Phytoplankton iron limitation in the Humboldt Current and Peru Upwelling

Hutchins, David A.; Hare, Clinton E.; Weaver, Richard S.; Zhang, Y.; Firme, Giselle F.; DiTullio, Giacomo R.; Alm, Melissa B.; Riseman, S. F.; Maucher, Jennifer M.; Geesey, Mark E.; Trick, Charles G.; Smith, Geoffrey J.; Rue, Eden L.; Conn, J.; Bruland, Kenneth W.

doi:10.4319/lo.2002.47.4.0997

Cited by 215 publications

(139 citation statements)

References 39 publications

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“…1): West of Glacier Bay at 59u0.569N, 139u50.589W (Coastal experiment) and southwest of Kodiak Island at 53u44.829N, 155u18.79W (HNLC experiment). Acidwashed, trace-metal-clean 1.1-liter polycarbonate bottles were filled with water from the GeoFish clean pumping system (Hutchins et al 2002;Bruland et al 2005) from an average depth of 1-3 m. To avoid trace-metal contamination, all manipulating and processing of experimental bottles was performed in the trace-metal-clean room using trace-metal-clean techniques. For the coastal experiment, triplicate bottles were amended with NO { 3 (20 mmol L 21 ), B 12 (100 pmol L 21 ), and both compounds.…”

Section: Methodsmentioning

confidence: 99%

“…Water was collected from near surface via a conductivity temperature depth rosette or directly from the GeoFish clean underway surface-sampling system. This system delivered water from 1-m to 3-m depth into a tracemetal-clean room via a trace-metal-clean Teflon pumping system (Hutchins et al 2002;Bruland et al 2005). Triplicate chlorophyll a (Chl a) samples were collected on 0.2-mm and 2-mm polycarbonate filters and frozen and analyzed according to Parsons et al (1984).…”

Section: Methodsmentioning

confidence: 99%

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The effect of vitamin B₁₂ on phytoplankton growth and community structure in the Gulf of Alaska

Koch

Marcoval

Panzeca

et al. 2011

Limnology & Oceanography

116

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A majority of eukaryotic phytoplankton species require an exogenous source of vitamin B 12 for growth and recent field studies in some coastal and polar regions indicate that the addition of vitamin B 12 alone, or with another limiting nutrient can influence the accumulation of phytoplankton biomass. We quantified the concentrations and uptake rates of vitamin B 12 , characterized phytoplankton community composition, and examined the ability of vitamin B 12 to alter the growth and composition of phytoplankton communities in the Gulf of Alaska. Picoplankton (0.2-2 mm) were responsible for the majority of vitamin B 12 uptake in both coastal and high-nutrient low-chlorophyll (HNLC) regions and B 12 concentrations and uptake rates were higher in HNLC regions compared to coastal regions with higher iron (Fe) concentrations. During vitamin amendment experiments, B 12 alone or in conjunction with other limiting nutrients (N or Fe) significantly enhanced algal biomass and increased the growth rates of multiple groups of larger (. 2 mm) phytoplankton. This included ecologically significant, B 12 auxotrophs such as Gymnodinium sp. and Alexandrium sp. (in the costal experiment) as well as Chaetoceros sp. and Gymnodinium sp. (in the HNLC experiment). The ability of vitamin B 12 to shape algal community composition in coastal and HNLC areas of the Gulf of Alaska, even in cases where it does not limit total phytoplankton production, suggests that it may influence carbon export in this and other polar ecosystems.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

The effect of vitamin B₁₂ on phytoplankton growth and community structure in the Gulf of Alaska

Koch

Marcoval

Panzeca

et al. 2011

Limnology & Oceanography

116

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“…At low latitudes, in the absence of an upwelling, the greater temperature differential between the warm upper mixed layer and the cooler deeper waters decreases the extent of eddy diffusion of nutrients from the deeper phosphate-and combined nitrogen-rich waters to the surface nutrient-poor waters. The impact on the supply of phytoplankton-available iron of such decreased eddy diffusion is much less than for phosphate and combined nitrogen, since phytoplankton-available iron input to the ocean is mainly aeolian (discussed by Archer et al 2000;Hutchins et al 2002;Parekh et al 2004;Boyd 2007;Boyd et al 2010b). The restriction on the nutrient flux from the deep ocean means even less new productivity and even less potential for continued export production from this already nutrient-limited ocean.…”

