Phylogenetic Diversities and Community Structure of Members of the Extremely Halophilic Archaea (Order Halobacteriales) in Multiple Saline Sediment Habitats

Youssef, Noha H.; Ashlock-Savage, Kristen N.

doi:10.1128/aem.07420-11

Cited by 90 publications

(70 citation statements)

References 64 publications

(106 reference statements)

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“…Moreover, a number of putative archaeal OTUs associated with the redox transition zone and monimolimnion (depths of 33 m to 120 m) were identified with "no blast hits" using Greengenes but assigned to Halobacteriales using SILVA. Because both databases are not well annotated for Halobacteria (31), the Sakinaw Lake data set was mapped onto the full-length Halobacteria SSU rRNA gene database generated by Youssef and colleagues (31) using the program CD-HIT (cd-hit-est-2d) (32). The data set could not be clustered with the Halobacteria reference sequences at 99%, 97%, or 95% identity.…”

Section: Methodsmentioning

confidence: 99%

Illuminating Microbial Dark Matter in Meromictic Sakinaw Lake

Gies

Konwar

Beatty

et al. 2014

Appl Environ Microbiol

105

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Despite recent advances in metagenomic and single-cell genomic sequencing to investigate uncultivated microbial diversity and metabolic potential, fundamental questions related to population structure, interactions, and biogeochemical roles of candidate divisions remain. Numerous molecular surveys suggest that stratified ecosystems manifesting anoxic, sulfidic, and/or methanerich conditions are enriched in these enigmatic microbes. Here we describe diversity, abundance, and cooccurrence patterns of uncultivated microbial communities inhabiting the permanently stratified waters of meromictic Sakinaw Lake, British Columbia, Canada, using 454 sequencing of the small-subunit rRNA gene with three-domain resolution. Operational taxonomic units (OTUs) were affiliated with 64 phyla, including more than 25 candidate divisions. Pronounced trends in community structure were observed for all three domains with eukaryotic sequences vanishing almost completely below the mixolimnion, followed by a rapid and sustained increase in methanogen-affiliated (ϳ10%) and unassigned (ϳ60%) archaeal sequences as well as bacterial OTUs affiliated with Chloroflexi (ϳ22%) and candidate divisions (ϳ28%). Network analysis revealed highly correlated, depthdependent cooccurrence patterns between Chloroflexi, candidate divisions WWE1, OP9/JS1, OP8, and OD1, methanogens, and unassigned archaeal OTUs indicating niche partitioning and putative syntrophic growth modes. Indeed, pathway reconstruction using recently published Sakinaw Lake single-cell genomes affiliated with OP9/JS1 and OP8 revealed complete coverage of the Wood-Ljungdahl pathway with potential to drive syntrophic acetate oxidation to hydrogen and carbon dioxide under methanogenic conditions. Taken together, these observations point to previously unrecognized syntrophic networks in meromictic lake ecosystems with the potential to inform design and operation of anaerobic methanogenic bioreactors.

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Section: Methodsmentioning

confidence: 99%

Illuminating Microbial Dark Matter in Meromictic Sakinaw Lake

Gies

Konwar

Beatty

et al. 2014

Appl Environ Microbiol

105

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“…Members of the class Halobacteria are extremely halophilic and haloalkaliphilic (Brito-Echeverria et al 2011;Youssef et al 2012). Members of the genus Halorubrum are ubiquitous halophilic, aerobic archaeans that inhabit saline and hypersaline soils (Papke et al 2004).…”

Section: Archaeamentioning

confidence: 99%

“…In most cases only a few soil samples of a single specific saline system, or a small number of cloned sequences or DGGE bands, have been investigated and analyzed. Some studies have focused only one particular microbial group such as Archaea (Valenzuela-Encinas et al 2009;Youssef et al 2012) or Actinobacteria (Singh et al 2012). Numerous sequences recovered from saline soils are available from the GenBank, but many of these are largely overlooked because they are not published in the literature.…”

