Microbial communities and their predicted metabolic characteristics in deep fracture groundwaters of the crystalline bedrock at Olkiluoto, Finland

The microbial diversity in oligotrophic isolated crystalline Fennoscandian Shield bedrock fracture groundwaters is high, but the core community has not been identified. Here we characterized the bacterial and archaeal communities in 12 water conductive fractures situated at depths between 296 and 79...

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Bibliographic Details
Published in:Biogeosciences
Main Authors: Bomberg, Malin, Lamminmäki, Tiina, Itävaara, Merja
Format: Article in Journal/Newspaper
Language:English
Published: 2016
Subjects:
archaea
bacteria (microorganisms)
Calvin
Fennoscandian
Online Access:https://cris.vtt.fi/en/publications/3a8b76e5-1e78-4a1f-8354-debd821579a9
https://doi.org/10.5194/bg-13-6031-2016
Description
Summary:The microbial diversity in oligotrophic isolated crystalline Fennoscandian Shield bedrock fracture groundwaters is high, but the core community has not been identified. Here we characterized the bacterial and archaeal communities in 12 water conductive fractures situated at depths between 296 and 798g m by high throughput amplicon sequencing using the Illumina HiSeq platform. Between 1.7g * g 104 and 1.2g * g 106 bacterial or archaeal sequence reads per sample were obtained. These sequences revealed that up to 95 and 99g % of the bacterial and archaeal sequences obtained from the 12 samples, respectively, belonged to only a few common species, i.e.The core microbiome. However, the remaining rare microbiome contained over 3-and 6-fold more bacterial and archaeal taxa. The metabolic properties of the microbial communities were predicted using PICRUSt. The approximate estimation showed that the metabolic pathways commonly included fermentation, fatty acid oxidation, glycolysis/gluconeogenesis, oxidative phosphorylation, and methanogenesis/anaerobic methane oxidation, but carbon fixation through the Calvin cycle, reductive TCA cycle, and the Wood-Ljungdahl pathway was also predicted. The rare microbiome is an unlimited source of genomic functionality in all ecosystems. It may consist of remnants of microbial communities prevailing in earlier environmental conditions, but could also be induced again if changes in their living conditions occur.

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