Differential expression of Glut 1 mRNA and protein levels correlates with increased sensitivity to the glyco-conjugated nitric oxide donor (2-glu-SNAP) in different tumor cell types.

Nitric Oxide (NO) releasing agents can serve as potent cytotoxic agents. However at present there are no effective ways to target delivery of NO donors like S-nitroso-N-acetyl-penicillamine (SNAP). SNAP conjugated to glucose (2-gluSNAP) can be readily transported across the membrane by GLUT 1 transporters. Therefore, sensitivity of cells to 2-gluSNAP may depend on glucose-transporter GLUT 1. We evaluated the cytotoxicity of SNAP and 2-gluSNAP on a GLUT 1 rich glioblastoma cell line T98G and GLUT 1 deficient osteoblastoma cell line 143B and its mitochondria-deficient variant rhoo (cell line 206). The cytotoxity of SNAP and 2-gluSNAP was assessed by clonogenic assay performed in the above cell lines in vitro. Immunoblotting and semi-quantitative real-time PCR assays were used to evaluate the expression of GLUT 1 transporter at protein and mRNA levels. The glioblastoma cell line T98G was more sensitive to 2-gluSNAP than unconjugated SNAP. SNAP and 2-gluSNAP affected the osteosarcoma cell lines 143B and rhoo poorly. Immunoblot analysis detected GLUT 1 protein in T98G cells and not in 143B or rhoo. There was about a 10-fold difference in GLUT 1 mRNA level in T98G cells compared to 143B and rhoo cell lines. This is consistent with our cytotoxicity studies and immunoblot analysis. Our results give credence to our hypothesis that the sensitivity to NO donors can be increased by glyco-conjugation and the cytotoxicity of the glyco-conjugated NO donors depends on the expression of GLUT 1 mRNA and protein.

Hypersensitization of tumor cells to glycolytic inhibitors.

The slow growth of cells in the inner core of solid tumors presents a form of multidrug resistance to most of the standard chemotherapeutic agents, which target the outer more rapidly dividing cells. However, the anaerobic environment of the more centrally located tumor cells also provides an opportunity to exploit their dependence on glycolysis for therapeutic gain. We have developed two in vitro models to investigate this possibility. Model A represents osteosarcoma wild-type (wt) cells treated with agents which inhibit mitochondrial oxidative phosphorylation (Oxphos) by interacting with complexes I, III, and V of the electron transport chain in different ways, i.e., rhodamine 123 (Rho 123), rotenone, antimycin A, and oligomycin. All of these agents were found to hypersensitize wt cells to the glycolytic inhibitor 2-deoxyglucose. Cells treated with Rho 123 also become hypersensitive to oxamate, an analogue of pyruvate, which blocks the step of glycolysis that converts pyruvate to lactic acid. Model B is rho(0) cells which have lost their mitochondrial DNA and therefore cannot undergo Oxphos. These cells are 10 and 4.9 times more sensitive to 2-deoxyglucose and oxamate, respectively, than wt cells. Lactic acid levels, which are a measure of anaerobic metabolism, were found to be > 3 times higher in rho(0) than in wt cells. Moreover, when wt cells were treated with Rho 123, lactic acid amounts increased as a function of increasing Rho 123 doses. Under similar Rho 123 treatment, rho(0) cells did not increase their lactic acid levels. These data confirm that cell models A and B are similarly sensitive to glycolytic inhibitors due to their dependence on anaerobic metabolism. Overall, our in vitro results suggest that glycolytic inhibitors could be used to specifically target the slow-growing cells of a tumor and thereby increase the efficacy of current chemotherapeutic and irradiation protocols designed to kill rapidly dividing cells. Moreover, glycolytic inhibitors could be particularly useful in combination with anti-angiogenic agents, which, a priori, should make tumors more anaerobic.

Rho(0) tumor cells: a model for studying whether mitochondria are targets for rhodamine 123, doxorubicin, and other drugs.

