Kinetic parameters for the uptake of anthracycline by drug-resistant and drug-sensitive K562 cells

Multidrug resistance (MDR) reversers: High activity and efficacy in a series of asymmetrical N,N-bis(alkanol)amine aryl esters

As a continuation of our research on potent and efficacious P-gp-dependent multidrug resistance (MDR) reversers, several new N,N-bis(alkanol)amine aryl esters were designed and synthesized, varying the aromatic moieties or the length of the methylenic chain. The new compounds were tested on doxorubicin-resistant erythroleukemia K562 cells (K562/DOX) in the pirarubicin uptake assay, where most of the new compounds were shown to be active. In particular the asymmetrical compounds, characterized by two linkers of different length, generally showed fairly high activities as MDR reversers. Some selected compounds (isomers 15-17) were further studied by evaluating their doxorubicin cytotoxicity enhancement (reversal fold, RF) on the K562/DOX cell line. The results of both pharmacological assays indicate that compounds 16 (GDE6) and 17 (GDE19) could be interesting leads for the development of new P-gp dependent MDR modulators.

Anthracycline Nano-Delivery Systems to Overcome Multiple Drug Resistance: A Comprehensive Review

Anthracyclines (doxorubicin, daunorubicin, and idarubicin) are very effective chemotherapeutic drugs to treat many cancers; however, the development of multiple drug resistance (MDR) is one of the major limitations for their clinical applications. Nano-delivery systems have emerged as the novel cancer therapeutics to overcome MDR. Up until now, many anthracycline nano-delivery systems have been developed and reported to effectively circumvent MDR both in-vitro and in-vivo, and some of these systems have even advanced to clinical trials, such as the HPMA-doxorubicin (HPMA-DOX) conjugate. Doxil, a DOX PEGylated liposome formulation, was developed and approved by FDA in 1995. Unfortunately, this formulation does not address the MDR problem. In this comprehensive review, more than ten types of developed anthracycline nano-delivery systems to overcome MDR and their proposed mechanisms are covered and discussed, including liposomes; polymeric micelles, conjugate and nanoparticles; peptide/protein conjugates; solid-lipid, magnetic, gold, silica, and cyclodextrin nanoparticles; and carbon nanotubes.

New structure-activity relationship studies in a series of N,N-bis(cyclohexanol)amine aryl esters as potent reversers of P-glycoprotein-mediated multidrug resistance (MDR)

As a continuation of previous research on a new series of potent and efficacious P-gp-dependent multidrug resistant (MDR) reversers with a N,N-bis(cyclohexanol)amine scaffold, we have designed and synthesized several analogs by modulation of the two aromatic moieties linked through ester functions to the N,N-bis(cyclohexanol)amine, aiming to optimize activity and to extend structure-activity relationships (SAR) within the series. This scaffold, when esterified with two different aromatic carboxylic acids, gives origin to four geometric isomers (cis/trans, trans/trans, cis/cis and trans/cis). The new compounds were tested on doxorubicin-resistant erythroleukemia K562 cells (K562/DOX) in the pirarubicin uptake assay. Most of them resulted in being potent modulators of the extrusion pump P-gp, showing potency values ([I](0.5)) in the submicromolar and nanomolar range. Of these, compounds 2b, 2c, 3d, 5a-d and 6d, showed excellent efficacy with a α(max) close to 1. Selected compounds (2d, 3a, 3b, 5a-d) were further studied to evaluate their doxorubicin cytotoxicity potentiation (RF) on doxorubicin-resistant erythroleukemia K562 cells and were found able to enhance significantly doxorubicin cytotoxicity on K562/DOX cells. The results of both pirarubicin uptake and the cytotoxicity assay, indicate that the new compounds of the series are potent P-gp-mediated MDR reversers. They present a structure with a mix of flexible and rigid moieties, a property that seems critical to allow the molecules to choose the most productive of the several binding modes possible in the transporter recognition site. In particular, compounds 5c and 5d, similar to the already reported analogous isomers 1c and 1d,(29) are potent and efficacious modulators of P-gp-dependent MDR and may be promising leads for the development of MDR-reversal drugs.

