Evidence for Geographic Isolation and Signs of Endemism within a Protistan Morphospecies

Boenigk, Jens; Pfandl, Karin; Garstecki, Tobias; Harms, Hauke; Novarino, Gianfranco; Chatzinotas, Antonis

doi:10.1128/aem.00601-06

Cited by 69 publications

(72 citation statements)

References 35 publications

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“…Although we acknowledge that our dataset represents only a crosssection of the biodiversity of east Antarctic lakes, both eukaryotic and cyanobacterial communities are structured by geographical factors, after environmental variables are factored out. This, together with the relatively high amount of cyanobacterial sequences that have no relatives from non-Antarctic environments in GenBank, and the presence of Antarctic endemics in at least 3 other taxonomic groups, namely diatoms , flagellates (Boenigk et al 2006) and green algae (De Wever et al 2009), appears to contradict previous claims that for microorganisms "everything is everywhere" (Baas Becking 1934). Our results thus suggest that Antarctic microbial communities are probably structured by the same processes as those occurring in macroorganisms, as has been observed in studies of global diatom communities (Vyverman et al 2007).…”

Section: Discussionmentioning

confidence: 69%

“…This is likely due to the fact that the SSU rDNA is insufficient to discriminate to the species level because of its low taxonomic resolution. In fact, previous studies reported a relatively high number of endemics belonging to a variety of eukaryotic taxonomic groups (Barnes et al 2006, Gibson et al 2006b), such as diatoms , Esposito et al 2006, nematodes (Bamforth et al 2005), ciliates (Petz et al 2007), mites and springtails (Convey & Stevens 2007), flagellates (Boenigk et al 2006) and recently also green algae (De Wever et al 2009). …”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Structuring effects of climate-related environmental factors on Antarctic microbial mat communities

Verleyen

Sabbe²,

Hodgson³

et al. 2010

Aquat. Microb. Ecol.

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Both ground-based and satellite data show that parts of Antarctica have entered a period of rapid climate change, which already affects the functioning and productivity of limnetic ecosystems. To predict the consequences of future climate anomalies for lacustrine microbial communities, we not only need better baseline information on their biodiversity but also on the climaterelated environmental factors structuring these communities. Here we applied denaturing gradient gel electrophoresis (DGGE) of the small subunit ribosomal DNA (SSU rDNA) to assess the genetic composition and distribution of Cyanobacteria and eukaryotes in 37 benthic microbial mat samples from east Antarctic lakes. The lakes were selected to span a wide range of environmental gradients governed by differences in lake morphology and chemical limnology across 5 ice-free oases. Sequence analysis of selected DGGE bands revealed a high degree of potential endemism among the Cyanobacteria (mainly represented by Oscillatoriales and Nostocales), and the presence of a variety of protists (alveolates, stramenopiles and green algae), fungi, tardigrades and nematodes, which corroborates previous microscopy-based observations. Variation partitioning analyses revealed that the microbial mat community structure is largely regulated by both geographical and local environmental factors of which salinity (and related variables), lake water depth and nutrient concentrations are of major importance. These 3 groups of environmental variables have previously been shown to change drastically in Antarctica in response to climate change. Together, these results have obvious consequences for predicting the trajectory of biodiversity under changing climate conditions and call for the continued assessment of the biodiversity of these unique ecosystems.KEY WORDS: Antarctica · Climate change · Lake · Microbial mats · DGGE Resale or republication not permitted without written consent of the publisherAquat Microb Ecol 59: [11][12][13][14][15][16][17][18][19][20][21][22][23][24] 2010 showing a rapid net cooling trend, such as the McMurdo Dry Valleys, where temperatures dropped by 0.7°C per decade between 1986 and 2000 (Doran et al. 2002). In east Antarctica, many regions are similarly experiencing marked changes in their weather, including increased wind speeds (Gillett & Thompson 2003) and changing patterns of snow and ice accumulation .The recent temperature and climate anomalies have also had impacts on both terrestrial and marine ecosystems in the Antarctic (Walther et al. 2002). Experiments measuring the ecological changes occurring at inland nunataks, dry valleys and coastal ice-free areas, have likened these ecosystems to 'canaries in a coalmine' and 'natural experiments' with which to identify biological responses to changing climate variables that are applicable on a wider (global) scale (see Convey 2001, Robinson et al. 2003, Lyons et al. 2006 for reviews). Already lacustrine ecosystems in some icefree regions have been shown to respond quickly to air t...

