Phenotypic differences in PFIC2 and BRIC2 correlate with protein stability of mutant Bsep and impaired taurocholate secretion in MDCK II cells

Progressive familial cholestasis (PFIC) 2 and benign recurrent intrahepatic cholestasis (BRIC) 2 are caused by mutations in the bile salt export pump (BSEP, ABCB11) gene; however, their prognosis differs. PFIC2 progresses to cirrhosis and requires liver transplantation, whereas BRIC2 is clinically benign. To identify the molecular mechanism(s) responsible for the phenotypic differences, eight PFIC2 and two BRIC2 mutations were introduced in rat Bsep, which was transfected in MDCK II cells. Taurocholate transport activity, protein expression, and subcellular distribution of these mutant proteins were studied in a polarized MDCK II monolayer. The taurocholate transport activity was approximately half of the wild-type (WT) in BRIC2 mutants (A570T and R1050C), was substantially less in two PFIC2 mutants (D482G and E297G), and was almost abolished in six other PFIC2 mutants (K461E, G982R, R1153C, R1268Q, 3767–3768insC, and R1057X). Bsep protein expression levels correlated closely with transport activity, except for R1057X. The half-life of the D482G mutant was shorter than that of the WT (1.35 h vs. 3.49 h in the mature form). BRIC2 mutants and three PFIC mutants (D482G, E297G, and R1057X) were predominantly distributed in the apical membrane. The other PFIC2 mutants remained intracellular. The R1057X mutant protein was stably expressed and trafficked to the apical membrane, suggesting that the COOH-terminal tail is required for transport activity but not for correct targeting. In conclusion, taurocholate transport function was impaired in proportion to rapid degradation of Bsep protein in the mutants, which were aligned in the following order: A570T and R1050C > D482G > E297G > K461E, G982R, R1153C, R1268Q, 3767–3768insC, and R1057X. These results may explain the phenotypic difference between BRIC2 and PFIC2.

N-glycosylation controls functional activity of Oatp1, an organic anion transporter

Rat Oatp1 (Slc21a1) is an organic anion-transporting polypeptide believed to be an anion exchanger. To characterize its mechanism of transport, Oatp1 was expressed in Saccharomyces cerevisiae under control of the GAL1 promoter. Protein was present at high levels in isolated S. cerevisiae secretory vesicles but had minimal posttranslational modifications and failed to exhibit taurocholate transport activity. Apparent molecular mass ( M) of Oatp1 in yeast was similar to that of unmodified protein, ∼62 kDa, whereas in liver plasma membranes Oatp1 has an M of ∼85 kDa. To assess whether underglycosylation of Oatp1 in yeast suppressed functional activity, Oatp1 was expressed in Xenopus laevis oocytes with and without tunicamycin, a glycosylation inhibitor. With tunicamycin, M of Oatp1 decreased from ∼72 to ∼62 kDa and transport activity was nearly abolished. Mutations to four predicted N-glycosylation sites on Oatp1 (Asn to Asp at positions 62, 124, 135, and 492) revealed a cumulative effect on function of Oatp1, leading to total loss of taurocholate transport activity when all glycosylation sites were removed. M of the quadruple mutant was ∼ 62 kDa, confirming that these asparagine residues are sites of glycosylation in Oatp1. Relatively little of the quadruple mutant was able to reach the plasma membrane, and most remained in unidentified intracellular compartments. In contrast, two of the triple mutants tested (N62/124/135D and N124/135/492D) were present in the plasma membrane fraction yet exhibited minimal transport activity. These results demonstrate that both membrane targeting and functional activity of Oatp1 are controlled by the extent of N-glycosylation.

Substitution of Trp1242 of TM17 alters substrate specificity of human multidrug resistance protein 3

Multidrug resistance protein 3 (MRP3) is an ATP-dependent transporter of 17β-estradiol 17β(d-glucuronide) (E217βG), leukotriene C4 (LTC4), methotrexate, and the bile salts taurocholate and glycocholate. In the present study, the role of a highly conserved Trp residue at position 1242 on MRP3 transport function was examined by expressing wild-type MRP3 and Ala-, Cys-, Phe-, Tyr-, and Pro-substituted mutants in human embryonic kidney 293T cells. Four MRP3-Trp1242 mutants showed significantly increased E217βG uptake, whereas transport by the Pro mutant was undetectable. Similarly, the Pro mutant did not transport LTC4. By comparison, LTC4transport by the Ala, Cys, Phe, and Tyr mutants was reduced by ∼35%. The Ala, Cys, Phe, and Tyr mutants all showed greatly reduced methotrexate and leucovorin transport, except the Tyr mutant, which transported leucovorin at levels comparable with wild-type MRP3. In contrast, the MRP3-Trp1242 substitutions did not significantly affect taurocholate transport or taurocholate and glycocholate inhibition of E217βG uptake. Thus Trp1242 substitutions markedly alter the substrate specificity of MRP3 but leave bile salt binding and transport intact.

ATP-dependent transport of reduced glutathione in yeast secretory vesicles

Turnover of cellular reduced glutathione (GSH) is accomplished predominantly by export into the extracellular space; however, the plasma membrane transport mechanisms that mediate GSH efflux are not well characterized. The present study examined GSH transport using secretory vesicles isolated from the sec6-4 mutant strain of Saccharomyces cerevisiae. In contrast with studies in mammalian membrane vesicles, GSH transport in yeast secretory vesicles was mediated largely by an ATP-dependent, low-affinity pathway (Km 19±5 mM). ATP-dependent [3H]GSH transport was cis-inhibited by substrates of the yeast YCF1 transporter, including sulphobromophthalein, glutathione S-conjugates and the alkaloid verapamil, and was competitively inhibited by S-(2,4-dinitrophenyl)glutathione (DNP-SG). Similarly, GSH competitively inhibited ATP-dependent [3H]DNP-SG transport, with a Ki of 18±2 mM, but had no effect on ATP-dependent [3H]taurocholate transport. ATP-dependent GSH transport was not affected by either membrane potential or pH-gradient uncouplers, but was inhibited by 4,4´-di-isothiocyanatostilbene-2,2´-disulphonate, probenecid and sulphinpyrazone, which are inhibitors of mrp1 and mrp2, mammalian homologues of the yeast YCF1 transporter. Western blot analysis of the secretory vesicle membrane fraction confirmed the presence of Ycf1p. These results provide the first direct evidence for low-affinity, ATP-dependent transport of GSH, and demonstrate that this ATP-dependent pathway displays kinetic characteristics similar to those of the yeast YCF1 transporter.