Anthraquinone antitumour agents, doxorubicin, pirarubicin and benzoperimidine BP1, trigger caspase-3/caspase-8-dependent apoptosis of leukaemia sensitive HL60 and resistant HL60/VINC and HL60/DOX cells

We examined the effect of selected anthraquinone antitumour agents - doxorubicin (DOX), pirarubicin (PIRA) and benzoperimidine BP1 - on inducing apoptosis of the sensitive leukaemia HL60 cell line and its multidrug resistance sublines overexpressing P-glycoprotein (HL60/VINC) and multidrug resistance-associated protein 1 (HL60/DOX). All agents used at IC50 and IC90 were able to influence the cell cycle of sensitive HL60 and resistant cells and induce apoptosis. Interestingly, it was seen that HL60/VINC cells were more susceptible to undergo caspase-3/caspase-8-dependent apoptosis induced by the studied anthraquinone compounds compared with HL60 and HL60/DOX cells. However, the examined agents did not change the expression of Fas receptors on the surface of HL60-sensitive and-resistant cells.

Evaluation of the potential of transferrin-adriamycin conjugates in the treatment of bladder cancer

OBJECTIVE

To assess the ability of a transferrin-adriamycin conjugate (Tf-ADR) to target transferrin receptor (TfR)-positive cancer cells selectively and to overcome drug resistance in bladder cancer cell lines.

MATERIALS AND METHODS

Two paired sets of cell lines were used: the first was Chinese hamster ovary (CHO) cells (TfR-negative TRVb cells, as a model for normal resting cells, and TRVb-1 cells which were transfected with human TfR), and the second was a pair of bladder cancer cell lines (ADR-sensitive MGH-U1 cells and ADR-resistant MGH-U1R cells). Cell survival curves were determined after treatment with ADR, Tf and Tf-ADR.

RESULTS

MGH-U1, TRVb and TRVb-1 cells required similar concentrations of ADR and Tf-ADR for 50% inhibition of growth; MGH-U1R cells were resistant to both ADR and TF-ADR.

CONCLUSION

Tf-ADR did not prevent toxicity to the TfR-negative cells nor did it overcome the resistance of the ADR-resistant cells. These results imply that Tf-ADR does not provide a better cytotoxic drug delivery system for the treatment of bladder cancer.

A comparison of the phenomenology and genetics of multidrug resistance in cancer cells and quinoline resistance in Plasmodium falciparum

Plasmodium falciparum is the causative agent of the most deadly form of human malaria. Chemotherapy traditionally has been the main line of defense against this parasite, and chloroquine, the drug of choice, has been one of the most successful drugs ever developed. Unfortunately, the evolution and spread of resistance to chloroquine and other quinoline-containing drugs means that these compounds are now virtually useless in many endemic areas. Future prospects for the use of quinoline compounds improved considerably when it was demonstrated that chloroquine resistance could be circumvented in vitro by a number of structurally and functionally unrelated compounds such as verapamil and desipramine. The phenomenon of resistance reversal by compounds such as verapamil is also a key feature of drug resistance in mammalian cells, and this has raised the possibility that the underlying mechanisms of drug resistance of the two cell types could be similar. This hypothesis has prompted a large number of studies into the genetics and biochemistry of resistance to quinoline-containing drugs in P. falciparum. Both the genetic and the biochemical studies have raised issues of controversy and stimulated much debate. These issues are discussed in this review, in the context of a comparison with the genetics and biochemistry of multidrug resistance in mammalian cells.

Transport of the anti-cancer drug doxorubicin across cytoplasmic membranes and membranes composed of phospholipids derived from Escherichia coli occurs via a similar mechanism

An assay was developed to measure and directly compare transport of doxorubicin across right-side-out cytoplasmic membrane vesicles (ROV) and across model membranes (LUVET) composed of pure phospholipids, isolated from the corresponding cells. Escherichia coli was used as a model organism, since mutants are available which differ in phospholipid composition. Both in LUVET and ROV only passive diffusion across the bilayer is involved, because effects of drug concentration, pH, divalent cations, the phospholipid composition, and the active transport inhibitor verapamil were comparable. Permeability coefficients were about 2-3-times higher in ROV compared to LUVET. Furthermore, in LUVET an average activation energy of 87 kJ/mol and in ROV of 50 kJ/mol was observed. These differences are suggested to result from differences in membrane order between LUVET and ROV and differences in the temperature dependence of membrane order in LUVET and ROV, respectively. Because no background carrier-facilitated doxorubicin transport seems to be present, ROV are an excellent model system to study the effect of phospholipid composition on drug transport after expression of a multidrug resistance-conferring protein. Furthermore, data of passive diffusion of doxorubicin obtained with LUVET are representative for more complex, biologically relevant membrane systems.

