Ocean Aerobiology

Alsante, Alyssa; Thornton, Daniel C. O.; Brooks, Sarah D.

doi:10.3389/fmicb.2021.764178

Cited by 20 publications

(16 citation statements)

References 301 publications

(435 reference statements)

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“…Almost 90% of storms form within 20° north or south of the equator (Britannica, 2022;National Hurricane Center and Central Paci c Hurricane Center National Oceanic and Atmospheric Administration, 2022), and CBM is also endemic in this region (Queiroz-Telles et al, 2017;Santos et al, 2021). Notably, the ndings of DeLeon-Rodriguez et al, (2013) (DeLeon-Rodriguez et al, 2013 suggested that fogging of large fungal spore communities occurs during tropical hurricanes, and airborne fungi may remain viable after being carried aloft (Alsante et al, 2021;Mayer et al, 2020), where long-distance, transcontinental and even oceanic transport occurs. The fungal microbiota is a dynamic and underappreciated aspect of the lower oceanic layer, and the extensive ooding after mega-hurricanes can create ideal conditions (Barbeau et al, 2010) for the growth of molds such as Fonsecaea spp.…”

Section: Discussionmentioning

confidence: 99%

Evolutionary Relationships, Phylogeographic Patterns, and a Hypothesis for Air- and Sea-driven Global Spread of Chromoblastomycosis by Etiological Fonsecaea Agents

Wang

Hao²,

Cai

et al. 2022

Preprint

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Fonsecaea spp. is the most common pathogen underlying chromoblastomycosis. However, many aspects of its evolutionary history are not fully understood, and a timescale for its diversification is lacking . Here, we propose, explain, and validate the evolutionary relationships, transmission routes, and modes of transmission among pathogenic species of the genus Fonsecaea . we investigated the sequences of a total of 510 intra-ribosomal transcribed regions and 485 reported cases of eight strains of the genus Fonsecaea , that have spread epidemically worldwide, persisted, and diversified over 38.27 million years. This period coincides with the diversification of many filamentous fungi, and this evolution explains the diversity and origin of pathogenic species of Fonsecaea spp . , as well as the possible transmission routes. Fonsecaea pedrosoi originated in the Atlantic Ocean near Brazil, F. monophora originated in the Pacific Ocean near southern China, and F. nubica originated in the Indian Ocean near Madagascar. F. pugnacius originated and is endemic in the Atlantic Ocean near Brazil. We proposed the hypothesis that non-pathogenic environmental strains in the environment ( Fonsecaea brasiliensis , F. multimorphosa , F. minima , and F. erecta ) evolved into pathogenic strains ( F. pedrosoi , F. pugnacius , F. nubica , and F. monophora ) and spread globally with global tropical cyclone and ocean currents pathways. F. multimorphosa is potentially infectious to humans. The present study’s results will greatly facilitate the prevention, treatment, and cure of Fonsecaea infections and give insight and reference to researchers in the field of fungal research, especially other pathogenic fungi and environmental fungi.

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Section: Discussionmentioning

confidence: 99%

Evolutionary Relationships, Phylogeographic Patterns, and a Hypothesis for Air- and Sea-driven Global Spread of Chromoblastomycosis by Etiological Fonsecaea Agents

Wang

Hao²,

Cai

et al. 2022

Preprint

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“…Currently, we cannot state which bacterial phylotypes remained viable during atmospheric transport and were actively growing or involved in specific cellular pathways. This question could be investigated by sequencing efforts of the airborne ribosomal 16S RNA transcripts as well as other specific genes of interest (Alsante et al, 2021). One such gene could be nifH as airborne diazotrophs are routinely found in dust samples (Foster et al, 2009), which, in turn, may fix N 2 upon deposition in seawater (Rahav et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…The low levels of the relatively viability proxy during the dust event may be attributed to anthropogenic inhibitors carried by the dust, mainly metals and organic pollutants. Thus, transport time, the presence of pollutants and the chemical reactions on surface particles during the dust event probably impacted the microbial viability, yet further research is needed to assess how physical and chemical microhabitats impacts microorganism functionality (Alsante et al, 2021). Moreover, given the acidic conditions in the atmosphere and clouds (Pye et al, 2020), trace-metals leachability and thus potential toxicity may increase (Koçak et al, 2007).…”

