Short-range contributions of local sources to ambient air

Elena S. Gusareva; Nicolas E. Gaultier; Akira Uchida; Balakrishnan N.V. Premkrishnan; Cassie E. Heinle; Wen J. Phung; Anthony Wong; Kenny J.X. Lau; Zhei H. Yap; Yanqing Koh; Poh N. Ang; Alexander Putra; Deepa Panicker; Jessica G.H. Lee; Luis C. Neves; Daniela I. Drautz-Moses; Stephan C. Schuster

doi:10.1093/pnasnexus/pgac043

Short-range contributions of local sources to ambient air

Elena S. Gusareva, Nicolas E. Gaultier, Akira Uchida, Balakrishnan N.V. Premkrishnan, Cassie E. Heinle, Wen J. Phung, Anthony Wong, Kenny J.X. Lau, Zhei H. Yap, Yanqing Koh, Poh N. Ang, Alexander Putra, Deepa Panicker, Jessica G.H. Lee, Luis C. Neves, Daniela I. Drautz-Moses, Stephan C. Schuster^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Recent developments in aerobiology have enabled the investigation of airborne biomass with high temporal and taxonomic resolution. In this study, we assess the contributions of local sources to ambient air within a 160,000 m2 tropical avian park (AP). We sequenced and analyzed 120 air samples from seven locations situated 160 to 400 m apart, representing distinct microhabitats. Each microhabitat contained a characteristic air microbiome, defined by the abundance and richness of its airborne microbial community members, supported by both, PCoA and Random Forest analysis. Each outdoor microhabitat contained 1% to 18.6% location-specific taxa, while a core microbiome of 27.1% of the total taxa was shared. To identify and assess local sources, we compared the AP dataset with a DVE reference dataset from a location 2 km away, collected during a year-round sampling campaign. Intersection of data from the two sites demonstrated 61.6% of airborne species originated from local sources of the AP, 34.5% from ambient air background, and only 3.9% of species were specific to the DVE reference site. In-depth taxonomic analysis demonstrated association of bacteria-dominated air microbiomes with indoor spaces, while fungi-dominated airborne microbial biomass was predominant in outdoor settings with ample vegetation. The approach presented here demonstrates an ability to identify local source contributions against an ambient air background, despite the prevailing mixing of air masses caused by atmospheric turbulences.

Original language	English
Article number	pgac043
Journal	PNAS Nexus
Volume	1
Issue number	2
DOIs	https://doi.org/10.1093/pnasnexus/pgac043
Publication status	Published - May 1 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© The Author(s) 2022. Published by Oxford University Press on behalf of the National Academy of Sciences.

ASJC Scopus Subject Areas

General

Keywords

air microbiome
bioaerosols
eDNA
local and remote microbial sources
microbial ecology

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10.1093/pnasnexus/pgac043

Cite this

Gusareva, E. S., Gaultier, N. E., Uchida, A., Premkrishnan, B. N. V., Heinle, C. E., Phung, W. J., Wong, A., Lau, K. J. X., Yap, Z. H., Koh, Y., Ang, P. N., Putra, A., Panicker, D., Lee, J. G. H., Neves, L. C., Drautz-Moses, D. I., & Schuster, S. C. (2022). Short-range contributions of local sources to ambient air. PNAS Nexus, 1(2), Article pgac043. https://doi.org/10.1093/pnasnexus/pgac043

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abstract = "Recent developments in aerobiology have enabled the investigation of airborne biomass with high temporal and taxonomic resolution. In this study, we assess the contributions of local sources to ambient air within a 160,000 m2 tropical avian park (AP). We sequenced and analyzed 120 air samples from seven locations situated 160 to 400 m apart, representing distinct microhabitats. Each microhabitat contained a characteristic air microbiome, defined by the abundance and richness of its airborne microbial community members, supported by both, PCoA and Random Forest analysis. Each outdoor microhabitat contained 1% to 18.6% location-specific taxa, while a core microbiome of 27.1% of the total taxa was shared. To identify and assess local sources, we compared the AP dataset with a DVE reference dataset from a location 2 km away, collected during a year-round sampling campaign. Intersection of data from the two sites demonstrated 61.6% of airborne species originated from local sources of the AP, 34.5% from ambient air background, and only 3.9% of species were specific to the DVE reference site. In-depth taxonomic analysis demonstrated association of bacteria-dominated air microbiomes with indoor spaces, while fungi-dominated airborne microbial biomass was predominant in outdoor settings with ample vegetation. The approach presented here demonstrates an ability to identify local source contributions against an ambient air background, despite the prevailing mixing of air masses caused by atmospheric turbulences.",

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AU - Gusareva, Elena S.

AU - Gaultier, Nicolas E.

AU - Uchida, Akira

AU - Premkrishnan, Balakrishnan N.V.

AU - Heinle, Cassie E.

AU - Phung, Wen J.

AU - Wong, Anthony

AU - Lau, Kenny J.X.

AU - Yap, Zhei H.

AU - Koh, Yanqing

AU - Ang, Poh N.

AU - Putra, Alexander

AU - Panicker, Deepa

AU - Lee, Jessica G.H.

AU - Neves, Luis C.

AU - Drautz-Moses, Daniela I.

AU - Schuster, Stephan C.

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N2 - Recent developments in aerobiology have enabled the investigation of airborne biomass with high temporal and taxonomic resolution. In this study, we assess the contributions of local sources to ambient air within a 160,000 m2 tropical avian park (AP). We sequenced and analyzed 120 air samples from seven locations situated 160 to 400 m apart, representing distinct microhabitats. Each microhabitat contained a characteristic air microbiome, defined by the abundance and richness of its airborne microbial community members, supported by both, PCoA and Random Forest analysis. Each outdoor microhabitat contained 1% to 18.6% location-specific taxa, while a core microbiome of 27.1% of the total taxa was shared. To identify and assess local sources, we compared the AP dataset with a DVE reference dataset from a location 2 km away, collected during a year-round sampling campaign. Intersection of data from the two sites demonstrated 61.6% of airborne species originated from local sources of the AP, 34.5% from ambient air background, and only 3.9% of species were specific to the DVE reference site. In-depth taxonomic analysis demonstrated association of bacteria-dominated air microbiomes with indoor spaces, while fungi-dominated airborne microbial biomass was predominant in outdoor settings with ample vegetation. The approach presented here demonstrates an ability to identify local source contributions against an ambient air background, despite the prevailing mixing of air masses caused by atmospheric turbulences.

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KW - microbial ecology

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Short-range contributions of local sources to ambient air

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

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