Cytotoxic effects of a doxorubicin-transferrin conjugate in multidrug-resistant KB cells

Cancer chemotherapy is often limited by the emergence of multidrug-resistant tumor cells. Multidrug resistance (MDR) can be caused by amplification of the MDR genes and overexpression of the P-glycoprotein, which is capable of lowering intracellular drug concentrations. A doxorubicin-transferrin conjugate has been synthesized and exerts its cytotoxic effects through a transmembrane mechanism. We have examined the cytotoxicity of this conjugate and compared it with doxorubicin in sensitive (KB-3-1) and in multidrug-resistant KB cell lines (KB-8-5, KB-C1, and KB-V1). In the clonogenic assay, doxorubicin exhibited IC50 concentrations of 0.03 and 0.12 microM in the sensitive (KB-3-1) and resistant (KB-8-5) cell lines, respectively, whereas, doxorubicin-transferrin conjugate was more effective with IC50 concentrations of 0.006 and 0.028 microM, respectively. In highly multidrug-resistant KB-C1 and KB-V1 cells, doxorubicin up to 1 microM did not cause any cytotoxic effects, while the doxorubicin-transferrin conjugate inhibited colony formation of these cells with IC50 levels of 0.2 and 0.025 microM, respectively. These results demonstrate that doxorubicin-transferrin is effective against multidrug-resistant tumor cells.

Non-competitive inhibition of P-glycoprotein-associated efflux of THP-adriamycin by verapamil in living K562 leukemia cells

The decrease of the intracellular concentration of drug in resistant cells as compared to sensitive cells is, in most of cases, correlated with the presence, in the membrane of resistant cells, of a 170-kDa P-glycoprotein (P-gp) responsible for an active efflux of the drug. The fluorescence emission spectra from anthracycline-treated cells suspended in buffer have been used to follow the P-gp-associated efflux of these drugs in the absence or presence of verapamil. In the present study, 4'-o-tetrahydro-pyranyladriamycin (THP-adriamycin) was used. Two different methods were used to determine the kinetics of active efflux of THP-adriamycin: (1) at the steady-state, (2) directly, after the addition of glucose to cells first incubated with THP-adriamycin in the presence of N3- and in the absence of glucose. Kinetic analysis indicates: (1) a saturation of the active efflux when the cytosolic free drug concentration increased (the Michaelis constant Km = 0.5 +/- 0.3 microM) and (2) that the inhibitory effect of verapamil on P-gp-associated efflux of THP-adriamycin in living cells is non-competitive.

Role of anionic phospholipids in the interaction of doxorubicin and plasma membrane vesicles: drug binding and structural consequences in bacterial systems

Anthracycline-membrane interactions play a role in the transport, the cytoplasmic distribution, and possibly also the activity of anthracyclines. Previous work on model membranes has shown that the widely-applied anticancer drug doxorubicin interacts specifically with anionic phospholipids [de Wolf, F. A., et al. (1991) Biochim. Biophys. Acta 106, 67-80]. We have now been able to investigate these interactions, and their selectivity for anionic phospholipids, directly in plasma membranes. Because of the recent availability of Escherichia coli mutants in which the anionic phospholipid content ranges from only 10% to as much as 100% of the total phospholipid content, we used this bacterium as a source of plasma membranes. We compared the interactions of the cationic anthracycline doxorubicin with (1) plasma membranes of different mutant strains, (2) total lipid extracts of these membranes, and (3) synthetic phospholipid mixtures in which a comparable fraction of the phospholipids was negatively charged. The results show that anionic phospholipids are important determinants of doxorubicin binding, not only in model membranes but also in plasma membrane systems. Only in plasma membranes with a very low anionic lipid content was the binding to the anionic phospholipid masked by other factors. Using an unsaturated fatty acid auxotroph grown on [11,11-2H2]oleic acid, it appeared from 2H-NMR data that doxorubicin induces a disordering of acyl chains in bacterial plasma membranes and their total lipid extracts. This indicates that the binding is not purely electrostatic but involves the insertion of drug molecules into the lipid matrix, probably due to hydrophobic interactions.

