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In situ transformation of ethoxylate and glycol surfactants by shale-colonizing microorganisms during hydraulic fracturing.

Publication ,  Journal Article
Evans, MV; Getzinger, G; Luek, JL; Hanson, AJ; McLaughlin, MC; Blotevogel, J; Welch, SA; Nicora, CD; Purvine, SO; Xu, C; Cole, DR; Darrah, TH ...
Published in: The ISME journal
November 2019

In the last decade, extensive application of hydraulic fracturing technologies to unconventional low-permeability hydrocarbon-rich formations has significantly increased natural-gas production in the United States and abroad. The injection of surface-sourced fluids to generate fractures in the deep subsurface introduces microbial cells and substrates to low-permeability rock. A subset of injected organic additives has been investigated for their ability to support biological growth in shale microbial community members; however, to date, little is known on how complex xenobiotic organic compounds undergo biotransformations in this deep rock ecosystem. Here, high-resolution chemical, metagenomic, and proteomic analyses reveal that widely-used surfactants are degraded by the shale-associated taxa Halanaerobium, both in situ and under laboratory conditions. These halotolerant bacteria exhibit surfactant substrate specificities, preferring polymeric propoxylated glycols (PPGs) and longer alkyl polyethoxylates (AEOs) over polyethylene glycols (PEGs) and shorter AEOs. Enzymatic transformation occurs through repeated terminal-end polyglycol chain shortening during co-metabolic growth through the methylglyoxal bypass. This work provides the first evidence that shale microorganisms can transform xenobiotic surfactants in fracture fluid formulations, potentially affecting the efficiency of hydrocarbon recovery, and demonstrating an important association between injected substrates and microbial growth in an engineered subsurface ecosystem.

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Published In

The ISME journal

DOI

EISSN

1751-7370

ISSN

1751-7362

Publication Date

November 2019

Volume

13

Issue

11

Start / End Page

2690 / 2700

Related Subject Headings

  • Wastewater
  • Surface-Active Agents
  • Proteomics
  • Oil and Gas Fields
  • Ohio
  • Natural Gas
  • Minerals
  • Microbiota
  • Microbiology
  • Hydraulic Fracking
 

Citation

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Evans, M. V., Getzinger, G., Luek, J. L., Hanson, A. J., McLaughlin, M. C., Blotevogel, J., … Mouser, P. J. (2019). In situ transformation of ethoxylate and glycol surfactants by shale-colonizing microorganisms during hydraulic fracturing. The ISME Journal, 13(11), 2690–2700. https://doi.org/10.1038/s41396-019-0466-0
Evans, Morgan V., Gordon Getzinger, Jenna L. Luek, Andrea J. Hanson, Molly C. McLaughlin, Jens Blotevogel, Susan A. Welch, et al. “In situ transformation of ethoxylate and glycol surfactants by shale-colonizing microorganisms during hydraulic fracturing.The ISME Journal 13, no. 11 (November 2019): 2690–2700. https://doi.org/10.1038/s41396-019-0466-0.
Evans MV, Getzinger G, Luek JL, Hanson AJ, McLaughlin MC, Blotevogel J, et al. In situ transformation of ethoxylate and glycol surfactants by shale-colonizing microorganisms during hydraulic fracturing. The ISME journal. 2019 Nov;13(11):2690–700.
Evans, Morgan V., et al. “In situ transformation of ethoxylate and glycol surfactants by shale-colonizing microorganisms during hydraulic fracturing.The ISME Journal, vol. 13, no. 11, Nov. 2019, pp. 2690–700. Epmc, doi:10.1038/s41396-019-0466-0.
Evans MV, Getzinger G, Luek JL, Hanson AJ, McLaughlin MC, Blotevogel J, Welch SA, Nicora CD, Purvine SO, Xu C, Cole DR, Darrah TH, Hoyt DW, Metz TO, Lee Ferguson P, Lipton MS, Wilkins MJ, Mouser PJ. In situ transformation of ethoxylate and glycol surfactants by shale-colonizing microorganisms during hydraulic fracturing. The ISME journal. 2019 Nov;13(11):2690–2700.

Published In

The ISME journal

DOI

EISSN

1751-7370

ISSN

1751-7362

Publication Date

November 2019

Volume

13

Issue

11

Start / End Page

2690 / 2700

Related Subject Headings

  • Wastewater
  • Surface-Active Agents
  • Proteomics
  • Oil and Gas Fields
  • Ohio
  • Natural Gas
  • Minerals
  • Microbiota
  • Microbiology
  • Hydraulic Fracking