Propane Respiration Jump-Starts Microbial Response to a Deep Oil Spill
Diving into Deep Water
The Deepwater Horizon oil spill in the Gulf of Mexico was one of the largest oil spills on record. Its setting at the bottom of the sea floor posed an unanticipated risk as substantial amounts of hydrocarbons leaked into the deepwater column. Three separate cruises identified and sampled deep underwater hydrocarbon plumes that existed in May and June, 2010—before the well head was ultimately sealed. Camilli et al. (p. 201; published online 19 August) used an automated underwater vehicle to assess the dimensions of a stabilized, diffuse underwater plume of oil that was 22 miles long and estimated the daily quantity of oil released from the well, based on the concentration and dimensions of the plume. Hazen et al. (p. 204; published online 26 August) also observed an underwater plume at the same depth and found that hydrocarbon-degrading bacteria were enriched in the plume and were breaking down some parts of the oil. Finally, Valentine et al. (p. 208; published online 16 September) found that natural gas, including propane and ethane, were also present in hydrocarbon plumes. These gases were broken down quickly by bacteria, but primed the system for biodegradation of larger hydrocarbons, including those comprising the leaking crude oil. Differences were observed in dissolved oxygen levels in the plumes (a proxy for bacterial respiration), which may reflect differences in the location of sampling or the aging of the plumes.
Abstract
The Deepwater Horizon event resulted in suspension of oil in the Gulf of Mexico water column because the leakage occurred at great depth. The distribution and fate of other abundant hydrocarbon constituents, such as natural gases, are also important in determining the impact of the leakage but are not yet well understood. From 11 to 21 June 2010, we investigated dissolved hydrocarbon gases at depth using chemical and isotopic surveys and on-site biodegradation studies. Propane and ethane were the primary drivers of microbial respiration, accounting for up to 70% of the observed oxygen depletion in fresh plumes. Propane and ethane trapped in the deep water may therefore promote rapid hydrocarbon respiration by low-diversity bacterial blooms, priming bacterial populations for degradation of other hydrocarbons in the aging plume.
Get full access to this article
View all available purchase options and get full access to this article.
Already a Subscriber?Sign In
Supplementary Material
File (valentine_som.pdf)
References and Notes
1
Dasanayaka L. K., Yapa P. D., Role of plume dynamics phase in a deepwater oil and gas release model. J. Hydroenviron. Res. 2, 243 (2009).
2
Yapa P. D., Dasanayaka L. K., Bandara U. C., Nakata K., Modeling the impact of an accidental release of methane gas in deepwater. Oceans 1–4, 109 (2008).
3
Camilli R., et al., Tracking hydrocarbon plume transport and biodegradation at Deepwater Horizon. Science 330, 201 (2010); published online 19 August 2010 (10.1126/science.1195223).
4
Chen F., Yapa P. D., Modeling gas separation from a bent deepwater oil and gas jet/plume. J. Mar. Syst. 45, 189 (2004).
5
U.S. Geological Survey, “Deepwater Horizon MC252 Gulf Incident Oil Budget: Government Estimates - Through August 01 (Day 104)” (USGS, 2010); www.noaanews.noaa.gov/stories2010/PDFs/DeepwaterHorizonOilBudget20100801.pdf.
6
Materials and methods are available on Science Online.
7
Valentine D., Measure methane to quantify the oil spill. Nature 465, 421 (2010).
8
J. M. Brooks, Thesis, Texas A&M University (1975).
9
Grant N. J., Whiticar M. J., Stable carbon isotopic evidence for methane oxidation in plumes above Hydrate Ridge, Cascadia Oregon Margin. Global Biogeochem. Cycles 16, 1124 (2002).
10
Mau S., et al., Estimates of methane output from mud extrusions at the erosive convergent margin off Costa Rica. Mar. Geol. 225, 129 (2006).
11
Mau S., et al., Dissolved methane distributions and air-sea flux in the plume of a massive seep field, Coal Oil Point, California. Geophys. Res. Lett. 34, L22603 (2007).