Interactions of iron-anthracycline complexes with living cells: a microspectrofluorometric study

The interaction of iron-anthracycline complexes with tumor cells has been studied using microspectrofluorometry. The anthracyclines used were adriamycin, 4'-O-tetrahydropyranyladriamycin and daunorubicin. In every case, a 1:3 Fe(III)-anthracycline complex is formed. The three daunorubicin molecules that bind to one Fe(III) are not chemically modified through complexation with iron. In the case of the Fe(III)-adriamycin and Fe(III)-4'-O-tetrahydropyranyladriamycin complexes, about one of the three anthracycline molecules is chemically modified, yielding a highly lipophilic derivative, the 7,8-dehydro-9,10-desacetyladriamycin. The others molecules remain unchanged, i.e., highly hydrophilic in the case of adriamycin. These two species have a different fluorescent spectrum and can be identified inside the cell, using microspectrofluorometry. In the case of the Fe(III)-adriamycin complex, the lipophilic derivative is more rapidly internalized in the cell than the hydrophilic one. Diffusion into the plasmic membrane is the limiting step for the uptake of anthracycline by cells; this means that the plasmic membrane speeds up the dissociation of the Fe(III)-anthracycline complex.

Cell cycle dependent uptake and release of anthracycline by drug-resistant and drug-sensitive human leukaemic K562 cells

The appearance of cellular resistance to antitumor drugs is a major problem in cancer chemotherapy. This results from the overexpression of the mdr 1 gene which encodes the 170 kDa P-glycoprotein or multidrug transporter. The uptake and release of 4'-O-tetrahydropyranyladriamycin by drug-sensitive and drug-resistant K562 cells in the different phase of the cycle have been determined. Synchronized cells were obtained by centrifugal elutriation. The kinetics, as well as the amount of drug intercalated inside the nucleus and free in the cytoplasm, have been determined using a spectrofluorometric method that we have developed and that does not compromise cell viability. The kinetics of active efflux of the drug under the effect of P-glycoprotein has been determined. We have calculated that the number of 4'-O-tetrahydropyranyladriamycin molecules, which are actively effluxed per cell and per second, is constant whatever the cell cycle phase.

Accumulation of degradation products of doxorubicin and pirarubicin formed in cell culture medium within sensitive and resistant cells

Quantitative study of doxorubicin (Adriamycin), pirarubicin (4'-o-tetrahypyranyladriamycin) and daunorubicin in the nucleus of living cells was performed using microspectrofluorometry. As for the cytotoxic assays, drug-sensitive and drug-resistant K562 cells were incubated for 3 days with concentrations of drug ranging from 4 nM to 1 mM. When drug-sensitive cells were incubated with pirarubicin, the spectrum recorded from inside the nucleus was characteristic of anthracycline intercalated between the base pairs in the nucleus. However, when drug-sensitive cells were incubated with doxorubicin and drug-resistant cells with pirarubicin or doxorubicin, a new fluorescent spectrum was obtained which was due to 7,8-dehydro-9,10-desacetyldoxorubicinone, a pirarubicin and doxorubicin degradation product that is formed in the medium. This compound which is highly lipophilic is taken up rapidly into both sensitive and resistant cells.

Cytotoxicity of a transferrin-adriamycin conjugate to anthracycline-resistant cells

Conjugates of adriamycin coupled to transferrin by glutaraldehyde are cytotoxic to human promyelocytic (HL-60) and erythroleukemic (K562) cells. Growth inhibition of adriamycin-sensitive cells, as evaluated by thymidine incorporation and the MTT-assay, was higher for conjugates than for free adriamycin. The cytotoxicity toward adriamycin-resistant K562 and HL-60 cells was 3-fold and more than 10-fold higher, respectively, for the transferrin-adriamycin conjugate than for the free drug. The effect of the conjugate was dependent on its adriamycin content, i.e., on its conjugation number.