Characterization of adriamycin-resistant and radiation-sensitive Chinese hamster cell lines

Down-regulation of catalase gene expression in the doxorubicin-resistant AML subline AML-2/DX100

A major obstacle to successful cancer chemotherapy is the development of multidrug resistance (MDR). The previous study revealed that a doxorubicin-resistant AML subline (AML-2/DX100) overexpressed an MDR-associated protein (MRP) but not P-glycoprotein. The AML-2/DX100 also showed various levels of resistance to daunorubicin and vincristine but was paradoxically sensitive to hydrogen peroxide (5-fold), t-butyl hydroperoxide (3-fold), and paraquat (2-fold) when compared to the drug-sensitive parental AML-2 cells (AML-2/WT). We compared the activities of antioxidant enzymes to detoxify reactive oxygen species (ROS), including superoxide dismutases, glutathione S-transferase, catalase, glutathione reductase, glutathione peroxidase, and glucose-6-phosphate dehydrogenase in both AML-2/WT and AML-2/DX100. Interestingly, of these antioxidant enzymes, catalase activity of AML-2/DX100 decreased significantly to about one-third that of AML-2/WT (P < 0.000005). The decreased activity of catalase was due to reduced expression of the catalase gene; confirmed by Western blot and reverse transcription-polymerase chain reaction (RT-PCR) analyses. The decreased activity of catalase was maintained even in the absence of doxorubicin for 3 months as well as by the treatment of probenecid, an MRP inhibitor. In addition, there was no difference in catalase activity between HL-60 and another MRP-overexpressing subline HL-60/Adr. Taken together, the paradoxical increase in the sensitivity of an MRP-overexpressing AML-2/DX100 in response to peroxides and paraquat is due to the down-regulation of catalase gene expression, which totally independent of overexpression of MRP. It is therefore possible that decreased catalase activity could be exploited as an Achilles' heel in resistant cells such as this.

Lysosomal accumulation of drugs in drug-sensitive MES-SA but not multidrug-resistant MES-SA/Dx5 uterine sarcoma cells

Sequestration of drugs in intracellular vesicles has been associated with multidrug-resistance (MDR), but it is not clear why vesicular drug accumulation, which depends upon intracellular pH gradients, should be associated with MDR. Using a human uterine sarcoma cell line (MES-SA) and a doxorubicin (DOX)-resistant variant cell line (Dx-5), which expresses p-glycoprotein (PGP), we have addressed the relationship between multidrug resistance, vesicular acidification, and vesicular drug accumulation. Consistent with a pH-dependent mechanism of vesicular drug accumulation, studies of living cells vitally labeled with multiple probes indicate that DOX and daunorubicin (DNR) predominately accumulate in lysosomes, whose lumenal pH was measured at < 4.5, but are not detected in endosomes, whose pH was measured at 5.9. However, vesicular DOX accumulation is more pronounced in the drug-sensitive MES-SA cells and minimal in Dx5 cells even when cellular levels of DOX are increased by verapamil treatment. While lysosomal accumulation of DOX correlated well with pharmacologically induced differences in lysosome pH in MES-SA cells, lysosomal accumulation was minimal in Dx5 cells regardless of lysosomal pH. We found no differences in the pH of either endosomes or lysosomes between MES-SA and Dx5 cells, suggesting that, in contrast to other MDR cell systems, the drug-resistant Dx5 cells are refractory to pH-dependent vesicular drug accumulation. These studies demonstrate that altered endomembrane pH regulation is not a necessary consequence of cell transformation, and that vesicular sequestration of drugs is not a necessary characteristic of MDR.