A human osteosarcoma cell line devoid of mitochondrial DNA (rho(0)) and its wild-type parental cell counterpart (wt) are presented as a model to investigate drug targeting. By virtue of the absence of mitochondrial DNA, rho(0) cells cannot perform electron transport or oxidative phosphorylation. Since most of the drugs studied are transported by the efflux pumping systems controlled by the MDR1 and MRP1 genes, both cell lines were examined for the expression of these genes, and it was found that no MDR1 and only low amounts of MRP1 were expressed. Growth inhibition experiments indicated that doxorubicin (Dox), vinblastine, and paclitaxel were equitoxic in these cell lines. On the other hand, the IC(50) for rhodamine 123 (Rho 123) in rho(0) cells was 50 times higher than in wt cells. This result correlates with a lower accumulation of Rho 123 in rho(0) cells as measured by fluorescence microscopy and flow cytometry (3 times less than in wt cells). In contrast, when stained with Dox, both cell types accumulated similar amounts. Surprisingly, in these non-P-glycoprotein expressing cells, verapamil increased both Dox and Rho 123 retention. Overall, these data suggest that: (i) functional mitochondria do not appear to be targets for the growth inhibitory activities of Dox, paclitaxel, or vinblastine; (ii) for lipophilic cations like Rho 123, however, normal functioning mitochondria and maintenance of a normal mitochondrial membrane potential (Deltapsi(mt)) appear to play a critical role in the intracellular accumulation and subsequent cytotoxicities of these compounds; and (iii) verapamil increases drug accumulation in non-P-glycoprotein expressing cell lines, most likely by direct action on Deltapsi(mt) for Rho 123 and safranin O, and on heretofore unidentified plasma membrane transporters, as well as via interaction with low levels of MRP1, for Dox. These results should be considered when Rho 123 and verapamil are used to detect P-glycoprotein.

Comparison of annamycin to adriamycin in cardiac and MDR tumor cell systems.

Based on the response of a wide variety of tumors to the anthracycline, Adriamycin, numerous studies have been initiated to find an even more effective analog. In this pursuit two of the obstacles that have been necessary to overcome are a unique dose dependent Adriamycin-induced cardiotoxicity reported in patients treated with this chemotherapeutic agent as well as p-gp-mediated multi drug resistance (MDR) which has been found in tumor cells exposed to Adriamycin in vitro and in vivo as well as in human tumor samples. Using an in vitro cardiac cell system and MDR+ and MDR- Friend leukemia cell lines we find that a relatively new anthracycline, Annamycin, has reduced cardiotoxic activity but is more effective in inhibiting the growth of MDR+ cells than Adriamycin. The reduced cardiotoxicity of Annamycin is approximately 10 fold lower than Adriamycin whereas the increased efficacy against the MDR+ Friend leukemia tumor cell line is about 2 fold. The observation that Adriamycin preferentially accumulates in cardiac-muscle (CM) but not in cardiac non-muscle (NM) cells while Annamycin accumulates equally in both, may explain in part the reduced cardiotoxicity of Annamycin. Moreover, the cytosolic accumulation of Annamycin vs the nuclear localization of Adriamycin suggests a different target site for each drug.

Structurally different anthracyclines provoke different effects on cell cycle and tumor B cell differentiation.

Previously we have detected a stimulatory effect on immunoglobulin (IgG) synthesis when hybridoma cells were treated with doxorubicin. In order to determine whether this is a general property of anthracycline, we have selected three analogs--doxorubicin (DOX), pirarubicin (THP-DOX) and aclarubicin (ACR)--which differ mainly in the methylation state of their amino sugars. Cell cycle analysis by flow cytometry and drug localization by scanning confocal microscopy were also performed. The results show that when cells (UN2 hybridoma B cells), were exposed to subtoxic doses of DOX or THP (with unmethylated amino sugars), a strong increases in IgG secretion, heavy (H) and light (L) chain synthesis and the corresponding mRNA levels were induced. Furthermore these two drugs arrested the cells in the G2/M phase of the cell cycle. In contrast, exposure to ACR (with its methylated amino sugar) at similar subtoxic doses induced a blockade of cells in the G1 phase with no increase of IgG synthesis, at the subtoxic doses used, all three drugs could still be detected in the nucleus as well as in the cytoplasm, as determined by confocal laser microscopy. Thus, the relationship between cell cycle blockade, IgG stimulation and anthracycline structure is suggested by these results.

Phenotypic diversity in human fibroblasts from myelometaplasic and non-myelometaplasic hematopoietic tissues.