12
Reeburgh W. S., Oceanic methane biogeochemistry. Chem. Rev. 107, 486 (2007).
13
Valentine D. L., Blanton D. C., Reeburgh W. S., Kastner M., Water column methane oxidation adjacent to an area of active hydrate dissociation, Eel River Basin. Geochim. Cosmochim. Acta 65, 2633 (2001).
14
Schrope M., Oil cruise finds deep-sea plume. Nature 465, 274 (2010); published online 24 August 2010 (10.1126/science.1195979).
15
Joint Analysis Group, “Review of Preliminary Data to Examine Subsurface Oil In the Vicinity of MC252#1 May 19 to June 19, 2010” (NOAA, 2010); http://beta.w1.noaa.gov/sciencemissions/PDFs/JAG_Data_Report_Subsurface%20Oil_Final.pdf.
16
Hazen T. C., et al., Deep-sea oil plume enriches indigenous oil-degrading bacteria. Science 330, 204 (2010); published online 24 August 2010 (10.1126/science.1195979).
17
Kinnaman F. S., Valentine D. L., Tyler S. C., Carbon and hydrogen isotope fractionation associated with the aerobic microbial oxidation of methane, ethane, propane and butane. Geochim. Cosmochim. Acta 71, 271 (2007).
18
Gelwicks J. T., Risatti J. B., Hayes J. M., Carbon isotope effects associated with autotrophic acetogenesis. Org. Geochem. 14, 441 (1989).
19
Gelwicks J. T., Risatti J. B., Hayes J. M., Carbon isotope effects associated with aceticlastic methanogenesis. Appl. Environ. Microbiol. 60, 467 (1994).
20
Mastalerz V., de Lange G. J., Dahlmann A., Differential aerobic and anaerobic oxidation of hydrocarbon gases discharged at mud volcanoes in the Nile deep-sea fan. Geochim. Cosmochim. Acta 73, 3849 (2009).
21
Dyksterhouse S. E., Gray J. P., Herwig R. P., Lara J. C., Staley J. T., Cycloclasticus pugetii gen. nov., sp. nov., an aromatic hydrocarbon-degrading bacterium from marine sediments. Int. J. Syst. Bacteriol. 45, 116 (1995).
22
Geiselbrecht A. D., Hedlund B. P., Tichi M. A., Staley J. T., Isolation of marine polycyclic aromatic hydrocarbon (PAH)-degrading Cycloclasticus strains from the Gulf of Mexico and comparison of their PAH degradation ability with that of puget sound Cycloclasticus strains. Appl. Environ. Microbiol. 64, 4703 (1998).
23
Maruyama A., et al., Dynamics of microbial populations and strong selection for Cycloclasticus pugetii following the Nakhodka oil spill. Microb. Ecol. 46, 442 (2003).
24
Chung W. K., King G. M., Isolation, characterization, and polyaromatic hydrocarbon degradation potential of aerobic bacteria from marine macrofaunal burrow sediments and description of Lutibacterium anuloederans gen. nov., sp. nov., and Cycloclasticus spirillensus sp. nov. Appl. Environ. Microbiol. 67, 5585 (2001).
25
Brakstad O. G., Nonstad I., Faksness L. G., Brandvik P. J., Responses of microbial communities in Arctic sea ice after contamination by crude petroleum oil. Microb. Ecol. 55, 540 (2008).
26
Hedlund B. P., Geiselbrecht A. D., Bair T. J., Staley J. T., Polycyclic aromatic hydrocarbon degradation by a new marine bacterium, Neptunomonas naphthovorans gen. nov., sp. nov. Appl. Environ. Microbiol. 65, 251 (1999).
27
Redmond M. C., Valentine D. L., Sessions A. L., Novel methane, ethane, and propane oxidizing bacteria at marine hydrocarbon seeps identified by stable isotope probing. Appl. Environ. Microbiol. Published online 30 July 2010; (
Information & Authors
Information
Published In
Science
Volume 330 | Issue 6001
8 October 2010
8 October 2010
Copyright
Copyright © 2010, American Association for the Advancement of Science.
