Cysteine Enhances Bioavailability of Copper to Marine Phytoplankton

Walsh, Michael J.; Goodnow, Sarah D.; Vezeau, Grace E.; Richter, Lubna V.; Ahner, Beth A.

doi:10.1021/acs.est.5b02112

Cited by 43 publications

(59 citation statements)

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“…Moreover, if FeL 2 is highly bioavailable to phytoplankton, as suggested for EPS (Hassler et al, 2011b(Hassler et al, , 2014, this pool could potentially benefit phytoplankton growth (e.g., Hassler et al, 2011b). In this case, weak ligands would be important for iron phytoplankton nutrition, as reported for other metals such as Zn (Aristilde et al, 2012) and Cu (Walsh et al, 2015).…”

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

confidence: 89%

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

confidence: 89%

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

2017

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“…Few studies describe the role of polyphosphate bodies in marine algae however the status of high density P bodies in the marine seaweed Macrocystis pyrifera have also been observed to alter with varying water quality characteristics. 49 Detailed investigations on cell morphology along with elemental analyses of the marine algae, Tetraselmis suecica, indicated that after Cu exposure, Cu was stored in P-rich bodies with characteristics similar to polyphosphate bodies. 50 Daniels and Chamberlain 45 also reported that Cu was associated with P, S and Ca bodies in the Cu-tolerant marine alga Amphora veneta (as was found in this study); however, they also observed that Cu was found in spherical bodies that were not rich in P. Polyphosphate bodies in microalgae clearly play a role in the detoxification of Cu in microalgae; however, whether this role is via direct binding of Cu to polyphosphates or other binding sites within polyphosphate granules, or other compartments rich in S and Ca, requires further investigation and is likely to be species specific.…”

Section: Discussionmentioning

confidence: 99%

Copper Uptake, Intracellular Localization, and Speciation in Marine Microalgae Measured by Synchrotron Radiation X-ray Fluorescence and Absorption Microspectroscopy

Adams

Dillon

Vogt

et al. 2016

Environ. Sci. Technol.

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Metal toxicity to aquatic organisms depends on the speciation of the metal and its binding to the critical receptor site(s) (biotic ligand) of the organism. The intracellular nature of the biotic ligand for Cu in microalgal cells was investigated using the high elemental sensitivity of microprobe synchrotron radiation X-ray fluorescence (SR-XRF) and X-ray absorption near-edge spectroscopy (XANES). The marine microalgae, Ceratoneis closterium, Phaeodactylum tricornutum, and Tetraselmis sp. were selected based on their varying sensitivities to Cu (72-h 50% population growth inhibitions of 8–47 μg Cu/L). Intracellular Cu in control cells was similar for all three species (2.5–3.2 × 10–15 g Cu/cell) and increased 4-fold in C. closterium and Tetraselmis sp. when exposed to copper, but was unchanged in P. tricornutum (72-h exposure to 19, 40, and 40 μg Cu/L, respectively). Whole cell microprobe SR-XRF identified endogenous Cu in the central compartment (cytoplasm) of control (unexposed) cells. After Cu exposure, Cu was colocated with organelles/granules dense in P, S, Ca, and Si and this was clearly evident in thin sections of Tetraselmis sp. XANES indicated coexistence of Cu(I) and Cu(II) in control and Cu-exposed cells, with the Cu ligand (e.g., phytochelatin) in P. tricornutum different from that in C. closterium and Tetraselmis sp. This study supports the hypothesis that Cu(II) is reduced to Cu(I) and that polyphosphate bodies and phytochelatins play a significant role in the internalization and detoxification of Cu in marine microalgae.

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“…Cu(II) is reduced to Cu(I) within 2-40 min by Cu(I) binding thiols like glutathione and cysteine (Leal and van den Berg, 1998). Cu-limitation has been demonstrated to increase rates of cell surface reduction of Cu(II) to Cu(I) in Emiliania huxleyi (Walsh et al, 2015). They demonstrated that cysteine can increase the bioavailability of copper to copper-limited cells through the reductive release of Cu(I) from Cu(II) ligands such as EDTA.…”

Section: Implications For Thaumarchaeotamentioning

confidence: 99%

“…The bloom starts when the free Cu ′ is already very low (Figure 5A), indicating that the availability of inorganic Cu ′ , whether as Cu(I) or as Cu(II), is not important. We hypothesize that the copper arrives at the cell as a Cu(I)-thiol species, where there is a direct exchange of copper to Cubinding groups on the cell wall, allowing active transport of the copper into the cell through a high affinity transporter, as described for E. huxleyi (Walsh et al, 2015). We suspect that the low Cu 2+ is not driven directly by the Thaumarchaeota through production of L 1 , but rather that L 1 is released independently, likely by other microorganisms in the water column or from the sediment and pore waters.…”

Section: Implications For Thaumarchaeotamentioning

confidence: 99%

“…They differ in this regard from ammonia oxidizing bacteria (AOB), which use Fe-dependent metalloenzymes for many of the same functions. AOA are one of several organisms demonstrated in culture studies to be limited by the availability of copper (Amin et al, 2013), along with methane oxidizing archaea (Glass and Orphan, 2012) and some phytoplankton (Annett et al, 2008;Guo et al, 2010;Walsh et al, 2015). AOA are significant contributors to nitrification and thus to the global nitrogen cycle (Francis et al, 2005;Beman et al, 2010) contributing significantly to nitrous oxide (N 2 O) fluxes (Santoro and Casciotti, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Chemical Speciation of Copper in a Salt Marsh Estuary and Bioavailability to Thaumarchaeota

2017

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Cysteine Enhances Bioavailability of Copper to Marine Phytoplankton

Cited by 43 publications

References 50 publications

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

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

Copper Uptake, Intracellular Localization, and Speciation in Marine Microalgae Measured by Synchrotron Radiation X-ray Fluorescence and Absorption Microspectroscopy

Chemical Speciation of Copper in a Salt Marsh Estuary and Bioavailability to Thaumarchaeota

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