NMR spectroscopy studies of severe hypokalemia in isolated rat hearts.

Effects of acute tissue potassium depletion on cellular energy metabolism are poorly understood. To examine this issue, we performed the following studies in an isovolumic isolated perfused heart preparation. Perfusion of isolated hearts with media lacking potassium (K = 0 mmol/l) for 30 min resulted in ventricular fibrillation, rapid decreases in creatine phosphate (PCr) and ATP, and increases in Pi. During reinstitution of normal perfusate potassium, hearts did not resume normal contractions, and no increases in tissue ATP were observed. However, some normalization of PCr and Pi were noted during reinstitution of normal perfusate. Perfusion with media containing K = 2 mmol/l caused significant but less dramatic decreases in tissue ATP concentrations than perfusion with media containing K = 0 mmol/l. Reduction of perfusate calcium from 1.2 (normal) to 0.6 mmol/l in media containing K = 0 mmol/l attenuated the fall in ATP seen with media containing K = 0 mmol/l. Conversely, increasing perfusate calcium to 2.4 mmol/l in media containing K = 2 mmol/l markedly worsened the fall in tissue ATP seen in media containing K = 2 mmol/l. In this subgroup (K = 2 mmol/l, Ca = 2.4 mmol/l), ventricular fibrillation developed approximately one-half of the time. However, no differences in the rate of ATP fall were observed between those hearts that fibrillated and those that did not. During perfusion with media containing K = 0 mmol/l, nuclear magnetic resonance (NMR)-visible tissue potassium concentrations fell rapidly and dramatically. Significant but less severe reductions in NMR-visible potassium were seen during perfusion with media containing K = 2 mmol/l. With K = 2 mmol/l perfusate, the rate of cellular potassium loss was influenced by perfusate calcium concentration. When cardiac mitochondria were examined after perfusion with media containing K = 0 mmol/l, evidence for calcium loading as well as respiratory dysfunction was noted. These data indicate that reductions in perfusate potassium caused dramatic reductions in tissue ATP and NMR-visible potassium concentrations. The abnormal energy metabolism that results from acute cellular potassium depletion appears to be due, at least in part, to impaired energy production by cardiac mitochondria that become calcium loaded.

Decreased mutation rate for cellular resistance to doxorubicin and suppression of mdr1 gene activation by the cyclosporin PSC 833.

BACKGROUND: Various mechanisms can contribute to cellular resistance to doxorubicin. These include expression of the multidrug transporter P-glycoprotein (product of the mdr1 gene [also known as PGY1], Mrp (multidrug resistance-associated protein), the p110 major vault protein, altered glutathione metabolism, and altered levels or activity of topoisomerase II (Topo II). We reported recently that single-step treatment of human MES-SA sarcoma cells with 40 nM doxorubicin resulted in selection of spontaneous mutants at a rate of 1.8 x 10(-6) per cell generation. All individually selected mutants manifested the multidrug-resistant phenotype, related to activation of the mdr1 gene. PURPOSE: Luria and Delbrück fluctuation analysis was performed with MES-SA cells to determine the mutation rate and the nature and mechanisms of resistance after single-step selection with doxorubicin in the presence of the cyclosporin PSC 833, a potent modulator of multidrug resistance. METHODS: Ten flasks were seeded with 2000 cells/flask and grown to confluent populations of approximately 8 x 10(6) cells. After reseeding in 96-well plates, the populations were treated with 40 nM doxorubicin and 2 microM PSC 833 for 3 weeks. Surviving colonies were scored, individually harvested, and propagated. The drug-resistant phenotype was assessed by the tetrazolium dye (MTT) cytotoxicity assay and by monitoring cellular glutathione content and radiolabeled drug accumulation. Coupled reverse transcription-polymerase chain reaction (RT-PCR) was used to evaluate mdr1, MRP, Topo II alpha, and Topo II beta gene expression. Topo II, P-glycoprotein, and p110 levels were examined by immunoblotting or immunocytochemistry. Topo II activity was assessed by decatenation of kinetoplast DNA, and etoposide-induced cleavable complex formation was studied by the potassium-sodium dodecyl sulfate precipitation assay. RESULTS: Mutations were detected at a rate of 2.5 x 10(-7) per cell generation. Analysis of variance indicates that spontaneous mutations, rather than changes in cellular function, conferred resistance to doxorubicin and PSC 833. None of the isolated clones expressed mdr1 messenger RNA or P-glycoprotein, and none exhibited an increase in MRP expression. No alterations were found in cellular glutathione content, intracellular accumulations of daunorubicin and etoposide, levels of p110 protein, or levels of Topo II beta transcripts. However, a significant decrease in Topo II alpha messenger RNA and protein was found in all examined clones, as well as decreased Topo II catalytic activity and reduced cleavable complex formation in the presence of etoposide. CONCLUSIONS: PSC 833 co-selection reduced the mutation rate for doxorubicin-selected resistance by 10-fold and suppressed the emergence of mdr1 mutants. Survival of cells exposed to doxorubicin and PSC 833 occurs by selection of spontaneously arising mutants that exhibit altered Topo II alpha expression. IMPLICATIONS: Our results suggest that treatment with multidrug resistance modulators such as PSC 833 together with multidrug resistance-related cytotoxins may suppress the activation of mdr1 and prevent the emergence of resistant cancer cell clones with the multidrug-resistant phenotype.