How Fe3+ binds anthracycline antitumour compounds. The myth and the reality of a chemical sphinx

The interaction of Fe3+ with several anthracycline antitumour antibiotics has been reinvestigated. Absorption and circular dichroism (CD) measurements were carried out (i) in aqueous solution and (ii) in semi-aqueous MeOH to avoid the stacking of the anthracycline molecules. The Fe3+ binding to anthracycline was dependent on the metal-to-ligand molar ratio, antibiotic concentration, ionic strength, and pH. The formation of two major Fe3(+)-anthracycline complexes, I and II, was observed for all the drugs. These species differed in their coordination modes to the anthracycline ligands. Complex I was a monomeric species, where Fe3+ was bound to the anthracycline through the {C(11)-O-; C(12) = O} chelating site. In complex II, Fe3+ was also bound through the {C(5) = O; C(6)-O-} coordination site. Thus, the antibiotic ligand was acting as a bridge between two metal ions, forming oligomeric (or polymeric) structures. The different degree of association of the anthracyclines could be responsible for the reactivity of the metal ion. In fact, complexes I and II could constitute mononuclear, binuclear or polynuclear Fe3+ species depending on the competitive kinetics of both coordination and hydrolysis of the metal ion.

Inhibition of P-glycoprotein-mediated transport by a hydrophobic contaminant in commercial gluconate salts

The substitution of gluconate for Cl- is commonly used to characterize Cl- transport or Cl--dependent transport mechanisms. We evaluated the effects of substituting gluconate for Cl- on the transport of the P-glycoprotein substrate rhodamine 123 (R123). The replacement of Ringer solution containing Cl- (Cl--Ringer) with gluconate-Ringer inhibited R123 efflux, whereas the replacement of Cl- by other anions (sulfate or cyclamate) had no effect. The inhibition of R123 efflux by gluconate-Ringer was absent after chloroform extraction of the sodium gluconate salt. The readdition of the sodium gluconate-chloroform extract to the extracted gluconate-Ringer or to cyclamate-Ringer inhibited R123 efflux, whereas its addition to Cl--Ringer had no effect. These observations indicate that the inhibition of P-glycoprotein-mediated R123 transport by gluconate is due to one or more chloroform-soluble contaminants and that the inhibition is absent in the presence of Cl-. The results are consistent with the fact that P-glycoprotein substrates are hydrophobic. Care should be taken when replacing ions to evaluate membrane transport mechanisms because highly pure commercial preparations may still contain potent contaminants that affect transport.

P-glycoprotein is not a swelling-activated Cl- channel; possible role as a Cl- channel regulator

1. The whole-cell configuration of the patch-clamp technique was used to determine if P-glycoprotein (Pgp) is a swelling-activated Cl- channel. 2. Hamster pgp1 cDNA was transfected into a mouse fibroblast cell line resulting in expression of functional Pgp in the plasma membrane. This cell line was obtained without exposure to chemotherapeutic agents. 3. Swelling-activated whole-cell Cl- current (ICl,swell) was elicited by lowering the bath osmolality. ICl,swell was characterized in detail in the pgp1-transfected mouse cell line and compared with that of its parental cell line. Expression of Pgp did not modify the magnitude or properties of ICl,swell, except that addition of the anti-Pgp antibody C219 to the pipette solution inhibited this current by 75% only in the Pgp-expressing cells. 4. ICl,swell in the mouse Pgp-expressing cell line was compared with that in a Pgp-expressing hamster fibroblast cell line. The characteristics of ICl,swell (voltage dependence, blocker sensitivity, anion selectivity sequence, requirement for hydrolysable ATP) in Pgp-expressing cells were different between the two cell lines. These results suggest that the channel(s) responsible for ICl,swell are different between the two cell lines. In addition, C219 inhibited ICl,swell in both Pgp-expressing cell lines, even though they seem to express different swelling-activated Cl- channels. 5. We conclude that firstly, Pgp is not a swelling-activated Cl- channel; secondly, it possibly functions as a Cl- channel regulator; and thirdly, ICl,swell is underlined by different Cl- channels in different cells.

