Hydrophobic bile acids but not hydrophilic bile acids induce apoptosis in HCT116 cells. We expressed sodium-dependent bile acid transporters in HCT116 cells, and the intracellular concentration of hydrophilic bile acids increased to that of the hydrophobic bile acids. But no sign of apoptosis was observed, which suggests a hydrophobic-bile acid-specific mechanism for the induction of apoptosis in HCT116 cells.
Inhibition of multidrug resistance protein 1 (MRP1) mediated cytostatic drug efflux might be useful in the treatment of drug resistant tumors. Because the glutathione (GSH) conjugate of ethacrynic acid (EA), GS-EA, is a good substrate of MRP1, GS-EA derivatives are expected to be good inhibitors of MRP1. To study structure-activity relationships of MRP1 inhibition, a series of novel GS-EA analogs was synthesized in which peptide bonds of the GSH backbone were replaced by isosteric groups [Bioorg Med Chem10:195–205, 2002]. Several of these compounds were effective inhibitors of MRP1-mediated [3H]GS-EA and [3H]E217βG transport, as studied in membrane vesicles prepared from MRP1-overproducing Sf9 cells. The modifications of the peptide backbone have distinct implications for recognition by MRP1: the γ-glutamyl-cysteine peptide bond is important for binding, whereas the cysteinyl-glycine amide does not seem essential. When the γ-glutamyl-cysteine peptide bond (C-CO-N) is replaced by a urethane isostere (O-CO-N), an effective competitive MRP1-inhibitor (Ki = 11 μM) is obtained. After esterification of this compound to improve its cellular uptake, it inhibited MRP1-mediated efflux of calcein from 2008 ovarian carcinoma cells overexpressing MRP1. This compound also partially reversed the resistance of these cells to methotrexate. Because the urethane isostere is stable toward γ-glutamyl transpeptidase-mediated breakdown, it is an interesting lead-compound for the development of in vivo active MRP1 inhibitors.
Understanding of the interactions between P‐glycoprotein and multidrug resistance (MDR) reversing agents is important in designing more effective MDR modulators. We examined transcellular transport of several MDR modulators by using a drug‐sensitive epithelial cell line, LLC‐PK 1 and its transformant cell line, LLC‐GA5‐COL300, which expresses human P‐glycoprotein on the apical surface. Basal‐to‐apical transports of azidopine and diltiazem across the LLC‐GA5‐COL300 monolayer were increased and apical‐to‐basal transports were decreased compared to those across the LLC‐PK 1 monolayer, indicating that P‐glycoprotein transports azidopine and diltiazem. Movements of nitrendipine and staurosporine across the epithelial monolayer were not affected by P‐glycoprotein. These results suggests that some MDR modulators exert their inhibitory effect not only by blocking the initial binding of anticancer drugs but throughout the course of the transport process.
Rats of different ages (3 to 15-wk-old) were fed on a 25% casein diet for one week, and the nitrogen balance and liver serine dehydratase (SDH, EC 4.2.1.13) activity were then determined. The value for nitrogen balance decreased with the age of the rats, while the liver SDH activity increased. A statistical analysis showed clear inverse correlation between the two factors (R2 = 0.7372, p < 0.01). This result suggests that SDH was induced by response to the amount of surplus amino acids from dietary protein taken beyond the body’s requirement. The increase in SDH activity was accompanied by an increase in the level of SDH mRNA. Since the half-life of this mRNA did not change significantly, the induction was mainly controlled at the level of transcription. In addition, the induction seems not to be related to gluconeogenesis, since the mRNA levels of tyrosine aminotransferase (TAT) and phosphoenolpyruvate carboxykinase (PEPCK), other gluconeogenic enzymes, were not changed under these experimental conditions.
Although ileal and hepatic Na(+)-dependent bile acid transporters (SLC10A2 and SLC10A1 respectively) share structural similarities, the mutation of conserved amino acids often has distinct effects on them. We have identified two Cys residues in mouse Slc10a2 (Cys(51) and Cys(106)) the replacement of which by Ala remarkably reduces taurocholic acid (TCA) transport. Although Cys(51) is conserved in Slc10a1 as Cys(44), Ala substitution gave no apparent difference in TCA uptake. Here, we further analyzed the kinetics of TCA uptake and cell surface localization of these mutants. The C51A and C106A mutants of Slc10a2 showed significantly reduced TCA uptake, while no apparent difference in TCA uptake was observed for the Slc10a1-C44A mutant. The K(m) values for TCA uptake by these mutants were comparable, suggesting that these residues are not involved in the interaction with TCA.
