CYANIDIA (CYANIDIALES) POPULATION DIVERSITY AND DYNAMICS IN AN ACID‐SULFATE‐CHLORIDE SPRING IN YELLOWSTONE NATIONAL PARK<sup>1</sup>

Lehr, Corinne R.; Frank, Shaun D.; Norris, Tracy B.; D’Imperio, Seth; Калинин, А. В.; Toplin, J. A.; Castenholz, Richard W.; McDermott, Timothy R.

doi:10.1111/j.1529-8817.2006.00293.x

Cited by 28 publications

(51 citation statements)

References 48 publications

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“…or C. merolae in this one endolithic sample. In contrast, we did not detect any C. caldarium phylotypes through extensive culturing attempts from collections in YNP, Japan, and New Zealand, nor has C. caldarium been detected in 18S rDNA molecular surveys of Dragon Spring in Norris Geyser Basin (17) or in Nymph Creek (10), both in YNP. The paper by Walker et al (36) claims to have identified a cyanidial sequence closest to C. caldarium from an endolithic sample in the Norris Geyser Basin, but we believe this claim is in error (unpublished data).…”

Section: Discussioncontrasting

confidence: 81%

“…In other work, we further checked the possibility that Galdieria morphotypes were contaminated with a few C. merolae type cells that might more readily rupture and release their DNA because of the lack of a cell wall, leading to the preferential amplification of their DNA. A culture of a Galdieria sulphuraria type II from YNP (CCMEE 5572), possessing a rigid cell wall, was mixed in various proportions with a "true" Cyanidioschyzon merolae morphotype (CCMEE 5610 4a Recently, we found that cpSSRs (or microsatellites) could be used to identify genetic differences among six cultured Galdieria-like type IA morphotypes that shared identical 18S rRNA gene sequences with C. merolae (17). Therefore, in the current study, we employed an approach similar to the above method to more closely examine these strains for evidence of genotypic variation.…”

Section: Figmentioning

confidence: 99%

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Biogeographic and Phylogenetic Diversity of Thermoacidophilic Cyanidiales in Yellowstone National Park, Japan, and New Zealand

Toplin

Norris

Lehr

et al. 2008

Appl Environ Microbiol

114

117

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Members of the rhodophytan order Cyanidiales are unique among phototrophs in their ability to live in extreme environments that combine low pH levels (ϳ0.2 to 4.0) and moderately high temperatures of 40 to 56°C. These unicellular algae occur in far-flung volcanic areas throughout the earth. Three genera (Cyanidium, Galdieria, and Cyanidioschyzon) are recognized. The phylogenetic diversity of culture isolates of the Cyanidiales from habitats throughout Yellowstone National Park (YNP), three areas in Japan, and seven regions in New Zealand was examined by using the chloroplast RuBisCO large subunit gene (rbcL) and the 18S rRNA gene. Based on the nucleotide sequences of both genes, the YNP isolates fall into two groups, one with high identity to Galdieria sulphuraria (type II) and another that is by far the most common and extensively distributed Yellowstone type (type IA). The latter is a spherical, walled cell that reproduces by internal divisions, with a subsequent release of smaller daughter cells. This type, nevertheless, shows a 99 to 100% identity to Cyanidioschyzon merolae (type IB), which lacks a wall, divides by "fission"-like cytokinesis into two daughter cells, and has less than 5% of the cell volume of type IA. The evolutionary and taxonomic ramifications of this disparity are discussed. Although the 18S rRNA and rbcL genes did not reveal diversity among the numerous isolates of type IA, chloroplast short sequence repeats did show some variation by location within YNP. In contrast, Japanese and New Zealand strains showed considerable diversity when we examined only the sequences of 18S and rbcL genes. Most exhibited identities closer to Galdieria maxima than to other strains, but these identities were commonly as low as 91 to 93%. Some of these Japanese and New Zealand strains probably represent undescribed species that diverged after long-term geographic isolation.The Cyanidiales are an order of asexual, unicellular red algae that are able to grow in low-pH environments and at moderately high temperatures throughout the globe (4, 31, 32). These algae are not red, but blue-green, due to their predominant pigments, c-phycocyanin and chlorophyll a. Many members of this order are known to grow at temperatures as high as 56°C and at pH levels from 0.2 to 4.0. No other photosynthetic microorganisms are known to inhabit this combination of conditions, and these algae often form well-developed mats in acidic geothermal locations. Surprisingly though, little is known about the ecology, biodiversity, and geographical distribution of these organisms. In these acidic habitats, no prokaryotic phototrophs are known to exist below a pH level of ϳ4 and the number of species reaching levels below pH 5 is small (37).The order Cyanidiales consists of three recognized genera, Cyanidium, Galdieria, and Cyanidioschyzon (6, 13, 16), referred to colloquially as "cyanidia" in this work. The genera Cyanidium and Cyanidioschyzon are thought to include a single species each, Cyanidium caldarium and Cyanidioschyzon merolae, respe...

