New Abundant Microbial Groups in Aquatic Hypersaline Environments

Ghai, Rohit; Pašić, Lejla; Fernández, Ana Beatriz; Martín-Cuadrado, Ana-Belén; Mizuno, Carolina Megumi; McMahon, Katherine D.; Papke, R. Thane; Stepanauskas, Ramūnas; Rodriguez-Brito, Beltrán; Rohwer, Forest; Sánchez‐Porro, Cristina; Ventosa, António; Rodrı́guez-Valera, Francisco

doi:10.1038/srep00135

Cited by 273 publications

(344 citation statements)

References 57 publications

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“…Even though the bacterial abundance was comparable to that typically described for high-salt environments (Demergasso et al, 2008;Baricz et al, 2014), the fact that they constituted~78% of the monimolimnion community was unanticipated, as previous studies reported the dominance of Archaea at salinities 4300 g l − 1 (Ghai et al, 2011;Baricz et al, 2014). We assume that the increased abundance of Bacteria in the deeper water strata could be achieved by outcompeting Archaea in suboxic hypersaline conditions, as the majority of halophilic archaeal species are aerobic (Andrei et al, 2012).…”

Section: Vertical Patterns In Prokaryotic Abundancesmentioning

confidence: 65%

Contrasting taxonomic stratification of microbial communities in two hypersaline meromictic lakes

et al. 2015

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Hypersaline meromictic lakes are extreme environments in which water stratification is associated with powerful physicochemical gradients and high salt concentrations. Furthermore, their physical stability coupled with vertical water column partitioning makes them important research model systems in microbial niche differentiation and biogeochemical cycling. Here, we compare the prokaryotic assemblages from Ursu and Fara Fund hypersaline meromictic lakes (Transylvanian Basin, Romania) in relation to their limnological factors and infer their role in elemental cycling by matching taxa to known taxon-specific biogeochemical functions. To assess the composition and structure of prokaryotic communities and the environmental factors that structure them, deepcoverage small subunit (SSU) ribosomal RNA (rDNA) amplicon sequencing, community domainspecific quantitative PCR and physicochemical analyses were performed on samples collected along depth profiles. The analyses showed that the lakes harbored multiple and diverse prokaryotic communities whose distribution mirrored the water stratification patterns. Ursu Lake was found to be dominated by Bacteria and to have a greater prokaryotic diversity than Fara Fund Lake that harbored an increased cell density and was populated mostly by Archaea within oxic strata. In spite of their contrasting diversity, the microbial populations indigenous to each lake pointed to similar physiological functions within carbon degradation and sulfate reduction. Furthermore, the taxonomy results coupled with methane detection and its stable C isotope composition indicated the presence of a yet-undescribed methanogenic group in the lakes' hypersaline monimolimnion. In addition, ultrasmall uncultivated archaeal lineages were detected in the chemocline of Fara Fund Lake, where the recently proposed Nanohaloarchaeota phylum was found to thrive.

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Section: Vertical Patterns In Prokaryotic Abundancesmentioning

confidence: 65%

Contrasting taxonomic stratification of microbial communities in two hypersaline meromictic lakes

et al. 2015

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“…These advances led to the identification and genomic characterization of multiple novel high-rank archaeal lineages that have previously escaped detection in 16S ribosomal RNA (rRNA) gene-based diversity surveys because of their extremely low relative abundance, limited distribution or mismatches to archaeal 16S rRNA gene primer sequences (Baker et al, 2010;Nunoura et al, 2011;Narasingarao et al, 2012). These discoveries necessitated phylogenetic and phylogenomic-based reassessment of the taxonomic structure of the domain Archaea (Lake et al, 1984;BrochierArmanet et al, 2008;Elkins et al, 2008;Ghai et al, 2011;Guy and Ettema, 2011;Williams et al, 2012). The most recent and comprehensive phylogenomicsbased assessment of the domain Archaea (Rinke et al, 2013) combined data from 35 novel archaeal single amplified genomes (SAGs) with previously published archaeal genomes to propose a three archaeal superphyla scheme.…”

