Identification of novel drug resistance-associated proteins by a panel of rat monoclonal antibodies.

Since some multidrug-resistant (MDR) tumor cell lines show drug accumulation defects but do not over-express Pgp or MDR protein (MRP), a search was made for novel MDR-related transporter proteins by immunizing rats with non-small cell lung cancer SW- 1573/2R120 cells to produce monoclonal antibodies (MAbs). Five rat MAbs (LMR-4, -12, -42, -44 and -94) were generated, showing strong membranous staining of non-Pgp MDR SW- 1573/2R120 tumor cells and minimal reactivity to the corresponding parental and revertant cell lines. In addition, a 6th MAb (LMR-5) was isolated, recognizing the MDR-related lung resistance protein (LRP), previously identified as the major vault protein. The first 5 LMR MAbs show predominantly membranous staining of several non-Pgp MDR tumor cell lines of different histogenetic origins, except for LMR-4, which recognizes only MDR sublines of the SW- 1573 cell line. Flow-cytometric analysis revealed that all MAbs, except LMR-4 and -5, detect outside epitopes. Functional studies showed that these MAbs did not restore the daunorubicin accumulation defect. All but one of the MAbs (LMR-42) showed staining of distinct normal human tissues, notably epithelial cells lining the airways and digestive tract. In addition, staining of vascular endothelial cells was found with all MAbs except LMR-4. Three MAbs (LMR-12, -44 and -94) showed remarkable immunoreactivity with vincristine-selected SW- 1573 sublines. By immunoblotting and precipitation, the LMR antigens were found to be in the 42-69 kDa range.

Altered MRP is associated with multidrug resistance and reduced drug accumulation in human SW-1573 cells.

We have analysed the contribution of several parameters, e.g. drug accumulation, MDR1 P-glycoprotein (P-gp), multidrug resistance-associated protein (MRP) and topoisomerase (topo) II, to drug resistance in a large set of drug-resistant variants of the human non-small-cell lung cancer cell line SW-1573 derived by selection with low concentrations of doxorubicin or vincristine. Selection with either drug nearly always resulted in MDR clones. The resistance of these clones could be explained by reduced drug accumulation and was associated with a decrease rather than an increase in the low MDR1 mRNA level. To test whether a decrease in MDR1 mRNA indirectly affected resistance in these cells, we introduced a MDR1-specific hammerhead ribozyme into wild-type SW-1573 cells. Although this led to a substantial reduction in MDR1 mRNA, it did not result in resistance. In all resistant clones we found an altered form of the multidrug resistance-associated protein (MRP), migrating slightly slower during SDS-polyacrylamide gel electrophoresis than MRP in parental cells. This altered MRP was also present in non-P-gp MDR somatic cell hybrids of the SW-1573 cells, demonstrating a clear linkage with the MDR phenotype. Treatment of crude cellular membrane fractions with N-glycanase, endoglycosidase H or neuraminidase showed that the altered migration of MRP on SDS-PAGE is due to a post-translational modification. There was no detectable difference in sialic acid content. In most but not all doxorubicin-selected clones, this MDR phenotype was accompanied by a reduction in topo II alpha mRNA level. No reduction was found in the clones selected with vincristine. We conclude from these results that selection of the SW-1573 cell line for low levels of doxorubicin or vincristine resistance, predominantly results in MDR with reduced drug accumulation associated with the presence of an altered MRP protein. This mechanism can be accompanied by other resistance mechanisms, such as reduced topo II alpha mRNA in case of doxorubicin selection.

Mechanisms of MRP over-expression in four human lung-cancer cell lines and analysis of the MRP amplicon.

Some multidrug resistant cell lines over-express the gene encoding the multidrug-resistance-associated protein (MRP). In all cell lines reported thus far, over-expression is associated with gene amplification. We have studied the predominant mechanisms of MRP over-expression in 4 human lung-cancer cell lines that cover a range of drug-resistance levels, and we have analyzed the MRP amplicon. In the SW-1573-derived, weakly resistant cell line 30.3M, MRP mRNA is elevated 3-fold in the absence of gene amplification. Run-on analysis shows that the increased MRP gene expression in this cell line is due to transcriptional activation. In the highly resistant GLC4/ADR and COR-L23/R cells, MRP gene amplification predominates, whereas in the moderately resistant MOR/R cells, gene amplification is combined with a mechanism resulting in an additional increase in the level of MRP mRNA. Fluorescence in situ hybridization shows that, in the GLC4/ADR cells, amplified MRP sequences are present both in double minute chromosomes (DM) and in homogeneously staining regions (HSR). By pulsed-field gel electrophoresis we show that the MRP-containing DM are 1 Mb in length. Chromosome-16-specific repetitive sequences adjacent to the MRP gene are also present in the DM and HSR, compatible with the involvement of these sequences in recombination events underlying MRP gene amplification. Our results show that low levels of drug resistance may arise by transcriptional activation of the MRP gene, whereas at high levels of drug resistance amplification of the MRP gene predominates, possibly facilitated by the presence of recombination-prone sequences.

Reduced topoisomerase II activity in multidrug-resistant human non-small cell lung cancer cell lines.

