Chalcogenopyrylium Dyes as Modulators of Multidrug Resistance Protein (MRP) 1, MRP2 and MRP4 Transport Activities

MYETTE, ROBERT LEONARD

29 November 2011

MRPs mediate the ATP-dependent efflux of a structurally diverse array of compounds. Certain MRPs, including MRP1, MRP2 and MRP4, are involved in multidrug resistance in tumour cells, while in non-malignant cells these MRPs can influence the distribution and/or elimination of many clinically important drugs. In addition, these MRPs mediate the efflux of physiological metabolites, many of which are conjugated organic anions. Modulation of the drug transporting activity of MRP1 (and to a lesser extent MRP2 and MRP4) has been a long sought after therapeutic objective. In this study, the modulatory abilities of five structurally distinct classes (I-V) of chalcogenopyrylium dyes (CGPs) were examined utilizing an in vitro assay which measures inhibition of radiolabeled estradiol glucuronide ([3H]E217βG) (a prototypical MRP substrate) uptake into inside-out membrane vesicles prepared from MRP-transfected human embryonic kidney (HEK) cells. Additionally, some CGPs were tested in a calcein efflux assay using intact MRP1-transfected HEK cells. Sixteen of 34 CGPs initially tested at a single concentration (≤30 μM) inhibited MRP1-mediated uptake by >50%, with IC50’s ranging from 0.7-7.6 μM. Of the 9 CGPs with IC50’s ≤2 μM, five belonged to Class I, two to Class II, and two to Class IV. When tested in the calcein efflux assay, only 4 of 16 CGPs inhibited MRP1-mediated cellular efflux by >50% (I-3, -4, -6, IV-1) while a fifth (II-5) inhibited efflux by 23%. These five CGPs were then tested as modulators of [3H]E217βG uptake by MRP2 and MRP4. Their effects on MRP2 transport activity were differential with two (I-4, I-6) inhibiting transport (IC50’s 2.0, 7.1 μM), two (I-3, IV-1) stimulating transport (>2-fold), while II-5 had no effect. On the other hand, all five CGPs inhibited [3H]E217βG uptake by MRP4, but less effectively than by MRP1. Finally, five analogs of CGP IV-1 were tested for their effects on MRP1, MRP2 and MRP4 [3H]E217βG uptake, but none were more efficacious than CGP IV-1. The CGPs tested here represent novel MRP1, MRP2 and MRP4 modulators with variable effects on transport activities. These CGPs may represent a new avenue for the development of clinically applicable modulators of MRP proteins involved in multidrug resistance. / Thesis (Master, Pathology & Molecular Medicine) -- Queen's University, 2011-11-28 17:50:49.432

Multidrug Resistance Proteins

Chalcogenopyrylium Dyes

Investigation of the comparative cost-effectiveness of different strategies for the management of multidrug-resistant tuberculosis

Rockcliffe, Nicole

January 2003

The tuberculosis epidemic is escalating in South Africa as well as globally. This escalation is exacerbated by the increasing prevalence of multidrug-resistant tuberculosis (MDRTB), which is defined by the World Health Organisation (WHO) as resistance of Mycobacteria to at least isoniazid and rifampicin. Multi-drug resistant tuberculosis is estimated to occur in 1-2% of newly diagnosed tuberculosis (TB) patients and in 4-8% of previously treated patients. MDRTB is both difficult and expensive to treat, costing up to 126 times that of drug-sensitive TB. Resource constrained countries such as South Africa often lack both the money and the infrastructure to treat this disease. The aim of this project was to determine whether the performance of a systematic review with subsequent economic modelling could influence the decision making process for policy makers. Data was gathered and an economic evaluation of MDRTB treatment was performed from the perspective of the South African Department of Health. Three treatment alternatives were identified: a protocol regimen of second line anti-tuberculosis agents, as recommended in the South African guidelines for MDRTB, an appropriate regimen designed for each patient according to the results of culture and drug susceptibility tests, and non-drug management. A decision-analysis model using DATA 3.0 by Treeage® was developed to estimate the costs of each alternative. Outcomes were measured in terms of cost alone as well as the ‘number of cases cured’ and the number of ‘years of life saved’ for patients dying, being cured or failing treatment. Drug, hospital and laboratory costs incurred using each alternative were included in the analysis. A sensitivity analysis was performed on all variables in order to identify threshold values that would change the outcome of the evaluation. Results of the decision analysis indicate that the individualised regimen was both the cheaper and more cost-effective regimen of the two active treatment options, and was estimated to cost R50 661 per case cured and R2 070 per year of life saved. The protocol regimen was estimated to cost R73 609 per case cured and R2 741 per year of life saved. The outcome of the decision analysis was sensitive to changes in some of the variables used to model the disease, particularly the daily cost of drugs, the length of time spent in hospital and the length of treatment received by those patients dying or failing treatment. This modelling exercise highlighted significant deficiencies in the quality of evidence on MDRTB management available to policy makers. Pragmatic choices based on operational and other logistic concerns may need to be reviewed when further information becomes available. A case can be made for the establishment of a national database of costing and efficacy information to guide future policy revisions of the South African MDRTB treatment programme, which is resource intensive and of only moderate efficacy. However, due to the widely disparate range of studies on which this evaluation was based, the outcome of the study may not be credible. In this case, the use of a systematic review with subsequent economic modelling could not validly influence policy-makers to change the decision that they made on the basis of drug availability.