Section: Introductionmentioning

confidence: 99%

A meta-analysis of the publicly available bacterial and archaeal sequence diversity in saline soils

Gong

2013

World J Microbiol Biotechnol

102

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An integrated view of bacterial and archaeal diversity in saline soil habitats is essential for understanding the biological and ecological processes and exploiting potential of microbial resources from such environments. This study examined the collective bacterial and archaeal diversity in saline soils using a meta-analysis approach. All available 16S rDNA sequences recovered from saline soils were retrieved from publicly available databases and subjected to phylogenetic and statistical analyses. A total of 9,043 bacterial and 1,039 archaeal sequences, each longer than 250 bp, were examined. The bacterial sequences were assigned into 5,784 operational taxonomic units (OTUs, based on C97 % sequence identity), representing 24 known bacterial phyla, with Proteobacteria (44.9 %), Actinobacteria (12.3 %), Firmicutes (10.4 %), Acidobacteria (9.0 %), Bacteroidetes (6.8 %), and Chloroflexi (5.9 %) being predominant. Lysobacter (12.8 %) was the dominant bacterial genus in saline soils, followed by Sphingomonas (4.5 %), Halomonas (2.5 %), and Gemmatimonas (2.5 %). Archaeal sequences were assigned to 602 OTUs, primarily from the phyla Euryarchaeota (88.7 %) and Crenarchaeota (11.3 %).Halorubrum and Thermofilum were the dominant archaeal genera in saline soils. Rarefaction analysis indicated that less than 25 % of bacterial diversity, and approximately 50 % of archaeal diversity, in saline soil habitats has been sampled. This analysis of the global bacterial and archaeal diversity in saline soil habitats can guide future studies to further examine the microbial diversity of saline soils.

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“…As these electron acceptors are present in hypersaline anoxic habitats at very low concentrations (Oren, 2011), it might appear that these facultative anaerobes cannot play a significant role in anaerobic environments. Nonetheless, molecular ecology studies demonstrated that highly reduced sulfur-rich hypersaline sediments and salt deposits are inhabited by haloarchaea with no cultured representatives (Walsh et al, 2005;Youssef et al, 2011). Can these organisms use elemental sulfur, which may be very abundant, as the alternative terminal electron acceptor?…”

Section: Introductionmentioning

confidence: 99%

Elemental sulfur and acetate can support life of a novel strictly anaerobic haloarchaeon

et al. 2015

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Archaea domain is comprised of many versatile taxa that often colonize extreme habitats. Here, we report the discovery of strictly anaerobic extremely halophilic euryarchaeon, capable of obtaining energy by dissimilatory reduction of elemental sulfur using acetate as the only electron donor and forming sulfide and CO 2 as the only products. This type of respiration has never been observed in hypersaline anoxic habitats and is the first example of such metabolic capability in the entire Archaea domain. We isolated and cultivated these unusual organisms, selecting one representative strain, HSR2, for detailed characterization. Our studies including physiological tests, genome sequencing, gene expression, metabolomics and [ 14 C]-bicarbonate assimilation assays revealed that HSR2 oxidized acetate completely via the tricarboxylic acid cycle. Anabolic assimilation of acetate occurred via activated glyoxylate bypass and anaplerotic carboxylation. HSR2 possessed sulfurtransferase and an array of membrane-bound polysulfide reductase genes, all of which were expressed during the growth. Our findings suggest the biogeochemical contribution of haloarchaea in hypersaline anoxic environments must be reconsidered.

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Phylogenetic Diversities and Community Structure of Members of the Extremely Halophilic Archaea (Order Halobacteriales) in Multiple Saline Sediment Habitats

Cited by 90 publications

References 64 publications

Illuminating Microbial Dark Matter in Meromictic Sakinaw Lake

Illuminating Microbial Dark Matter in Meromictic Sakinaw Lake

A meta-analysis of the publicly available bacterial and archaeal sequence diversity in saline soils

Elemental sulfur and acetate can support life of a novel strictly anaerobic haloarchaeon

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