Biological Ice-Nucleating Particles Deposited Year-Round in Subtropical Precipitation

Airborne bacteria that nucleate ice at relatively warm temperatures (>-10°C) can interact with cloud water droplets, affecting the formation of ice in clouds and the residency time of the cells in the atmosphere. We sampled 65 precipitation events in southeastern Louisiana over 2 years to examine...

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Bibliographic Details
Published in:Applied and environmental microbiology 2019-12, Vol.85 (23), p.1
Main Authors: Joyce, Rachel E, Lavender, Heather, Farrar, Jennifer, Werth, Jason T, Weber, Carolyn F, D'Andrilli, Juliana, Vaitilingom, Mickaël, Christner, Brent C
Format: Article
Language:English
Subjects:
Airborne bacteria
Airborne microorganisms
Bacteria
Bioaerosols
Clouds
Dissolved organic matter
Environmental Microbiology
Fluorescence
Heat treatment
Ice
Ice formation
Ice nucleation
Lysozyme
Nimbostratus clouds
Nucleation
Phenotypes
Precipitation
Sleet
Spotlight
Statistical analysis
Statistical methods
Temperature
Terrestrial environments
Water drops
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Summary:Airborne bacteria that nucleate ice at relatively warm temperatures (>-10°C) can interact with cloud water droplets, affecting the formation of ice in clouds and the residency time of the cells in the atmosphere. We sampled 65 precipitation events in southeastern Louisiana over 2 years to examine the effect of season, meteorological conditions, storm type, and ecoregion source on the concentration and type of ice-nucleating particles (INPs) deposited. INPs sensitive to heat treatment were inferred to be biological in origin, and the highest concentrations of biological INPs (∼16,000 INPs liter active at ≥-10°C) were observed in snow and sleet samples from wintertime nimbostratus clouds with cloud top temperatures as warm as -7°C. Statistical analysis revealed three temperature classes of biological INPs (INPs active from -5 to -10°C, -11 to -12°C, and -13 to -14°C) and one temperature class of INPs that were sensitive to lysozyme (i.e., bacterial INPs, active from -5 to -10°C). Significant correlations between the INP data and abundances of taxa in the , , and unclassified bacterial divisions implied that certain members of these phyla may possess the ice nucleation phenotype. The interrelation between the INP classes and fluorescent dissolved organic matter, major ion concentrations (Na , Cl , SO , and NO ), and backward air mass trajectories indicated that the highest concentrations of INPs were sourced from high-latitude North American and Asian continental environments, whereas the lowest values were observed when air was sourced from marine ecoregions. The intra- and extracontinental regions identified as sources of biological INPs in precipitation deposited in the southeastern United States suggests that these bioaerosols can disperse and affect meteorological conditions thousands of kilometers from their terrestrial points of origin. The particles most effective at inducing the freezing of water in the atmosphere are microbiological in origin; however, information on the species harboring this phenotype, their environmental distribution, and ecological sources are very limited. Analysis of precipitation collected over 2 years in Louisiana showed that INPs active at the warmest temperatures were sourced from terrestrial ecosystems and displayed behaviors that implicated specific bacterial taxa as the source of the ice nucleation activity. The abundance of biological INPs was highest in precipitation from winter storms and implied that their in-cloud
ISSN:0099-2240
1098-5336
DOI:10.1128/AEM.01567-19