Tuberculosis

Multidrug resistance

Tuberculosis -- Treatment

A study of MRP1-drug interactions : identification of the drug binding site(s)

Daoud, Roni N.

January 2000

No description available.

Cancer -- Chemotherapy.

Multidrug resistance.

CD antigens.

Establishing a role for ecto-phosphatase in drug resistance /

Windsor, James Brian,

January 2000

Thesis (Ph. D.)--University of Texas at Austin, 2000. / Vita. Includes bibliographical references (leaves 107-111). Available also in a digital version from Dissertation Abstracts.

Characterization of P-glycoprotein expression as a multixenobiotic resistance mechanism in fish /

Bard, Shannon Mala.

January 1900

Thesis (Ph. D.)--Massachusetts Institute of Technology and Woods Hole Oceanographic Institution, 2000. / "February, 2001." "Funding was provided by National Institute of Health grant ES-07381 and a Rinehart Coastal Research Center grant." Includes bibliographical references (p. 174-177).

Molecular mechanism of transport by the secondary-active multidrug transporter LmrP

Schaedler, Theresia Anna

January 2010

No description available.

615.1

Molecular studies on the transport cycle and power stroke of bacterial multidrug ABC exporters

Doshi, Rupak

January 2011

No description available.

615.1

Identification and characterization of a novel mechanism of multidrug resistance in tumour cells

Wang, Ying, 1958-

January 1998

The development of multidrug resistance (MDR) in tumour cells to a wide range of anticancer drugs has become a major obstacle in the chemotherapeutic treatment of cancer. Molecular characterization of MDR tumour cells has led to the identification of several cell-based genetic alterations including the overexpression of a membrane protein, P-glycoprotein (P-gp). P-gp is a ATP dependent drug efflux pump and P-gp ATPase activity has been demonstrated to be essential in drug transport. In an effort to understand how P-gp ATPase activity is coupled to drug binding and transport, we examined the effects of N-ethylmaleimide (NEM), a potent inhibitor of P-gp ATPase, on P-gp drug binding and transport. Our results show that short term treatment of MDR cells with NEM led to a concentration-dependent increase in P-gp drug binding and phosphorylation. In addition, NEM increases [3H]-vinblastine accumulation in drug resistant cells but not in sensitive cells. Our study suggests that inhibition of P-gp ATPase activity, and not increased phosphorylation of P-gp by NEM, is responsible for the observed increase in P-gp-drug binding. / Selection of tumour cell lines in vitro has led to multiple cellular changes that may mediate drug resistance to anticancer drugs. The role of other mechanisms, in addition to P-gp and multidrug resistance protein (MRP) in drug resistance, is supported by evidence from studies with tumour cell lines and clinical tumours. In an effort to identify other cellular changes that may be important in tumour drug resistance to anticancer drugs, we have used a differential immunodot blot method to isolate monoclonal antibodies that bind to proteins in drug resistant but not in drug sensitive cells. By using the immunodot blot method, we have isolated a monoclonal antibody (IPM96) which recognized a 40 kDa protein (P-40) in several MDR cell lines. The expression of P-40 is concurrent with the level of drug resistance. Biochemical characterization showed P-40 to be associated with the cell membrane and in the soluble fraction. Molecular cloning of P40 cDNA revealed that P-40 is identical to annexin I, a substrate for the epidermal growth factor receptor tyrosine kinase. The observed increase in P-40 (or annexin I) protein levels in drug resistant cells is due to the elevation of P-40 transcripts. The pharmacological characterization of P-40 cDNA transfectants (P-40-MCF-7) has demonstrated that overexpression of P-40 in drug sensitive cells is capable of conferring drug resistance to adriamycin, actinomycin D, Taxol and cisplatin. Taken together, our study provides convincing evidence that annexin I is important in the development of drug resistance in cancer cells. In addition, it suggests a novel mechanism of drug resistance that is different from the ATP-dependent drug efflux pumps that mediate P-gp- and MRP-associated MDR

Cancer -- Chemotherapy.