Fibroblasts from a variety of tissues interact with and influence the behavior of the cell types they are associated with by producing specific proteins that mediate these interactions. Thus, it is not surprising that fibroblasts have been shown to differ phenotypically and functionally depending on the tissue they are isolated from and its physiologic state. To study fibroblasts of hematopoietic tissues, cultures were established from human normal bone marrow (BM), and from non-myelometaplasic (NS) and myelometaplasic spleen (MMS) tissues and analyzed for phenotypic characteristics. The results are summarized as follows: (1) cytoskeletal elements: virtually all the MMS fibroblasts were stained positively for alpha-sm-actin while only a small fraction of BM and of NS fibroblasts were positive for this antigen; (2) extracellular matrix elements: MMS fibroblasts stained positively for ED-B fibronectin and tenascin while the other 2 fibroblast cell types did not; (3) cell surface molecules: NS and MMS fibroblasts expressed significantly higher levels of ICAM-1, VLA-4 and CD9 than BM fibroblasts. Moreover, MMS fibroblasts showed a higher expression of ICAM-1 and VLA-4 than NS fibroblasts; and (4) cytokines: IL-II, RANTES and MIP-1alpha were produced in higher amounts by BM than by NS fibroblasts. Conversely, production of GM-CSF, SCF, M-CSF and MCP-1alpha was elevated in NS compared with BM fibroblasts. The production of these cytokines was generally reduced in MMS cells. Overall, our results demonstrate that phenotypic characteristics can be identified to distinguish fibroblasts from normal and pathologic hematopoietic tissues. Such phenotypic characteristics suggest functional differences of each type of fibroblast in their influence on the blood cells with which they are associated.

Accumulation of simple organic cations correlates with differential cytotoxicity in multidrug-resistant and -sensitive human and rodent cells.

Structure/functional studies previously reported showed that in a series of simple organic cations in which the charge is delocalized, an aromatic ring and a minimal degree of lipophilicity (log P > -1) were required for recognition by murine cells which express P-glycoprotein (p-gp)-mediated multidrug resistance (MDR). In the present report we find that 3H-octylpyridinium, the simple aromatic cation which has been shown to be preferentially toxic to MDR- as compared to MDR+ cells, accumulates 4.7-fold greater in the MDR- cell line. In contrast, we find that 3H-guanidinium which displays no selective toxicity between MDR+ and MDR- cells, shows no significant uptake differences between these two cell types. We also present data which demonstrate that other organic cations which contain aromatic rings, a minimal degree of lipophilicity (log P> -1) and carry a delocalized (Rho 123) or shielded (triphenylmethyl phosphonium) positive charge, also accumulate to a greater degree in MDR- vs MDR+ cells. Additionally, we find that human cells which express p-gp MDR, have similar requirements for recognition of these simple compounds. In fact, the sensitivity profiles of these compounds closely correlate between murine and human cell lines. It was also found that none of the series of simple organic compounds tested showed modulatory activity in MDR+ cells, as assayed by monitoring retention of Rho 123. Thus, the requirements for MDR recognition vs those for MDR modulation are clearly distinguished with these simple structured compounds. In comparison, the calcium channel antagonist, verapamil, and a calcium channel agonist, Bay K 8644, both showed modulatory activity by increasing Rho 123 retention in MDR+ cells, further supporting the interpretation that verapamil's modulation of MDR is unrelated to its action on calcium flux. Overall, the data presented here add further information for defining the structural requirements of compounds for their recognition by, or modulation of, human cells expressing p-gp-mediated MDR.

Circumvention of P-GP MDR as a function of anthracycline lipophilicity and charge.

