Subsurface microbial communities as a tool for characterizing regional-scale groundwater flow

Subsurface microbial community distribution patterns are influenced by biogeochemical and groundwater fluxes and may inform hydraulic connections along groundwater-flow paths. This study examined the regional-scale microbial community of the Death Valley Regional Flow System and evaluated whether su...

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Veröffentlicht in:	The Science of the total environment 2022-10, Vol.842 (N/A), p.156768-156768, Article 156768
Hauptverfasser:	Merino, Nancy, Jackson, Tracie R., Campbell, James H., Kersting, Annie B., Sackett, Joshua, Fisher, Jenny C., Bruckner, James C., Zavarin, Mavrik, Hamilton-Brehm, Scott D., Moser, Duane P.
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Schlagworte:	BASIC BIOLOGICAL SCIENCES Death Valley Deep biosphere environment ENVIRONMENTAL SCIENCES Fractured-rock aquifer groundwater groundwater flow meadows microbial communities Microbial community assembly Nevada oases RADIATION, THERMAL, AND OTHER ENVIRON. POLLUTANT EFFECTS ON LIVING ORGS. AND BIOL. MAT Regional-scale aquifer microbial community streams Subsurface microbial ecology
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creator	Merino, Nancy Jackson, Tracie R. Campbell, James H. Kersting, Annie B. Sackett, Joshua Fisher, Jenny C. Bruckner, James C. Zavarin, Mavrik Hamilton-Brehm, Scott D. Moser, Duane P.
description	Subsurface microbial community distribution patterns are influenced by biogeochemical and groundwater fluxes and may inform hydraulic connections along groundwater-flow paths. This study examined the regional-scale microbial community of the Death Valley Regional Flow System and evaluated whether subsurface communities can be used to identify groundwater-flow paths between recharge and discharge areas. Samples were collected from 36 sites in three groundwater basins: Pahute Mesa–Oasis Valley (PMOV), Ash Meadows (AM), and Alkali Flat–Furnace Creek Ranch (AFFCR). Microbial diversity within and between communities varied by location, and communities were separated into two overall groups that affiliated with the AM and PMOV/AFFCR basins. Network analysis revealed patterns between clusters of common microbes that represented groundwaters with similar geochemical conditions and largely corroborated hydraulic connections between recharge and discharge areas. Null model analyses identified deterministic and stochastic ecological processes contributing to microbial community assemblages. Most communities were more different than expected and governed by dispersal limitation, geochemical differences, or undominating processes. However, certain communities from sites located within or near the Nevada National Security Site were more similar than expected and dominated by homogeneous dispersal or selection. Overall, the (dis)similarities between the microbial communities of DVRFS recharge and discharge areas supported previously documented hydraulic connections between: (1) Spring Mountains and Ash Meadows; (2) Frenchman and Yucca Flat and Amargosa Desert; and (3) Amargosa Desert and Death Valley. However, only a portion of the flow path between Pahute Mesa and Oasis Valley could be supported by microbial community analyses, likely due to well-associated artifacts in samples from the two Oasis Valley sites. This study demonstrates the utility of combining microbial data with hydrologic, geologic, and water-chemistry information to comprehensively characterize groundwater systems, highlighting both strengths and limitations of this approach. [Display omitted] •The subsurface microbial community is consistent with known hydraulic connections.•Location plays a major role in microbial community variation.•Network analysis of common microbes corroborated recharge and discharge areas.•Ecological null models provided insight into community assembly patterns.
doi_str_mv	10.1016/j.scitotenv.2022.156768
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This study examined the regional-scale microbial community of the Death Valley Regional Flow System and evaluated whether subsurface communities can be used to identify groundwater-flow paths between recharge and discharge areas. Samples were collected from 36 sites in three groundwater basins: Pahute Mesa–Oasis Valley (PMOV), Ash Meadows (AM), and Alkali Flat–Furnace Creek Ranch (AFFCR). Microbial diversity within and between communities varied by location, and communities were separated into two overall groups that affiliated with the AM and PMOV/AFFCR basins. Network analysis revealed patterns between clusters of common microbes that represented groundwaters with similar geochemical conditions and largely corroborated hydraulic connections between recharge and discharge areas. Null model analyses identified deterministic and stochastic ecological processes contributing to microbial community assemblages. Most communities were more different than expected and governed by dispersal limitation, geochemical differences, or undominating processes. However, certain communities from sites located within or near the Nevada National Security Site were more similar than expected and dominated by homogeneous dispersal or selection. Overall, the (dis)similarities between the microbial communities of DVRFS recharge and discharge areas supported previously documented hydraulic connections between: (1) Spring Mountains and Ash Meadows; (2) Frenchman and Yucca Flat and Amargosa Desert; and (3) Amargosa Desert and Death Valley. However, only a portion of the flow path between Pahute Mesa and Oasis Valley could be supported by microbial community analyses, likely due to well-associated artifacts in samples from the two Oasis Valley sites. This study demonstrates the utility of combining microbial data with hydrologic, geologic, and water-chemistry information to comprehensively characterize groundwater systems, highlighting both strengths and limitations of this approach. [Display omitted] •The subsurface microbial community is consistent with known hydraulic connections.•Location plays a major role in microbial community variation.•Network analysis of common microbes corroborated recharge and discharge areas.•Ecological null models provided insight into community assembly patterns.