Community composition and seasonal changes of archaea in coarse and fine air particulate matter

Wehking, Jörn; Pickersgill, Daniel A.; Bowers, Robert M.; Teschner, David; Pöschl, Ulrich; Fröhlich-Nowoisky, Janine; Després, Viviane R.

doi:10.5194/bg-15-4205-2018

Cited by 16 publications

(9 citation statements)

References 58 publications

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“…Although the miniLEO system overall does not appear to be conducive for either of these environments (low pH and anaerobic conditions), the gradual increase in Thermoplasmata (from 2.6% in the surficial sample to 11.9% in Depth_70 samples) is suggestive of pockets of microenvironments for such metabolisms to thrive and/or likelihood of organisms with novel metabolic strategies. Additionally, the absence of Euryarcheota in the parent material and irrigation water suggests that air is most likely the source, as highlighted in a recent study (Wehking et al, ), which shows Euryarcheota as a dominant airborne archaea in the fine particulate matter. Overall, our study revealed a highly diverse bacterial population and comparatively less diverse archaeal population in the incipient terrestrial basalt soil system subjected to enhanced weathering processes.…”

Section: Discussionmentioning

confidence: 91%

Assessing Microbial Community Patterns During Incipient Soil Formation From Basalt

et al. 2019

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Microbial dynamics drive the biotic machinery of early soil evolution. However, integrated knowledge of microbial community establishment, functional associations, and community assembly processes in incipient soil is lacking. This study presents a novel approach of combining microbial phylogenetic profiling, functional predictions, and community assembly processes to analyze drivers of microbial community establishment in an emerging soil system. Rigorous submeter sampling of a basalt-soil lysimeter after 2 years of irrigation revealed that microbial community colonization patterns and associated soil parameters were depth dependent. Phylogenetic analysis of 16S rRNA gene sequences indicated the presence of diverse bacterial and archaeal phyla, with high relative abundance of Actinomyceles on the surface and a consistently high abundance of Proteobacteria (Alpha, Beta, Gamma, and Delta) at all depths. Despite depth-dependent variation in community diversity, predicted functional gene analysis suggested that microbial metabolisms did not differ with depth, thereby suggesting redundancy in functional potential throughout the system. Null modeling revealed that microbial community assembly patterns were predominantly governed by variable selection. The relative influence of variable selection decreased with depth, indicating unique and relatively harsh environmental conditions near the surface and more benign conditions with depth. Additionally, community composition near the center of the domain was influenced by high levels of dispersal, suggesting that spatial processes interact with deterministic selection imposed by the environment. These results suggest that for oligotrophic systems, there are major differences in the length scales of variation between vertical and horizontal dimensions with the vertical dimension dominating variation in physical, chemical, and biological features.Citation:

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Section: Discussionmentioning

confidence: 91%

Assessing Microbial Community Patterns During Incipient Soil Formation From Basalt

et al. 2019

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“…At the phylum level, the archaea Crenarchaeota was sharply lower (<1%) in the phyllosphere but higher in both air and soil samples, which concurred with the previous study ( Vorholt, 2012 ). The shared of Crenarchaeota within air, phyllosphere, and soil suggested that soil may be a possible source of archaea affecting adjacent air ( Wehking et al, 2018 ). Previous studies have found that the bacterial families of Rhizobiaceae and Pseudomonadaceae are commonly observed in plants, which would help create differences in composition of the phyllosphere, air, and soil samples ( Yanni et al, 1997 ; Hunter et al, 2010 ).…”

Section: Discussionmentioning

confidence: 99%

Microbial Flow Within an Air-Phyllosphere-Soil Continuum

Zhou

Giles

et al. 2021

Front. Microbiol.

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The phyllosphere is populated by numerous microorganisms. Microbes from the wider environment, i.e., air and soil, are considered key contributors to phyllosphere microbial communities, but their contribution is unclear. This study seeks to address this knowledge gap by controlling the movement of microbes along the air-phyllosphere-soil continuum. Customized equipment with dual chambers was constructed that permitted airflow to enter the first chamber while the second chamber recruited filtered microbe-free air from the initial chamber. Allium schoenoprasum (chive) and Sonchus oleraceus (sow thistle) were cultivated in both chambers, and the microbial communities from air, phyllosphere, and soil samples were characterized. Shares of microbial OTUs in the equipment suggested a potential interconnection between the air, phyllosphere, and soil system. Fast expectation-maximization microbial source tracking (FEAST) suggested that soil was the major source of airborne microbial communities. In contrast, the contribution of airborne and soil microbes to phyllosphere microbial communities of either A. schoenoprasum or S. oleraceus was limited. Notably, the soilborne microbes were the only environmental sources to phyllosphere in the second chamber and could affect the composition of phyllosphere microbiota indirectly by air flow. The current study demonstrated the possible sources of phyllosphere microbes by controlling external airborne microbes in a designed microcosm system and provided a potential strategy for recruitment for phyllosphere recruitment.

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“…19,64,68 Variations over seasons and in airmass origin were also linked to changes in aerosol microbial community composition. 1,2,6,9,69,70 The aerobiome community composition displays mixtures of sources, and detecting a constant and stable indigenous microbial community was not yet reported. As such, the identi ed microorganisms may serve as tracers for the sources contributing to the aerobiome.…”

Section: Discussionmentioning

confidence: 99%

The Biogeography of Dust in the Eastern Mediterranean

Rudich

Gat

Cytryn

et al. 2021

Preprint

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The atmospheric microbiome, the aerobiome, represents a complex mixture of suspended microorganisms originating from different environments, e.g., soil, marine environments, and plants. Aerobiomes sampled around the globe show distinct compositions, yet some common features might be observed. Defining these similarities and differences will contribute to our understanding of this understudied environment. In this study, we sequenced the metagenomes of atmospheric dust collected in Israel, representing different particulate matter (PM) concentrations, dust origins and atmospheric trajectories. The metagenomes were compared to publicly available atmospheric metagenomes, as well as to marine and soil metagenomes from the Eastern Mediterranean region. This study helps elucidate the role of dust storms in replenishing the atmosphere with bacteria, fungi and archaea, which facilitate essential biogeochemical processes, by investigating microbiomes and functional genes from dust metagenomes. Our results reveal a high level of similarity between metagenomes of dust sampled in Israel and metagenomes of dust collected in Saudi Arabia asynchronically. Moreover, by identifying taxa and genes that are correlated with PM concentrations, we suggest a possible "core" atmospheric microbiome composed mainly of fungi. Application of the SourceTracker algorithm revealed an inverse correlation between the "core" aerobiome and the fraction of soil-derived bacteria and archaea in the dust metagenomes. Marine microbiomes contributed very little to the dust microbiome, even in dust that traversed the Mediterranean and Red Seas. The dust metagenomes showed a high relative abundance of genes associated with antibiotic resistance, sporulation and the ability to degrade aromatic pollutants, which could not be traced to any of the natural microbiomes that were examined. This study represents an important step toward integrating the knowledge accumulated on the global aerobiome and reveals the important role of dust storms in contributing to the presence of various environmentally relevant microbial functions.

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Community composition and seasonal changes of archaea in coarse and fine air particulate matter

Cited by 16 publications

References 58 publications

Assessing Microbial Community Patterns During Incipient Soil Formation From Basalt

Assessing Microbial Community Patterns During Incipient Soil Formation From Basalt

Microbial Flow Within an Air-Phyllosphere-Soil Continuum

The Biogeography of Dust in the Eastern Mediterranean

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