Comparison of furosemide and vinblastine secretion from cell lines overexpressing multidrug resistance protein (P-glycoprotein) and multidrug resistance-associated proteins (MRP1 and MRP2)

Recent studies in our laboratory have shown that the loop diuretic, furosemide, is actively secreted by Caco-2 cells and rat jejunal tissue. This active secretion could be the result of efflux transporters such as P-gp, MRP1 or MRP2 (cMOAT). To determine if any of these transporters is responsible for the secretion of furosemide, we compared directional permeability in the wild-type cell lines, MDCK strains I and II, and LLC-PK1, vs. cell lines that overexpress a single transporter, in both the presence and absence of various inhibitors, for furosemide as compared to vinblastine. Sulfinpyrazone significantly inhibited the transport of vinblastine in MRP2 expressing cells, but not the wild-type controls. Vinblastine could not be confirmed as a substrate of MRP1. We were also unable to demonstrate that any particular transporter affected furosemide in excess of the background effects of endogenous transporters in the parental cell lines. Furosemide secretion from these kidney-derived cell lines is probably not the primary result of any of the well characterized efflux transporters (P-gp, MRP1 or MRP2), although they may still play a role in the observed Caco-2 secretion. This equivocal result acknowledges the difficulty in trying to determine the effect of a single protein in a complicated expression system.     

多药耐药性P-糖蛋白在药物肠道吸收中的作用

目的综述近五年来多药耐药性P 糖蛋白作用于药物肠道吸收过程的研究进展。方法在查阅文献的基础上介绍了P 糖蛋白的分子结构、作用机制及其底物、抑制剂和诱导剂 ,并阐明P 糖蛋白对药物肠道吸收的作用及其所引起的临床上药物相互作用。结果与结论P 糖蛋白积极参与药物肠道吸收过程 ,充分了解这一点有助于合理设计药物制剂处方 ,提高药物生物利用度 ,避免临床上药物相互作用     

Effects of budesonide on P-glycoprotein expression in intestinal cell lines

BACKGROUND AND PURPOSE: P-glycoprotein (P-gp) is an important efflux transporter that supports the barrier function of the gut against invading antigens and against administered drugs. Since glucocorticoids, such as budesonide, are frequently used during inflammatory bowel disease we investigated how budesonide influences P-gp expression in different intestinal cell lines. EXPERIMENTAL APPROACH: LS180 and Caco-2 cells were incubated with budesonide and changes in P-gp expression were determined on mRNA, protein and functional level. The mRNA expression levels of glucocorticoid receptor (GR) and pregnane X receptor (PXR) were determined in these cell lines. PXR receptor was transiently transfected into Caco-2 cells. KEY RESULTS: Budesonide showed an induction of P-gp in LS180 cells and a down-regulation in Caco-2 cells. Expression levels of nuclear receptors revealed high expression of PXR only in LS180 cells and exclusive expression of GR in Caco-2 cells. Mifepristone, an anti-glucocorticoid, could not reverse the down-regulation of P-gp by budesonide in Caco-2 cells. In PXR-transfected Caco-2 cells the budesonide-mediated down-regulation of P-gp was abolished. Furthermore the expression of cytochrome P450 3A4 (CYP3A4), another PXR target gene, was induced in PXR-transfected Caco-2 cells after budesonide treatment. CONCLUSIONS AND IMPLICATIONS: Budesonide has the potential to influence MDR1 expression in vitro. In LS180 cells, the induction of MDR1 by budesonide probably is mediated via PXR. The mechanism of the down-regulation in Caco-2 cells still remains unclear, but GR does not seem to be involved. Further studies are required to evaluate how budesonide alters P-gp expression in vivo.     

Structure-function relationships of multidrug resistance P-glycoprotein

The direct structure-function relationships of P-glycoprotein (P-gp) are presently unknown. In this paper two P-gp models are described: a homology model based on the Escherichia coli MsbA lipid transporter and a model based on the cross-linking results of Loo and Clarke. The pharmacophore pattern for the H-site (Hoechst 33342) is derived and binding sites on the transmembrane domains TM5 and TM11 are identified. Binding sites of rhodamines are also proposed on TM6 and TM12 in accordance with the published data. Location of the binding sites is opposite in both models, suggesting that TMs undergo rotation exposing the substrate bound from the membrane to the pore. It has been concluded that the models derived represent two different functional states of P-gp corresponding to nucleotide-free and nucleotide-bound P-gp. A qualitative correspondence to the P-gp crystallographic structure at 20 A resolution is found. A hypothesis is proposed about rearrangement of TMs upon state transition.     