</description><identifier>ISSN: 0048-9697</identifier><identifier>EISSN: 1879-1026</identifier><identifier>DOI: 10.1016/j.scitotenv.2022.156768</identifier><language>eng</language><publisher>United States: Elsevier B.V</publisher><subject>BASIC BIOLOGICAL SCIENCES ; Death Valley ; Deep biosphere ; environment ; ENVIRONMENTAL SCIENCES ; Fractured-rock aquifer ; groundwater ; groundwater flow ; meadows ; microbial communities ; Microbial community assembly ; Nevada ; oases ; RADIATION, THERMAL, AND OTHER ENVIRON. POLLUTANT EFFECTS ON LIVING ORGS. AND BIOL. 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This study examined the regional-scale microbial community of the Death Valley Regional Flow System and evaluated whether subsurface communities can be used to identify groundwater-flow paths between recharge and discharge areas. Samples were collected from 36 sites in three groundwater basins: Pahute Mesa–Oasis Valley (PMOV), Ash Meadows (AM), and Alkali Flat–Furnace Creek Ranch (AFFCR). Microbial diversity within and between communities varied by location, and communities were separated into two overall groups that affiliated with the AM and PMOV/AFFCR basins. Network analysis revealed patterns between clusters of common microbes that represented groundwaters with similar geochemical conditions and largely corroborated hydraulic connections between recharge and discharge areas. Null model analyses identified deterministic and stochastic ecological processes contributing to microbial community assemblages. Most communities were more different than expected and governed by dispersal limitation, geochemical differences, or undominating processes. However, certain communities from sites located within or near the Nevada National Security Site were more similar than expected and dominated by homogeneous dispersal or selection. Overall, the (dis)similarities between the microbial communities of DVRFS recharge and discharge areas supported previously documented hydraulic connections between: (1) Spring Mountains and Ash Meadows; (2) Frenchman and Yucca Flat and Amargosa Desert; and (3) Amargosa Desert and Death Valley. However, only a portion of the flow path between Pahute Mesa and Oasis Valley could be supported by microbial community analyses, likely due to well-associated artifacts in samples from the two Oasis Valley sites. This study demonstrates the utility of combining microbial data with hydrologic, geologic, and water-chemistry information to comprehensively characterize groundwater systems, highlighting both strengths and limitations of this approach. [Display omitted] •The subsurface microbial community is consistent with known hydraulic connections.•Location plays a major role in microbial community variation.•Network analysis of common microbes corroborated recharge and discharge areas.•Ecological null models provided insight into community assembly patterns.</description><subject>BASIC BIOLOGICAL SCIENCES</subject><subject>Death Valley</subject><subject>Deep biosphere</subject><subject>environment</subject><subject>ENVIRONMENTAL SCIENCES</subject><subject>Fractured-rock aquifer</subject><subject>groundwater</subject><subject>groundwater flow</subject><subject>meadows</subject><subject>microbial communities</subject><subject>Microbial community assembly</subject><subject>Nevada</subject><subject>oases</subject><subject>RADIATION, THERMAL, AND OTHER ENVIRON. POLLUTANT EFFECTS ON LIVING ORGS. AND BIOL. 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POLLUTANT EFFECTS ON LIVING ORGS. AND BIOL. 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This study examined the regional-scale microbial community of the Death Valley Regional Flow System and evaluated whether subsurface communities can be used to identify groundwater-flow paths between recharge and discharge areas. Samples were collected from 36 sites in three groundwater basins: Pahute Mesa–Oasis Valley (PMOV), Ash Meadows (AM), and Alkali Flat–Furnace Creek Ranch (AFFCR). Microbial diversity within and between communities varied by location, and communities were separated into two overall groups that affiliated with the AM and PMOV/AFFCR basins. Network analysis revealed patterns between clusters of common microbes that represented groundwaters with similar geochemical conditions and largely corroborated hydraulic connections between recharge and discharge areas. Null model analyses identified deterministic and stochastic ecological processes contributing to microbial community assemblages. Most communities were more different than expected and governed by dispersal limitation, geochemical differences, or undominating processes. However, certain communities from sites located within or near the Nevada National Security Site were more similar than expected and dominated by homogeneous dispersal or selection. Overall, the (dis)similarities between the microbial communities of DVRFS recharge and discharge areas supported previously documented hydraulic connections between: (1) Spring Mountains and Ash Meadows; (2) Frenchman and Yucca Flat and Amargosa Desert; and (3) Amargosa Desert and Death Valley. However, only a portion of the flow path between Pahute Mesa and Oasis Valley could be supported by microbial community analyses, likely due to well-associated artifacts in samples from the two Oasis Valley sites. This study demonstrates the utility of combining microbial data with hydrologic, geologic, and water-chemistry information to comprehensively characterize groundwater systems, highlighting both strengths and limitations of this approach. [Display omitted] •The subsurface microbial community is consistent with known hydraulic connections.•Location plays a major role in microbial community variation.•Network analysis of common microbes corroborated recharge and discharge areas.•Ecological null models provided insight into community assembly patterns.</abstract><cop>United States</cop><pub>Elsevier B.V</pub><doi>10.1016/j.scitotenv.2022.156768</doi><tpages>1</tpages><oa>free_for_read</oa></addata></record>
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subjects	BASIC BIOLOGICAL SCIENCES Death Valley Deep biosphere environment ENVIRONMENTAL SCIENCES Fractured-rock aquifer groundwater groundwater flow meadows microbial communities Microbial community assembly Nevada oases RADIATION, THERMAL, AND OTHER ENVIRON. POLLUTANT EFFECTS ON LIVING ORGS. AND BIOL. MAT Regional-scale aquifer microbial community streams Subsurface microbial ecology
title	Subsurface microbial communities as a tool for characterizing regional-scale groundwater flow
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