2007
DOI: 10.1897/06-395r.1
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Transfer and efflux of cadmium and silver in marine snails and fish fed pre‐exposed mussel prey

Abstract: Subcellular metal distribution may play an important role in the bioaccumulation and trophic transfer of metals in marine food chains. In the present study, we preexposed the green mussel Perna viridis to Ag and Cd and quantified their trophic transfer efficiencies to two predators (whelks [Thais clavigera] and fish [Terapon jarbua]). For the mussels, more Ag was distributed in the metal-rich granule (MRG) fraction following Ag exposure, and more Cd was distributed in the metallothionein-like protein following… Show more

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Cited by 10 publications
(2 citation statements)
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“…Sequestration by cellular ligands such as metallothionein, lysosomes, and mineralized organically based concretions appears to be one of the most commonly adopted strategies by invertebrates [15–17]. Nowadays, different biochemical fractionation techniques allow identification of subcellular distribution of metal in aquatic animals and permit quantification of the subcellular fates of metals in view of metal toxicity or metal transfer to a higher trophic level [17–19]. The soluble fraction is made up of metallothionein‐like proteins, but metals also target molecules such as enzymes [20,21], which seem to have an important role in the detoxification and toxicology of metal [22,23].…”
Section: Introductionmentioning
confidence: 99%
“…Sequestration by cellular ligands such as metallothionein, lysosomes, and mineralized organically based concretions appears to be one of the most commonly adopted strategies by invertebrates [15–17]. Nowadays, different biochemical fractionation techniques allow identification of subcellular distribution of metal in aquatic animals and permit quantification of the subcellular fates of metals in view of metal toxicity or metal transfer to a higher trophic level [17–19]. The soluble fraction is made up of metallothionein‐like proteins, but metals also target molecules such as enzymes [20,21], which seem to have an important role in the detoxification and toxicology of metal [22,23].…”
Section: Introductionmentioning
confidence: 99%
“…Sequestration by cellular ligands such as metallothionein, lysosomes, and mineralized organically based concretions appears to be one of the most commonly adopted strategies by invertebrates [15][16][17]. Nowadays, different biochemical fractionation techniques allow identification of subcellular distribution of metal in aquatic animals and permit quantification of the subcellular fates of metals in view of metal toxicity or metal transfer to a higher trophic level [17][18][19]. The soluble fraction is made up of metallothionein-like proteins, but metals also target molecules such as enzymes [20,21], which seem to have an important role in the detoxification and toxicology of metal [22,23].…”
Section: Introductionmentioning
confidence: 99%