Selenite (HSeO3-) is a monovalent anion of the essential trace element and micronutrient selenium (Se). In therapeutic concentrations, HSeO3- has been studied for treating certain cancers, serious inflammatory disorders, and septic shock. Little is known, however, about HSeO3- uptake into mammalian cells; until now, no mammalian HSeO3- uptake transporter has been identified. The ubiquitous mammalian ZIP8 divalent cation transporter (encoded by the SLC39A8 gene) is bicarbonate-dependent, moving endogenous substrates (Zn2+, Mn2+, Fe2+ or Co2+) and nonessential metals such as Cd2+ into the cell. Herein we studied HSeO3- uptake in: human and mouse cell cultures, shRNA-knockdown experiments, Xenopus oocytes, wild-type mice and two transgenic mouse lines having genetically altered ZIP8 expression, and mouse erythrocytes ex vivo. In mammalian cell culture, excess Zn2+ levels and/or ZIP8 over-expression can be associated with diminished viability in selenite-treated cells. Intraperitoneal HSeO3- causes the largest ZIP8-dependent increases in intracellular Se content in liver, followed by kidney, heart, lung and spleen. In every model system studied, HSeO3- uptake is tightly associated with ZIP8 protein levels and sufficient Zn2+ and HCO3- concentrations, suggesting that the ZIP8-mediated electroneutral complex transported contains three ions: Zn2+/(HCO3-)(HSeO3-). Transporters having three different ions in their transport complex are not without precedent. Although there might be other HSeO3- influx transporters as yet undiscovered, data herein suggest that mammalian ZIP8 plays a major role in HSeO3- uptake.
Keywords: ZIP8; membrane-bound transporter; micronutrient; selenite; zinc.