Spatiotemporal patterns of microbial composition and diversity in precipitation

Spatiotemporal patterns of microbial composition and diversity in precipitation

Microbes in the atmosphere have broad ecological impacts, including the potential to trigger precipitation through species and strains that act as ice nucleation particles. To characterize spatiotemporal trends of microbial assemblages in precipitation we sequenced 16S (bacterial) and 18S (fungal) r...

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Bibliographic Details
Published in:Ecological monographs Vol. 90; no. 1; pp. 1 - 26
Main Authors: Aho, Ken A., Weber, Carolyn F., Christner, Brent C., Vinatzer, Boris A., Morris, Cindy E., Joyce, Rachel, Failor, Kevin C., Werth, Jason T., Bayless-Edwards, Aurora L. H., Schmale, David G.
Format: Journal Article
Language:English
Published: Durham John Wiley and Sons, Inc 01-02-2020
Ecological Society of America
Subjects:
atmosphere
Bacteria
Bioaerosols
Biodiversity and Ecology
biogeography
bioprecipitation
community ecology
Composition
Dispersal
Environmental Sciences
Fungi
Global Changes
Heterogeneity
Ice
Ice nucleation
metabarcoding
metacommunity
meteorology
microbial ecology
Microorganisms
Nucleation
Precipitation
Rainfall
rRNA 18S
Statistical analysis
Statistical methods
Storms
Taxa
Taxonomy
Trends
Wet deposition
atmosphere
precipitation
metabarcoding
biogeography
meteorology
community ecology
bioprecipitation
microbial ecology
metacommunity
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Summary:Microbes in the atmosphere have broad ecological impacts, including the potential to trigger precipitation through species and strains that act as ice nucleation particles. To characterize spatiotemporal trends of microbial assemblages in precipitation we sequenced 16S (bacterial) and 18S (fungal) rRNA gene amplicon libraries collected from 72 precipitation events in three U.S. states (Idaho, Louisiana, and Virginia) over four seasons. We considered these data from the perspective of a novel metacommunity framework. In agreement with our heuristic, we found evidence for distinct mechanisms underlying the composition and diversity of bacterial and fungal assemblages in precipitation. Specifically, we determined that (1) bacterial operational taxonomic unit (OTU) composition of precipitation was strongly associated with macroscale drivers including season and high-altitude characteristics of storms; (2) fungal OTU composition was strongly correlated with mesoscale drivers including particular spatial locations; (3) β-diversity (heterogeneity of taxa among samples) for both bacteria and fungi was largely maintained by turnover of taxa; however, (4) bacterial assemblages had higher contributions to total β-diversity from nestedness (i.e., lower richness assemblages were largely taxonomic subsets of richer assemblages), due to losses of taxa during dispersal, particularly among potential ice nucleation active bacteria; and (5) fungal assemblages had higher contributions to total β-diversity from turnover due to OTU replacement. Spatiotemporal trends in precipitation-borne metacommunities allowed delineation of a large number of statistically significant indicator taxa for particular sites and seasons, including trends for bacteria that are potentially ice nucleation active. Our findings advance understanding regarding the dispersion of aerosolized microbes via wet deposition, and the development of theory concerning potential assembly rules for bioaerosol assemblages.
ISSN:0012-9615
1557-7015
DOI:10.1002/ecm.1394