Saharan dust nutrients promote
            <i>Vibrio</i>
            bloom formation in marine surface waters

Westrich, Jason R.; Ebling, Alina M.; Landing, William M.; Joyner, Jessica; Kemp, Keri M.; Griffin, Dale W.; Lipp, Erin K.

doi:10.1073/pnas.1518080113

Cited by 83 publications

(85 citation statements)

References 58 publications

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“…Also, given that they are halotolerant (rather than halophilic), psychrotolerant (rather than psychrophilic), and metabolically versatile indicates that they are flexible in their response to water potential, temperature, and nutrient availability. Therefore, given the evidence available so far, our working model for why Naganishia species are so prevalent on these high elevation volcanoes is that they are flexible “opportunitrophs” ( cf Polz et al 2006; Westrich et al 2016) that can grow during rare periods of water (from melting snow) and nutrient availability (from Aeolian inputs). However, much more work is needed to verify that Naganishia species are actually functioning in these high elevation soils (and at similar sites in Antarctica) and to understand how they are dispersed through the atmosphere to remote sites throughout the cryosphere.…”

Section: Discussionmentioning

confidence: 99%

ANaganishiain high places: functioning populations or dormant cells from the atmosphere?

et al. 2017

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Here, we review the current state of knowledge concerning high-elevation members of the extremophilic Cryptococcus albidus clade (now classified as the genus Naganishia). These fungi dominate eukaryotic microbial communities across the highest elevation, soil-like material (tephra) on volcanoes such as Llullaillaco, Socompa, and Saírecabur in the Atacama region of Chile, Argentina, and Bolivia. Recent studies indicate that Naganishia species are among the most resistant organisms to UV radiation, and a strain of N. friedmannii from Volcán Llullaillaco is the first organism that is known to grow during the extreme, diurnal freeze-thaw cycles that occur on a continuous basis at elevations above 6000 m.a.s.l. in the Atacama region. These and other extremophilic traits discussed in this review may serve a dual purpose of allowing Naganishia species to survive long-distance transport through the atmosphere and to survive the extreme conditions found at high elevations. Current evidence indicates that there are frequent dispersal events between high-elevation volcanoes of Atacama region and the Dry Valleys of Antarctica via “Rossby Wave” merging of the polar and sub-tropical jet streams. This dispersal hypothesis needs further verification, as does the hypothesis that Naganishia species are flexible “opportunitrophs” that can grow during rare periods of water (from melting snow) and nutrient availability (from Aeolian inputs) in one of the most extreme terrestrial habitats on Earth.

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Section: Discussionmentioning

confidence: 99%

ANaganishiain high places: functioning populations or dormant cells from the atmosphere?

et al. 2017

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“…Biologically produced Fe-binding organic ligands are (i) related to alleviation of Fe stress [bacterially-produced siderophores (Rue and Bruland, 1995;Trick et al, 1995;Mawji et al, 2008;Velasquez et al, 2011), the toxin domoic acid produced by the diatom Nitzschia Maldonado et al, 2002)], (ii) retention of episodic iron input (Adly et al, 2015;Westrich et al, 2016), or (iii) ligands produced through biological recycling or basal biological activity such as hemes , ferritin (Castruita et al, 2008), polysaccharides (Ozturk et al, 2004;Hassler et al, 2011a), and EPS (Nichols et al, 2004;Hassler et al, 2011b;Norman et al, 2015). Interestingly, amongst most of these organic ligands, only EPS were reported to contribute to the pool of HS-like substances which is not surprising given that EPS and HS are polyfunctional macromolecules.…”

Section: Organic Ligands Distribution-sources Production and Loss Pmentioning

confidence: 99%

“…Enhanced production of siderophores should be linked to regional patterns in heterotrophic bacterial and cyanobacteria iron stress and its opportunistic alleviation (Kirchman et al, 2009;Adly et al, 2015;Westrich et al, 2016) using a wide range of iron acquisition strategies (Cordero et al, 2012;Moran et al, 2016). Most of the insights gained into siderophores distributions have relied upon the comparable conditional stability constants between them and the L 1 class of ligands, even though no direct links have been made to date between siderophores and the L 1 class (MacRellis et al, 2001).…”

Section: Siderophoresmentioning

confidence: 99%

“…The observations of low concentrations (<10 pM) of siderophores (Boiteau et al, 2016a;Repeta et al, 2016) may be due to energetic constraints associated with their production (Volker and Wolf-Gladrow, 1999) and the "public goods" theory, in which synergies and multiple uptake strategies take place amongst a consortium of heterotrophic bacteria (e.g., Cordero et al, 2012). The cost of siderophores production must be traded off against the benefit obtained from the ability to rapidly sequester iron that is supplied episodically such as by dust inputs (Boyd and Tagliabue, 2015;Westrich et al, 2016). Overall, these calculations ( Figure 3A) point out that even a low concentration of siderophores is effective for bacterial uptake as they can use the bulk of Fe-L 2 complexes as a suitable exchangeable iron pool.…”

