Arsenic and phosphorus biogeochemistry in the ocean: Arsenic species as proxies for P‐limitation

Wurl, Oliver; Zimmer, Louise A.; Cutter, Gregory A.

doi:10.4319/lo.2013.58.2.0729

Cited by 54 publications

(50 citation statements)

References 58 publications

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“…The drawdown of DOP is suggested by the lower DOP concentration and higher APA activity in the phosphate-deplete subtropical North Atlantic compared to the phosphate-replete subtropical South Atlantic where DOP concentrations are elevated and APA almost immeasurable (Mather et al, 2008). There is also a zonal contrast, with higher APA in the western subtropical Atlantic than the eastern subtropical Atlantic Wurl et al, 2013;Reynolds et al, 2014), suggesting that phosphate limitation is more prevalent in the western subtropical Atlantic. These northsouth and east-west basin scale contrasts in phosphorus dynamics are partially constrained by the spatial extent of wet and dry dust deposition (Moore et al, 2006;Schlosser et al, 2014) and hence magnitude and distribution of nitrogen fixation, as well as physical transfer of nutrients via nutrient streams (Williams et al, 2011).…”

Section: Introductionmentioning

confidence: 83%

“…However, when phosphate is in short supply, many marine organisms, including the marine filamentous diazotroph, Trichodesmium (Sohm et al, 2008;Orcutt et al, 2013), cyanobacteria such as Synechococcus (Tetu et al, 2009) and Prochlorococcus (Kathuria and Martiny, 2011), some species of dinoflagellate (Dyhrman and Palenik, 1999;Lin et al, 2012), coccolithophores (Jakuba et al, 2008), diatoms (Dyhrman and Ruttenberg, 2006) and bacteria (Huang and Hong, 1999) are known to synthesize hydrolytic enzymes in order to access the DOP pool. Since the late 1980s, studies on phosphohydrolytic enzymes have largely focused on the activity of alkaline phosphatase (AP; Sebastián et al, 2004a,b;Sohm and Capone, 2006;Mather et al, 2008;Sohm et al, 2008;Duhamel et al, 2010Duhamel et al, , 2011Lomas et al, 2010;Orchard et al, 2010;Suzumura et al, 2012;McLaughlin et al, 2013;Lin et al, 2013;Sato et al, 2013;Wurl et al, 2013;Martin et al, 2014;Reynolds et al, 2014), a group of metalloenzymes that hydrolyse phosphomonoester bonds (Cembella et al, 1984a,b;Hoppe, 2003). As phosphate esters account for up to 70% of the DOP pool (Karl and Yanagi, 1997;Kolowith et al, 2001;Karl and Björkman, 2002), AP plays a significant role in the cycling and metabolism of phosphorus in the ocean.…”

Section: Introductionmentioning

confidence: 99%

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Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments

et al. 2014

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Phosphorus is an essential nutrient for all life on earth. In the ocean, the most bioavailable form of phosphorus is inorganic phosphate, but in the extensive subtropical gyres, phosphate concentrations can be chronically low and limit primary productivity and nitrogen fixation. In these regions, organisms produce hydrolytic enzymes, such as alkaline phosphatase (AP), that enable them to utilize the more replete dissolved organic phosphorus (DOP) pool to meet their cellular phosphorus demands. In this study, we synthesized data from 14 published studies and present our own findings from two research cruises (D326 and D361) in the eastern subtropical Atlantic to explore the relationship between AP activity (APA) and nutrients, Saharan dust and trace metals. We found that below a threshold phosphate concentration of ∼30 nM, APA increased with an inverse hyperbolic relationship with phosphate concentration. Meanwhile, DOP concentrations decreased with enhanced APA, indicating utilization of the DOP pool. We found APA rates were significantly higher in the subtropical Atlantic compared to the subtropical Pacific Ocean, even over the same low phosphate concentration range (0-50 nM). While the phosphate concentration may have a first order control on the APA rates, we speculate that other factors influence this basin scale contrast. Using bioassay experiments, we show that the addition of Saharan dust and zinc significantly increased the rate of APA. To our knowledge, our results are the first direct field-based evidence that APA is limited by zinc in the subtropical ocean. Further work is required to explore the relationship between trace metals such as iron and zinc, which are co-factors of phosphohydrolytic enzymes, specifically PhoX and PhoA, respectively, and APA in the ocean.

