Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition

Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition

Deep sea oil exploration is increasing and presents environmental challenges for deep ocean ecosystems. Marine oil spills often result in contamination of sediments with oil; following the Deepwater Horizon (DwH) disaster up to 31% of the released oil entrained in the water column was deposited as o...

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Main Authors: Luis J. Perez Calderon, Lloyd D. Potts, Evangelia Gontikaki, Cécile Gubry-Rangin, Thomas Cornulier, Alejandro Gallego, James A. Anderson, Ursula Witte
Format: Article
Language:English
Published: Frontiers Media S.A. 2018-05-01
Series:Frontiers in Marine Science
Subjects:
oil spill
deep-sea sediment
hydrocarbon degradation
hydrocarbon entrainment
bacteria
dispersant
Online Access:http://journal.frontiersin.org/article/10.3389/fmars.2018.00159/full
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language English
format Article
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author Luis J. Perez Calderon
Luis J. Perez Calderon
Luis J. Perez Calderon
Lloyd D. Potts
Lloyd D. Potts
Lloyd D. Potts
Evangelia Gontikaki
Cécile Gubry-Rangin
Thomas Cornulier
Alejandro Gallego
James A. Anderson
Ursula Witte
spellingShingle Luis J. Perez Calderon
Luis J. Perez Calderon
Luis J. Perez Calderon
Lloyd D. Potts
Lloyd D. Potts
Lloyd D. Potts
Evangelia Gontikaki
Cécile Gubry-Rangin
Thomas Cornulier
Alejandro Gallego
James A. Anderson
Ursula Witte
Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition
Frontiers in Marine Science
oil spill
deep-sea sediment
hydrocarbon degradation
hydrocarbon entrainment
bacteria
dispersant
author_facet Luis J. Perez Calderon
Luis J. Perez Calderon
Luis J. Perez Calderon
Lloyd D. Potts
Lloyd D. Potts
Lloyd D. Potts
Evangelia Gontikaki
Cécile Gubry-Rangin
Thomas Cornulier
Alejandro Gallego
James A. Anderson
Ursula Witte
author_sort Luis J. Perez Calderon
title Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition
title_short Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition
title_full Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition
title_fullStr Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition
title_full_unstemmed Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant Addition
title_sort bacterial community response in deep faroe-shetland channel sediments following hydrocarbon entrainment with and without dispersant addition
publisher Frontiers Media S.A.
series Frontiers in Marine Science
issn 2296-7745
publishDate 2018-05-01
description Deep sea oil exploration is increasing and presents environmental challenges for deep ocean ecosystems. Marine oil spills often result in contamination of sediments with oil; following the Deepwater Horizon (DwH) disaster up to 31% of the released oil entrained in the water column was deposited as oily residues on the seabed. Although the aftermath of DwH was studied intensely, lessons learned may not be directly transferable to other deep-sea hydrocarbon exploration areas, such as the Faroe-Shetland Channel (FSC) which comprises cold temperatures and a unique hydrodynamic regime. Here, transport of hydrocarbons into deep FSC sediments, subsequent responses in benthic microbial populations and effects of dispersant application on hydrocarbon fate and microbial communities were investigated. Sediments from 1,000 m in the FSC were incubated at 0°C for 71 days after addition of a 20-hydrocarbon component oil-sediment aggregate. Dispersant was added periodically from day 4. An additional set of cores using sterilized and homogenized sediment was analyzed to evaluate the effects of sediment matrix modification on hydrocarbon entrainment. Sediment layers were independently analyzed for hydrocarbon content by gas chromatography with flame ionization detection and modeled with linear mixed effects models. Oil was entrained over 4 cm deep into FSC sediments after 42 days and dispersant effectiveness on hydrocarbon removal from sediment to the water column decreased with time. Sterilizing and homogenizing sediment resulted in hydrocarbon transport over 4 cm into sediments after 7 days. Significant shifts in bacterial populations were observed (DGGE profiling) in response to hydrocarbon exposure after 42 days and below 2 cm deep. Dispersant application resulted in an accelerated and modified shift in bacterial communities. Bacterial 16S rRNA gene sequencing of oiled sediments revealed dominance of Colwellia and of Fusibacter when dispersant was applied over oiled sediments. The increased relative abundance of anaerobic hydrocarbon degraders through time suggests creation of anoxic niches due to smothering. The study showed that hydrocarbons can entrain deep sediments to over 4 cm in a short time and that FSC indigenous bacteria are able to respond to a contamination event, even at a low temperature, reflecting the in situ conditions.