Reversers of the multidrug resistance transporter P-glycoprotein

Multidrug resistance can arise from the presence of the membrane-bound pump, P-glycoprotein, in a tumor. Major efforts have been made to develop inhibitors of this pump, and a number of promising blockers have reached late stages of clinical trials. The kinetics of the inhibition of P-glycoprotein is complex, with binding sites that can interact synergistically. Reversers of increased affinity and specificity could, in principle, be developed on the basis of these synergies, and offer some promise in cancer therapeutics.     

人脑胶质瘤中耐药蛋白P-gp和MRP1的表达

目的 探讨人脑胶质瘤中耐药蛋白P—gp和MRP表达情况。方法 37例人脑胶质瘤标本，包括星形细胞瘤25例(纤维型7例，原浆型6例，间变型12例)，胶质母细胞瘤12例(多形性胶质母细胞瘤4例)；10例正常脑组织作为对照。P—gp和MRPl的检测采用免疫组化ABC法。结果 P—gp肿瘤中阳性率为24．3％(9／37)，正常脑组织为10％(1／10)，两无统计学差异。P-gp在肿瘤中阳性率为73％(27／37)，正常脑组织无表达，两组间有明显差异。P—gp和MRPl在标本血管内皮细胞中存在表达，其中P—gp阳性率为24．3％(9／37)，MRPl为35．1％(13／37)。结论 人脑胶质\瘤中，P—gp和MRPl均有所表达，其中P—gp较少，而MRPl明显增多，提示与耐药关系密切。在肿瘤血管内皮细胞中，两存在异常，提示血脑屏障可能参与了肿瘤耐药现象的产生。     

Relevance of multidrug resistance proteins for intestinal drug absorption in vitro and in vivo

Multidrug resistance proteins (p-glycoprotein and mrps) are becoming increasingly important to explain the pharmacokinetics and action of drugs. Located in epithelial and endothelial cells of the gastrointestinal tract, liver, kidney, blood brain barrier, choroid plexus and other organs, they are critical determinants for the movement of a large number of commonly prescribed drugs across cellular barriers. Here we provide a brief overview of the role of multidrug resistance proteins in drug absorption from the gastrointestinal tract. We address the different types of multidrug resistance proteins involved, describe experimental models to study the influence of these proteins on transcellular transport and discuss the impact of multidrug resistance proteins on overall drug bioavailability in vivo.     

Characterization of multidrug resistance 1a/P-glycoprotein knockout rats generated by zinc finger nucleases

The development of zinc finger nuclease (ZFN) technology has enabled the genetic engineering of the rat genome. The ability to manipulate the rat genome has great promise to augment the utility of rats for biological and pharmacological studies. A Wistar Hannover rat model lacking the multidrug resistance protein Mdr1a P-glycoprotein (P-gp) was generated using a rat Mdr1a-specific ZFN. Mdr1a was completely absent in tissues, including brain and small intestine, of the knockout rat. Pharmacokinetic studies with the Mdr1a P-gp substrates loperamide, indinavir, and talinolol indicated that Mdr1a was functionally inactive in the blood-brain barrier and intestine in Mdr1a(-/-) rats. To identify possible compensatory mechanisms in Mdr1a(-/-) rats, the expression levels of drug-metabolizing enzyme and transporter-related genes were compared in brain, liver, kidney, and intestine of male and female Mdr1a(-/-) and control rats. In general, alterations in gene expression of these genes in Mdr1a(-/-) rats seemed to be modest, with more changes in female than in male rats. Taken together, our studies demonstrate that the ZFN-generated Mdr1a(-/-) rat will be a valuable tool for central nervous system drug target validation and determining the role of P-gp in drug absorption and disposition.     