Section: Viability Proxy Of Airborne Prokaryotes During An Extreme Du...mentioning

confidence: 99%

“…Evidently, atmospheric aerosols contain bacteria, archaea, algae, viruses, fungi, and pollen originating from land (Kellogg and Griffin, 2006;Griffin et al, 2007) or the ocean (Prospero et al, 2005;Flores et al, 2020). Airborne microorganisms were identified in almost every aerosol sample collected over aquatic and terrestrial environments (Leck and Bigg, 2005;Favet et al, 2013;Yahya et al, 2019), usually ranging from ~10 3 to ~10 7 cells per m 3 of air (Mayol et al, 2017;Rahav et al, 2019;Alsante et al, 2021), and were shown to contribute to bacterial production, primary production, N 2 fixation and viral infections (Peter et al, 2014;Rahav et al, 2018;Rahav et al, 2020). Understanding the parameters that determine the survival of airborne microorganisms is of great ecological significance and may shed light on microbial dispersion throughout the world's oceans.…”

Section: Introductionmentioning

confidence: 99%

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Relative viability proxy of airborne prokaryotic microorganisms at the Southeastern Mediterranean coastal Sea

Rahav

Paytan

Herut

2022

Front. Environ. Sci.

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The atmosphere plays a fundamental role in transporting airborne prokaryotes across the oceans and land. Despite the harsh atmospheric conditions, a considerable fraction of the airborne prokaryotic microorganisms survive the journey and remain viable upon deposition, and can affect the receiving environment. Here, we provide the first estimate of potential viability proxy for airborne prokaryotic cells at the Southeastern Mediterranean coast in 22 events during 2015, representing marine and terrestrial air-mass trajectories and a significant dust storm event. This was assessed using sequence amplicons of the small subunit ribosomal RNA gene (SSU rRNA) jointly with other complementary measurements. To estimate the relative viability in our dataset we used the ratio between the abundance of the bacterial SSU rRNA transcripts in a given sampling date and the lowest measured value (23.7.2015) as a measure of a relative viability proxy. The abundance of prokaryotes SSU rRNA transcripts ranged from ∼500 to 11,000 copies m3, with ∼2-fold higher relative viability proxy in marine-origin aerosols than predominantly terrestrial atmospheric trajectories. The relative viability proxy of prokaryotes was low during the peak of an intense and prolonged dust storm, and increased by ∼1.5-fold in the subsequent days representing background conditions (<1700 ng Al m−3). Furthermore, we show that anthropogenic/toxic trace-metals (Cu/Al, Pb/Al) negatively correlates with potentially viable airborne prokaryotes in marine trajectory aerosols, whereas mineral dust load (Al, Fe proxy) positively affect their potential viability proxy. This may suggest that airborne prokaryotes associated to marine trajectories benefit from a particle-associate lifestyle, enabling relatively higher humidity and supply of nutrients attributed to mineral dust particles.

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“…Virus aerosolization from the SML was previously studied 15,30,33 , but investigations pursuing metagenomic approaches to explore the virioneuston and its aerosolization in the field are lacking. A recent review highlighted the need to quantify marine aerobiota, to characterize the spatial-temporal dimensions of dispersal, and to understand acclimations of marine microorganisms to atmospheric conditions 34 . Once airborne, viruses could even fulfill other functions as recently suggested 35 : Airborne marine viruses could serve as ice-nucleating particles (INP), a function already described for many microorganisms 36,37 , and act as catalysts to mediate freezing at temperatures warmer than - 10 °C.…”

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confidence: 99%

Heads in the clouds: marine viruses disperse bidirectionally along the natural water cycle

Rahlff

Esser

Plewka

et al. 2022

Preprint

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Marine viruses have thoroughly been studied in seawater, yet their dispersal from neuston ecosystems at the air-sea interface towards the atmosphere remains a knowledge gap. Here, we show that 6.2 % of the studied virus population were shared between air-sea interface ecosystems and rainwater. Virus enrichment in the 1-mm thin surface microlayer and sea foams happened selectively, and variant analysis proved virus transfer to aerosols and rain. Viruses detected in rain and aerosols showed a significantly higher percent G/C base content compared to marine viruses, and a genetically distinct rain virome supports that those viruses could inhabit higher air masses. CRISPR spacer matches of marine prokaryotes to foreign viruses from rainwater prove regular virus-host encounters at the air-sea interface. Our findings on aerosolization and long-range atmospheric dispersal implicate virus-mediated carbon turnover in remote areas, viral dispersal mechanisms relevant to human health, and involvement of viruses in atmospheric processes like ice-nucleation.

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Ocean Aerobiology

Cited by 20 publications

References 301 publications

Evolutionary Relationships, Phylogeographic Patterns, and a Hypothesis for Air- and Sea-driven Global Spread of Chromoblastomycosis by Etiological Fonsecaea Agents

Evolutionary Relationships, Phylogeographic Patterns, and a Hypothesis for Air- and Sea-driven Global Spread of Chromoblastomycosis by Etiological Fonsecaea Agents

Relative viability proxy of airborne prokaryotic microorganisms at the Southeastern Mediterranean coastal Sea

Heads in the clouds: marine viruses disperse bidirectionally along the natural water cycle

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