topic oil spill
deep-sea sediment
hydrocarbon degradation
hydrocarbon entrainment
bacteria
dispersant
url http://journal.frontiersin.org/article/10.3389/fmars.2018.00159/full
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spelling doaj-122934c27e254e88be484a28bafc72f42020-11-24T21:42:08ZengFrontiers Media S.A.Frontiers in Marine Science2296-77452018-05-01510.3389/fmars.2018.00159319935Bacterial Community Response in Deep Faroe-Shetland Channel Sediments Following Hydrocarbon Entrainment With and Without Dispersant AdditionLuis J. Perez Calderon0Luis J. Perez Calderon1Luis J. Perez Calderon2Lloyd D. Potts3Lloyd D. Potts4Lloyd D. Potts5Evangelia Gontikaki6Cécile Gubry-Rangin7Thomas Cornulier8Alejandro Gallego9James A. Anderson10Ursula Witte11Institute of Biological and Environmental Science, School of Biological Sciences, University of Aberdeen, Aberdeen, United KingdomSurface Chemistry and Catalysis Group, Materials and Chemical Engineering, School of Engineering, University of Aberdeen, Aberdeen, United KingdomMarine Scotland Science, Marine Laboratory Aberdeen, Aberdeen, United KingdomInstitute of Biological and Environmental Science, School of Biological Sciences, University of Aberdeen, Aberdeen, United KingdomSurface Chemistry and Catalysis Group, Materials and Chemical Engineering, School of Engineering, University of Aberdeen, Aberdeen, United KingdomMarine Scotland Science, Marine Laboratory Aberdeen, Aberdeen, United KingdomInstitute of Biological and Environmental Science, School of Biological Sciences, University of Aberdeen, Aberdeen, United KingdomInstitute of Biological and Environmental Science, School of Biological Sciences, University of Aberdeen, Aberdeen, United KingdomInstitute of Biological and Environmental Science, School of Biological Sciences, University of Aberdeen, Aberdeen, United KingdomMarine Scotland Science, Marine Laboratory Aberdeen, Aberdeen, United KingdomSurface Chemistry and Catalysis Group, Materials and Chemical Engineering, School of Engineering, University of Aberdeen, Aberdeen, United KingdomInstitute of Biological and Environmental Science, School of Biological Sciences, University of Aberdeen, Aberdeen, United KingdomDeep sea oil exploration is increasing and presents environmental challenges for deep ocean ecosystems. Marine oil spills often result in contamination of sediments with oil; following the Deepwater Horizon (DwH) disaster up to 31% of the released oil entrained in the water column was deposited as oily residues on the seabed. Although the aftermath of DwH was studied intensely, lessons learned may not be directly transferable to other deep-sea hydrocarbon exploration areas, such as the Faroe-Shetland Channel (FSC) which comprises cold temperatures and a unique hydrodynamic regime. Here, transport of hydrocarbons into deep FSC sediments, subsequent responses in benthic microbial populations and effects of dispersant application on hydrocarbon fate and microbial communities were investigated. Sediments from 1,000 m in the FSC were incubated at 0°C for 71 days after addition of a 20-hydrocarbon component oil-sediment aggregate. Dispersant was added periodically from day 4. An additional set of cores using sterilized and homogenized sediment was analyzed to evaluate the effects of sediment matrix modification on hydrocarbon entrainment. Sediment layers were independently analyzed for hydrocarbon content by gas chromatography with flame ionization detection and modeled with linear mixed effects models. Oil was entrained over 4 cm deep into FSC sediments after 42 days and dispersant effectiveness on hydrocarbon removal from sediment to the water column decreased with time. Sterilizing and homogenizing sediment resulted in hydrocarbon transport over 4 cm into sediments after 7 days. Significant shifts in bacterial populations were observed (DGGE profiling) in response to hydrocarbon exposure after 42 days and below 2 cm deep. Dispersant application resulted in an accelerated and modified shift in bacterial communities. Bacterial 16S rRNA gene sequencing of oiled sediments revealed dominance of Colwellia and of Fusibacter when dispersant was applied over oiled sediments. The increased relative abundance of anaerobic hydrocarbon degraders through time suggests creation of anoxic niches due to smothering. The study showed that hydrocarbons can entrain deep sediments to over 4 cm in a short time and that FSC indigenous bacteria are able to respond to a contamination event, even at a low temperature, reflecting the in situ conditions.http://journal.frontiersin.org/article/10.3389/fmars.2018.00159/fulloil spilldeep-sea sedimenthydrocarbon degradationhydrocarbon entrainmentbacteriadispersant

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