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Section: Introductionmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments

et al. 2014

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“…Along an open ocean transect that covered varying phosphate regimes, when the PO 4 :AsO 4 ratio was less than 1, the total arsenic pool consisted of a greater proportion of reduced and methylated arsenicals compared with the relatively phosphate-rich region, with an inorganic PO 4 :AsO 4 ratio of 100:1 (Cutter and Cutter, 2006). In the North Atlantic, both methylated arsenicals and arsenite detoxification products have been identified and the spatial distribution of arsenite closely corresponded with phosphate availability and can be used in conjunction with measures of alkaline phosphatase to identify regions of phosphorus limitation (Wurl et al, 2013). There is also evidence that the diazotrophic cyanobacterial communities in these phosphate-poor regions are responding to arsenic toxicity.…”

Section: Discussionmentioning

confidence: 99%

“…In the marine environment, inorganic arsenate accounts for about 85% of the standing pool of arsenic with the remaining portion of the arsenic pool comprised of the inorganic arsenite and various organoarsenicals, including two of the main products of the methylation pathway, monomethylarsonic acid and dimethylarsinic acid (Andreae, 1979;Cutter et al, 2001;Cutter and Cutter, 2006;Wurl et al, 2013). Arsenate has a nutrient-like depth distribution because it is a bioactive molecule which is transformed by marine biota in the surface waters via the two pathways described above (Andreae, 1979).…”

Section: Introductionmentioning

confidence: 99%

“…to available phosphate (Karl and Tien, 1997;Wurl et al, 2013). While inorganic arsenic concentrations are relatively stable throughout the surface waters of the open ocean ranging from 12.9-15.7 nmol l − 1 (Andreae, 1979;Cutter and Cutter, 1998;Cutter et al, 2001;Ellwood and Maher, 2002;Cutter and Cutter, 2006), surface phosphate concentrations are far more variable, ranging fromo0.1 μmol l − 1 in oligotrophic subtropical gyres to 42.0 μmol l − 1 in the Southern Ocean (Karl, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Genomic potential for arsenic efflux and methylation varies among global Prochlorococcus populations

Saunders

Rocap

2015

The ISME Journal

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The globally significant picocyanobacterium Prochlorococcus is the main primary producer in oligotrophic subtropical gyres. When phosphate concentrations are very low in the marine environment, the mol:mol availability of phosphate relative to the chemically similar arsenate molecule is reduced, potentially resulting in increased cellular arsenic exposure. To mediate accidental arsenate uptake, some Prochlorococcus isolates contain genes encoding a full or partial efflux detoxification pathway, consisting of an arsenate reductase (arsC), an arsenite-specific efflux pump (acr3) and an arsenic-related repressive regulator (arsR). This efflux pathway was the only previously known arsenic detox pathway in Prochlorococcus. We have identified an additional putative arsenic mediation strategy in Prochlorococcus driven by the enzyme arsenite S-adenosylmethionine methyltransferase (ArsM) which can convert inorganic arsenic into more innocuous organic forms and appears to be a more widespread mode of detoxification. We used a phylogenetically informed approach to identify Prochlorococcus linked arsenic genes from both pathways in the Global Ocean Sampling survey. The putative arsenic methylation pathway is nearly ubiquitously present in global Prochlorococcus populations. In contrast, the complete efflux pathway is only maintained in populations which experience extremely low PO4:AsO4, such as regions in the tropical and subtropical Atlantic. Thus, environmental exposure to arsenic appears to select for maintenance of the efflux detoxification pathway in Prochlorococcus. The differential distribution of these two pathways has implications for global arsenic cycling, as their associated end products, arsenite or organoarsenicals, have differing biochemical activities and residence times.

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Environmental controls on the biogeography of diazotrophy and Trichodesmium in the Atlantic Ocean

Snow

Schlösser

Woodward

et al. 2015

Global Biogeochemical Cycles

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The cyanobacterium Trichodesmium is responsible for a significant proportion of the annual "new" nitrogen introduced into the global ocean. Despite being arguably the best studied marine diazotroph, the factors controlling the distribution and growth of Trichodesmium remain a subject of debate, with sea surface temperature, the partial pressure of CO 2 , and nutrients including iron (Fe) and phosphorus (P), all suggested to be important. Synthesizing data from seven cruises collectively spanning large temporal and spatial scales across the Atlantic Ocean, including two previously unreported studies crossing the largely undersampled South Atlantic gyre, we assessed the relationship between proposed environmental drivers and both community N 2 fixation rates and the distribution of Trichodesmium. Simple linear regression analysis would suggest no relationship between any of the sampled environmental variables and N 2 fixation rates. However, considering the concentrations of iron and phosphorus together within a simplified resource-ratio framework, illustrated using an idealized numerical model, indicates the combined effects these nutrients have on Trichodesmium and broader diazotroph biogeography, alongside the reciprocal maintenance of different biogeographic provinces of the (sub)tropical Atlantic in states of Fe or P oligotrophy by diazotrophy. The qualitative principles of the resource-ratio framework are argued to be consistent with both the previously described North-South Atlantic contrast in Trichodesmium abundance and the presence and consequence of a substantial non-Trichodesmium diazotrophic community in the western South Atlantic subtropical gyre. A comprehensive, observation-based explanation of the interactions between Trichodesmium and the wider diazotrophic community with iron and phosphorus in the Atlantic Ocean is thus revealed.

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Arsenic and phosphorus biogeochemistry in the ocean: Arsenic species as proxies for P‐limitation

Cited by 54 publications

References 58 publications

Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments

Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments

Genomic potential for arsenic efflux and methylation varies among global Prochlorococcus populations

Environmental controls on the biogeography of diazotrophy and Trichodesmium in the Atlantic Ocean

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