Bilitranslocase is involved in the uptake of bromosulfophthalein in rat and human liver.

Hepatic disposition of bromosulfophthalein (BSP), bilirubin and bile salts partially overlap, as these anions share both uptake and excretion mechanisms. Multiple organic anion transporters mediate hepatic BSP uptake, i.e. members of the SLCO and SLC22 gene families and bilitranslocase (TCDB #2.A.65.1.1). This study aimed at evaluating the relative contribution of bilitranslocase in BSP uptake in precision-cut human and rat liver slices. To this purpose, two different anti-sequence bilitranslocase antibodies were used as specific, functional inhibitors of bilitranslocase. The intact liver physiology was accurately reproduced in this BSP uptake assay, since uptake was strongly temperature-dependentand inhibited by hepatotropic organic anions, such as 50 nM bilirubin, 1 µM nicotinic acid, 2 µM digoxin, 5 µMindocyanine green and 100 µM taurocholate. The bilitranslocase antibodies inhibited BSP uptake both in rat and human liver slices. The combined use of bilitranslocase antibodies and taurocholate caused additive-type inhibition, confirming that bilitranslocase is not a bile salt transporter; by contrast, bilirubin caused no additive-type inhibition. In conclusion this data, indicate the role of the bilirubin transporter bilitranslocase as one of the transporters involved in the uptake of anions like BSP in parallel with other organic anion carriers. Moreover this data indicate the value of precision-cut liver slices for phenotypic drug uptake studies.

Uptake of bilirubin into HepG2 cells assayed by thermal lens spectroscopy. Function of bilitranslocase.

Bilitranslocase is a carrier protein localized at the basolateral domain of the hepatocyte plasma membrane. It transports various organic anions, including bromosulfophthalein and anthocyanins. Functional studies in subcellular fractions enriched in plasma membrane revealed a high-affinity binding site for bilirubin, associated with bilitranslocase. The aim of this work was to test whether the liver uptake of bilirubin depends on the activity of bilitranslocase. To this purpose, an assay of bilirubin uptake into HepG2 cell cultures was set up. The transport assay medium contained bilirubin at a concentration of approximately 50 nm in the absence of albumin. To analyse the relative changes in bilirubin concentration in the medium throughout the uptake experiment, a highly sensitive thermal lens spectrometry method was used. The mechanism of bilirubin uptake into HepG2 cells was investigated by using inhibitors such as anti-sequence bilitranslocase antibodies, the protein-modifying reagent phenylmethanesulfonyl fluoride and diverse organic anions, including nicotinic acid, taurocholate and digoxin. To validate the assay further, both bromosulfophthalein and indocyanine green uptake in HepG2 cells was also characterized. The results obtained show that bilitranslocase is a carrier with specificity for both bilirubin and bromosulfophthalein, but not for indocyanine green.

Characterization of electrogenic bromosulfophthalein transport in carnation petal microsomes and its inhibition by antibodies against bilitranslocase.

Bilitranslocase is a rat liver plasma membrane carrier, displaying a high-affinity binding site for bilirubin. It is competitively inhibited by grape anthocyanins, including aglycones and their mono- and di-glycosylated derivatives. In plant cells, anthocyanins are synthesized in the cytoplasm and then translocated into the central vacuole, by mechanisms yet to be fully characterized. The aim of this work was to determine whether a homologue of rat liver bilitranslocase is expressed in carnation petals, where it might play a role in the membrane transport of anthocyanins. The bromosulfophthalein-based assay of rat liver bilitranslocase transport activity was implemented in subcellular membrane fractions, leading to the identification of a bromosulfophthalein carrier (K(M) = 5.3 microm), which is competitively inhibited by cyanidine 3-glucoside (Ki = 51.6 microm) and mainly noncompetitively by cyanidin (Ki = 88.3 microm). Two antisequence antibodies against bilitranslocase inhibited this carrier. In analogy to liver bilitranslocase, one antibody identified a bilirubin-binding site (Kd = 1.7 nm) in the carnation carrier. The other antibody identified a high-affinity binding site for cyanidine 3-glucoside (Kd = 1.7 microm) on the carnation carrier only, and a high-affinity bilirubin-binding site (Kd = 0.33 nm) on the liver carrier only. Immunoblots showed a putative homologue of rat liver bilitranslocase in both plasma membrane and tonoplast fractions, isolated from carnation petals. Furthermore, only epidermal cells were immunolabeled in petal sections examined by microscopy. In conclusion, carnation petals express a homologue of rat liver bilitranslocase, with a putative function in the membrane transport of secondary metabolites.