From a number of studies it has been suggested that positive charge and degree of lipophilicity dictate, or at least influence, whether anthracyclines are recognized by the apparently clinical important mechanism of tumor cell resistance, i.e., P-gp-mediated multidrug resistance. Using a selected series of analogs in which lipophilicity and or positive charge are altered we find the following: (1) Positively-charged anthracyclines as compared to their neutral counterparts are better recognized by MDR+ cells. (2) With increasing lipophilicity charge becomes less important for MDR recognition. (3) In MDR+ cells with a resistance index to Adriamycin (ADR) of 4534, as compared to an MDR- parental line, almost all of the resistance is circumvented (resistance index = 3) with an anthracycline which does not contain a protonatable nitrogen and is highly lipophilic (partition coefficient, log p = > 1.99). (4) As lipophilicity is increased to log p > 1.99 and nuclear binding is decreased, anthracycline localization switches from nuclear to cytoplasmic which most likely indicates a different cytotoxic target and mechanism of action. (5) Cytoplasmically localized anthracyclines appear to distribute also in mitochondria which suggests these organelles as possible new anthracycline targets. In contrast, ADR shows no mitochondrial localization. (6) Photoaffinity analysis suggests that the highly lipophilic analogs, regardless of charge, interfere with NASV-Vp binding to P-gp. This is consistent with the idea that highly lipophilic anthracyclines act as modulators of MDR which may contribute to their mechanism of overcoming this form of resistance. The possible clinical significance of these data is that highly lipophilic anthracyclines are shown to circumvent MDR which most likely reflects their ability to localize in the cytoplasm and affect targets other than nuclear DNA, i.e., mitochondria, and to act as self modulators of MDR. Thus, a new approach to circumventing MDR and other mechanisms of resistance which involve nuclear targets is the use of active anthracyclines which are highly lipophilic and localize in the cytoplasm/mitochondria.

Relationship of multidrug resistance to rhodamine-123 selectivity between carcinoma and normal epithelial cells: taxol and vinblastine modulate drug efflux.

Preferential retention and cytotoxicity of Rhodamine-123 (Rho-123) was originally reported in a number of carcinoma cell types isolated from a variety of tissues as compared to normal epithelial cells from a limited number of other tissues. In the present study, we have examined Rho-123 selectivity in normal and tumor cell lines isolated from the same tissue source, i.e., human breast. We found that: (a) in matched pairs of normal and carcinoma breast cells, Rho-123 displays no preferential retention in either cell type; (b) there is no preferential toxicity in carcinoma as compared to normal breast cells; in fact, one of the carcinoma cell lines (MDA-MB231) shows moderate resistance to this dye; (c) all of the human breast cell lines do not express P-glycoprotein-mediated multidrug resistance; (d) the normal monkey kidney epithelial cell line CV-1, which was originally used as a model to demonstrate the relative resistance of normal epithelial cells to this drug, is found to express high levels of the mdr-1 gene, is resistant to other multidrug-resistant drugs (taxol and vinblastine), and its resistance to Rho-123 as well as decreased Rho-123 retention can be reversed by verapamil; and (e) taxol and vinblastine are found to block increased Rho-123 efflux in CV-1 cells. Thus, overall the data suggest that preferential retention and cytotoxicity of Rho-123 in carcinoma versus normal epithelial cells is related to the differential expression of the mdr-1 gene.

Antiproliferative activity of taxol on human tumor and normal breast cells vs. effects on cardiac cells.

The antiproliferative activity of the chemotherapeutic agent taxol was evaluated on 2 normal and 2 carcinoma human breast-cell lines and compared with its effects on newborn rat cardiac cells growing in vitro. Relatively little difference in ID50 response (ranging from 0.6 to 2.0 ng/ml) to taxol was found between normal and tumorous breast epithelial cells. Arrhythmias and slowing of beat frequencies of cardiac cells were induced by taxol but at doses approximately 10 times higher than those necessary to inhibit proliferation in dividing cells. Microtubules assayed by immunostaining appeared to be similarly retracted around the nucleus in both breast and heart cells. Overall, our results suggest that taxol does not selectively inhibit the growth of tumor vs. normal human breast cells. They also support the hypothesis that effects on microtubule integrity are associated with effects on cardiac function and that the clinical cardiac activity of taxol already reported may be due, at least in part, to a direct effect of taxol on cardiac cells as demonstrated in these in vitro studies. Thus, caution is needed, in view of possible cardiac effects, when using taxol in future clinical protocols, especially when combined with other cardioactive agents such as Adriamycin.

Cross resistance relevance of the chemical structure of different anthracyclines in multidrug resistant cells.

