Large Fractions of CO
            <sub>2</sub>
            -Fixing Microorganisms in Pristine Limestone Aquifers Appear To Be Involved in the Oxidation of Reduced Sulfur and Nitrogen Compounds

Herrmann, Martina; Rusznyák, Anna; Akob, Denise M.; Schulze, Isabel; Opitz, Sebastian E. W.; Totsche, Kai Uwe; Küsel, Kirsten

doi:10.1128/aem.03269-14

Cited by 91 publications

(94 citation statements)

References 77 publications

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“…Within the time period of monitoring there was no significant change from previous reported hydrochemical patterns (Table 1) (Herrmann et al, 2015;Küsel et al, 2016). Water chemistry reflects the limestone environment of the catchment.…”

Section: Hydrochemistrymentioning

confidence: 73%

“…Chemolithoautotrophic microorganisms, i.e., microbes that metabolize CO 2 instead of organic carbon, have been shown to be key players and important primary producers in groundwater microbial communities (Alfreider et al, 2012;Hutchins et al, 2016;Kellermann et al, 2012). A high potential for microbial CO 2 fixation has already been demonstrated in our studied aquifers by molecular analyses (Herrmann et al, 2015;Lazar et al, 2016a;Schwab et al, 2017b). We hypothesized that turnover of OM derived from chemoautotrophic microorganisms should be reflected in DIC isotopes, since OM derived from CO 2 fixation should be isotopically distinct from other sources like surface-derived OM or sedimentary organic matter.…”

Section: Introductionmentioning

confidence: 73%

“…Chemolithoautotrophs can use six different metabolic pathways to fix DIC, of which the Calvin-Benson cycle and the acetyl-CoA pathway are the two most important ones (Fuchs, 2011). Herrmann et al (2015) found that up to 17 % of the microbial community in well H-43 has the potential for chemolithoautotrophic CO 2 fixation via the Calvin-Benson cycle linked to the oxidation of reduced sulfur and nitrogen compounds. The CalvinBenson cycle can function under anoxic and oxic conditions, whereas microorganisms using the acetyl-CoA pathway are restricted to strictly anoxic conditions (Fuchs, 2011;Berg, 2011).…”

Section: Biogeochemical Processes Affecting Dic In Group 2 Wellsmentioning

confidence: 99%

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Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

Nowak

Schwab

Lazar

et al. 2017

Hydrol. Earth Syst. Sci.

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Abstract. Isotopes of dissolved inorganic carbon (DIC) are used to indicate both transit times and biogeochemical evolution of groundwaters. These signals can be complicated in carbonate aquifers, as both abiotic (i.e., carbonate equilibria) and biotic factors influence the δ 13 C and 14 C of DIC. We applied a novel graphical method for tracking changes in the δ 13 C and 14 C of DIC in two distinct aquifer complexes identified in the Hainich Critical Zone Exploratory (CZE), a platform to study how water transport links surface and shallow groundwaters in limestone and marlstone rocks in central Germany. For more quantitative estimates of contributions of different biotic and abiotic carbon sources to the DIC pool, we used the NETPATH geochemical modeling program, which accounts for changes in dissolved ions in addition to C isotopes.Although water residence times in the Hainich CZE aquifers based on hydrogeology are relatively short (years or less), DIC isotopes in the shallow, mostly anoxic, aquifer assemblage (HTU) were depleted in 14 C compared to a deeper, oxic, aquifer complex (HTL). Carbon isotopes and chemical changes in the deeper HTL wells could be explained by interaction of recharge waters equilibrated with post-bomb 14 C sources with carbonates. However, oxygen depletion and δ 13 C and 14 C values of DIC below those expected from the processes of carbonate equilibrium alone indicate considerably different biogeochemical evolution of waters in the upper aquifer assemblage (HTU wells). Changes in 14 C and 13 C in the upper aquifer complexes result from a number of biotic and abiotic processes, including oxidation of 14 C-depleted OM derived from recycled microbial carbon and sedimentary organic matter as well as water-rock interactions. The microbial pathways inferred from DIC isotope shifts and changes in water chemistry in the HTU wells were supported by comparison with in situ microbial community structure based on 16S rRNA analyses.Our findings demonstrate the large variation in the importance of biotic as well as abiotic controls on 13 C and 14 C of DIC in closely related aquifer assemblages. Further, they support the importance of subsurface-derived carbon sources like DIC for chemolithoautotrophic microorganisms as well as rock-derived organic matter for supporting heterotrophic groundwater microbial communities and indicate that even shallow aquifers have microbial communities that use a variety of subsurface-derived carbon sources.

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Section: Hydrochemistrymentioning

confidence: 73%

Section: Introductionmentioning

confidence: 73%

Section: Biogeochemical Processes Affecting Dic In Group 2 Wellsmentioning

confidence: 99%

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Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

Nowak

Schwab

Lazar

et al. 2017

Hydrol. Earth Syst. Sci.

