Soils associated to different tree communities do not elicit predictable responses in lake bacterial community structure and function

Freshwater bacterioplankton communities are influenced by the inputs of material and bacteria from the surrounding landscape, yet few studies have investigated how different terrestrial inputs affect bacterioplankton. We examined whether the addition of soils collected under various tree species com...

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Bibliographic Details
Published in:FEMS microbiology ecology 2018-08, Vol.94 (8), p.1
Main Authors: Ruiz-González, Clara, Archambault, Esther, Laforest-Lapointe, Isabelle, Del Giorgio, Paul A, Kembel, Steven W, Messier, Christian, Nock, Charles A, Beisner, Beatrix E
Format: Article
Language:English
Subjects:
Aquatic communities
Aquatic Organisms - classification
Aquatic Organisms - genetics
Aquatic Organisms - isolation & purification
Bacteria
Bacterioplankton
Bacteroidetes - classification
Bacteroidetes - genetics
Bacteroidetes - isolation & purification
Burkholderiales - classification
Burkholderiales - genetics
Burkholderiales - isolation & purification
Community structure
Composition
Ecology
Environmental aspects
Forest soils
Forests
Gene sequencing
Inoculum
Lakes
Lakes - microbiology
Metabolism
Microbial colonies
Microbiology
Plankton - microbiology
Plant species
Rhizobiaceae - classification
Rhizobiaceae - genetics
Rhizobiaceae - isolation & purification
RNA, Ribosomal, 16S - genetics
rRNA 16S
Soil - chemistry
Soil bacteria
Soil Microbiology
Soil microorganisms
Soil water
Soils
Structure-function relationships
Substrates
Taxa
Trees
Trees - genetics
Trees - microbiology
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Summary:Freshwater bacterioplankton communities are influenced by the inputs of material and bacteria from the surrounding landscape, yet few studies have investigated how different terrestrial inputs affect bacterioplankton. We examined whether the addition of soils collected under various tree species combinations differentially influences lake bacterial communities. Lake water was incubated for 6 days following addition of five different soils. We assessed the taxonomic composition (16S rRNA gene sequencing) and metabolic activity (Biolog Ecoplates) of lake bacteria with and without soil addition, and compared these to initial soil communities. Soil bacterial assemblages showed a strong influence of tree composition, but such community differences were not reflected in the structure of lake communities that developed during the experiment. Bacterial taxa showing the largest abundance increases during incubation were initially present in both lake water and across most soils, and were related to Cytophagales, Burkholderiales and Rhizobiales. No clear metabolic profiles based on inoculum source were found, yet soil-amended communities used 60% more substrate than non-inoculated communities. Overall, we show that terrestrial inputs influence aquatic communities by stimulating the growth and activity of certain ubiquitous taxa distributed across the terrestrial-aquatic continuum, yet different forest soils did not cause predictable changes in lake bacterioplankton assemblages.
ISSN:1574-6941
0168-6496
1574-6941
DOI:10.1093/femsec/fiy115