Airborne Bacteria in Earth's Lower Stratosphere Resemble Taxa Detected in the Troposphere: Results From a New NASA Aircraft Bioaerosol Collector (ABC)

Smith, David J.; Ravichandar, Jayamary Divya; Jain, Sunit; Griffin, Dale W.; Yu, Hongbin; Tan, Qian; Thissen, James B.; Lusby, Terry C.; Nicoll, Patrick; Shedler, Sarah; Martinez, P.; Osorio, Alejandro Zarur; Lechniak, Jason A.; Choi, Samuel; Sabino, Kayleen; Iverson, Kathryn; Chan, Luisa; Jaing, Crystal; McGrath, John W.

doi:10.3389/fmicb.2018.01752

Cited by 70 publications

(70 citation statements)

References 98 publications

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“…The driving bacterial classes identified here were repeatedly found in other bioaerosol studies; Bacilli and Cyanobacteria were repeatedly identified with dust storms and long-range troposopheric transport, while Alpha-, Beta-and Gammaproteobacteria as well as Actinobacteria often characterised non-dust below the PBL air (Jeon et al, 2011;Maki et al, 2017;Smith et al, 2010Smith et al, , 2011Smith et al, , 2012Smith et al, , 2018. Some species of Bacilli are frequently detected in connection with dust events, and hence long-distance transport, and are seen as characteristic of Saharan and Chad desert sand events (Favet et al, 2013;Smith et al, 2010Smith et al, , 2012.…”

Section: What Drives the Differences?supporting

confidence: 75%

Beyond the planetary boundary layer: Bacterial and fungal vertical biogeography at Mount Sonnblick, Austria

Els

Baumann‐Stanzer

Larose

et al. 2019

Geography and Environment

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The atmosphere harbours a vast diversity of primary biological aerosols (PBAs) that are subjected to vertical and horizontal dispersal mechanisms that are not fully understood. In addition to size and weight constraints on PBAs to be lifted into the air column, local meteorological features dominate the fate of bioaerosols and their possible inclusion in long‐range transport. For organic particles to be included into long distant dispersal, they have to overcome surface vertical mixing of the planetary boundary layer (PBL) to reach levels of laminar air movement. Hence, the biogeography of PBAs along a vertical distribution through the PBL needed further study. To assess the microbial biodiversity along an altitudinal gradient, air samples were collected between 1,000 and 3,100 m above sea level at Mount Sonnblick in the Austrian Alps. 16S rRNA gene and internal transcribed spacer sequencing for bacteria and fungi, respectively, were used to define distinct microbial communities that were separated by the PBL. Up to the top of the PBL, plant‐associated bacteria and fungi were detected and were subjected to limited vertical dispersal due to size‐constraints. This indicates that those communities become aerosolised but were not lifted into higher altitudes. However, a variety of ubiquitous, thermophilic strains that are often identified with heavy dust events and high endurance towards extreme conditions were significantly increased (relative abundance) at higher elevations. The lack of information on vertical dispersal is due to reliance on ground‐based investigations that bias the interpretation of dispersal dynamics. Thus, to understand the mechanisms for near‐ground communities to become airborne and subsequently included in long‐range transport, we recommend investigating meteorological driving forces for an improved biogeographical assessment. Here, we show, for the first time, an assessment of the biogeography of bacterial and fungal assemblages along a vertical alpine air column transect.

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Section: What Drives the Differences?supporting

confidence: 75%

Beyond the planetary boundary layer: Bacterial and fungal vertical biogeography at Mount Sonnblick, Austria

Els

Baumann‐Stanzer

Larose

et al. 2019

Geography and Environment

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“…Our results showed that, despite the similitudes in the bacterial diversity between our atmospheric samples and the previously reported ones, there are a number of important and stark differences. For example, we did not find any sequence related to Afipia sp., one of the main constituents of the troposphere community (>40% of total community) reported by DeLeon-Rodriguez et al (2013), as well as some of the most abundant families recently described by Smith et al (2018) in the lower stratosphere (such as Staphylococcaceae, Moraxellaceae, Lachnospiraceae and Ruminococcaceae), although we found a similar number of OTUS. Furthermore, one of the main components found in our samples related to Saharan intrusion, Microvirga sp., has not been reported previously in the consulted literature.…”

Section: Diversity Of Bacteria Sequences Were Affiliated With 27 Bacsupporting

confidence: 71%

Impacts of Saharan Dust Intrusions on Bacterial Communities of the Low Troposphere