Article versions
You are viewing the most recent version of this article.
Submission history
Received: 23 August 2010
Accepted: 8 September 2010
Published in print: 8 October 2010
Acknowledgments
This research was supported by the National Science Foundation through awards OCE 1042097 and OCE 0961725 to D.L.V. and OCE 1042650 and OCE 0849246 to J.D.K. and by the Department of Energy through award DE-NT0005667 to D.L.V. We thank the captain and crew of the research vessel Cape Hatteras, R. Stephens Smith, R. Amon, K. Goodman S. Bagby, G. Paradis, A. Best, L. Werra, C. Hansen, L. Sanchez, H. Hill, S. Joye, and the staff at Picarro Inc. for valuable technical assistance and discussions. Sequences are available on GenBank, accession numbers HQ222989 to HQ222996.
Authors
Metrics & Citations
Metrics
Article Usage
Altmetrics
Citations
Export citation
Select the format you want to export the citation of this publication.
Cited by
- Oil fate and mass balance for the Deepwater Horizon oil spill, Marine Pollution Bulletin, 171, (112681), (2021).https://doi.org/10.1016/j.marpolbul.2021.112681
- Prokaryotes at High Pressure in the Oceans and Deep Biosphere, Life at High Pressure, (193-229), (2021).https://doi.org/10.1007/978-3-030-67587-5
- Biodegradation of water-accommodated aromatic oil compounds in Arctic seawater at 0 °C, Chemosphere, (131751), (2021).https://doi.org/10.1016/j.chemosphere.2021.131751
- Mapping spatial and temporal variation of seafloor organic matter Δ14C and δ13C in the Northern Gulf of Mexico following the Deepwater Horizon Oil Spill, Marine Pollution Bulletin, 164, (112076), (2021).https://doi.org/10.1016/j.marpolbul.2021.112076
- Benthic foraminiferal morphological response to the 2010 Deepwater Horizon oil spill, Marine Micropaleontology, 164, (101971), (2021).https://doi.org/10.1016/j.marmicro.2021.101971
- The Complexity of Spills: The Fate of the Deepwater Horizon Oil , Annual Review of Marine Science, 13, 1, (109-136), (2021).https://doi.org/10.1146/annurev-marine-032320-095153
- Natural Escapes of Oil in Sedimentary Basins: Space‐borne Recognition and Pairing with Seafloor and Sub‐seafloor Features, Remote Detection and Maritime Pollution, (151-165), (2021).https://doi.org/10.1002/9781119801849
- Diesel and Crude Oil Biodegradation by Cold-Adapted Microbial Communities in the Labrador Sea, Applied and Environmental Microbiology, 87, 20, (2021).https://doi.org/10.1128/AEM.00800-21
- Microbial Abundance and Diversity in Subsurface Lower Oceanic Crust at Atlantis Bank, Southwest Indian Ridge, Applied and Environmental Microbiology, 87, 22, (2021).https://doi.org/10.1128/AEM.01519-21
- Response and oil degradation activities of a northeast Atlantic bacterial community to biogenic and synthetic surfactants, Microbiome, 9, 1, (2021).https://doi.org/10.1186/s40168-021-01143-5
- See more
Loading...
View Options
Get Access
Log in to view the full text
AAAS login provides access to Science for AAAS Members, and access to other journals in the Science family to users who have purchased individual subscriptions.
- Become a AAAS Member
- Activate your AAAS ID
- Purchase Access to Other Journals in the Science Family
- Account Help
Log in via OpenAthens.
Log in via Shibboleth.
More options
Register for free to read this article
As a service to the community, this article is available for free. Login or register for free to read this article.
Buy a single issue of Science for just $15 USD.
View options
PDF format
Download this article as a PDF file
Download PDF