Relative Importance of H
            <sub>2</sub>
            and H
            <sub>2</sub>
            S as Energy Sources for Primary Production in Geothermal Springs

D’Imperio, Seth; Lehr, Corinne R.; Oduro, Harry; Druschel, Gregory K.; Kühl, Michael; McDermott, Timothy R.

doi:10.1128/aem.00852-08

Cited by 50 publications

(81 citation statements)

References 41 publications

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“…At [H 2 ]40.1 nM, H 2 oxidation is more exergonic per O 2 molecule than sulfide oxidation (based on data in Bach and Edwards (2003)). The presence of H 2 -oxidizing clades has been correlated with the free energy of this reaction (Spear et al, 2005), but its importance vis-a`-vis sulfide oxidation is probably controlled by the H 2 affinities and uptake kinetics of guild members (D'Imperio et al, 2008). We speculate that hydrogen-oxidizing bacteria (possibly including Ralstonia sp.)…”

Section: Discussionmentioning

confidence: 99%

An oligarchic microbial assemblage in the anoxic bottom waters of a volcanic subglacial lake

et al. 2008

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In 2006, we sampled the anoxic bottom waters of a volcanic lake beneath the Vatnajö kull ice cap (Iceland). The sample contained 5 Â 10 5 cells per ml, and whole-cell fluorescent in situ hybridization (FISH) and PCR with domain-specific probes showed these to be essentially all bacteria, with no detectable archaea. Pyrosequencing of the V6 hypervariable region of the 16S ribosomal RNA gene, Sanger sequencing of a clone library and FISH-based enumeration of four major phylotypes revealed that the assemblage was dominated by a few groups of putative chemotrophic bacteria whose closest cultivated relatives use sulfide, sulfur or hydrogen as electron donors, and oxygen, sulfate or CO 2 as electron acceptors. Hundreds of other phylotypes are present at lower abundance in our V6 tag libraries and a rarefaction analysis indicates that sampling did not reach saturation, but FISH data limit the remaining biome to o10-20% of all cells. The composition of this oligarchy can be understood in the context of the chemical disequilibrium created by the mixing of sulfidic lake water and oxygenated glacial meltwater.

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Section: Discussionmentioning

confidence: 99%

An oligarchic microbial assemblage in the anoxic bottom waters of a volcanic subglacial lake

et al. 2008

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“…In addition, submerged substrata at the spring's source are blanketed by precipitates of elemental sulfur (S°), hereafter referred to as S o floc (23). Inventories of bacterial and archaeal 16S rRNA genes recovered from S o floc collected from the source of Dragon Spring indicate the presence of Crenarchaeota and Aquificae (4,15). The latter are related to chemolithoautotrophic Hydrogenobaculum spp., representatives of which have recently been isolated from the spring (15).…”

Section: ؊1mentioning

confidence: 99%

“…Inventories of bacterial and archaeal 16S rRNA genes recovered from S o floc collected from the source of Dragon Spring indicate the presence of Crenarchaeota and Aquificae (4,15). The latter are related to chemolithoautotrophic Hydrogenobaculum spp., representatives of which have recently been isolated from the spring (15). In the present study, we demonstrate uptake and fixation of CO 2 at a temperature of 73°C by a Hydrogenobaculum-dominated microbial community associated with S o floc collected from the source of Dragon Spring.…”

Section: ؊1mentioning

confidence: 99%

“…The pH of the water is ϳ3.1, and the temperature of the water at the source fluctuates from 65 to 78°C, which is well above the upper temperature limit for photosynthesis under acidic conditions. Potential electron donors for chemolithoautotrophic growth in the source water include hydrogen (H 2 ) and sulfide (S 2Ϫ ) at concentrations of 13 nM and 65 M, respectively (15). In addition, submerged substrata at the spring's source are blanketed by precipitates of elemental sulfur (S°), hereafter referred to as S o floc (23).…”

Section: ؊1mentioning

confidence: 99%

“…Evidence for chemosynthesis in these environments is based on the recovery of 16S rRNA gene sequences that are affiliated with cultivated representatives of the phyla Aquificae and Crenarchaeota, many of which are capable of CO 2 fixation via the oxidation of hydrogen (H 2 ) and/or sulfide (HS Ϫ ) (15,17,21,24,26,28,41,46). Surprisingly, CO 2 fixation has yet to be demonstrated in situ in YNP hot spring environments (acidic or alkaline) where temperatures exceed the limits of photosynthesis and where primary production is thought to be driven by chemoautotrophic metabolism (14,15,28,29).Dragon Spring, an acid-sulfate-chloride (ASC) spring located in the Norris Geyser Basin of YNP, is a likely habitat for chemoautotrophic primary production. The pH of the water is ϳ3.1, and the temperature of the water at the source fluctuates from 65 to 78°C, which is well above the upper temperature limit for photosynthesis under acidic conditions.…”

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CO ₂ Uptake and Fixation by a Thermoacidophilic Microbial Community Attached to Precipitated Sulfur in a Geothermal Spring