González-Toril

Osuna

Viúdez‐Moreiras

et al. 2020

Sci Rep

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We have analyzed the bacterial community of a large Saharan dust event in the iberian peninsula and, for the first time, we offer new insights regarding the bacterial distribution at different altitudes of the lower troposphere and the replacement of the microbial airborne structure as the dust event receeds. Samples from different open-air altitudes (surface, 100 m and 3 km), were obtained onboard the National Institute for Aerospace Technology (INTA) C-212 aircrafts. Samples were collected during dust and dust-free air masses as well two weeks after the dust event. Samples related in height or time scale seems to show more similar community composition patterns compared with unrelated samples. The most abundant bacterial species during the dust event, grouped in three different phyla: (a) Proteobacteria: Rhizobiales, Sphingomonadales, Rhodobacterales, (b) Actinobacteria: Geodermatophilaceae; (c) Firmicutes: Bacillaceae. Most of these taxa are well known for being extremely stress-resistant. After the dust intrusion, Rhizobium was the most abundant genus, (40-90% total sequences). Samples taken during the flights carried out 15 days after the dust event were much more similar to the dust event samples compared with the remaining samples. in this case, Brevundimonas, and Methylobacterium as well as Cupriavidus and Mesorizobium were the most abundant genera.Airborne microbes are ubiquitous in the atmosphere 1 and are thought to play important roles in meteorological processes (i.e. clouds and snow formation or precipitation patterns alterations) 2,3 , as well as in the long-range dispersal of plant and livestock pathogens 4,5 and in the maintenance of the diversity in aquatic systems 6 . Likewise, airborne bacteria can have important effects on human health, producing allergic asthma and seasonal allergies, and could interfere in the productivity of managed and natural ecosystems 7 . Global abundance of aerial microorganisms has been estimated, based on data from terrestrial environments, to range between 10 4 to 10 6 m −3 8 . However, more recent studies, incorporating direct counting by microscopy or quantitative PCR 9 , have yielded, more accurate, higher estimates of the abundance of airborne microbes and seasonal patterns 10 . Additionally, the atmosphere is one of the most extreme environments and microorganisms inhabiting in the troposphere are exposed to higher UV radiation, desiccation, cold temperatures and nutrient deprivation than in other environments 11,12 .Several studies have also demonstrated the potential for microorganisms to be transported over long distances through the atmosphere, associated to desert dust, as a route for the colonization of new habitats 13,14 . Thus, desert dust clouds may serve not only as a source of nutrients for terrestrial plants and primary producers in nutrient depleted oceanic waters 15,16 , but may also serve as a vehicle for global transport of microorganisms, including pathogens 13,17 .The Sahara-Sahel regions of North Africa are the dominant sources of aerosolize...

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“…Studies focusing on free tropospheric air microbial communities often present data from single campaigns or few flights (Schmale and Ross 2015;Techy et al 2010;Jimenez-Sanchez et al 2018;Smith et al 2018;Maki et al 2017;Xia et al 2013;Zweifel et al 2012) and have shown that microbes present in the free troposphere might originate from long-range travel (Maki et al 2017;Smith and David 2012;Smith et al 2011Smith et al , 2012Brown and Hovmøller 2002;Burrows et al 2009a, b). Air masses above and below PBL differ significantly in microbial composition.…”

Section: Introductionmentioning

confidence: 99%

“…Air masses above and below PBL differ significantly in microbial composition. Free tropospheric habitats tend to have more Firmicutes (Smith et al 2018;, Proteobacteria, Burkholderiales (DeLeon-Rodriguez et al 2013) and extremophile yeasts, Saccharomycetes and Microbotryomycetes (Els et al 2019). While the existence of either a stable (DeLeon-Rodriguez et al 2013) or a highly variable (Zweifel et al 2012) extremophile free tropospheric PBA community is disputed, generally few studies addressing the question were mainly performed over marine and oceanic regions (DeLeon-Rodriguez et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Microbial composition in seasonal time series of free tropospheric air and precipitation reveals community separation

et al. 2019

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Primary biological aerosols are transported over large distances, are traveling in various media such as dry air masses, clouds or fog, and eventually deposited with dry deposition, especially for larger particles, or precipitation like rain, hail or snow. To investigate relative abundance and diversity of airborne bacterial and fungal communities, samples have been collected with a liquid impinger (Coriolis l) from the top of Mount Sonnblick (3106 m asl, Austrian Alps) from the respective sources under a temporal aspect over four seasons over the year to include all climatic conditions. Bacterial and fungal

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Airborne Bacteria in Earth's Lower Stratosphere Resemble Taxa Detected in the Troposphere: Results From a New NASA Aircraft Bioaerosol Collector (ABC)

Cited by 70 publications

References 98 publications

Beyond the planetary boundary layer: Bacterial and fungal vertical biogeography at Mount Sonnblick, Austria

Beyond the planetary boundary layer: Bacterial and fungal vertical biogeography at Mount Sonnblick, Austria

Impacts of Saharan Dust Intrusions on Bacterial Communities of the Low Troposphere

Microbial composition in seasonal time series of free tropospheric air and precipitation reveals community separation

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