Cloning, localization and characterization of a Zn transporter (Zip10) from fly, dog, and human (893.39)

Abstract

Background: Zn is implicated as having a role in the formation of calcium oxalate (CaOx) kidney stones. Our studies indicate that Slc39a10 (Zip10) may be important in this process. Zip10 has identifiable sequences in human, dog and fly (Drosophila). As we are interested in a translational model of kidney stones, we examined Zip10 from all 3 species.Methods: Zip10 cDNAs were cloned from human & dog (kidney) and fly (whole fly) using gene specific primers and RT‐PCR. Clones were put into a Xenopus oocyte expression vector so that Zip10 function could be measured. Three days post‐injection, oocytes were pre‐incubated in ND96, followed by 30 min in ND96 + 10 μM ZnCl + the PET isotope 63Zn, with varying pHs and ion concentrations. 63Zn uptake was measured in each oocyte using a gamma counter. Zip10 oocytes were also checked using electrophysiology (ion selective electrodes & voltage clamping).Results: Zip10 mRNA & protein are found in gut and kidney. In mouse kidney, Zip10 antibodies stained the apical membrane of proximal tubules. All clones transported 63Zn (nmol/oocyte/hr): hZip10 = 70±8; cZip10= 44 ±7; dZip10= 64 ±8; water = 0.4 ±0.1. These clones seem to be most active at pH 7.5 as uptakes decreased at 5.5 and 8.5. Replacement of either all Cl‐ (with HCO3舉) or all Na+ (with choline) reduced Zn‐uptake. Electrophysiology revealed no evidence of I or V changes with addition of Zn (electroneutral).Conclusions: Our results indicated that all three Zip10 clones transport Zn2+. Understanding the detailed mechanisms of these Zn transporters in oocytes presents the opportunity to better use our Drosophila model in the study of CaOx stone formation and absorption.Grant Funding Source: Supported by DK83007, DK92408