Towards Mechanistic Understanding of Mercury Availability and Toxicity to Aquatic Primary Producers

Dranguet, Perrine; Flück, Rebecca; Regier, Nicole; Cosio, Claudia; Faucheur, Séverine Le

doi:10.2533/chimia.2014.799

Cited by 20 publications

(25 citation statements)

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“…Bravo et al () suggested that in eutrophic lakes receiving low inputs of terrigenous OM, sediment Hg concentrations are determined by atmospheric inputs. Besides dissolved Hg II , lipophilic Hg compounds such as uncharged HgCl 2 and CH 3 HgCl complexes are important for the uptake by algae (Mason et al ; Dranguet et al ), but binding to terrestrial DOM limits the uptake of both metals (e.g., (Brooks et al ; Schartup et al b ). Enhanced photo‐oxidation of DOM‐Hg under higher TSI might enhance Hg II uptake by algae, in a similar way as found for Cu (Moffett et al ; Sander et al ; Shank et al ).…”

Section: Resultsmentioning

confidence: 99%

“…Oxidized dissolved Hg (Hg II ‐species such as HgCl 2 ) and methylmercury (CH 3 HgX, (MeHg)) are the dominant species taken up. Lipophilic CH 3 HgCl has a higher bioaccumulation factor than other Hg II ‐species, whereas DOM‐bound Hg appears to decrease uptake by algae (Dranguet et al ; Le Faucheur et al ; Schartup et al b ). Direct uptake of dissolved or gaseous elemental mercury (GEM) by phytoplankton seems to be of minor importance as no detectable accumulation of Hg could be observed when GEM was used in bioaccumulation experiments (Le Faucheur et al ).…”

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confidence: 99%

“…Transport by dissolved organic matter (DOM) is the major pathway of Hg from catchments into aquatic systems (Driscoll et al 1995). In freshwater systems and estuaries, algae have been shown to accumulate Hg from the water phase and influence Hg cycling by affecting its concentrations, speciation, and transport to the sediments (Mason et al 1996;Pickhardt et al 2002;Fitzgerald et al 2007;Pickhardt and Fisher 2007;Dranguet et al 2014;Le Faucheur et al 2014). The mechanism of Hg uptake by phytoplankton is not well understood, but could involve both, facilitated transport and diffusion (Dranguet et al 2014;Le Faucheur et al 2014).…”

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confidence: 99%

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Solar irradiance and primary productivity controlled mercury accumulation in sediments of a remote lake in the Southern Hemisphere during the past 4000 years

Biester

Pérez-Rodríguez

Gilfedder

et al. 2017

Limnology & Oceanography

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Mercury (Hg) is a toxic trace element known to highly accumulate in aquatic biota and uptake by algae is the main entry‐point into the aquatic food chain. However, the effect of changes in solar irradiance and climatic conditions on Hg uptake by algae is largely unknown. We analyzed the link between sediment Hg accumulation, cyclic changes in total solar irradiance (TSI), and related changes in lake productivity as well as climate during the past 4.5 thousand years (kyr) in sediments of a small highly productive lake in Southern Patagonia (53°S). The analyses encompass proxies for TSI (based on 10Be), sediment geochemical composition, and lake productivity (FTIR spectra, and hydrogen‐index). The sediment record shows high concentrations of organic matter (median 70%) and strong variations in Hg accumulation rates (14–53 μg m2 yr−1) which correspond to changes in aquatic productivity and TSI. Accumulation of Hg was highest during dryer periods when irradiance and lake productivity was high. During these periods, accumulation was up to fourfold higher compared to those of lower TSI, lower productivity, and wetter climatic conditions. Higher amounts of algae biomass can increase Hg scavenging by organic particles and Hg export to the sediment. To obtain mass balance, we assume that the increase in sediment Hg accumulation rates during periods of lower Hg fluxes from the catchment (drier) caused a decrease in water phase Hg and in rates of Hg evasion from the lake.