Boyd

Leavitt

Geesey

2009

Appl Environ Microbiol

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Carbon fixation at temperatures above 73°C, the upper limit for photosynthesis, is carried out by chemosynthetic thermophiles. Yellowstone National Park (YNP), Wyoming possesses many thermal features that, while too hot for photosynthesis, presumably support chemosynthetic-based carbon fixation. To our knowledge, in situ rates of chemosynthetic reactions at these high temperatures in YNP or other high-temperature terrestrial geothermal springs have not yet been reported. A microbial community attached to precipitated elemental sulfur (S o floc) at the source of Dragon Spring (73°C, pH 3.1) in Norris Geyser Basin, YNP, exhibited a maximum rate of CO 2 uptake of 21.3 ؎ 11.9 g of C 107 cells ؊1 h ؊1. When extrapolated over the estimated total quantity of S o floc at the spring's source, the S o floc-associated microbial community accounted for the uptake of 121 mg of C h ؊1 at this site. On a per-cell basis, the rate was higher than that calculated for a photosynthetic mat microbial community dominated by Synechococcus spp. in alkaline springs at comparable temperatures. A portion of the carbon taken up as CO 2 by the S o floc-associated biomass was recovered in the cellular nucleic acid pool, demonstrating that uptake was coupled to fixation. The most abundant sequences in a 16S rRNA clone library of the S o floc-associated community were related to chemolithoautotrophic Hydrogenobaculum strains previously isolated from springs in the Norris Geyser Basin. These microorganisms likely contributed to the uptake and fixation of CO 2 in this geothermal habitat.The upper temperature limit for primary production via photosynthesis is ϳ73°C (7,8,11). At this temperature, photosynthesis is restricted to cyanobacteria of the genus Synechococcus, which generally inhabit alkaline environments (11). In acidic environments (pH Ͻ 4.0), the upper temperature limit for photosynthetic-based primary production is ϳ56°C. Under these conditions, phototrophic activity is restricted to the unicellular eukaryotic red algae Cyanidium, Galdieria, and Cyanidioschyzon, collectively referred to as "cyanidia" (6, 12, 31, 48). Primary production above this temperature in acidic environments occurs through chemoautotrophy, a metabolism restricted to prokaryotes.Yellowstone National Park (YNP), WY, possesses numerous high-temperature (73 to 93°C) geothermal environments that are thought to support communities of microorganisms through chemoautotrophic-based primary production. Evidence for chemosynthesis in these environments is based on the recovery of 16S rRNA gene sequences that are affiliated with cultivated representatives of the phyla Aquificae and Crenarchaeota, many of which are capable of CO 2 fixation via the oxidation of hydrogen (H 2 ) and/or sulfide (HS Ϫ ) (15,17,21,24,26,28,41,46). Surprisingly, CO 2 fixation has yet to be demonstrated in situ in YNP hot spring environments (acidic or alkaline) where temperatures exceed the limits of photosynthesis and where primary production is thought to be driven by chemoautotrophic metabolism ...

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Dynamics of the Yellowstone hydrothermal system

2014

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The Yellowstone Plateau Volcanic Field is characterized by extensive seismicity, episodes of uplift and subsidence, and a hydrothermal system that comprises more than 10,000 thermal features, including geysers, fumaroles, mud pots, thermal springs, and hydrothermal explosion craters. The diverse chemical and isotopic compositions of waters and gases derive from mantle, crustal, and meteoric sources and extensive water-gas-rock interaction at variable pressures and temperatures. The thermal features are host to all domains of life that utilize diverse inorganic sources of energy for metabolism. The unique and exceptional features of the hydrothermal system have attracted numerous researchers to Yellowstone beginning with the Washburn and Hayden expeditions in the 1870s. Since a seminal review published a quarter of a century ago, research in many fields has greatly advanced our understanding of the many coupled processes operating in and on the hydrothermal system. Specific advances include more refined geophysical images of the magmatic system, better constraints on the time scale of magmatic processes, characterization of fluid sources and water-rock interactions, quantitative estimates of heat and magmatic volatile fluxes, discovering and quantifying the role of thermophile microorganisms in the geochemical cycle, defining the chronology of hydrothermal explosions and their relation to glacial cycles, defining possible links between hydrothermal activity, deformation, and seismicity; quantifying geyser dynamics; and the discovery of extensive hydrothermal activity in Yellowstone Lake. Discussion of these many advances forms the basis of this review."This whole region was, in comparatively modern geologic times, the scene of the most wonderful volcanic activity of any portion of our country. The hot springs and the geysers represent the late stages-the vents or escape pipes-of these remarkable volcanic manifestations of the internal forces. All these springs are adorned with decorations more beautiful than human art ever conceived, and which have required thousands of years for the cunning hand of nature to form" [Hayden, 1883, p. 70]. Ferdinand V. Hayden led the 1871 geological survey of northwestern Wyoming, leading to the establishment of Yellowstone as the first U.S. National Park in 1872.

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Relative Importance of H ₂ and H ₂ S as Energy Sources for Primary Production in Geothermal Springs

Cited by 50 publications

References 41 publications

An oligarchic microbial assemblage in the anoxic bottom waters of a volcanic subglacial lake

An oligarchic microbial assemblage in the anoxic bottom waters of a volcanic subglacial lake

CO ₂ Uptake and Fixation by a Thermoacidophilic Microbial Community Attached to Precipitated Sulfur in a Geothermal Spring

Dynamics of the Yellowstone hydrothermal system

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Relative Importance of H 2 and H 2 S as Energy Sources for Primary Production in Geothermal Springs

Cited by 50 publications

References 41 publications

An oligarchic microbial assemblage in the anoxic bottom waters of a volcanic subglacial lake

An oligarchic microbial assemblage in the anoxic bottom waters of a volcanic subglacial lake

CO 2 Uptake and Fixation by a Thermoacidophilic Microbial Community Attached to Precipitated Sulfur in a Geothermal Spring

Dynamics of the Yellowstone hydrothermal system

Contact Info

Product

Resources

About

Relative Importance of H ₂ and H ₂ S as Energy Sources for Primary Production in Geothermal Springs

CO ₂ Uptake and Fixation by a Thermoacidophilic Microbial Community Attached to Precipitated Sulfur in a Geothermal Spring