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Section: Discussioncontrasting

confidence: 81%

Section: Figmentioning

confidence: 99%

Biogeographic and Phylogenetic Diversity of Thermoacidophilic Cyanidiales in Yellowstone National Park, Japan, and New Zealand

Toplin

Norris

Lehr

et al. 2008

Appl Environ Microbiol

114

117

View full text Add to dashboard Cite

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“…Our results indicate that the distribution of hydA in YNP is non-random and is pH-dependent, suggesting a role for pH in the ecology and evolution of hydA in YNP. The pH-dependent distribution of hydA in YNP is similar to the distribution of phototrophs in YNP as evinced by the distribution of bchL/chlL genes where the upper temperature limit for oxygenic phototrophs in alkaline environments was observed to decrease from B70 1C in alkaline pH 9.0 systems to B48 1C in acidic pH 3.0 systems, a set of observations that are consistent with the qualitative trends noted in earlier studies (Cox and Shock, 2003;Spear et al, 2005;Lehr et al, 2007). The relationship between the presence of hydA and bchL/chlL could be explained, in part, by the temporal dynamics of phototrophic mat communities, which cycle from oxygen saturation during the day to anoxia at night (Revsbech and Ward, 1984).…”

Section: Discussionsupporting

confidence: 87%

[FeFe]-hydrogenase in Yellowstone National Park: evidence for dispersal limitation and phylogenetic niche conservatism

et al. 2010

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Hydrogen (H 2 ) has an important role in the anaerobic degradation of organic carbon and is the basis for many syntrophic interactions that commonly occur in microbial communities. Little is known, however, with regard to the biotic and/or abiotic factors that control the distribution and phylogenetic diversity of organisms which produce H 2 in microbial communities. In this study, we examined the [FeFe]-hydrogenase gene (hydA) as a proxy for fermentative bacterial H 2 production along physical and chemical gradients in various geothermal springs in Yellowstone National Park (YNP), WY, USA. The distribution of hydA in YNP geothermal springs was constrained by pH to environments co-inhabited by oxygenic phototrophs and to environments predicted to have low inputs of abiotic H 2 . The individual HydA asssemblages from YNP springs were more closely related when compared with randomly assembled communities, which suggests ecological filtering. Model selection approaches revealed that geographic distance was the best explanatory variable to predict the phylogenetic relatedness of HydA communities. This evinces the dispersal limitation imposed by the geothermal spring environment on HydA phylogenetic diversity even at small spatial scales. pH differences between sites is the second highest ranked explanatory variable of HydA phylogenetic relatedness, which suggests that the ecology related to pH imposes strong phylogenetic niche conservatism. Collectively, these results indicate that pH has imposed strong niche conservatism on fermentative bacteria and that, within a narrow pH realm, YNP springs are dispersal limited with respect to fermentative bacterial communities.

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“…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.…”

Section: ؊1mentioning

confidence: 99%

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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CYANIDIA (CYANIDIALES) POPULATION DIVERSITY AND DYNAMICS IN AN ACID‐SULFATE‐CHLORIDE SPRING IN YELLOWSTONE NATIONAL PARK¹

Cited by 28 publications

References 48 publications

Biogeographic and Phylogenetic Diversity of Thermoacidophilic Cyanidiales in Yellowstone National Park, Japan, and New Zealand

Biogeographic and Phylogenetic Diversity of Thermoacidophilic Cyanidiales in Yellowstone National Park, Japan, and New Zealand

[FeFe]-hydrogenase in Yellowstone National Park: evidence for dispersal limitation and phylogenetic niche conservatism

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

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CYANIDIA (CYANIDIALES) POPULATION DIVERSITY AND DYNAMICS IN AN ACID‐SULFATE‐CHLORIDE SPRING IN YELLOWSTONE NATIONAL PARK1

Cited by 28 publications

References 48 publications

Biogeographic and Phylogenetic Diversity of Thermoacidophilic Cyanidiales in Yellowstone National Park, Japan, and New Zealand

Biogeographic and Phylogenetic Diversity of Thermoacidophilic Cyanidiales in Yellowstone National Park, Japan, and New Zealand

[FeFe]-hydrogenase in Yellowstone National Park: evidence for dispersal limitation and phylogenetic niche conservatism

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

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Resources

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CYANIDIA (CYANIDIALES) POPULATION DIVERSITY AND DYNAMICS IN AN ACID‐SULFATE‐CHLORIDE SPRING IN YELLOWSTONE NATIONAL PARK¹

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