Multidrug resistance.

P-glycoprotein.

APPLICATION OF CYSTEINE SCANNING MUTAGENESIS TO THE MULTIDRUG RESISTANCE PROTEIN (MRP)1

Theis, ASHLEY

17 February 2009

Multidrug resistance protein (MRP)1, a member of the ABCC branch of the ATP-binding cassette (ABC) superfamily of transporters, can confer resistance to a broad spectrum of chemotherapeutic agents. In addition to the core functional unit of ABC transporters that consists of two membrane spanning domains (MSD) and two nucleotide binding domains (NBD), MRP1 contains a third MSD (MSD0) resulting in the following arrangement: NH2-MSD-(MSD-NBD)2. In lieu of high-resolution structural information for MRP1, cysteine scanning mutagenesis (CSM) was applied to MRP1 and involves the development of a functional template devoid of cysteines into which paired cysteines can be introduced. Previous attempts to create a functional, cys-less template of MRP1 demonstrated that cysteines in MSD0 were structurally and functional important (1;2). However, given that MRP1 lacking MSD0 remains functional, a partially functional, cys-less MRP1 lacking this domain has been expressed in yeast (3-5). Given these results, with the ultimate goal of applying CSM to MRP1 in its entirety, we investigated the endogenous cysteines within MSD0 and co-expressed MRP1 half-molecules and validated these potential CSM templates by transport and ATP binding/hydrolysis assays. Mutation of cysteines within the core of MRP1 had detrimental effects on MRP1 transport activity and further mutation of cysteines by domain revealed that wild-type activity was retained in an MSD0-less MRP1 dual lacking cysteines in both NBDs. This construct was used for introduction of cysteines on juxtaposed faces of the NBD1:NBD2 heterodimer at positions 775 and 1329; comparable residues in the related Cystic Fibrosis Transmembrane Regulator (CFTR/ABCC7) have been suggested to be evolutionarily coupled and joined by a hydrogen bond, maintained in structures of related proteins (6). Unfortunately, functional assays revealed that introduction of cysteines at these positions greatly reduced transport activity of MRP1 and diminished trapping of nucleotide at both NBDs. Finally, alanine substitution of the seven cysteines in MSD0 was not without effect and cellular trafficking assays, co-expression studies and SDS-PAGE analysis suggested an altered conformation of this domain. In addition, a disulfide pair of Cys7 and Cys32 was suggested by these experiments in MSD0 and further supported by examination of these mutants in full-length MRP1. / Thesis (Master, Pathology & Molecular Medicine) -- Queen's University, 2009-02-17 12:51:38.13

multidrug resistance

ABC transporter

cancer

cysteine

A study of MRP1-drug interactions : identification of the drug binding site(s)

Daoud, Roni N.

January 2000

Over-expression of either P-gp1 and/or MRP1 in tumor cell lines confers resistance to structurally diverse anti-cancer drugs. Although the role of these two proteins in clinical drug resistance remains to be confirmed, the use of Pgp1-specific inhibitors in combination with standard anti-cancer drugs have demonstrated significant improvement in clinical response. However, evidence exists that reversal of P-gp1 alone is not sufficient. Therefore, while no drugs are currently available that can efficiently reverse MRP1 drug efflux in tumor cells, there is an urgent need to develop MRP1-specific blockers. In an effort to gain a better understanding of MRP1-drug interactions and to identify sequences within MRP1 that interact directly with drugs, we developed two structurally diverse photosensitive drug analogues, a quinoline-based compound (IACI) and a xanthone-derivative (IAARh123). Both compounds photolabeled MRP1 and showed a direct and specific interaction with the protein at physiologically relevant sites. Initial mapping of photolabeled sequences in MRP1 (Chapters 2 and 3), identified multiple IACI- or IAARh123-photolabeled peptides (∼4--7 kDa) derived from both the N-terminal (MSD0+MSD1+NBD 1) and C-terminal (MSD2+NBD2) domains of MRP1. A subsequent study (Chapter 4), using MRP1 variants with hemagglutinin (HA) epitopes inserted at eight different locations, led to a higher resolution mapping of the previously identified IACI- or IAARh123-labeled peptides. Specifically, two photolabeled peptides (∼6--7 kDa), derived from variants with insertions at positions 574 and 1222, were immunoprecipitated with anti-HA monoclonal antibody. Based on the location of the HA epitopes in the latter variants together with molecular masses of the two peptides, the photolabeled amino acid residues were localized to MRP1 sequences encoding transmembranes 10 and 11 of MSD1 and transmembranes 16 and 17 of MSD 2. Interestingly, the same sequences were photolabeled with both

CD antigens.

Multidrug resistance.

Cancer -- Chemotherapy.