TY - JOUR
T1 - Seasonal fluctuations in ionic concentrations drive microbial succession in a hypersaline lake community
AU - Podell, Sheila
AU - Emerson, Joanne B.
AU - Jones, Claudia M.
AU - Ugalde, Juan A.
AU - Welch, Sue
AU - Heidelberg, Karla B.
AU - Banfield, Jillian F.
AU - Allen, Eric E.
N1 - Funding Information:
We thank Dawn Cardace and Jochen Brocks for sample collection assistance at Lake Tyrrell; Mike Dyall-Smith for generous access to reagents and laboratory equipment; Cheetham Salt Works (Lake Tyrrell, Australia) for permission to collect samples; Matt Lewis and the J Craig Venter Institute for library construction and sequencing; and the US Department of Energy Joint Genomes Institute for genome annotation support via the Integrated Microbial Genome Expert Review (IMG-ER) resource. Funding for this work was provided by NSF award number 0626526 (JFB, KBH and EEA). JAU was supported by a Fulbright– Conicyt fellowship.
PY - 2014/5
Y1 - 2014/5
N2 - Microbial community succession was examined over a two-year period using spatially and temporally coordinated water chemistry measurements, metagenomic sequencing, phylogenetic binning and de novo metagenomic assembly in the extreme hypersaline habitat of Lake Tyrrell, Victoria, Australia. Relative abundances of Haloquadratum-related sequences were positively correlated with co-varying concentrations of potassium, magnesium and sulfate, but not sodium, chloride or calcium ions, while relative abundances of Halorubrum, Haloarcula, Halonotius, Halobaculum and Salinibacter-related sequences correlated negatively with Haloquadratum and these same ionic factors. Nanohaloarchaea and Halorhabdus-related sequence abundances were inversely correlated with each other, but not other taxonomic groups. These data, along with predicted gene functions from nearly-complete assembled population metagenomes, suggest different ecological phenotypes for Nanohaloarchaea and Halorhabdus-related strains versus other community members. Nucleotide percent G+C compositions were consistently lower in community metagenomic reads from summer versus winter samples. The same seasonal G+C trends were observed within taxonomically binned read subsets from each of seven different genus-level archaeal groups. Relative seasonal abundances were also linked to percent G+C for assembled population genomes. Together, these data suggest that extreme ionic conditions may exert selective pressure on archaeal populations at the level of genomic nucleotide composition, thus contributing to seasonal successional processes. Despite the unavailability of cultured representatives for most of the organisms identified in this study, effective coordination of physical and biological measurements has enabled discovery and quantification of unexpected taxon-specific, environmentally mediated factors influencing microbial community structure.
AB - Microbial community succession was examined over a two-year period using spatially and temporally coordinated water chemistry measurements, metagenomic sequencing, phylogenetic binning and de novo metagenomic assembly in the extreme hypersaline habitat of Lake Tyrrell, Victoria, Australia. Relative abundances of Haloquadratum-related sequences were positively correlated with co-varying concentrations of potassium, magnesium and sulfate, but not sodium, chloride or calcium ions, while relative abundances of Halorubrum, Haloarcula, Halonotius, Halobaculum and Salinibacter-related sequences correlated negatively with Haloquadratum and these same ionic factors. Nanohaloarchaea and Halorhabdus-related sequence abundances were inversely correlated with each other, but not other taxonomic groups. These data, along with predicted gene functions from nearly-complete assembled population metagenomes, suggest different ecological phenotypes for Nanohaloarchaea and Halorhabdus-related strains versus other community members. Nucleotide percent G+C compositions were consistently lower in community metagenomic reads from summer versus winter samples. The same seasonal G+C trends were observed within taxonomically binned read subsets from each of seven different genus-level archaeal groups. Relative seasonal abundances were also linked to percent G+C for assembled population genomes. Together, these data suggest that extreme ionic conditions may exert selective pressure on archaeal populations at the level of genomic nucleotide composition, thus contributing to seasonal successional processes. Despite the unavailability of cultured representatives for most of the organisms identified in this study, effective coordination of physical and biological measurements has enabled discovery and quantification of unexpected taxon-specific, environmentally mediated factors influencing microbial community structure.
KW - archaea
KW - halophile
KW - hypersaline
KW - metagenome
KW - microbial succession
UR - http://www.scopus.com/inward/record.url?scp=84899487999&partnerID=8YFLogxK
U2 - 10.1038/ismej.2013.221
DO - 10.1038/ismej.2013.221
M3 - Article
C2 - 24335829
AN - SCOPUS:84899487999
SN - 1751-7362
VL - 8
SP - 979
EP - 990
JO - ISME Journal
JF - ISME Journal
IS - 5
ER -