Section: Introductionmentioning

confidence: 99%

“…The DPANN superphylum encompasses the 'Nanoarchaeota' (Waters et al, 2003;Podar et al, 2013), the only DPANN phylum with cultured representatives, as well as the candidate phyla 'Nanohaloarchaeota' (defined from metagenomic assembly (Narasingarao et al, 2012) and SAGs (Ghai et al, 2011) from hypersaline environments); 'Parvarchaeota' (defined from a metagenomic assembly from an acid mine drainage; Baker et al, 2010), 'Aenigmarchaeota' (defined from three SAGs from Homestake mine groundwater seep (Lead, SD, USA) and the Great Boiling Spring sediments; Rinke et al, 2013) and 'Diapherotrites' (defined from SAGs from Homestake mine groundwater seep; Rinke et al, 2013). As such, the DPANN superphylum represents an intriguing collection of phyla with disparate physiological preferences and environmental distribution, ranging from the obligatory symbiotic and thermophilic species within the 'Nanoarchaeota', to the acidophilic candidate phylum 'Parvarachaeota' and to the non-extremophilic candidate phyla 'Aenigmarchaeota' and 'Diapherotrites'.…”

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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“…Full random metagenome sequencing of multiple hypersaline systems (Santa Polasaltern in Spain -13 to 37% salinity), the hypersaline lake Tyrell in Australia (29% salinity) and crystallizer ponds in the USA (18 to 38% salinity) show equally high phylotypic diversity and the general dominance of Archaea, in particular the square-shaped halophilic archaeon Haloquadratum walsbyi [38][39][40][41]. Remarkably, de novo sequence assembly of metagenomic samples from hypersaline environments has led to the discovery of a novel uncultivated class, the "Nanohaloarchaea", previously detected only once by "classic" 16S rRNA amplicon sequencing [42] but now known to be dominant in these systems across the world [39,40]. De novo genome annotation has revealed the projected metabolic capacities of the uncultured Nanohaloarchaea with (i) a unique combination of protein amino acids to increase both osmo-resistance and protein flexibility, (ii) the first complete archaeal pentose-phosphate-pathway and (iii) the absence of Gvp gas vesicle protein orthologs which are otherwise highly conserved in halophilic archaeal genomes [40].…”

Section: Extremely Halophilic Habitatsmentioning

confidence: 99%

“…De novo genome annotation has revealed the projected metabolic capacities of the uncultured Nanohaloarchaea with (i) a unique combination of protein amino acids to increase both osmo-resistance and protein flexibility, (ii) the first complete archaeal pentose-phosphate-pathway and (iii) the absence of Gvp gas vesicle protein orthologs which are otherwise highly conserved in halophilic archaeal genomes [40]. Single-cell genomic analyses have further characterized a member of this euryarchaeal class as a low-GC photoheterotrophic, salt-in strategist with the ability to degrade polysaccharides [39].…”

Section: Extremely Halophilic Habitatsmentioning

confidence: 99%

Metagenomics of extreme environments

Cowan¹,

Ramond²,

Makhalanyane³

et al. 2015

Current Opinion in Microbiology

117

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Whether they are exposed to extremes of heat, cold, or buried deep beneath the Earth"s surface, microorganisms have an uncanny ability to survive under these conditions. This ability to survive has fascinated scientists for nearly a century, but the recent development of metagenomics and "omics tools has allowed us to make huge leaps in understanding the remarkable complexity and versatility of extremophile communities. Here, in the context of the recently developed metagenomic tools, we discuss recent research on the community composition, adaptive strategies and biological functions of extremophiles.

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New Abundant Microbial Groups in Aquatic Hypersaline Environments

Cited by 273 publications

References 57 publications

Contrasting taxonomic stratification of microbial communities in two hypersaline meromictic lakes

Contrasting taxonomic stratification of microbial communities in two hypersaline meromictic lakes

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

Metagenomics of extreme environments

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