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Section: Resultsmentioning

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Solar irradiance and primary productivity controlled mercury accumulation in sediments of a remote lake in the Southern Hemisphere during the past 4000 years

Biester

Pérez-Rodríguez

Gilfedder

et al. 2017

Limnology & Oceanography

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“…Mercury (Hg) contamination of freshwaters arises from the deposition of atmospheric Hg (dry settling or rainfall), polluted soils runoffs, industrial effluents, gold-mining and reemission from historical contaminated systems ( [1,2]). It subsequently settles in the sediment of lakes, rivers or bays where it is transformed into methylmercury (MeHg), absorbed by primary producers, transferred to primary and secondary consumers, and accumulates especially in long-lived predatory species, e.g., shark and swordfish.…”

Section: Introductionmentioning

confidence: 99%

“…Typical environmental concentrations measured in rivers and lakes range between 0.003 and 30 nM THg ( [5]). Both IHg and MeHg are mainly bound to dissolved organic matter (DOM) ( [1,6,7]) in particular to thiol (RSH) groups. For the fraction of Hg not bound with DOM, water chemistry (e.g., pH and chloride concentration) controls its distribution among different dissolved chemical species and complexes ( [8,9]).…”

Section: Introductionmentioning

confidence: 99%

Molecular Effects of Inorganic and Methyl Mercury in Aquatic Primary Producers: Comparing Impact to A Macrophyte and A Green Microalga in Controlled Conditions

Beauvais-Flück

Cosio

2018

Geosciences

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Mercury (Hg) remains hazardous in aquatic environments, because of its toxicity and high biomagnification in food webs. In phytoplankton and macrophytes, Hg compounds at high concentration have been reported to affect the growth, photosynthesis, and nutrient metabolism, as well as to induce oxidative stress and damage. Here, we reviewed the recent knowledge gained on cellular toxicity of inorganic and methyl Hg (IHg; MeHg) in aquatic primary producers at more relevant environmental concentrations, with a particular focus on omics data. In addition, we compared a case study conducted with transcriptomic on the green microalga Chlamydomonas reinhardtii and the macrophyte Elodea nuttallii. At lower concentrations, IHg and MeHg influenced similar gene categories, including energy metabolism, cell structure, and nutrition. In addition, genes involved in the cell motility in the microalgae, and in hormone metabolism in the macrophyte were regulated. At equivalent intracellular concentration, MeHg regulated more genes than IHg supporting a higher molecular impact of the former. At the organism level in C. reinhardtii, MeHg increased reactive oxygen species, while both IHg and MeHg increased photosynthesis efficiency, whereas in E. nuttallii MeHg induced anti-oxidant responses and IHg reduced chlorophyll content. Data showed differences, according to species and characteristics of life cycle, in responses at the gene and cellular levels, but evidenced a higher molecular impact of MeHg than IHg and different cellular toxicity pathways in aquatic primary producers.

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Mercury bioavailability, transformations, and effects on freshwater biofilms

Dranguet

Faucheur

2017

Enviro Toxic and Chemistry

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Mercury (Hg) compounds represent an important risk to aquatic ecosystems because of their persistence, bioaccumulation, and biomagnification potential. In the present review, we critically examine state-of-the-art studies on the interactions of Hg compounds with freshwater biofilms, with an emphasis on Hg accumulation, transformations, and effects. Freshwater biofilms contain both primary producers (e.g., algae) and decomposers (e.g., bacteria and fungi), which contribute to both aquatic food webs and the microbial loop. Hence they play a central role in shallow water and streams, and also contribute to Hg trophic transfer through their consumption. Both inorganic and methylated mercury compounds accumulate in biofilms, which could transform them mainly by methylation, demethylation, and reduction. Accumulated Hg compounds could induce diverse metabolic and physiological perturbations in the microorganisms embedded in the biofilm matrix and affect their community composition. The bioavailability of Hg compounds, their transformations, and their effects depend on their concentrations and speciation, ambient water characteristics, biofilm matrix composition, and microorganism-specific characteristics. The basic processes governing the interactions of Hg compounds with biofilm constituents are understudied. The development of novel conceptual and methodological approaches allowing an understanding of the chemo-and biodynamic aspects is necessary to improve the knowledge on Hg cycling in shallow water as well as to enable improved use of freshwater biofilms as potential indicators of water quality and to support better informed risk assessment. Environ Toxicol Chem 2017;36:3194-3205. # 2017 SETAC

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Towards Mechanistic Understanding of Mercury Availability and Toxicity to Aquatic Primary Producers

Cited by 20 publications

References 57 publications

Solar irradiance and primary productivity controlled mercury accumulation in sediments of a remote lake in the Southern Hemisphere during the past 4000 years

Solar irradiance and primary productivity controlled mercury accumulation in sediments of a remote lake in the Southern Hemisphere during the past 4000 years

Molecular Effects of Inorganic and Methyl Mercury in Aquatic Primary Producers: Comparing Impact to A Macrophyte and A Green Microalga in Controlled Conditions

Mercury bioavailability, transformations, and effects on freshwater biofilms

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