Novel mechanism of resistance to paclitaxel (Taxol) in human K562 leukemia cells by combined selection with PSC 833.

A paclitaxel-resistant cell line, KPTA5, was established by co-selecting the parental erythroleukemic cell line K562 with stepwise increased concentrations of paclitaxel (Taxol) in the presence of the cyclosporin D analogue PSC 833 (2 microM), a potent modulator of the multidrug resistance phenotype. KPTA5 cells are 9-fold resistant to paclitaxel and taxotere, but do not exhibit significant resistance to Vinca alkaloids, etoposide, anthracyclines, antimetabolites, or alkylating agents. Doubling time and morphology were similar to the parental K562 cells. Reverse transcriptase-polymerase chain reaction (rt-PCR) analysis revealed no alterations in the expression of the mdr1 and MRP genes. Cellular paclitaxel accumulation was unchanged. Cell cycle analyses showed that at 20 nM there was a significantly higher proportion of K562 cells blocked in G2/M, in comparison with KPTA5 cells. In both cases, disruption of the mitotic spindles and the presence of multiple mitotic asters were comparable but occurred at lower paclitaxel concentrations in K562 cells than in KPTA5 cells. There was no difference in total tubulin content between K562 and KPTA5 cells as analyzed by immunoblotting with an anti-beta-tubulin monoclonal antibody. However, we found that KPTA5 cells presented a 2-fold increase both in 5 beta-tubulin mRNA expression and in the corresponding tubulin protein Class IV isotype content, as evaluated by rt-PCR and immunostaining. In conclusion, the KPTA5 cell line displays a novel mechanism of resistance to paclitaxel which does not involve altered cellular drug accumulation. The data presented suggest that alterations in expression of the 5 beta-tubulin gene may be involved in paclitaxel resistance.

Volume-activated chloride current is not related to P-glycoprotein overexpression.

It has been suggested that P-glycoprotein (P-gp), an ATP-dependent transporter responsible for classical multidrug resistance, is also a volume-regulated chloride channel. We reexamined this hypothesis by use of whole-cell patch clamp recordings of three matched pairs of cell lines, which were either drug-sensitive or drug-resistant due to P-gp overexpression. We demonstrate here that volume-regulated chloride-selective currents can be induced in cells with or without P-gp expression. Overexpression of either P-gp or cystic fibrosis transmembrane conductance regulator, the protein product of the CF gene and another member of the ATP-dependent transporters, is associated with a hypotonicity-induced, rapid onset, transient current prior to onset of the volume-sensitive chloride-selective current, an apparent nonspecific effect related to the overexpression of an integral membrane protein. These results suggest that there is no relationship between P-gp and the chloride channel activated by cell swelling.

Prevalence of multidrug resistance related to activation of the mdr1 gene in human sarcoma mutants derived by single-step doxorubicin selection.

