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• W2070510776 endingPage "3805" @default.
• W2070510776 startingPage "3785" @default.
• W2070510776 abstract "Microorganisms are ubiquitous in deep subsurface environments, but their role in the global carbon cycle is not well-understood. The natural abundance δ13C and Δ14C values of microbial membrane phospholipid fatty acids (PLFAs) were measured and used to assess the carbon sources of bacteria in sedimentary and granitic groundwaters sampled from three boreholes in the vicinity of the Tono Uranium Mine, Gifu, Japan. Sample storage experiments were performed and drill waters analyzed to characterize potential sources of microbial contamination. The most abundant PLFA structures in all waters sampled were 16:0, 16:1ω7c, cy17:0, and 18:1ω7c. A PLFA biomarker for type II methanotrophs, 18:1ω8c, comprised 3% and 18% of total PLFAs in anoxic sedimentary and granitic waters, respectively, sampled from the KNA-6 borehole. The presence of this biomarker was unexpected given that type II methanotrophs are considered obligate aerobes. However, a bacterium that grows aerobically with CH4 as the sole energy source and which also produces 56% of its total PLFAs as 18:1ω8c was isolated from both waters, providing additional evidence for the presence of type II methanotrophs. The Δ14C values determined for type II methanotroph PLFAs in the sedimentary (−861‰) and granite (−867‰) waters were very similar to the Δ14C values of dissolved inorganic carbon (DIC) in each water (∼−850‰). This suggests that type II methanotrophs ultimately derive all their carbon from inorganic sources, whether directly from DIC and/or from CH4 produced by the reduction of DIC. In contrast, δ13C values of type II PLFAs in the sedimentary (−93‰) and granite (−60‰) waters indicate that these organisms use different carbon assimilation schemes in each environment despite very similar δ13CCH4 values (∼−95‰) for each water. The δ13CPLFA values (−28‰ to −45‰) of non-methanotrophic bacteria in the KNA-6 LTL water do not clearly distinguish between heterotrophic and autotrophic metabolisms, but Δ14CPLFA values indicate that >65% of total bacteria filtered from the KNA-6 LTL water are heterotrophs. Ancient Δ14C values (∼−1000‰) of some PLFAs suggest that many heterotrophs utilize ancient organic matter, perhaps from lignite seams within the sedimentary rocks. The more negative range of δ13CPLFA values determined for the KNA-6 granitic water (−42‰ to −66‰) are likely the result of a microbial ecosystem dominated by chemolithoautotrophy, perhaps fuelled by abiogenic H2. Results of sample storage experiments showed substantial shifts in microbial community composition and δ13CPLFA values (as much as 5‰) during 2–4 days of dark, refrigerated, aseptic storage. However, water samples collected and immediately filtered back in the lab from freshly drilled MSB-2 borehole appeared to maintain the same relative relationships between δ13CPLFA values for sedimentary and granitic host rocks as observed for samples directly filtered under artesian flow from the KNA-6 borehole of the Tono Uranium Mine." @default.
• W2070510776 created "2016-06-24" @default.
• W2070510776 creator A5007461835 @default.
• W2070510776 creator A5019988607 @default.
• W2070510776 creator A5046662432 @default.
• W2070510776 creator A5047908276 @default.
• W2070510776 creator A5054418115 @default.
• W2070510776 creator A5072540315 @default.
• W2070510776 date "2010-07-01" @default.
• W2070510776 modified "2023-10-16" @default.
• W2070510776 title "Microbial carbon cycling in oligotrophic regional aquifers near the Tono Uranium Mine, Japan as inferred from δ13C and Δ14C values of in situ phospholipid fatty acids and carbon sources" @default.
• W2070510776 cites W1556665743 @default.
• W2070510776 cites W1557237219 @default.
• W2070510776 cites W1592574262 @default.
• W2070510776 cites W1612517152 @default.
• W2070510776 cites W1614550045 @default.
