Dynamics of metal subcellular distribution and its relationship with metal uptake in marine mussels

Abstract

We examined the dynamics of subcellular distribution of metals (Cd, Ag, and Zn) in the marine green mussel Perna viridis by partitioning the metals into the insoluble fraction (IF), heat-sensitive proteins (HSP), and metallothionein-like proteins (MTLP) during metal uptake and elimination. Variations in metal uptake and elimination then were correlated with the subcellular distributions of these metals. The IF and HSP were the first ligands to bind with the metals during the dissolved exposure, and more metals were found in the HSP when the metal influx rate was higher. However, to minimize toxicity, metals were redistributed from HSP to MTLP afterwards. The subcellular distribution of metals was dependent of the exposure route in the mussels. During dietary metal exposure, the metals attained equilibrium before they were assimilated and the metal assimilation efficiency was independent of the metal partitioning in different subcellular fractions. During the efflux, metals in the soluble fraction mediated depuration, whereas metals in the insoluble fraction acted as a final storage pool. Redistribution also may occur between the metal-sensitive and inactive pools without significant depuration as a secondary protective mechanism. We further demonstrated that the higher efflux rate of Ag and Cd was related to a higher partitioning in the MTLP and a lower partitioning in the IF. Our study shows that subcellular pools other than MTLP were involved in immediate metal handling in the bivalves. The wide dynamics of subcellular metal distribution suggests that the relevance of individual subcellular fractions is dependent on the exposure pathway.