Fluctuation analysis experiments were performed in the human sarcoma cell line MES-SA to assess whether selection or induction mechanisms determine resistance to doxorubicin (DOX), mutation rates, and the nature of the surviving clones. Thirteen flasks were seeded with 2000 cells/flask and grown to confluent populations of approximately 3.3 x 10(6) cells. After reseeding in 96-well plates, each population was treated with 40 nM DOX for 2 weeks. Surviving colonies were scored and harvested. Clones were propagated and analyzed for drug resistance phenotype. Expression of the mdr1, mrp, and topoisomerase II alpha and II beta genes was analyzed by reverse transcription-polymerase chain reaction. Accumulation of the P-glycoprotein substrate rhodamine-123 was measured by flow cytometry, with and without the cyclosporin D analogue SDZ PSC 833. Cellular glutathione levels were measured by flow cytometry, and M(r) 110,000 vesicular protein (p110) expression was detected by immunohistochemistry. Analysis of variance supported the hypothesis of spontaneous mutations rather than induction conferring DOX resistance. At this stringent level (5-6 log cell killing) of drug exposure, the mutation rate was estimated at 1.8 x 10(-6) per cell generation. All 30 propagated clones demonstrated cross-resistance to vinblastine, etoposide, and paclitaxel (Taxol), but not to cisplatin or bleomycin. Increased mRNA levels of mdr1 were observed in all 27 clones tested, including at least 1 from each of the 13 populations. No alterations were found in expression or level of topoisomerase II alpha or II beta, mrp, glutathione, and p110. Expression of P-glycoprotein was confirmed by flow cytometry using the monoclonal antibody UIC2. In almost all tested clones, decreased intracellular rhodamine-123 accumulation was modulated by 2 microM SDZ PSC 833, and the vinblastine resistance in all examined clones was completely reversed by SDZ PSC 833 and verapamil. Our study demonstrates that survival of cells exposed to DOX in a single step occurs as a result of a stochastic process consistent with mutational events. Activation of the mdr1 gene is the predominant mechanism selected by DOX in these resistant clones.

Mutation rates and mechanisms of resistance to etoposide determined from fluctuation analysis.

BACKGROUND: The major known mechanisms of resistance to etoposide include altered expression of its target enzyme, topoisomerase II (Topo II), and the multidrug-resistant phenotypes encoded by the mdr1 and MRP (multidrug resistance-associated protein) genes. There is little information regarding the distribution, frequency, and origin of these mechanisms in cancer cells. PURPOSE: We performed fluctuation analysis experiments with the human sarcoma cell line, MES-SA, to assess 1) if selection or induction mechanisms are involved in resistance to etoposide, 2) mutation rates for cellular resistance to etoposide, and 3) the nature of the single-step selected surviving clones. METHODS: Three groups of 10 flasks were seeded with more than 2000 cells each and allowed to grow to near confluence (approximately 3 x 10(6) cells per flask). After reseeding, each group received etoposide for 1 week at a final concentration of 0.5 microM (group A), 1.0 microM (group B), and 5.0 microM (group C). Surviving colonies in each of the 30 populations were scored and individually harvested. RESULTS: Mutation rates were estimated at 2.9 x 10(-6) (group A), 5.7 x 10(-7) (group B), and 1.7 x 10(-7) (group C) per cell generation. Of 61 propagated colonies, four of 26 from group A, five of 19 from group B, and none of 16 from group C were stably resistant. Analysis of variance supported the hypothesis of spontaneous mutations rather than induction, conferring etoposide resistance in groups A and B. Five of the stably resistant clones were cross-resistant to doxorubicin. Analysis by polymerase chain reaction failed to detect the expression of the multidrug-resistant gene mdr1 messenger RNA (mRNA) in any of the clones. No increase in expression of the MRP gene was observed. However, a significant decrease in both Topo II alpha and II beta mRNA (30%-70%) was found in six of seven stably resistant and six of six unstably resistant mutants. CONCLUSIONS: Our study demonstrates that resistance to etoposide arises spontaneously, with most clones surviving either stochastically or through very labile mechanisms of resistance. The experimental design has derived a set of resistant mutants from a single-step selection. In those clones, decreased expression of Topo II is the predominant mechanism selected. IMPLICATIONS: These findings suggest that stable resistance to etoposide chemotherapy may be acquired by selection of spontaneously arising mutants rather than induction by drug exposure. The stably resistant clones may represent descendants from a single mutational event in each population.