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Section: Discussionmentioning

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Structuring effects of climate-related environmental factors on Antarctic microbial mat communities

Verleyen

Sabbe²,

Hodgson³

et al. 2010

Aquat. Microb. Ecol.

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“…The debate over the degree to which protist communities exhibit global distribution has not been fully resolved (Foissner, 1999(Foissner, , 2006Lawley et al, 2004;Boenigk et al, 2006;Bass et al, 2007;Caron, 2009). We would like to emphasize that all existing knowledge of microbial diversity comes from samples, and, strictly speaking, is limited to the collection of samples analyzed so far-rather than environments from which they were obtained.…”

Section: Total Protistan Richness In the Cariaco Basinmentioning

confidence: 99%

Protistan microbial observatory in the Cariaco Basin, Caribbean. I. Pyrosequencing vs Sanger insights into species richness

et al. 2011

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Microbial diversity and distribution are topics of intensive research. In two companion papers in this issue, we describe the results of the Cariaco Microbial Observatory (Caribbean Sea, Venezuela). The Basin contains the largest body of marine anoxic water, and presents an opportunity to study protistan communities across biogeochemical gradients. In the first paper, we survey 18S ribosomal RNA (rRNA) gene sequence diversity using both Sanger-and pyrosequencing-based approaches, employing multiple PCR primers, and state-of-the-art statistical analyses to estimate microbial richness missed by the survey. Sampling the Basin at three stations, in two seasons, and at four depths with distinct biogeochemical regimes, we obtained the largest, and arguably the least biased collection of over 6000 nearly full-length protistan rRNA gene sequences from a given oceanographic regime to date, and over 80 000 pyrosequencing tags. These represent all major and many minor protistan taxa, at frequencies globally similar between the two sequence collections. This large data set provided, via the recently developed parametric modeling, the first statistically sound prediction of the total size of protistan richness in a large and varied environment, such as the Cariaco Basin: over 36 000 species, defined as almost full-length 18S rRNA gene sequence clusters sharing over 99% sequence homology. This richness is a small fraction of the grand total of known protists (over 100 000-500 000 species), suggesting a degree of protistan endemism.

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“…Geographic isolation may also be responsible for the diversification of eukaryotic groups during the Cryogenian. Several recent studies have documented evidence of geographic isolation and divergence in modern protist groups (Boenigk et al 2006;Foissner et al 2007;Casteleyn et al 2010), suggesting that protists in modern ecosystems are not cosmopolitan. As such, global glaciation may have potentially stimulated diversification, while keeping overall abundance low.…”

Section: Diversity Patterns In Relation To Tectonic and Geochemical Fmentioning

confidence: 99%

The Proterozoic Record of Eukaryotes

2015

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Abstract.-Proterozoic strata host evidence of global "Snowball Earth" glaciations, large perturbations to the carbon cycle, proposed changes in the redox state of oceans, the diversification of microscopic eukaryotes, and the rise of metazoans. Over the past half century, the number of fossils described from Proterozoic rocks has increased exponentially. These discoveries have occurred alongside an increased understanding of the Proterozoic Earth system and the geological context of fossil occurrences, including improved age constraints. However, the evaluation of relationships between Proterozoic environmental change and fossil diversity has been hampered by several factors, particularly lithological and taphonomic biases. Here we compile and analyze the current record of eukaryotic fossils in Proterozoic strata to assess the effect of biases and better constrain diversity through time. Our results show that mean within assemblage diversity increases through the Proterozoic Eon due to an increase in high diversity assemblages, and that this trend is robust to various external factors including lithology and paleogeographic location. In addition, assemblage composition changes dramatically through time. Most notably, robust recalcitrant taxa appear in the early Neoproterozoic Era, only to disappear by the beginning of the Ediacaran Period. Within assemblage diversity is significantly lower in the Cryogenian Period than in the preceding and following intervals, but the short duration of the nonglacial interlude and unusual depositional conditions may present additional biases. In general, large scale patterns of diversity are robust while smaller scale patterns are difficult to discern through the lens of lithological, taphonomic, and geographic variability.

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Evidence for Geographic Isolation and Signs of Endemism within a Protistan Morphospecies

Cited by 69 publications

References 35 publications

Structuring effects of climate-related environmental factors on Antarctic microbial mat communities

Structuring effects of climate-related environmental factors on Antarctic microbial mat communities

Protistan microbial observatory in the Cariaco Basin, Caribbean. I. Pyrosequencing vs Sanger insights into species richness

The Proterozoic Record of Eukaryotes

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