Characterization of two pharmacophores on the multidrug transporter P-glycoprotein

The multidrug transporter P-glycoprotein is a plasma membrane protein involved in cell and tissue detoxification and the multidrug resistance (MDR) phenotype. It actively expels from cells a number of cytotoxic molecules, all amphiphilic but chemically unrelated. We investigated the molecular characteristics involved in the binding selectivity of P-glycoprotein by means of a molecular modeling approach using various substrates combined with an enzymological study using these substrates and native membrane vesicles prepared from MDR cells. We determined affinities and mutual relationships from the changes in P-glycoprotein ATPase activity induced by a series of cyclic peptides and peptide-like compounds, used alone or in combination. Modeling of the intramolecular distribution of the hydrophobic and polar surfaces of this series of molecules made it possible to superimpose some of these surface elements. These molecular alignments were correlated with the observed mutual exclusions for binding on P-glycoprotein. This led to the characterization of two different, but partially overlapping, pharmacophores. On each of these pharmacophores, the ligands compete with each other. The typical MDR-associated molecules, verapamil, cyclosporin A, and actinomycin D, bound to pharmacophore 1, whereas vinblastine bound to pharmacophore 2. Thus, the multispecific binding pocket of P-glycoprotein can be seen as sites, located near one another, that bind ligands according to the distribution of their hydrophobic and polar elements rather than their chemical motifs. The existence of two pharmacophores increases the possibilities for multiple chemical structure recognition. The size of the ligands affects their ability to compete with other ligands for binding to P-glycoprotein.     

Induction of thymidylate synthase associated with multidrug resistance in human breast and colon cancer cell lines.

A series of Adriamycin-resistant human breast MCF-7 and human colon DLD-1 cancer cell lines were established by stepwise selection. The concentration of Adriamycin required to inhibit cell proliferation by 50% (IC50) in the parent breast line (MCF-7), Adriamycin-resistant lines (MCF-Ad5 and MCF-Ad10), and a 5-fluorouracil (5-FU)-revertant line (MCF-R) was 0.005, 3.3, 6, and 4.9 microM, respectively. The Adriamycin IC50 value for the resistant colon line (DLD-Ad) was 8.2 microM, 68-fold higher than that for its parent line (DLD-1) (IC50 = 0.12 microM). The MCF-Ad5 and MCF-Ad10 cells were cross-resistant to 5-FU, with respective 5-FU IC50 values of 11.7 and 22.5 microM, or 7.3- and 14-fold less sensitive than their parent MCF-7 (IC50 = 1.6 microM) line. The MCF-R line completely reverted in sensitivity to 5-FU, with an IC50 of 1.7 microM. The resistant DLD-Ad line was 3.5-fold more resistant to 5-FU than was the parent DLD-1 line. Using both the 5-fluoro-2'-deoxyuridine-5'-monophosphate binding and catalytic assays for measurement of thymidylate synthase (TS) activity, there was significantly increased TS activity in the resistant MCF-Ad5 (2.4- and 2.5-fold), MCF-Ad10 (11.5- and 6.8-fold), and DLD-Ad (4.8- and 10.7-fold) lines, for binding and catalytic assays, respectively, compared with their parent MCF-7 and DLD-1 lines. The level of TS in cytosolic extracts, as determined by Western immunoblot analysis, was markedly increased for the resistant MCF-Ad5 (31-fold), MCF-Ad10 (46-fold), and DLD-Ad (52-fold) cells. Measurement of TS mRNA levels by Northern analysis revealed elevation of TS mRNA in the resistant MCF-AD5 (16.7-fold), MCF-Ad10 (31-fold), and DLD-Ad (55-fold) cells. Southern analysis showed that this increase in TS mRNA was not accompanied by any major rearrangements or amplification of the TS gene. Incorporation of 5-FU into the RNA and DNA of the resistant MCF-Ad10 cells was not significantly different, compared with that for parent MCF-7 cells. These studies suggest that exposure of human breast and human colon cancer cells to Adriamycin leads to overexpression of TS, with concomitant development of resistance to 5-FU.     