P-glycoprotein / MDR1 was the first member of the ATP-binding cassette (ABC) transporter superfamily to be identified in a eukaryote. In eukaryotes, ABC proteins can be classified into three major groups based on function: transporters, regulators, and channels. MDR1 / P-glycoprotein is a prominent member of eukaryotic export-type ABC proteins. MDR1 / P-glycoprotein extrudes a very wide array of structurally dissimilar compounds, all lipophilic and ranging in mass from approximately 300 to 2000 Da, including cytotoxic drugs that act on different intracellular targets, steroid hormones, peptide antibiotics, immunosuppressive agents, calcium channel blockers, and others. Nucleotide binding and hydrolysis by MDR1 / P-glycorptrotein is tightly coupled with its function, substrate transport. ATP binding and hydrolysis were extensively analyzed with the purified MDR1 / P-glycoprotein. The vanadate-induced nucleotide trapping method was also applied to study the hydrolysis of ATP by MDR1 / P-glycoprotein. When MDR1 hydrolyzes ATP in the presence of excess orthovanadate, an analog of inorganic phosphate, it forms a metastable complex after hydrolysis. Using this method, MDR1 / P-glycoprotein can be specifically photoaffinity-labeled in the membrane, if 8-azido-[α32P]ATP is used as ATP. Visualization of the structure, as well as the biochemical data, is needed to fully understand how MDR1 / Pglycoprotein recognizes such a variety of compounds and how it carries its substrates across the membrane using the energy from ATP hydrolysis. To do so, large amounts of pure and stable proteins are required. Heterologous expression systems, which have been used to express P-glycoprotein, are also described.
Growing and mature rats were examined for the effect of a change in dietary protein requirements on the induction of liver serine dehydratase (SDH). The rats were fed on diets varying in casein content, and the weight change and nitrogen balance was determined. SDH activity and its gene expression were induced in both growing and mature rats when their protein intake exceeded their nutritional requirements.
A secondary bile acid, namely, deoxycholic acid (DCA), has been known to promote colon tumors; on the other hand, it also induces apoptosis in several human colon cancer cell lines. A hydrophobic primary bile acid, namely, chenodeoxycholic acid (CDCA), exhibits a similar property of apoptosis induction; DCA and CDCA also trigger some specific intracellular signal pathways in the human colon cancer cell line HCT116. In this article, we report that hydrophobic bile acids induce different cellular responses depending on their concentration, that is, a sublethal concentration of hydrophobic bile acids can suppress the apoptosis induced by a higher concentration of DCA. Pretreatment with DCA or CDCA at a concentration of < or = 200 microM for 8 h suppressed the apoptosis induced by 500 microM DCA in HCT116 cells. Under this condition, the association of caspase-9 and Apaf-1 and subsequent activation of caspase-9 were inhibited, but the release of cytochrome c from the mitochondria was not. At 200 microM, DCA and CDCA induced the phosphorylation of Akt and ERK1/2, although these phosphorylations do not appear to be indispensable for the cytoprotection. It is interpreted that prolonged exposure to sublethal concentrations of hydrophobic bile acids induces resistance to apoptosis, leading to promotion of colorectal tumorigenesis.
We have fused full length and the carboxyl-half of human MDR1 cDNA with the E. coli lacZ gene via a collagen linker and allowed their expression in yeast Saccharomyces cerevisiae. Using antibodies against beta-galactosidase we partially purified the fusion proteins by immunoprecipitation and show here that the full length fusion protein has ATPase activity. By contrast, the fusion protein containing the carboxyl-half of P-glycoprotein did not show ATPase activity, indicating that both domains of P-glycoprotein are necessary. By treatment of the immunoprecipitated fusion protein with collagenase, P-glycoprotein was released from the beta-galactosidase moiety. The results shown here open the possibility for a large scale purification of P-glycoprotein using this site specifically cleavable fusion protein.
