Examining the global distribution of dominant archaeal populations in soil

Bates, Scott T.; Berg-Lyons, Donna; Caporaso, J. Gregory; Walters, William A.; Knight, Rob; Fierer, Noah

doi:10.1038/ismej.2010.171

Cited by 1,115 publications

(772 citation statements)

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“…DNA concentrations for each amplification reaction were measured with the Nanodrop 2000 (Thermo Scientific, Bremen, Germany) and B600 ng of DNA from each reaction was pooled, then sent to the Ramaciotti Centre for Gene Function Analysis for sequencing using the GS-FLX pyrosequencing platform (Roche, Mannheim, Germany). For 16S rRNA amplicon sequencing, original cave DNA (rather than Phi29-amplified DNA) was used as a template in PCR with the primer set F515 and R806 of Bates et al (2011), which have been shown to successfully amplify an B250 bp region of the 16S rRNA gene from both bacteria and archaea (Bates et al, 2011). Reactions were performed in triplicate 25 ml reactions using the FastStart High Fidelity PCR System (Roche) according to the manufacturer's instructions with 1 ml template DNA.…”

Section: Methodsmentioning

confidence: 99%

Life in the dark: metagenomic evidence that a microbial slime community is driven by inorganic nitrogen metabolism

et al. 2013

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Beneath Australia’s large, dry Nullarbor Plain lies an extensive underwater cave system, where dense microbial communities known as ‘slime curtains’ are found. These communities exist in isolation from photosynthetically derived carbon and are presumed to be chemoautotrophic. Earlier work found high levels of nitrite and nitrate in the cave waters and a high relative abundance of Nitrospirae in bacterial 16S rRNA clone libraries. This suggested that these communities may be supported by nitrite oxidation, however, details of the inorganic nitrogen cycling in these communities remained unclear. Here we report analysis of 16S rRNA amplicon and metagenomic sequence data from the Weebubbie cave slime curtain community. The microbial community is comprised of a diverse assortment of bacterial and archaeal genera, including an abundant population of Thaumarchaeota. Sufficient thaumarchaeotal sequence was recovered to enable a partial genome sequence to be assembled, which showed considerable synteny with the corresponding regions in the genome of the autotrophic ammonia oxidiser Nitrosopumilus maritimus SCM1. This partial genome sequence, contained regions with high sequence identity to the ammonia mono-oxygenase operon and carbon fixing 3-hydroxypropionate/4-hydroxybutyrate cycle genes of N. maritimus SCM1. Additionally, the community, as a whole, included genes encoding key enzymes for inorganic nitrogen transformations, including nitrification and denitrification. We propose that the Weebubbie slime curtain community represents a distinctive microbial ecosystem, in which primary productivity is due to the combined activity of archaeal ammonia-oxidisers and bacterial nitrite oxidisers.

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Section: Methodsmentioning

confidence: 99%

Life in the dark: metagenomic evidence that a microbial slime community is driven by inorganic nitrogen metabolism

et al. 2013

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“…DNA was amplified in triplicate using primers specific to either the 16S or 18S rRNA gene. A portion of the 16S rRNA gene was amplified using the Archaea-and Bacteriaspecific primer set 515f/806r [20]. This 16S primer set is designed to amplify the V4 -V5 region of both Archaea and Bacteria, has few biases against specific taxa and accurately represents phylogenetic and taxonomic assignment of sequences [25].…”

Section: (C) Central Park Community-level Sequence Analysismentioning

confidence: 99%

“…We quantified the diversity living within the soils via high-throughput sequencing of a hypervariable region of the 16S small subunit rRNA gene for the bacterial and archaeal analyses [20] and a comparable region of the 18S rRNA gene for the eukaryotic analyses. For reasons of consistency and for lack of a better definition that applies across all three domains [14,21], we define a phylotype as those taxa that share greater than or equal to 97% sequence similarity in the targeted rRNA gene regions, following convention [22].…”

