Geographic and Environmental Sources of Variation in Lake Bacterial Community Composition

Yannarell, Anthony C.; Triplett, Eric W.

doi:10.1128/aem.71.1.227-239.2005

Cited by 332 publications

(289 citation statements)

References 81 publications

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“…The influence of both factors at intermediate scales was already shown by other studies (Green et al, 2004;Reche et al, 2005;Yannarell and Triplett, 2005), but our study suggest an effect of both factors for large scales as well, as shown for soil microbial communities (Fierer and Jackson, 2006). Although the small size, high dispersal rates, large population size and low extinction rates of microorganisms suggest a low effect of geographic barriers on microorganisms (Staley and Gosink, 1999;Beja et al, 2002;Finlay, 2002;Ramette and Tiedje, 2007), our study shows that the distribution of microorganisms in deep-sea sediments is limited at intermediate (10-3000 km) and large scales (43000 km).…”

Section: Diversity and Biogeography In Deep-sea Sediments R Schauer Esupporting

confidence: 51%

Bacterial diversity and biogeography in deep-sea surface sediments of the South Atlantic Ocean

et al. 2009

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Microbial biogeographic patterns in the deep sea depend on the ability of microorganisms to disperse. One possible limitation to microbial dispersal may be the Walvis Ridge that separates the Antarctic Lower Circumpolar Deep Water from the North Atlantic Deep Water. We examined bacterial communities in three basins of the eastern South Atlantic Ocean to determine diversity and biogeography of bacterial communities in deep-sea surface sediments. The analysis of 16S ribosomal RNA (rRNA) gene clone libraries in each basin revealed a high diversity, representing 521 phylotypes with 98% identity in 1051 sequences. Phylotypes affiliated with Gammaproteobacteria, Deltaproteobacteria and Acidobacteria were present in all three basins. The distribution of these shared phylotypes seemed to be influenced neither by the Walvis Ridge nor by different deep water masses, suggesting a high dispersal capability, as also indicated by low distance–decay relationships. However, the total bacterial diversity showed significant differences between the basins, based on 16S rRNA gene sequences as well as on terminal restriction fragment length polymorphism fingerprints. Noticeably, both geographic distance and environmental heterogeneity influenced bacterial diversity at intermediate (10–3000 km) and large scales (>3000 km), indicating a complex interplay of local contemporary environmental effects and dispersal limitation.

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Section: Diversity and Biogeography In Deep-sea Sediments R Schauer Esupporting

confidence: 51%

Bacterial diversity and biogeography in deep-sea surface sediments of the South Atlantic Ocean

et al. 2009

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“…Approximately 0.1% of the microbiome sequences had significant similarity (Eo0.001) to 16S rDNA genes in the Ribosomal Database Project (Cole et al, 2007). On the basis of these similarities, the microbial communities in the freshwater ponds exhibited typical freshwater bacterial groups as previously seen in other 16S rDNA surveys of freshwater environments (Arias et al, 2004;Lindstrom et al, 2005;Yannarell and Triplett, 2005;Briee et al, 2007). Corresponding analyses of microbiomes from the solar salterns showed the expected shift to an Archaea-dominated community in the high salinity pond (RodriguezValera et al, 1985;Benlloch et al, 2002).…”

Section: Resultsmentioning

confidence: 59%

Viral and microbial community dynamics in four aquatic environments

et al. 2010

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The species composition and metabolic potential of microbial and viral communities are predictable and stable for most ecosystems. This apparent stability contradicts theoretical models as well as the viral-microbial dynamics observed in simple ecosystems, both of which show Kill-the-Winner behavior causing cycling of the dominant taxa. Microbial and viral metagenomes were obtained from four human-controlled aquatic environments at various time points separated by one day to 41 year. These environments were maintained within narrow geochemical bounds and had characteristic species composition and metabolic potentials at all time points. However, underlying this stability were rapid changes at the fine-grained level of viral genotypes and microbial strains. These results suggest a model wherein functionally redundant microbial and viral taxa are cycling at the level of viral genotypes and virus-sensitive microbial strains. Microbial taxa, viral taxa, and metabolic function persist over time in stable ecosystems and both communities fluctuate in a Kill-the-Winner manner at the level of viral genotypes and microbial strains.

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“…Ramette (2007) suggested that these tools can also be readily applied in microbial ecology to help reduce data set complexity as DNA sequence data are increasingly available because of high-throughput sequencing technologies. Indeed, microbial ecology studies have increasingly used multivariate analyses to relate environmental variation with bacterial composition in aquatic systems (Yannarell and Triplett, 2005;Kent et al, 2007;Rubin and Leff, 2007), to determine bacterial community dynamics in relation to temporal variation in marine ecosystems (Pringault et al, 2007;Sapp et al, 2007), to develop microbial communities as indicators of ecosystem stress Córdova-Kreylos et al, 2006;Fields et al, 2006), as well as to link geophysical signatures to microbial communities (Allen et al, 2007).…”

Section: Engineering Controlsmentioning

confidence: 99%

Bacterial community succession during in situ uranium bioremediation: spatial similarities along controlled flow paths

Hwang

Gentry

et al. 2008

The ISME Journal

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Bacterial community succession was investigated in a field-scale subsurface reactor formed by a series of wells that received weekly ethanol additions to re-circulating groundwater. Ethanol additions stimulated denitrification, metal reduction, sulfate reduction and U(VI) reduction to sparingly soluble U(IV). Clone libraries of SSU rRNA gene sequences from groundwater samples enabled tracking of spatial and temporal changes over a 1.5-year period. Analyses showed that the communities changed in a manner consistent with geochemical variations that occurred along temporal and spatial scales. Canonical correspondence analysis revealed that the levels of nitrate, uranium, sulfide, sulfate and ethanol were strongly correlated with particular bacterial populations. As sulfate and U(VI) levels declined, sequences representative of sulfate reducers and metal reducers were detected at high levels. Ultimately, sequences associated with sulfate-reducing populations predominated, and sulfate levels declined as U(VI) remained at low levels. When engineering controls were compared with the population variation through canonical ordination, changes could be related to dissolved oxygen control and ethanol addition. The data also indicated that the indigenous populations responded differently to stimulation for bioreduction; however, the two biostimulated communities became more similar after different transitions in an idiosyncratic manner. The strong associations between particular environmental variables and certain populations provide insight into the establishment of practical and successful remediation strategies in radionuclidecontaminated environments with respect to engineering controls and microbial ecology.

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Geographic and Environmental Sources of Variation in Lake Bacterial Community Composition

Cited by 332 publications

References 81 publications

Bacterial diversity and biogeography in deep-sea surface sediments of the South Atlantic Ocean

Bacterial diversity and biogeography in deep-sea surface sediments of the South Atlantic Ocean

Viral and microbial community dynamics in four aquatic environments

Bacterial community succession during in situ uranium bioremediation: spatial similarities along controlled flow paths

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