Differential gene expression of organic anion transporters in male and female rats

Contribution of organic anion transporters to the renal uptake of anionic compounds and nucleoside derivatives in rat

Our previous kinetic analyses have shown that rat organic anion transporter 1 (rOat1; Slc22a6) and rOat3 (Slc22a8) are responsible for the renal uptake of p-aminohippurate and pravastatin, respectively. In this study, their contribution to the renal uptake of organic anions and nucleoside derivatives was examined by investigating the uptake by rOat1- and rOat3-expressing cells and kidney slices. Transfection of rOat1 resulted in an increase of the uptake of temocaprilat (Km = 0.56 microM), 2,4-dichlorophenoxyacetate (2,4-D; Km = 10 microM), and 3'-azido-3'-deoxythymidine (AZT; Km = 43 microM). rOat3-expressing cells showed significant uptake of temocaprilat (Km = 1.4 microM), estrone sulfate (Km = 5.3 microM), dehydroepiandrosterone sulfate (DHEAS; Km = 12 microM), and benzylpenicillin (PCG; Km = 85 microM). All the test compounds were accumulated in kidney slices in a carrier-mediated manner, although the saturable components of AZT and acyclovir were small. The Km of 2,4-D uptake by kidney slices was comparable with that of rOat1, and the corresponding values of DHEAS and PCG were similar to those of rOat3. The uptake of estrone sulfate and temocaprilat by kidney slices consisted of two saturable components, with the Km values of their high-affinity components being similar to those for rOat3 (estrone sulfate), and rOat1 and rOat3 (temocaprilat), respectively. These results suggest that the renal uptake of 2,4-D is mainly accounted for by rOat1 and the uptake of PCG and DHEAS by rOat3, and rOat3 is partly involved in the renal uptake of temocaprilat and estrone sulfate.

Endocrine regulation of rat organic anion transporters

Messenger RNA levels of rat organic anion transporter 1 (Oat1; Slc22a6) and Oat2 (Slc22a7) in kidney and Oat3 (Slc22a8) in liver are gender-predominant. Oat1 and Oat3 are male-predominant, whereas Oat2 is female-predominant. Gonadectomized and hypophysectomized (HX) rats were studied to determine whether sex steroids and/or growth hormone (GH) are responsible for these gender-divergent patterns. GH was administered to HX rats by two daily injections (simulating male secretion) or continuous infusion (simulating female secretion). Oat1 mRNA levels, normally higher in male than female kidney, were lowered by gonadectomy and HX in male rats, but not in females. Additionally, GH injections or infusion did not alter Oat1 levels in HX rats. Oat2 mRNA levels, typically much higher in female than in male kidney, were unaffected by gonadectomy. However, HX dramatically decreased Oat2 in female kidney without altering male levels. GH administered by continuous infusion increased Oat2 in kidneys of both HX male and female rats, whereas injections had no affect. Gonadectomy reduced Oat3 mRNA levels in male livers without affecting levels in female livers. In contrast, HX decreased male and elevated female Oat3 mRNA. GH injections did not significantly change Oat3 mRNA levels in HX rats, but infusion decreased Oat3 mRNA in liver. In conclusion, androgens, but not GH, are responsible for the Oat1 mRNA gender difference in kidney; the female GH secretion pattern is responsible for the Oat2 mRNA gender difference in kidney; and both androgens and the female GH secretion pattern are responsible for the Oat3 mRNA gender difference in liver.

Gender difference in the urinary excretion of organic anions in rats

This study was aimed at clarifying the gender differences in the urinary excretion of organic anions and the gene expression of organic anion transporters in rats. The renal clearance with regard to the plasma concentration (CL(urine,p)) of taurocholate, dibromosulfophthalein (DBSP), and zenarestat, all substrates and/or inhibitors of organic anion transporting polypeptide 1 (Oatp1), was much higher in female than in male rats. The following results imply that the transport system(s) for the reabsorption of zenarestat across the luminal side exhibits a gender difference: 1) the renal uptake clearance assessed by an in vivo integration plot analysis of zenarestat from the blood side does not show any clear gender differences; 2) the renal clearance with regard to the kidney concentration (CL(urine,k)) of zenarestat in female rats was approximately 30 times higher than in male rats; and 3) both CL(urine,p) and CL(urine,k) were increased in male rats by the coinfusion of DBSP, which is an inhibitor of organic anion transporters. Northern and Western blot analyses confirmed a previous finding that the gene expression of Oatp1, which is localized at the apical plasma membrane of the kidney, was much higher in the kidneys of male rats. Overall, a gender difference in urinary excretion is commonly observed for several organic anions, including Oatp1 substrates and inhibitors, and Oatp1 and/or transporters that have a similar substrate specificity to Oatp1 could be involved in such a phenomenon involving its substrates.

Impaired organic anion transport in kidney and choroid plexus of organic anion transporter 3 (Oat3 (Slc22a8)) knockout mice

To begin to develop in vivo model systems for the assessment of the contributions of specific organic anion transporter (OAT) family members to detoxification, development, and disease, we carried out a targeted disruption of the murine organic anion transporter 3 (Oat3) gene. Surviving Oat3(-/-) animals appear healthy, are fertile, and do not exhibit any gross morphological tissue abnormalities. No Oat3 mRNA expression was detected in kidney, liver, or choroid plexus (CP) of Oat3(-/-) mice. A distinct phenotype manifested by a substantial loss of organic anion transport capacity in kidney and CP was identified. Uptake sensitive to inhibition by bromosulfophthalein or probenecid was observed for taurocholate, estrone sulfate, and para-aminohippurate in renal slices from wild-type mice, whereas in Oat3(-/-) animals transport of these substances was greatly reduced. No discernable differences in uptake were observed between hepatic slices from wild-type and Oat3(-/-) littermates, suggesting Oat3 does not play a major role in hepatic organic anion uptake. Cellular accumulation of fluorescein was reduced by approximately 75% in CP from Oat3(-/-) mice. However, capillary accumulation of fluorescein-methotrexate was unchanged, indicating the effects of Oat3 loss are restricted to the entry step and that Oat3 is localized to the apical membrane of CP. These data indicate a key role for Oat3 in systemic detoxification and in control of the organic anion distribution in cerebrospinal fluid.