Multidrug-resistant (MDR) cell lines often have a compound phenotype, combining reduced drug accumulation with a decrease in topoisomerase II. We have analysed alterations in topoisomerase II in MDR derivatives of the human lung cancer cell line SW-1573. Selection with doxorubicin frequently resulted in reduced topo II alpha mRNA and protein levels, whereas clones selected with vincristine showed normal levels of topo II alpha. No alterations of topo II beta levels were detected. To determine the contribution of topo II alterations to drug resistance, topo II activity was analysed by the determination of DNA breaks induced by the topo II-inhibiting drug 4'-(9-acridinylamino)methane-sulphon-m-anisidide (m-AMSA) in living cells, as m-AMSA is not affected by the drug efflux mechanism in the SW-1573 cells. The number of m-AMSA-induced DNA breaks correlated well (r = 0.96) with in vitro m-AMSA sensitivity. Drug sensitivity, however, did not always correlate with reduced topo II mRNA or protein levels. In one of the five doxorubicin-selected clones m-AMSA resistance and a reduction in m-AMSA-induced DNA breaks were found in the absence of reduced topo II protein levels. Therefore, we assume that post-translational modifications of topo II also contribute to drug resistance in SW-1573 cells. These results suggest that methods that detect quantitative as well as qualitative alterations of topo II should be used to predict the responsiveness of tumours to cytotoxic agents. The assay we used, which measures DNA breaks as an end point of topo II activity, could be a good candidate.

Classical and novel forms of multidrug resistance and the physiological functions of P-glycoproteins in mammals.

In this paper, we review recent work on multidrug resistance (MDR) in Amsterdam. We have generated mice homozygous for a disruption of one of their P-glycoprotein (Pgp) genes. The mutations do not interfere with viability or fertility, showing that these Pgps have no indispensable role in early development or metabolism. Mice homozygous for a disruption of their mdr2 gene, however, develop liver disease and this appears to be due to their complete inability to secrete phospholipids into bile. This suggests that the mdr2 Pgp (and, by inference, its human MDR3 homologue) is essential for translocating phospholipids through the hepatocyte canalicular membrane in which this Pgp is located. These and other results show the importance of the genetic approach for studying drug metabolism. MDR is not only caused by increased activity of Pgps. When the human non-small cell lung carcinoma cell line SW-1573 is selected in vitro for low level doxorubicin resistance, the resistant variants are nearly always multidrug resistant, but this is not due to increased Pgp activity. Only when resistance is pushed to higher levels does activation of the MDR1 Pgp gene occur. This suggests that clinically relevant levels of drug resistance in some cells may be caused predominantly by non-Pgp-mediated drug resistance mechanisms. The protein responsible for MDR in the SW-1573 cells has not yet been identified and experiments are in progress to find the gene encoding it.

Analysis of the expression of MRP, the gene for a new putative transmembrane drug transporter, in human multidrug resistant lung cancer cell lines.

Human cells can become multidrug resistant (MDR) by an increase in the activity of the MDR1 P-glycoprotein or by other, as yet unknown mechanisms, referred to as non-P-glycoprotein mediated MDR (non-Pgp MDR). S. P. C. Cole et al. [Science (Washington DC), 258: 1650-1654, 1992] recently reported that in two cell lines non-Pgp MDR was associated with the overexpression of a new putative membrane transporter gene, MRP. Using an RNase protection assay we have analyzed the expression of MRP in non-Pgp MDR sublines of the human lung cancer cell lines SW-1573 (non-small cell lung cancer) and GLC4 (small cell lung cancer). In all of ten SW-1573 derived lines examined the MRP mRNA level was equal to that in the parental line, whereas MRP was 25-fold overexpressed in a resistant subline of GLC4. We conclude that overexpression of MRP cannot account for all forms of non-Pgp MDR.

Genetic transfer of non-P-glycoprotein-mediated multidrug resistance (MDR) in somatic cell fusion: dissection of a compound MDR phenotype.

A non-P-glycoprotein-mediated mechanism of multidrug resistance (non-Pgp MDR) has been identified in doxorubicin-selected sublines of the human non-small cell lung carcinoma cell line SW-1573. These sublines are cross-resistant to daunorubicin, VP16-213, Vinca alkaloids, colchicine, gramicidin D, and 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA). They accumulate less drug than the parental cells and their resistance is not due to the MDR1-encoded P-glycoprotein, as the resistant cell lines have lost the low amount of MDR1 mRNA detectable in parental cells. Here we show that the resistant cell lines also contain less topoisomerase II mRNA and enzyme activity than the parental cells. This might contribute to the resistance of these lines to drugs interacting with topoisomerase II, such as doxorubicin, daunorubicin, and VP16-213, but cannot account for the resistance to the other drugs. We have tested whether all properties of the non-Pgp MDR cell lines cosegregate in somatic cell fusions between lethally gamma-irradiated, resistant donor cells and drug-sensitive acceptor cells. Whereas a MDR phenotype with reduced drug accumulation and the loss of MDR1 P-glycoprotein mRNA were cotransferred to the acceptor cells, the decrease in topoisomerase II gene expression was not. We conclude that the MDR phenotype, the reduced drug accumulation, and the loss of MDR1 P-glycoprotein mRNA are genetically linked. They might be due to a single dominant mutation, which does not cause the alteration in topoisomerase II.