HYPERSALINE SOIL SUPPORTS A DIVERSE COMMUNITY OF DUNALIELLA (CHLOROPHYCEAE)

Numerous isolates of the green halophile Dunaliella were studied as part of a survey of microbial diversity at the Great Salt Plains (GSP) in Oklahoma, USA. The GSP is a large (~65 km²) salt flat with extreme temporal and spatial fluctuations in salinity and temperature. Although the flagellate halo...

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Veröffentlicht in:Journal of phycology 2010-10, Vol.46 (5), p.1038-1047
Hauptverfasser: Buchheim, Mark A, Kirkwood, Andrea E, Buchheim, Julie A, Verghese, Bindhu, Henley, William J
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Sprache:eng
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Zusammenfassung:Numerous isolates of the green halophile Dunaliella were studied as part of a survey of microbial diversity at the Great Salt Plains (GSP) in Oklahoma, USA. The GSP is a large (~65 km²) salt flat with extreme temporal and spatial fluctuations in salinity and temperature. Although the flagellate halophile Dunaliella is common worldwide, nearly all cultured isolates are from saline habitats that are primarily aquatic rather than primarily terrestrial. The diverse GSP Dunaliella strains exhibit three morphotypes: a predominantly motile form, a motile form with a prominent palmelloid phase (nonmotile, mucilage rich), and a palmelloid form with a weakly motile phase. All had broad salinity optima well below typical in situ salinities at the GSP, and two of the palmelloid isolates grew as well in freshwater as in highly saline media. Molecular phylogenetic and evolutionary analyses revealed that Dunaliella from the GSP (and two similar habitats in the Great Basin, USA) are allied with D. viridis Teodor. but possess phylogenetic diversity in excess of existing global isolates from aquatic habitats. In addition, isolates from primarily terrestrial habitats exhibit statistically higher rates of nucleotide substitution than the phylogenetically homogeneous set of primarily aquatic Dunaliella taxa. We hypothesize that dynamically extreme saline soil habitats may select for different and more diverse Dunaliella lineages than more stable saline aquatic habitats. We also propose Dunaliella as a tractable microbial model for in situ testing of evolutionary and phylogeographic hypotheses.
ISSN:0022-3646
1529-8817
DOI:10.1111/j.1529-8817.2010.00886.x