Reversal of P-glycoprotein associated multidrug resistance by new isoprenoid derivatives

To find a drug to overcome P-glycoprotein associated multidrug resistance, we synthesized 43 new isoprenoid derivatives. Ten compounds were effective in an in vitro assay with the human MDR-type resistant carcinoma KB/VJ-300 and MRP-type KB/VP-4 cell lines. One of the most effective compounds, N-5228 [trans-N,N'-bis(3,4-dimethoxybenzyl)-N-solanesyl-1,2-diaminocyclohexane, mol. wt 1100.481, was tested in P388/VCR-bearing mice. It showed a antitumor effect on MDR-type resistant tumor cells. Moreover, N-5228 potentiated the accumulation of [3H]vincristine in drug-resistant cells and blocked [3H]azidopine photoaffinity labeling of P-glycoprotein molecules in MDR-type resistant cell membranes. We think that N-5228 is promising as a lead compound in the screening of resistance reversing drugs for multidrug resistant cancers.     

The multidrug resistant modulator HZ08 reverses multidrug resistance via P-glycoprotein inhibition and apoptosis sensitization in human epidermoid carcinoma cell line KBV200

Previous studies have demonstrated that the multidrug resistance modulator HZ08 has a strong multidrug resistance reversal effect in vitro and in vivo by inhibiting P-glycoprotein and multidrug resistance-associated protein 1 in K562/A02 and MCF-7/ADM cells, respectively. However, there are many other mechanisms responsible for resistance. In this study, MTT assay was used to examine the cytotoxicity and multidrug resistance reversal of HZ08 in KBV200 cells. It was also used to detect Rh123 and adriamycin accumulation in the presence of HZ08 to assess the effect on P-glycoprotein. Caspase-3 activity was analyzed under the incubation of HZ08 per se and in combination with vincristine. Results showed that HZ08 could increase the activity of caspase-3 with P-glycoprotein inhibition. Further studies revealed that HZ08 increased vincristine-induced apoptosis, characterized as an intrinsic apoptosis pathway with enhanced G2/M phase arrest, since HZ08 had an effect on the intrinsic apoptotic regulator Bcl-2 and Bax. Therefore, the outstanding reversal effect of HZ08 occurs not only through suppressing the P-glycoprotein function but also through activating the intrinsic apoptosis pathway.     

Evaluation of antipsychotic drugs as inhibitors of multidrug resistance transporter P-glycoprotein

Rationale The multidrug resistance transporter, P-glycoprotein (P-gp), is involved in efflux transport of several antipsychotics in the blood–brain barrier (BBB).Objectives In the present study, we evaluated the inhibitory effect of the antipsychotics, i.e., risperidone, olanzapine, quetiapine, clozapine, haloperidol, chlorpromazine, a major metabolite of risperidone, 9-OH-risperidone, and a positive control inhibitor, PSC833, on the cellular uptake of a prototypic substrate of P-gp, rhodamine (Rhd) 123, in LLC-PK1 and L-MDR1 cells.Materials and methods After incubation of the antipsychotics (1–100 μM) and the positive (10 μM PSC833) or negative (1% dimethyl sulfoxide) controls with 5 μM Rhd 123 for 1 h, the effects of the antipsychotics on the intracellular accumulation of Rhd 123 were examined using a flow cytometric method.Results All the antipsychotics showed various degrees of inhibitory effects on P-gp activity. The rank order of the concentration of inhibitor to cause 50% of the maximal increment of intracellular Rhd 123 fluorescence (EC₅₀) was: PSC833 (0.5 μM) < olanzapine (3.9 μM) < chlorpromazine (5.8 μM) < risperidone (6.6 μM) < haloperidol (9.1 μM) < quetiapine (9.8 μM) < 9-OH-risperidone (12.5 μM) < clozapine (30 μM). Considering that the antipsychotics’ plasma concentrations are generally lower than 1 μM, the present results suggest that olanzapine and risperidone are the only agents that may inhibit P-gp activity in the BBB. However, most of the antipsychotics are extensively accumulated in tissues. In addition, when given orally, the drug concentrations in the gastrointestinal tract are likely to be high.Conclusions Pharmacokinetic interactions due to inhibition of P-gp activity by the antipsychotics appear possible and warrant further investigation.     