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“…Initial investigations have identified two factors which appear to be key drivers of microbial community composition and thus also strongly influence the potential for biogeochemical processes to take place: (i) the strong differences in oxygen availability between the two aquifers, and (ii) the distance to surface soils and thus the likelihood of the input and potential establishment of soil-derived microbial groups in the aquifer microbial communities (Opitz et al, 2014;Herrmann et al, 2015). Comparative investigations of microbial community structure in the groundwater using next generation amplicon sequencing of 16S rRNA genes and transcripts revealed that members of the Betaproteobacteria and the CytophagalesFlavobacteria-Bacteroidetes group dominate in the upper, anoxic aquifer while members of the Deltaproteobacteria and Nitrospira dominate the communities in the oxic, lower aquifer .…”

Section: Microbial Communitiesmentioning

confidence: 99%

How Deep Can Surface Signals Be Traced in the Critical Zone? Merging Biodiversity with Biogeochemistry Research in a Central German Muschelkalk Landscape

et al. 2016

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The Earth's Critical Zone (CZ) is a thin living layer connecting atmosphere and geosphere, including aquifers. Humans live in the CZ and benefit from the vital supporting services it provides. However, the CZ is increasingly impacted by human activities including land and resource use, pollution, and climate change. Recent interest in uniting the many disciplines studying this complex domain has initiated an international network of research infrastructure platforms that allow access to the CZ in a range of geologic settings. In this paper a new such infrastructure platform associated with the Collaborative Research Center AquaDiva is described, that uniquely seeks to combine CZ research with detailed investigation of the functional biodiversity of the subsurface. Overall, AquaDiva aims to test hypotheses about how water connects surface conditions set by land cover and land management to the biota and biogeochemical functions in the subsurface. With long-term and continuous observations, hypotheses about how seasonal variations and extreme events at the surface impact subsurface processes, community structure and function are tested. AquaDiva has established the Hainich Critical Zone Exploratory (CZE) in central Germany in an alkaline geological setting of German Triassic Muschelkalk formations. The Hainich CZE includes specialized monitoring wells to access the vadose zone and two main groundwater complexes in limestone and marlstone parent materials along a ∼6 km transect spanning forest, pasture, and agricultural land uses. Initial results demonstrate fundamental differences in the biota and biogeochemistry of the two aquifer complexes that trace back to the land uses in their respective recharge areas. They also show the importance of antecedent conditions on the impact of precipitation events on responses in terms of groundwater dynamics, chemistry and ecology. Thus, we find signals of surface land use and events can be detected in the subsurface CZ. Future research will expand to a second CZE in contrasting siliciclastic parent rock, to evaluate the relative importance of parent material lithology vs. surface conditions for the emergent characteristics of the subsurface CZ Küsel et al.Tracing Surface Signals into Subsurface and biodiversity. The Hainich CZE is open to researchers who bring new questions that the research platform can help answer.

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“…The type strain of Sulfuricella denitrificans was isolated from a cold anoxic hypolimnion of a freshwater lake, and was characterized as a psychrotolerant sulfur oxidizer (Watanabe et al, 2012). Based on nucleotide sequences, its close relatives have been found in freshwater lake sediments (Nelson et al, 2007;Song et al, 2012;Watanabe et al, 2013), Thioploca samples from two freshwater lakes (Nemoto et al, 2011), drinking water distribution systems (Li et al, 2010;Sun et al, 2014a, b), the sediment of a drinking water reservoir (Cheng et al, 2014), soil (Field et al, 2010), a bioreactor (Wang et al, 2015), subglacial sediment (Boyd et al, 2014), wetland sediment (Liu et al, 2014), a limestone aquifer (Herrmann et al, 2015), groundwater (Hong et al, 2013), black shale (Li et al, 2014), a horizontal subsurface flow system constructed in wetlands (Zhong et al, 2015) and the freshwater layer of a meromictic lake (Kubo et al, 2014). Members of the genus Sulfuricella are likely to contribute to sulfur cycling in a wide range of freshwater ecosystems, but only two cultured strains of the genus Sulfuricella have, so far, been described (Watanabe et al, 2015b).…”

mentioning

confidence: 99%

Sulfurirhabdus autotrophica gen. nov., sp. nov., isolated from a freshwater lake

Watanabe

Kojima

Shinohara

et al. 2016

International Journal of Systematic and Evolutionary Microbiology

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Large Fractions of CO ₂ -Fixing Microorganisms in Pristine Limestone Aquifers Appear To Be Involved in the Oxidation of Reduced Sulfur and Nitrogen Compounds

Cited by 91 publications

References 77 publications

Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

How Deep Can Surface Signals Be Traced in the Critical Zone? Merging Biodiversity with Biogeochemistry Research in a Central German Muschelkalk Landscape

Sulfurirhabdus autotrophica gen. nov., sp. nov., isolated from a freshwater lake

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Large Fractions of CO 2 -Fixing Microorganisms in Pristine Limestone Aquifers Appear To Be Involved in the Oxidation of Reduced Sulfur and Nitrogen Compounds

Cited by 91 publications

References 77 publications

Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

Carbon isotopes of dissolved inorganic carbon reflect utilization of different carbon sources by microbial communities in two limestone aquifer assemblages

How Deep Can Surface Signals Be Traced in the Critical Zone? Merging Biodiversity with Biogeochemistry Research in a Central German Muschelkalk Landscape

Sulfurirhabdus autotrophica gen. nov., sp. nov., isolated from a freshwater lake

Contact Info

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Large Fractions of CO ₂ -Fixing Microorganisms in Pristine Limestone Aquifers Appear To Be Involved in the Oxidation of Reduced Sulfur and Nitrogen Compounds