Section: Marine Phytoplanktonmentioning

confidence: 99%

Algal and aquatic plant carbon concentrating mechanisms in relation to environmental change

et al. 2011

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Abstract.Carbon dioxide concentrating mechanisms (also known as inorganic carbon concentrating mechanisms; both abbreviated as CCMs) presumably evolved under conditions of low CO 2 availability. However, the timing of their origin is unclear since there are no sound estimates from molecular clocks, and even if there were, there are no proxies for the functioning of CCMs. Accordingly, we cannot use previous episodes of high CO 2 (e.g. the Palaeocene-Eocene Thermal Maximum) to indicate how organisms with CCMs responded. Present and predicted environmental change in terms of increased CO 2 and temperature are leading to increased CO 2 and HCO 3 -and decreased CO 3 2-and pH in surface seawater, as well as decreasing the depth of the upper mixed layer and increasing the degree of isolation of this layer with respect to nutrient flux from deeper waters. The outcome of these forcing factors is to increase the availability of inorganic carbon, photosynthetic active radiation (PAR) and ultraviolet B radiation (UVB) to aquatic photolithotrophs and to decrease the supply of the nutrients (combined) nitrogen and phosphorus and of any non-aeolian iron. The influence of these variations on CCM expression has been examined to varying degrees as acclimation by extant organisms. Increased PAR increases CCM expression in terms of CO 2 affinity, while increased UVB has a range of effects in the organisms examined; little relevant information is available on increased temperature. Decreased combined nitrogen supply generally increases CO 2 affinity, decreased iron availability increases CO 2 affinity, and decreased phosphorus supply has varying effects on the organisms examined. There are few data sets showing interactions among the observed changes, and even less information on genetic (adaptation) 2 changes in response to the forcing factors. In freshwaters, changes in phytoplankton species composition may alter with environmental change with consequences for frequency of species with or without CCMs. The information available permits less predictive power as to the effect of the forcing factors on CCM expression than for their overall effects on growth. CCMs are currently not part of models as to how global environmental change has altered, and is likely to further alter, algal and aquatic plant primary productivity.Keywords CO 2 concentrating mechanism -combined nitrogen -inorganic carboniron -mixing depth -photosynthetically active radiation -phosphorus -temperature -UVA-UVB Abbreviations CCM CO 2 concentrating mechanism DOC Dissolved organic carbon PAR Photosynthetically active radiation (400-700 nm)Rubisco Ribulose bisphosphate carboxylase-oxygenase UVA Ultraviolet A radiation (320-400 nm) UVB Ultraviolet B radiation (280-320 nm)

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“…It is not clear, however, why AMZ settings do not support other nitrogen fixers whose physiological traits are more compatible with the ambient physicochemical conditions. As another possibility, iron limitation demonstrably hinders primary production in the ETSP AMZ region (63). Severe iron limitation could exclude nitrogen-fixing cyanobacteria whose iron requirements are particularly high (64).…”

Section: How Are Microbial Communities and Biogeochemical Processes Cmentioning

confidence: 99%

Microbial oceanography of anoxic oxygen minimum zones

Ulloa

Canfield

DeLong

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

376

403

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Vast expanses of oxygen-deficient and nitrite-rich water define the major oxygen minimum zones (OMZs) of the global ocean. They support diverse microbial communities that influence the nitrogen economy of the oceans, contributing to major losses of fixed nitrogen as dinitrogen (N 2 ) and nitrous oxide (N 2 O) gases. Anaerobic microbial processes, including the two pathways of N 2 production, denitrification and anaerobic ammonium oxidation, are oxygen-sensitive, with some occurring only under strictly anoxic conditions. The detection limit of the usual method (Winkler titrations) for measuring dissolved oxygen in seawater, however, is much too high to distinguish low oxygen conditions from true anoxia. However, new analytical technologies are revealing vanishingly low oxygen concentrations in nitriterich OMZs, indicating that these OMZs are essentially anoxic marine zones (AMZs). Autonomous monitoring platforms also reveal previously unrecognized episodic intrusions of oxygen into the AMZ core, which could periodically support aerobic metabolisms in a typically anoxic environment. Although nitrogen cycling is considered to dominate the microbial ecology and biogeochemistry of AMZs, recent environmental genomics and geochemical studies show the presence of other relevant processes, particularly those associated with the sulfur and carbon cycles. AMZs correspond to an intermediate state between two "end points" represented by fully oxic systems and fully sulfidic systems. Modern and ancient AMZs and sulfidic basins are chemically and functionally related. Global change is affecting the magnitude of biogeochemical fluxes and ocean chemical inventories, leading to shifts in AMZ chemistry and biology that are likely to continue well into the future.

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Phytoplankton iron limitation in the Humboldt Current and Peru Upwelling

Cited by 215 publications

References 39 publications

The effect of vitamin B₁₂ on phytoplankton growth and community structure in the Gulf of Alaska

The effect of vitamin B₁₂ on phytoplankton growth and community structure in the Gulf of Alaska

Algal and aquatic plant carbon concentrating mechanisms in relation to environmental change

Microbial oceanography of anoxic oxygen minimum zones

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Phytoplankton iron limitation in the Humboldt Current and Peru Upwelling

Cited by 215 publications

References 39 publications

The effect of vitamin B12 on phytoplankton growth and community structure in the Gulf of Alaska

The effect of vitamin B12 on phytoplankton growth and community structure in the Gulf of Alaska

Algal and aquatic plant carbon concentrating mechanisms in relation to environmental change

Microbial oceanography of anoxic oxygen minimum zones

Contact Info

Product

Resources

About

The effect of vitamin B₁₂ on phytoplankton growth and community structure in the Gulf of Alaska

The effect of vitamin B₁₂ on phytoplankton growth and community structure in the Gulf of Alaska