Biodegradation, Photo-oxidation, and Dissolution of Petroleum Compounds in an Arctic Fjord during Summer

Vergeynst, Leendert; Greer, Charles W.; Mosbech, Anders; Gustavson, Kim; Meire, Lorenz; Poulsen, Kristoffer G.; Christensen, Jan H.

doi:10.1021/acs.est.9b03336

Cited by 23 publications

(17 citation statements)

References 57 publications

(142 reference statements)

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“…However, an implementation of the whole-genome shotgun sequencing of the total DNA progressively contributes to the understanding of microbial diversity and biochemical pathways [16,17]. Several metagenomic studies have shown microorganisms with the potential to degrade crude oil components, such as alkanes and mono-and polyaromatic hydrocarbons, in Arctic seawater [18,19] and revealed oildegradation pathways for specific areas by the genes that encoded the enzymes involved in these pathways [20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Assessment of Hydrocarbon Degradation Potential in Microbial Communities in Arctic Sea Ice

et al. 2022

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The anthropogenic release of oil hydrocarbons into the cold marine environment is an increasing concern due to the elevated usage of sea routes and the exploration of new oil drilling sites in Arctic areas. The aim of this study was to evaluate prokaryotic community structures and the genetic potential of hydrocarbon degradation in the metagenomes of seawater, sea ice, and crude oil encapsulating the sea ice of the Norwegian fjord, Ofotfjorden. Although the results indicated substantial differences between the structure of prokaryotic communities in seawater and sea ice, the crude oil encapsulating sea ice (SIO) showed increased abundances of many genera-containing hydrocarbon-degrading organisms, including Bermanella, Colwellia, and Glaciecola. Although the metagenome of seawater was rich in a variety of hydrocarbon degradation-related functional genes (HDGs) associated with the metabolism of n-alkanes, and mono- and polyaromatic hydrocarbons, most of the normalized gene counts were highest in the clean sea ice metagenome, whereas in SIO, these counts were the lowest. The long-chain alkane degradation gene almA was detected from all the studied metagenomes and its counts exceeded ladA and alkB counts in both sea ice metagenomes. In addition, almA was related to the most diverse group of prokaryotic genera. Almost all 18 good- and high-quality metagenome-assembled genomes (MAGs) had diverse HDGs profiles. The MAGs recovered from the SIO metagenome belonged to the abundant taxa, such as Glaciecola, Bermanella, and Rhodobacteracea, in this environment. The genera associated with HDGs were often previously known as hydrocarbon-degrading genera. However, a substantial number of new associations, either between already known hydrocarbon-degrading genera and new HDGs or between genera not known to contain hydrocarbon degraders and multiple HDGs, were found. The superimposition of the results of comparing HDG associations with taxonomy, the HDG profiles of MAGs, and the full genomes of organisms in the KEGG database suggest that the found relationships need further investigation and verification.

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Section: Introductionmentioning

confidence: 99%

Assessment of Hydrocarbon Degradation Potential in Microbial Communities in Arctic Sea Ice

et al. 2022

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“…For example, hydrocarbons can interact with biotic and abiotic factors in the system so their chemical composition can change, especially when exposed to the environment for a long time (Gómez-Mellado et al, 2020). Adams et al (2016) and Vergeynst et al (2019) found that the soil type could influence the response to the pollutant since when evaluating areas with old spills. They observed that forage grasses developed in fine-textured soils; in contrast to soils with coarse texture where grass could not develop.…”

Section: Introductionmentioning

confidence: 99%

Pre-evaluation of contaminated soil for oil field reactivation in Moloacan, Veracruz, Mexico

Yzquierdo-Ruíz¹,

Torres-Sánchez²,

Garza-Rodríguez³

et al. 2022

RMIQ

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“…We previously established that the majority (>80%) of oil photo-oxidation by sunlight is caused by visible light (>400nm), 2 in line with other studies that found oil photooxidation using light in the visible range, 60,61 or at reduced UV irradiation (at 5 m depth in seawater or under 50 cm of sea ice). 62,63 Fourth, we conducted the photooxidation experiments in the absence of water, in line with previous laboratory experiments. 64 Since the source of oxygen incorporated into the oil is mainly molecular O2 rather than H2O, 35 the photooxidation mechanism is not expected to be influenced by the absence of water.…”

Section: Resultsmentioning

confidence: 99%

Changes in chemical composition and copepod toxicity during petroleum photooxidation

Katz

Chen

Fields

et al. 2022

Preprint

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Photoproducts can be formed rapidly in the initial phase of a marine oil spill. However, their toxicity is not well understood. In this study, oil was irradiated, chemically characterized, and tested for toxicity in three copepod species (A. tonsa, T. longicornis, C.finmarchicus). Irradiation led to a depletion of polycyclic aromatic hydrocarbons (PAHs) and n-alkanes in oil residues, along with an enrichment in aromatic and aliphatic oil photoproducts. Target lipid model-based calculations of PAH toxic units (TU-PAH) predicted that PAH toxicities were lower in water accommodated fractions (WAFs) of irradiated oil residues (“irradiated WAFs”) than in WAFs of dark-control samples (“dark WAFs”). In contrast, biomimetic extraction (BE) measurements showed increased bioaccumulation potential of irradiated WAFs compared to dark WAFs, mainly driven by photoproducts present in irradiated oil. In line with the BE results, copepod mortality increased in response to irradiated WAFs compared to dark WAFs. Low copepod toxicities were observed for WAFs produced with photooxidized oil slicks collected during the Deepwater Horizon oil spill. The results of this study suggest that while oil photoproducts have the potential to be a significant source of copepod toxicity, the water solubility of these products might mitigate their toxicity at sea.

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Biodegradation, Photo-oxidation, and Dissolution of Petroleum Compounds in an Arctic Fjord during Summer

Cited by 23 publications

References 57 publications

Assessment of Hydrocarbon Degradation Potential in Microbial Communities in Arctic Sea Ice

Assessment of Hydrocarbon Degradation Potential in Microbial Communities in Arctic Sea Ice

Pre-evaluation of contaminated soil for oil field reactivation in Moloacan, Veracruz, Mexico

Changes in chemical composition and copepod toxicity during petroleum photooxidation

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