Characterization of auromomycin-resistant hamster cell mutants that display a multidrug resistance phenotype

We have selected and characterized Chinese hamster ovary (CHO) cells resistant to auromomycin (AUR), an antitumor antibiotic composed of a protein moiety and a nonpeptide chromophore. AUR is cytotoxic as a consequence of DNA strand-scission activity associated with the chromophore. Initial single-step selections for clones resistant to AUR detected a subpopulation of phenotypically resistant colonies, but nearly all such clones failed to display heritable resistance. One isolate that did show somewhat increased resistance was selected further and yielded a clone designated AURR-R1 that exhibits stable 10-fold increased resistance to AUR. The R1 line is also resistant to the AUR chromophore and cross-resistant to the closely related agent neocarzinostatin (NCS) and to the NCS chromophore. For AUR-treated whole cells, resistance to AUR cytotoxicity was inversely correlated with DNA damage as measured by filter elution; by contrast, isolated nuclei from sensitive and resistant cells displayed similar levels of AUR-induced DNA damage. The R1 cell line was found to be cross-resistant to colchicine, Adriamycin, Daunomycin, and vinblastine. The resistance phenotype is expressed with incomplete dominance in cell hybrids and appears similar to the "classic" multidrug resistance of CHO cells selected with other agents. Indeed, we found the multidrug-resistant CHO line CCHR-C5 to be about 5-fold cross-resistant to AUR and to NCS. We ascertained that AUR-resistant (AURR) isolates express elevated levels of the molecular weight 170,000 P-glycoprotein often associated with multidrug resistance and also contain amplified DNA sequences that contain the gene for P-glycoprotein. When multiple-step enrichment selections were carried out as an alternative approach for isolating AURR mutants, each of nine clonal isolates showed phenotypes resembling the AURR-R1 line. Thus, our findings imply that increased cellular resistance to AUR may frequently be associated with P-glycoprotein-mediated multidrug resistance.     

Potent galloyl-based selective modulators targeting multidrug resistance associated protein 1 and P-glycoprotein

The multifactorial nature of chemotherapy failure in controlling cancer is often associated with the occurrence of multidrug resistance (MDR), a phenomenon likely related to the increased expression of members of the ATP binding cassette (ABC) transporter superfamily. In this respect, the most extensively characterized MDR transporters include ABCB1 (also known as MDR1 or P-glycoprotein) and ABCC1 (also known as MRP1) whose inhibition remains a priority to circumvent drug resistance. Herein, we report how the simple galloyl benzamide scaffold can be easily and properly decorated for the preparation of either MRP1 or P-gp highly selective inhibitors. In particular, some gallamides and pyrogallol-1-monomethyl ethers showed remarkable affinity and selectivity toward MRP1. On the other hand, trimethyl ether galloyl anilides, with few exceptions, exhibited moderate to very high and selective P-gp inhibition.     

Absorption properties and P-glycoprotein activity of modified Caco-2 cell lines.

Caco-2 cell line is extensively used as an in vitro model in studying small intestinal absorption but it lacks proper expression of efflux pumps and cytochrome P450 enzymes that are involved in absorption and first pass metabolism of drugs. We created two novel Caco-2 cell lines expressing orphan nuclear receptors pregnane X receptor and constitutive androstane receptor that regulate many genes involved in xenobiotic metabolism. We conducted a systematic study on expression of some metabolic genes, P-glycoprotein activity and absorption properties of several drugs with these new cell lines and previously described modified Caco-2 cell lines (MDR1 transfection, vincristine treatment and 1alpha,25-dihydroxyvitamin D3 treatment). A short culture time medium was also included in the study. Most modified cell lines formed tight differentiated monolayers. MDR1, CYP2C9 and CYP3A4 genes were upregulated in some cell lines. Elevated P-glycoprotein activities were observed by calcein-AM uptake experiments but this did not affect significantly the permeability of selected P-glycoprotein substrates. Some cell lines had similar passive and active permeability properties to Caco/WT cells while in few cell lines these were altered. Passive transcellular permeability was modestly elevated in all modified cell lines. In addition, several compounds showed pH-dependent permeability properties.     

Doxorubicin-loaded nanospheres bypass tumor cell multidrug resistance.