Section: Introductionmentioning

confidence: 99%

Biogeographic patterns in below-ground diversity in New York City's Central Park are similar to those observed globally

et al. 2014

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Soil biota play key roles in the functioning of terrestrial ecosystems, however, compared to our knowledge of above-ground plant and animal diversity, the biodiversity found in soils remains largely uncharacterized. Here, we present an assessment of soil biodiversity and biogeographic patterns across Central Park in New York City that spanned all three domains of life, demonstrating that even an urban, managed system harbours large amounts of undescribed soil biodiversity. Despite high variability across the Park, below-ground diversity patterns were predictable based on soil characteristics, with prokaryotic and eukaryotic communities exhibiting overlapping biogeographic patterns. Further, Central Park soils harboured nearly as many distinct soil microbial phylotypes and types of soil communities as we found in biomes across the globe (including arctic, tropical and desert soils). This integrated cross-domain investigation highlights that the amount and patterning of novel and uncharacterized diversity at a single urban location matches that observed across natural ecosystems spanning multiple biomes and continents.

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“…This notion was subsequently challenged by culture-independent diversity surveys that documented the occurrence of the Archaea in both extreme Orphan et al, 2000;Benlloch et al, 2001Benlloch et al, , 2002Baker and Banfield, 2003) and temperate habitats, for example, soil (Bintrim et al, 1997;Walsh et al, 2005;Bates et al, 2011;Tripathi et al, 2013), marine environments (DeLong, 1992;Fuhrman et al, 1992;Massana et al, 1997;Karner et al, 2001) and freshwater ecosystems (Lin et al, 2012;Yergeau et al, 2012;Berdjeb et al, 2013;Bricheux et al, 2013;Silveira et al, 2013;Vila-Costa et al, 2013). In addition to establishing the ubiquity of the Archaea on a global scale, these studies have also significantly expanded the scope of phylogenetic diversity within this domain, as many of the sequences identified represented novel, high-rank phylogenetic lineages (DeLong, 1992;Vetriani et al, 1999;Takai et al, 2001;Hallam et al, 2004;Elkins et al, 2008;Hu et al, 2011;Nunoura et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Insights into the metabolism, lifestyle and putative evolutionary history of the novel archaeal phylum ‘Diapherotrites’

et al. 2014

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The archaeal phylum ‘Diapherotrites’ was recently proposed based on phylogenomic analysis of genomes recovered from an underground water seep in an abandoned gold mine (Homestake mine in Lead, SD, USA). Here we present a detailed analysis of the metabolic capabilities and genomic features of three single amplified genomes (SAGs) belonging to the ‘Diapherotrites’. The most complete of the SAGs, Candidatus ‘Iainarchaeum andersonii’ (Cand. IA), had a small genome (∼1.24 Mb), short average gene length (822 bp), one ribosomal RNA operon, high coding density (∼90.4%), high percentage of overlapping genes (27.6%) and low incidence of gene duplication (2.16%). Cand. IA genome possesses limited catabolic capacities that, nevertheless, could theoretically support a free-living lifestyle by channeling a narrow range of substrates such as ribose, polyhydroxybutyrate and several amino acids to acetyl-coenzyme A. On the other hand, Cand. IA possesses relatively well-developed anabolic capabilities, although it remains auxotrophic for several amino acids and cofactors. Phylogenetic analysis suggests that the majority of Cand. IA anabolic genes were acquired from bacterial donors via horizontal gene transfer. We thus propose that members of the ‘Diapherotrites’ have evolved from an obligate symbiotic ancestor by acquiring anabolic genes from bacteria that enabled independent biosynthesis of biological molecules previously acquired from symbiotic hosts. ‘Diapherotrites’ 16S rRNA genes exhibit multiple mismatches with the majority of archaeal 16S rRNA primers, a fact that could be responsible for their observed rarity in amplicon-generated data sets. The limited substrate range, complex growth requirements and slow growth rate predicted could be responsible for its refraction to isolation.

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Examining the global distribution of dominant archaeal populations in soil

Cited by 1,115 publications

References 54 publications

Life in the dark: metagenomic evidence that a microbial slime community is driven by inorganic nitrogen metabolism

Life in the dark: metagenomic evidence that a microbial slime community is driven by inorganic nitrogen metabolism

Biogeographic patterns in below-ground diversity in New York City's Central Park are similar to those observed globally

Insights into the metabolism, lifestyle and putative evolutionary history of the novel archaeal phylum ‘Diapherotrites’

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