Isolation and characterization of a cell line resistant to 5-[3-(2-nitro-1-imidazoyl)-propyl]-phenanthridinium bromide (2-NLP-3), a DNA-intercalating hypoxic cell radiosensitizer and cytotoxin

A DNA-targeted hypoxic cell radiosensitizer and cytotoxin, 5-[3-(2-nitro-1-imidazoyl)-propyl]-phenanthridinium bromide (2-NLP-3), has been shown previously to have increased efficacy over untargeted analogues in vitro. To further study the mechanism of action of this compound, a cell line, CHO-1000, derived from Chinese hamster ovary (CHO) AA8-4 cells was isolated. This cell line is capable of continuously growing in a concentration of 2-NLP-3 approximately 10-fold greater than that tolerated by wild-type CHO cells. The resistance of CHO-1000 to 2-NLP-3 was compared with that of the P-glycoprotein overexpressing, multidrug resistant Chinese hamster cell line CHR-C5 (C5). The resistance of CHO-1000 cells to the acute toxic effects of 2-NLP-3 under both hypoxic and aerobic exposure conditions was intermediate to that of the sensitive CHO wild-type cells and the resistant C5 cells. A similar pattern was seen for the hypoxic cell radiosensitizing ability of 2-NLP-3. 2-NLP-3 produced significant depletion of glutathione under both hypoxic and aerobic conditions in all three cell lines studied, and the degree of depletion was correlated with drug toxicity. CHO-1000 and C5 cells were significantly more resistant to colchicine and doxorubicin compared with wild-type cells. The toxicity pattern of 2-NLP-3 and its comparison phenanthridinium ion, P3, was not the same for CHO-1000 cells compared with C5 cells. Verapamil was an effective agent for reversing the hypoxic resistance to 2-NLP-3 in both CHO-1000 and C5 cells, but only a partial reversal of aerobic resistance was observed in CHO-1000 cells. These results indicate that the resistant phenotype of CHO-1000 is mediated to some degree by P-glycoprotein expression, but that other as yet unidentified factors are also involved.

Sequestration of doxorubicin in vesicles in a multidrug-resistant cell line (LZ-100)

A multidrug-resistant Chinese hamster cell line, LZ-8, was subcultured in increasing levels of doxorubicin (DOX) until capable of growth in 100 micrograms/mL DOX. This new derivative, designated LZ-100, is the most DOX-resistant line in the LZ series, based on a comparison of Ki-1 values from cell survival studies. This increased level of drug resistance in LZ-100 cells did not result from (i) higher levels of P-glycoprotein (P-gp) in the plasma membrane compared with LZ-8 cells, since this protein constitutes approximately 20% of the total plasma membrane protein in both cell lines, or (ii) more efficient drug pumping by the same amount of P-gp, since efflux of rhodamine 123 and DOX was comparable in the two cell lines. However, an altered drug distribution was observed in LZ-100 cells compared with wild-type V79 cells; in LZ-100 cells DOX was largely excluded from the nucleus and was sequestered in vesicles in the cytoplasm. The number of vesicles per cell seen after DOX exposure corresponded with the level of drug resistance achieved by the LZ cell lines studied. DOX concentration-response experiments revealed that vesicle formation exhibited a biphasic relationship, with an initial rapid increase followed by a plateau where no further increase was observed. Time-course studies in LZ-100 cells revealed that the maximum number of DOX-containing vesicles per cell occurred 3-4 hr following initiation of DOX treatment. Radiation exposure (10 Gy) immediately preceding DOX treatment decreased the number of vesicles formed in LZ-100 cells by more than one-half and altered the subcellular distribution of DOX from an almost exclusively cytoplasmic to a homogeneous nuclear/cytoplasmic distribution. This redistribution was not a result of radiation inhibition of P-gp efflux. The inhibitory effect of radiation on vesicle formation increased with increasing radiation dose up to 10 Gy. Drug-containing vesicles were also observed in LZ-100 cells following exposure to mitoxantrone or daunorubicin (to which LZ-100 cells are also resistant), but fewer vesicles were observed than with DOX. These studies demonstrate that the drug sequestration phenomenon (i) occurs in cells exhibiting widely different levels of drug resistance, (ii) correlates with the level of drug resistance in LZ cell lines, (iii) occurs rapidly following exposure to DOX, mitoxantrone, or daunorubicin, and (iv) can be inhibited by irradiation.(ABSTRACT TRUNCATED AT 400 WORDS)

Unidirectional fluxes of rhodamine 123 in multidrug-resistant cells: evidence against direct drug extrusion from the plasma membrane

