Active Microbial Communities Inhabit Sulphate-Methane Interphase in Deep Bedrock Fracture Fluids in Olkiluoto, Finland

Bomberg, Malin; Nyyssönen, Mari; Pitkänen, Petteri; Lehtinen, Anne; Itävaara, Merja

doi:10.1155/2015/979530

Cited by 67 publications

(99 citation statements)

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“…The Fennoscandian deep biosphere contains highly diverse microbial communities with rather low cell counts [20,50,[61][62][63]. Although the community compositions have been extensively studied and found to contain a multitude of metabolic potential, only few studies exist to date that show the utilization of specific carbon sources by the deep subsurface community.…”

Section: Discussionmentioning

confidence: 99%

“…The preparation of the barcoded bacterial 16S rRNA gene amplicons was carried out by single round PCR using primers 8f and P2 covering the V1-V3 regions of the bacterial 16S rRNA gene ( Table 2). The primers used for the amplicon libraries were equipped with adapters for the 454 FLX platform, and each forward primer contained unique 6-nucleotide long barcode sequence as described by Bomberg et al [50]. The archaeal and bacterial amplicon library PCR was performed as described in Table S1.…”

Section: Amplicon Library Preparationmentioning

confidence: 99%

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Rare Biosphere Archaea Assimilate Acetate in Precambrian Terrestrial Subsurface at 2.2 km Depth

et al. 2018

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The deep biosphere contains a large portion of the total microbial communities on Earth, but little is known about the carbon sources that support deep life. In this study, we used Stable Isotope Probing (SIP) and high throughput amplicon sequencing to identify the acetate assimilating microbial communities at 2260 m depth in the bedrock of Outokumpu, Finland. The long-term and short-term effects of acetate on the microbial communities were assessed by DNA-targeted SIP and RNA targeted cell activation. The microbial communities reacted within hours to the amended acetate. Archaeal taxa representing the rare biosphere at 2260 m depth were identified and linked to the cycling of acetate, and were shown to have an impact on the functions and activity of the microbial communities in general through small key carbon compounds. The major archaeal lineages identified to assimilate acetate and metabolites derived from the labelled acetate were Methanosarcina spp., Methanococcus spp., Methanolobus spp., and unclassified Methanosarcinaceae. These archaea have previously been detected in the Outokumpu deep subsurface as minor groups. Nevertheless, their involvement in the assimilation of acetate and secretion of metabolites derived from acetate indicated an important role in the supporting of the whole community in the deep subsurface, where carbon sources are limited.Geosciences 2018, 8, 418 2 of 20 utilizing soluble gases, such as crustal methane or hydrogen from radiolytic decomposition of water, have been made since [5][6][7][8]. More specifically, the metabolic capabilities of deep terrestrial subsurface microbial communities include the pathways covering, e.g., methanogenesis [9][10][11], anaerobic methane oxidation [12], acetogenesis [4,13], sulfate reduction [14-16], oxidation of sulfur by denitrification [17], and reduction of iron [14].The Outokumpu deep scientific drill hole, located in Eastern Finland, hosts a unique environment piercing through crystalline Precambrian bedrock and its numerous saline fluid filled fracture zones. The composition of the microbial communities and the geochemical characteristics of the Outokumpu deep subsurface have been studied in detail [11,[18][19][20][21][22][23][24][25][26][27]. The metabolic strategies of the microbial communities at different depths in Outokumpu have been estimated through functional gene analysis and metagenomes [11,21]. Purkamo et al. [21,22] suggested that microbial communities commonly employ heterotrophic carbon assimilation in the Outokumpu deep subsurface, and that the communities have the capacity of both sulphate and nitrate reduction. At greater depths, genetic potential for autotrophic acetogenesis and hydrogenotrophic methanogenesis has been detected from Outokumpu metagenomes together with H 2 oxidation and CO 2 fixation coupling hydrogenases [11].The terrestrial deep subsurface represents an oligotrophic, nutrient-poor, and isolated habitat. The fact that heterotrophy appears to be common in the Outokumpu deep biosphere means that the carbon sub...