We have demonstrated that in vitro resistance of tumor cells to doxorubicin (Dox) can be fully circumvented by using doxorubicin-loaded nanospheres (Dox-NS), consisting of biodegradable polyisohexylcyanoacrylate polymers of 300 nm diameter and containing 2.83 mg of Dox per 31.5 mg of polymer. Five different multidrug-resistant cell lines, characterized by mdr1 amplification, were used in this study: Dox-R-MCF7, a human breast adenocarcinoma; SKVBL1, a human ovarian adenocarcinoma; K562-R, a human erythroleukemia; and two murine lines: P388-Adr-R, a monocytic leukemia of DBA2 mouse, and LR73MDR, a Chinese hamster ovarian cell line. These lines were 38.7, 210, 232, 143 and 20 times more resistant than their corresponding sensitive counterparts, respectively. Using Dox-NS, we obtained complete reversion of drug resistance in vitro, i.e. cell growth inhibition comparable with that obtained with sensitive cells exposed to free Dox. In vivo, we significantly prolonged the survival of DBA2 mice which had previously received P388-Adr-R cells by i.p. injections of Dox-NS, while free Dox injection was ineffective toward this rapidly growing tumor. (Prolongation of survival time: 115% vs 167% after Dox vs Dox-NS treatment, respectively.) Using the MCF7 cell line and its resistant variant, we studied the intracellular concentration and the cytoplasmic and nuclear distribution of Dox by laser microspectrofluorometry (LMSF). In sensitive cells, we observed a similar accumulation and distribution of Dox whatever the form of Dox delivery, i.e. whether free or carried by nanospheres. Analysis by LMSF showed that 99% of intranuclear Dox was bound to DNA after treatment with both forms of Dox. Of Dox, 81 and 83% were found in the intranuclear compartment of sensitive cells incubated with free Dox and Dox-NS, respectively. Resistant cells incubated with Dox-NS accumulated the same amount of Dox as sensitive cells incubated with free Dox or with Dox-NS. Dox, when loaded in nanospheres, bypasses the efflux mechanism responsible for multidrug resistance. LMSF analysis showed that Dox, transported and released by nanospheres, interacts with DNA identically in sensitive and resistant cells.     

多药耐药相关蛋白及其在肿瘤耐药中的作用

多药耐药(multidrug resistance,MDR)是导致肿瘤患者化疗失败的主要原因。介导多药耐药的重要机制之一是多药耐药相关蛋白(multidrug resistance-associated proteins,MRPs)的表达增加。MRPs是一类ATP能量依赖型跨膜转运蛋白,是具有选择性和特异性的药物外排泵。本文主要针对MRPs的生理特征、结构特点、耐药谱特征及其逆转进行综述。     

Establishment and characterization of adriamycin-resistant human colorectal adenocarcinoma HCT-15 cell lines with multidrug resistance

The multidrug resistance (MDR) phenotype, either intrinsic and/or acquired, is discussed in relation to several MDR-associated markers such as P-glycoprotein (P-gp) encoded by mdr1, multidrug-resistance-associated protein (MRP) encoded by MRP and lung-resistance-associated protein (LRP) encoded by LRP. Well-characterized in vitro models are required to elucidate the mechanisms of MDR. The aim of the present study is the establishment of a drug-resistant subline from human colorectal adenocarcinoma HCT-15 that intrinsically expresses moderate levels of P-gp, MRP and LRP. Three adriamycin-resistant sublines (HCT-15/ADM1, HCT-15/ADM2 and HCT-15/ADM2-2) were established by stepwise exposure in growth medium that was supplemented with 25-200 ng/ml adriamycin-resulting in a 2.2- to 7.8-fold increase in IC(50) values by using the XTT assay. They were cross-resistant to MDR-related drugs, epirubicin, mitoxantrone, vincristine, etoposide and taxol, but not the MDR-unrelated drug, mytomycin C. The resistance to adriamycin was confirmed in vivo by a lack of sensitivity in athymic nude mice. Gene expression data for mdr1/P-gp, MRP/MRP and LRP/LRP on both mRNA and protein levels demonstrated that the molecules contributing to MDR in resistant sublines are mainly P-gp and partially MRP. The newly established adriamycin-resistant sublines of HCT-15 will provide clinically relevant tools to investigate how to overcome drug resistance and elucidate possible mechanisms of acquired MDR in human colon cancer.