• W2070510776 cites W1719602416 @default.
• W2070510776 cites W1902524055 @default.
• W2070510776 cites W1929539987 @default.
• W2070510776 cites W1965628288 @default.
• W2070510776 cites W1967284299 @default.
• W2070510776 cites W1967894766 @default.
• W2070510776 cites W1970502832 @default.
• W2070510776 cites W1971390591 @default.
• W2070510776 cites W1972035091 @default.
• W2070510776 cites W1977427312 @default.
• W2070510776 cites W1978408039 @default.
• W2070510776 cites W1979532470 @default.
• W2070510776 cites W1980575078 @default.
• W2070510776 cites W1980857442 @default.
• W2070510776 cites W1982794640 @default.
• W2070510776 cites W1983782186 @default.
• W2070510776 cites W1988906236 @default.
• W2070510776 cites W1989898904 @default.
• W2070510776 cites W1994805532 @default.
• W2070510776 cites W1996706541 @default.
• W2070510776 cites W1998226372 @default.
• W2070510776 cites W1999993938 @default.
• W2070510776 cites W2000586575 @default.
• W2070510776 cites W2002685708 @default.
• W2070510776 cites W2002696227 @default.
• W2070510776 cites W2003785769 @default.
• W2070510776 cites W2005517056 @default.
• W2070510776 cites W2006440058 @default.
• W2070510776 cites W2008680648 @default.
• W2070510776 cites W2013055830 @default.
• W2070510776 cites W2014124919 @default.
• W2070510776 cites W2018276910 @default.
• W2070510776 cites W2020444159 @default.
• W2070510776 cites W2021857572 @default.
• W2070510776 cites W2021878820 @default.
• W2070510776 cites W2022396979 @default.
• W2070510776 cites W2029887783 @default.
• W2070510776 cites W2030690323 @default.
• W2070510776 cites W2038788794 @default.
• W2070510776 cites W2044594523 @default.
• W2070510776 cites W2048177019 @default.
• W2070510776 cites W2049245545 @default.
• W2070510776 cites W2052184963 @default.
• W2070510776 cites W2054445418 @default.
• W2070510776 cites W2057292298 @default.
• W2070510776 cites W2061105842 @default.
• W2070510776 cites W2062125071 @default.
• W2070510776 cites W2067298821 @default.
• W2070510776 cites W2067856736 @default.
• W2070510776 cites W2069879052 @default.
• W2070510776 cites W2071390384 @default.
• W2070510776 cites W2076218323 @default.
• W2070510776 cites W2077199974 @default.
• W2070510776 cites W2079363474 @default.
• W2070510776 cites W2079476794 @default.
• W2070510776 cites W2079611637 @default.
• W2070510776 cites W2084043444 @default.
• W2070510776 cites W2086661793 @default.
• W2070510776 cites W2088489068 @default.
• W2070510776 cites W2089965556 @default.
• W2070510776 cites W2090773474 @default.
• W2070510776 cites W2095061943 @default.
• W2070510776 cites W2095380366 @default.
• W2070510776 cites W2097702696 @default.
• W2070510776 cites W2098075393 @default.
• W2070510776 cites W2110364701 @default.
• W2070510776 cites W2113449951 @default.
• W2070510776 cites W2115414142 @default.
• W2070510776 cites W2117101710 @default.
• W2070510776 cites W2117764762 @default.
• W2070510776 cites W2118001436 @default.
• W2070510776 cites W2118598909 @default.
• W2070510776 cites W2123476126 @default.
• W2070510776 cites W2124185894 @default.
• W2070510776 cites W2129889299 @default.
• W2070510776 cites W2132465265 @default.
• W2070510776 cites W2133377589 @default.
• W2070510776 cites W2133867016 @default.
• W2070510776 cites W2134508082 @default.
• W2070510776 cites W2134849516 @default.
• W2070510776 cites W2140448721 @default.
• W2070510776 cites W2142998555 @default.

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