Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

Lay, Chih-Ying; Mykytczuk, Nadia; Yergeau, Étienne; Lamarche-Gagnon, Guillaume; Greer, Charles W.; Whyte, Lyle G.

doi:10.1128/aem.00153-13

Cited by 46 publications

(28 citation statements)

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“…Brine compositions and salt mineralogy at the springs are consistent with published data (Battler et al, ; Lay et al, ; Omelon et al, ; Ward & Pollard, ). Across all springs, fluids are dominated by sodium and chloride and contain significant concentrations of sulfate (Figure a and Table S1).…”

Section: Resultssupporting

confidence: 89%

Natural Analogue Constraints on Europa's Non‐ice Surface Material

Fox-Powell

Osinski

Applin

et al. 2019

Geophysical Research Letters

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Non‐icy material on the surface of Jupiter's moon Europa is hypothesized to have originated from its subsurface ocean and thus provide a record of ocean composition and habitability. The nature of this material is debated, but observations suggest that it comprises hydrated sulfate and chloride salts. Analogue spectroscopic studies have previously focused on single‐phase salts under controlled laboratory conditions. We investigated natural salts from perennially cold (<0 °C) hypersaline springs and characterized their reflectance properties at 100, 253, and 293 K. Despite similar major ion chemistry, these springs form mineralogically diverse deposits, which when measured at 100 K closely match reflectance spectra from Europa. In the most sulfate‐rich samples, we find that spectral features predicted from laboratory salts are obscured. Our data are consistent with sulfate‐dominated europan non‐icy material and further show that the emplacement of endogenic sulfates on Europa's surface would not preclude a chloride‐dominated ocean.

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Section: Resultssupporting

confidence: 89%

Natural Analogue Constraints on Europa's Non‐ice Surface Material

Fox-Powell

Osinski

Applin

et al. 2019

Geophysical Research Letters

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“…The abundant ions of LH are the same as GH4, in similar ratios but greater concentrations (Niederberger et al, 2010). Microbial and molecular characterization from both the spring outlet and channel indicate a low diversity community and the presence of anaerobic methanotrophs, methanogens, sulfur oxidizing bacteria and ammonia oxidizers (Niederberger et al, 2010; Lay et al, 2012, 2013; Lamarche-Gagnon et al, 2015). The biomass of both springs are very low, with the channel sediments of each inhabited by an order of magnitude more microbes than the outlet of the same spring (Colangelo-Lillis et al, 2016b).…”

Section: Methodsmentioning

confidence: 99%

“…Four of these vials were amended with lactate and another four with acetate (60 μL of 1 M carbon source, final concentration 10 mM). Per spring site, EdU ± carbon treated vials were formaldehyde fixed at time points: 0, 8, 24, and 96 h. Lactate was chosen because it can be utilized by many sulfate-reducers, known to be present and active in these sediments (Perreault et al, 2007; Lay et al, 2013). Acetate was chosen as it is among the most simple and ubiquitously utilized carbon sources, and has been employed in culturing isolates from LH (Niederberger et al, 2010).…”

Section: Methodsmentioning

confidence: 99%

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Viral Induced Microbial Mortality in Arctic Hypersaline Spring Sediments

et al. 2017

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Viruses are a primary influence on microbial mortality in the global ocean. The impacts of viruses on their microbial hosts in low-energy environments are poorly explored and are the focus of this study. To investigate the role of viruses in mediating mortality in low-energy environments where contacts between viruses and microbes are infrequent, we conducted a set of in situ time series incubations in the outlet and channel sediments of two cold, hypersaline springs of the Canadian High Arctic. We found microbial and viral populations in dynamic equilibrium, indicating approximately equal birth and death rates for each population. In situ rates of microbial growth were low (0.5–50 × 103 cells cm-3 h-1) as were rates of viral decay (0.09–170 × 104 virions cm-3 h-1). A large fraction of the springs’ viral communities (49–100%) were refractory to decay over the timescales of our experiments. Microcosms amended with lactate or acetate exhibited increased microbial growth rates (up to three-fold) indicating organic carbon as one limiting resource for the microbial communities in these environments. A substantial fraction (15–71%) of the microbial populations contained inducible proviruses that were released- occasionally in multiple pulses- over the eight monitored days following chemical induction. Our findings indicate that viruses in low-energy systems maintain low rates of production and activity, have a small but notable impact on microbial mortality (8–29% attenuation of growth) and that successful viral replication may primarily proceed by non-lethal strategies. In cold, low biomass marine systems of similar character (e.g., subsurface sediments), viruses may be a relatively minor driver of community mortality compared to less energy-limited environments such as the marine water column or surface sediments.

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“…However, E. sibiricu lost flagella at -2.5 °C, in contrast to P. halocryophilus which becomes motile at -15 °C. Metagenomic analysis of low temperature microbial communities in a high-arctic subzero hypersaline spring also revealed high abundance of genes associated with unsaturated fatty acid metabolism, suggestive of cell wall remodeling, along with periplasmic glucan, and cytosolic betaine synthesis genes associated with osmotolerance (betaine balances high osmotic pressure in high saline environments) (Lay et al, 2013). Oxidative stress genes were also highly abundant which has been attributed to a requirement to detoxify reactive radicals resulting from accumulation of electrons in the respiratory chain at very low metabolic rates (Lay et al, 2013).…”

Section: Permafrost Microbiology and The Role Of Permafrost Microbialmentioning

confidence: 99%

Microbial dynamics in a thawing world: Microbial ecology of a permafrost active layer

Mondav¹

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Microbial assemblages in the active layer of thawing permafrost were investigated over two years across a spatially related thaw gradient. This is the first massive pyrosequencing project to investigate, document and compare the microbial community of such systems. In situ measurements of geochemical parameters enabled linkage of the community dynamics to significant shifts in C (carbon) balance and community structure. The study investigated communities from a palsa mire with three internal sites selected that were Increased thawing of permafrost, a significant global C sink, makes cryo-sequestered C available for microbial degradation. Methanogenic Archaea convert this C to the potent greenhouse gas methane. The discovery of a novel methanogen of the RCII archaeal lineage at up to 70% abundance of the community allowed recovery of a population genome. The environmentally recovered genome and proteome of this archaea, iii 'Candidatus Methanoflorens stordalenmirensis', indicates that hydrogenotrophic methanogenesis is its main energy conservation pathway. Enrichment of C storage and membrane associated genes support 'Ca. M. stordalenmirensis' genomic adaption to its active layer environment. Meta-analysis of community surveys, 16S rRNA and mcrA genes, suggested that 'Methanoflorens spp.' are dominant and ubiquitous methanogens in permafrost and peatland soils. This lineage had previously been identified as significant in temperate peatlands but was thought to be a negligible contributor to methanogenesis at high latitudes.iv

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Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

Cited by 46 publications

References 100 publications

Natural Analogue Constraints on Europa's Non‐ice Surface Material

Natural Analogue Constraints on Europa's Non‐ice Surface Material

Viral Induced Microbial Mortality in Arctic Hypersaline Spring Sediments

Microbial dynamics in a thawing world: Microbial ecology of a permafrost active layer

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