Section: Implications Of the Co-existence Of Iron-binding Ligandsmentioning

confidence: 99%

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Toward a Regional Classification to Provide a More Inclusive Examination of the Ocean Biogeochemistry of Iron-Binding Ligands

2017

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Iron-binding ligands are paramount to understanding iron biogeochemistry and its potential to set the productivity and the magnitude of the biological pump in >30% of the ocean. However, the nature of these ligands is largely uncharacterized and little is known about their sources, sensitivity to photochemistry and biological transformation, or scavenging behavior. Despite many uncertainties, there is no doubt that ligands are produced by a wide range of biotic and abiotic processes, and that the bulk ligand pool encompasses a diverse range of molecules. Despite widespread recognition of the likelihood of a continuum of ligand classes making up the bulk ligand pool, studies to date largely focused on the dominant ligand. Thus, most studies have overlooked the need to assess where these targeted molecules fit across the spectrum of ligands that comprise the bulk ligand pool. Here we summarize present knowledge to critically assess the source(s), function(s), production pathways, and loss mechanisms of three important iron-binding organic ligand groups in order to assess their distinctive characteristics and how they link with observed ligand distributions. We considered that ligands are contained in broad groupings of exopolymer substances (EPS), humic substances (HS), and siderophores; using literature data for speciation modeling suggested that this adequately described the iron speciation reported in the ocean. We hypothesize that a holistic viewpoint of the multi-faceted controls on ligands dynamics is essential to begin to understand why some ligands can be expected to dominate in particular oceanic regions, depth strata, or exhibit seasonality and/or lateral gradients. We advocate that the development of a regional classification will enhance our understanding of the changing composition of the bulk ligand pool across the global ocean and to help address to what extent seasonality influences the makeup of this pool. This classification, based on selected functional ligand classes, can act as a bridge to use future ligand datasets to fill in the gaps in the continuum.

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“…Although perhaps best known as pathogens, of the ∼150 currently described species, only 12 are typically associated with human disease; however, all play potentially important roles in nutrient and chemical cycling in the marine environment (Grimes et al, 2009). Vibrio have a broad metabolic and genomic potential, are able to take advantage of ephemeral pulses of nutrients through chemotaxis and motility, and show rapid growth in response to nutrient addition (Worden et al, 2006;Takemura et al, 2014;Westrich et al, 2016). Vibrio are often found in close association with plankton and marine particulates where they degrade a broad range of substrates with extracellular enzymatic proteins such as chitinases, proteases, and lipases (Thompson and Polz, 2006), but can also survive in a free-living state (Worden et al, 2006;Hunt et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Vibrio Population Dynamics in Mid-Atlantic Surface Waters during Saharan Dust Events

Westrich

Griffin

Westphal³

et al. 2018

Front. Mar. Sci.

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Vibrio is a cosmopolitan genus of marine bacteria, highly investigated in coastal and estuarine environments. Vibrio have also been isolated from pelagic waters, yet very little is known about the ecology of these oligotrophic species. In this study we examined the relative change in bacterial abundance and more specifically the dynamics of Vibrio in the tropical North Atlantic in response to the arrival of pulses of Saharan dust aerosols, a major source of biologically important nutrients for downwind marine surface waters. Aerosol and surface water samples were collected over 1 month coinciding with at least two distinct dust events. Total bacterial counts increased by 1.6-fold correlating with the arrival of Saharan dust (r = 0.76; p = 0.001). Virus-like particles (VLP) also followed this trend and were correlated with bacterial counts (r = 0.67; p = 0.01). Vibrio specific qPCR targeting the 16S rRNA gene ranged from below detection limits to a high of 9,145 gene copies ml −1 with the arrival of dust. This increase equated to 6.5 × 10 2 −1.5 × 10 3 individual genome equivalents ml −1 based on the known range of 16S rRNA copies among this genus. Vibrio exhibited bloom-bust cycles potentially attributed to selective viral lysis or bloom depletion of organic carbon. This work is one of the few studies to examine the open ocean ecology of Vibrio, a conditionally rare taxon, whose bloom-bust lifestyle likely is a contributing factor in the flow of nutrients and energy in pelagic ecosystems.

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Saharan dust nutrients promote Vibrio bloom formation in marine surface waters

Cited by 83 publications

References 58 publications

ANaganishiain high places: functioning populations or dormant cells from the atmosphere?

ANaganishiain high places: functioning populations or dormant cells from the atmosphere?

Toward a Regional Classification to Provide a More Inclusive Examination of the Ocean Biogeochemistry of Iron-Binding Ligands

Vibrio Population Dynamics in Mid-Atlantic Surface Waters during Saharan Dust Events

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