P-glycoprotein (Pgp), a plasma membrane protein overexpressed in multidrug-resistant tumor cells, is an ATPase thought to actively export cytotoxic drugs. It has been proposed that Pgp transports drugs directly from the lipid bilayer to the external medium ("vacuum cleaner" hypothesis). A possible mechanism for this model is that the Pgp is a flippase--i.e., it catalyzes the translocation of hydrophobic substrates from the inner to the outer leaflet of the cell membrane. Two immediate predictions of the vacuum cleaner and flippase hypotheses are that the apparent unidirectional influx of substrate should be less in Pgp-expressing than in Pgp-lacking cells and that this difference should be abolished by inhibition of the Pgp. We used Chinese hamster fibroblasts with different levels of Pgp expression to measure true unidirectional fluxes of rhodamine 123 (R123), a Pgp-transported fluorescent dye that accumulates in mitochondria (hence, its cytosolic concentration remains low at short times after external addition). The unidirectional efflux of R123 was proportional to the level of Pgp expression and was reduced by Pgp inhibitors. The unidirectional influx of R123 was the same in sensitive and resistant cells--i.e., independent of the level of Pgp expression and insensitive to inhibitors of R123 efflux. From these results, we rule out the vacuum cleaner and flippase hypotheses and conclude that Pgp extracts the actively transported substrates from the cytosol and not from the plasma membrane.

Use of chromosome microdissection, the polymerase chain reaction, and dot blot hybridization to analyze double minute chromosomes

The potential usefulness of chromosome microdissection, the polymerase chain reaction (PCR), and dot blot hybridization as a quick screening method for determining the genetic composition of double minute chromosomes (DMs) was evaluated. DMs or abnormally banding regions (ABRs) were microdissected from multidrug-resistant hamster cell lines and amplified with PCR using primers specific for the hamster multidrug-resistance (MDR) gene, pgp 1. The microdissected-PCR-amplified products were shown to (a) hybridize to a 32P-labeled pCHP1 probe for the hamster MDR gene by using dot blot or Southern blot analysis and also (b) hybridize back to the chromosome region from which they were originally dissected by using fluorescent in situ hybridization. Microdissected/PCR-amplified DMs were also shown to hybridize to ABRs. When microdissected DMs and ABRs were amplified using hamster specific Alu primers, the resulting material was shown to hybridize with probes for hamster MDR and Alu. These results suggest that the DMs contained in these MDR hamster cell lines contain Alu-like sequences and the chromosome microdissection-PCR-hybridization approach might be used as a quick screening method for identifying genes amplified in DMs and ABRs in cell lines and human tumor samples.

An enhanced ability for transforming adriamycin into a noncytotoxic form in a multidrug-resistant cell line (LZ-8)

Multidrug-resistant LZ-8 cells are 9000-fold more resistant to Adriamycin (ADRM) exposure than wild-type V79 cells. To understand more about the mechanisms producing such high level resistance, we tested whether LZ-8 cells inactivate ADRM toxicity to a greater extent than wild-type V79 cells. ADRM was recovered from (1) culture media of wild-type V79 and ADRM-resistant LZ-8 cells; (2) V79 and LZ-8 cells; and (3) LZ-8 cell plasma membrane, and the cytotoxicity was determined by treating V79 cells for 1 hr with a known concentration of the recovered ADRM. ADRM obtained from LZ-8 cells or its culture medium exhibited less cytotoxicity than that recovered from V79 cells or its culture medium. ADRM extracted from LZ-8 cell plasma membrane was noncytotoxic. HPLC analysis revealed that the extracted ADRM was structurally changed compared to stock ADRM. The retention time in the column was 7 min for stock ADRM, and 23 min for the recovered ADRM. Thus, LZ-8 cells have an increased ability to transform ADRM into a noncytotoxic form compared to wild-type V79 cells. This transformation involves structural conversion into a previously unidentified ADRM metabolite. The greatly increased survival of LZ-8 cells compared to V79 cells after ADRM treatment is due to at least two mechanisms: (1) an enhanced ability to inactivate the cytotoxicity of ADRM, and (2) increased drug efflux resulting from the amplification and overexpression of the pgp 1 gene in these cells. Our results suggest the possibility that P-glycoprotein participates in drug binding/inactivation in addition to serving as a drug efflux pump.