection of soil samples heavily contaminated with hydrocarbon from Bagru (Rajasthan). Samples were analysed by solid liquid extraction method followed by FTIR (Fourier Transform Infrared) and HPLC (High Performance Liquid Chromatography) analysis. During microbiological analysis hydrocarbon degrading bacteria were screened. FTIR spectral analysis indicated the presence of the functional group’s alkanes and aromatic ringed compounds; 43% to 69% hydrocarbon content recorded by HPLC analysis of all the soil samples respectively. From the soil samples six gram-positive and four gram-negative bacterial isolates were explored possessing hydrocarbon degrading capacities in the range 47.04-87.31% and 10.12-95.24% respectively. Growth kinetic studies revealed the degradation up to 1000 ppm diesel in 3 days under in vitro conditions. These bacteria can further be exploited for diesel degradation and will certainly propose a possible solution to the prevailing issue for its biodegradation in ex-situ conditions after up scaling.

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Harnessing the Potential of Native Microbial Communities for Bioremediation of Oil Spills in the Iberian Peninsula NW Coast

Cited by 28 publications

References 78 publications

Genome-based taxonomic rearrangement of Oceanobacter-related bacteria including the description of Thalassolituus hydrocarbonoclasticus sp. nov. and Thalassolituus pacificus sp. nov. and emended description of the genus Thalassolituus

Genome-based taxonomic rearrangement of Oceanobacter-related bacteria including the description of Thalassolituus hydrocarbonoclasticus sp. nov. and Thalassolituus pacificus sp. nov. and emended description of the genus Thalassolituus

Study on the Changes in Immobilized Petroleum–Degrading Bacteria Beads in a Continuous Bioreactor Related to Physicochemical Performance, Degradation Ability, and Microbial Community

Exploiting bacterial isolates for diesel degrading potential under in vitro conditions

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