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Section: Discussionmentioning

confidence: 99%

Section: Amplicon Library Preparationmentioning

confidence: 99%

Rare Biosphere Archaea Assimilate Acetate in Precambrian Terrestrial Subsurface at 2.2 km Depth

et al. 2018

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“…These groups are known to contain crop pathogens5657, with Xanthomondales known to cause significant losses to cotton crops58 and Pseudomondales a known component of biofertilisers59, although members of this order are also common soil denitrifiers with no plant pathogenicity60. Both orders have been identified in contaminated groundwaters606162 with Xanthomonadales able to survive in groundwater for over a year63. Additionally Burkholderiales (e.g.…”

Section: Discussionmentioning

confidence: 99%

Wells provide a distorted view of life in the aquifer: implications for sampling, monitoring and assessment of groundwater ecosystems

Korbel

Chariton

Stephenson

et al. 2017

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When compared to surface ecosystems, groundwater sampling has unique constraints, including limited access to ecosystems through wells. In order to monitor groundwater, a detailed understanding of groundwater biota and what biological sampling of wells truly reflects, is paramount. This study aims to address this uncertainty, comparing the composition of biota in groundwater wells prior to and after purging, with samples collected prior to purging reflecting a potentially artificial environment and samples collected after purging representing the surrounding aquifer. This study uses DNA community profiling (metabarcoding) of 16S rDNA and 18S rDNA, combined with traditional stygofauna sampling methods, to characterise groundwater biota from four catchments within eastern Australia. Aquifer waters were dominated by Archaea and bacteria (e.g. Nitrosopumilales) that are often associated with nitrification processes, and contained a greater proportion of bacteria (e.g. Anaerolineales) associated with fermenting processes compared to well waters. In contrast, unpurged wells contained greater proportions of pathogenic bacteria and bacteria often associated with denitrification processes. In terms of eukaryotes, the abundances of copepods, syncarids and oligochaetes and total abundances of stygofauna were greater in wells than aquifers. These findings highlight the need to consider sampling requirements when completing groundwater ecology surveys.

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“…While the microbial communities in deep marine subsurface environments have been intensively characterized within the last decade with next-generation sequencing methods Biddle et al, 2008Biddle et al, , 2011Brazelton et al, 2012), high-throughput (HTP) sequencing techniques have only recently emerged in characterization of the terrestrial deep subsurface microbial communities Bomberg et al, 2014Bomberg et al, , 2015aLau et al, 2014;Mu et al, 2014). A vast amount of data obtained from HTP sequencing studies can be used to estimate ecological measures such as species richness, abundance and β-diversity, but it also allows the exploration of significant relationships between microbial taxa and their coexistence in a specific environment (Zhou et al, 2011;Barberan et al, 2012;Lupatini et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Microbial co-occurrence patterns in deep Precambrian bedrock fracture fluids

et al. 2016

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The bacterial and archaeal community composition and the possible carbon assimilation processes and energy sources of microbial communities in oligotrophic, deep, crystalline bedrock fractures is yet to be resolved. In this study, intrinsic microbial communities from groundwater of six fracture zones from 180 to 2300 m depths in Outokumpu bedrock were characterized using high-throughput amplicon sequencing and metagenomic prediction. Comamonadaceae-, Anaerobrancaceaeand Pseudomonadaceae-related operational taxonomic units (OTUs) form the core community in deep crystalline bedrock fractures in Outokumpu. Archaeal communities were mainly composed of Methanobacteriaceae-affiliating OTUs. The predicted bacterial metagenomes showed that pathways involved in fatty acid and amino sugar metabolism were common. In addition, relative abundance of genes coding the enzymes of autotrophic carbon fixation pathways in predicted metagenomes was low. This indicates that heterotrophic carbon assimilation is more important for microbial communities of the fracture zones. Network analysis based on cooccurrence of OTUs revealed possible "keystone" genera of the microbial communities belonging to Burkholderiales and Clostridiales. Bacterial communities in fractures resemble those found in oligotrophic, hydrogen-enriched environments. Serpentinization reactions of ophiolitic rocks in Outokumpu assemblage may provide a source of energy and organic carbon compounds for the microbial communities in the fractures. Sulfate reducers and methanogens form a minority of the total microbial communities, but OTUs forming these minor groups are similar to those found in other deep Precambrian terrestrial bedrock environments.

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Active Microbial Communities Inhabit Sulphate-Methane Interphase in Deep Bedrock Fracture Fluids in Olkiluoto, Finland

Cited by 67 publications

References 48 publications

Rare Biosphere Archaea Assimilate Acetate in Precambrian Terrestrial Subsurface at 2.2 km Depth

Rare Biosphere Archaea Assimilate Acetate in Precambrian Terrestrial Subsurface at 2.2 km Depth

Wells provide a distorted view of life in the aquifer: implications for sampling, monitoring and assessment of groundwater ecosystems

Microbial co-occurrence patterns in deep Precambrian bedrock fracture fluids

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