Positively charged doxorubicin (DOX) and non-positively charged anthracyclines, aclarubicin (ACR) and morpholino-carminomycin (KRN 8602), have been investigated with respect to pharmacological parameters, cytotoxicity, DNA damage and repair in DOX-sensitive and -resistant murine and human cells. Friend leukemia cells (FLC) resistant to high concentrations of doxorubicin (DOX-RFLC3) or daunorubicin (DNR-RFLC3) (1771 and 1543 fold resistance respectively) express less than 10 fold resistance to aclarubicin (ACR). In these cells, the intracellular accumulation of ACR is similar in sensitive and resistant cells. Resistance to ACR was not observed in either DOX-RFLC1 or DNR1 with a lower level of resistance (27 fold). Increased expression of a 170,000-dalton surface antigen (gp-170) was found to be correlated with the level of resistance. However, when the selective agent in ACR, despite the low level of resistance (2.8 fold) both high expression of gp 170 and resistance to DOX (77 fold) or DNR (62 fold) are observed. It is assumed therefore that induction of multidrug resistance phenotype can be achieved by compounds which do not display cross resistance with DOX or DNR. Reduced levels or absence of cross-resistance can be related to the electrical charge of the compound. This assumption is supported by further studies on DOX-sensitive or -resistant human K562 cells exposed to another non-positively charged anthracycline, KRN 8602. In the continuous presence of drug, K562/DOX were less resistant to KRN 8602 (2.9 fold) than to DOX (31 fold). After short time exposure followed by growth in drug-free medium, absence of cross-resistance to KRN 8602 has been observed in K562/DOX. Furthermore, accumulation experiments showed that high intracellular drug concentrations were rapidly achieved (within 15 min) in both DOX-sensitive and -resistant cells. In cells exposed to DOX, DNA single-strand break (DNA-SSBs) frequencies were related to time and drug concentration while those produced by KRN 8602 or ACR were maximal after short time incubation. DNA-SSBs produced by these anthracyclines are not repaired when cells are incubated in drug free medium. In DOX resistant cells, DNA-SSBs produced by DOX were repaired whereas those produced by ACR or KRN 8602 were not. It is suggested, therefore, that absence of cross resistance to various anthracyclines is related to differences in the chemical electrical charge, which may influence drug accumulation and DNA repair in resistant cells.

Two multidrug-resistant Friend leukemic cell lines selected with different drugs exhibit overproduction of different P-glycoproteins.

Two Friend leukemic multidrug-resistance (MDR) cell lines were established by exposure to stepwise increased concentrations of rhodamine-123 (RHO) (cell line RR-30) or Adriamycin (ADR) (cell line ARN-15). RR-30 displays preferential resistance to RHO, whereas ARN-15 is more resistant to ADR. The levels of resistance to other MDR drugs and reversibility by verapamil between these two MDR cell lines were somewhat different. Southern blot, RNase protection, and Western blot analysis using gene-specific probes demonstrated that RR-30 and ARN-15 cells preferentially amplified the mdr1 and mdr3 genes, respectively, leading to overexpression of the corresponding P-glycoproteins (p-gp). Our results suggest that members of the mdr gene family can be amplified independently by using different selecting agents, which could be responsible for the differences in the sensitivities to these selecting agents as well as to these MDR drugs.

Cytotoxic and photodynamic effects of Photofrin on sensitive and multi-drug-resistant Friend leukaemia cells.

To study cross-resistance to Photofrin (PF) photosensitization, a Friend leukaemia cell line (ADM-RFLC) with a high level of multi-drug resistance (MDR) and the parental sensitive cell line (FLC) have been used. PF uptake measured by HPLC shows a similar intracellular drug accumulation in both cell lines. The ID50s for cell growth inhibition by PF are also similar after exposure in the dark in the two cell lines, while after illumination they are slightly lower in ADM-RFLC than in FLC cells. Moreover, verapamil, known to reverse the MDR phenotype induced by P-glycoprotein over-expression (the drug efflux mechanism), affects equally ADM-RFLC and FLC cells sensitivity to PF. In addition, photodynamic treatment with PF did not reverse the resistance to rhodamine 123 and aclarubicin, but partly reverses resistance of ADM-RFLC cells to antitubulin drugs such as vinblastine or vincristine. These latter results could have clinical application in the treatment of tumours expressing the MDR phenotype.

Structural requirements of simple organic cations for recognition by multidrug-resistant cells.

We previously noted that a wide variety of drugs which are recognized by multidrug-resistant cells (MDR+) are positively charged. However, it remains unclear why and how such a large number of structurally different compounds can be distinguished by MDR+ cells. The majority of the diverse compounds subject to MDR are complex and thereby complicate definitive structure/function characterization of the P-glycoprotein-mediated MDR mechanism. Using a series of simple aromatic (alkypyridiniums) and nonaromatic (alkylguanidiniums) organic cations differing in their lipophilicity by stepwise additions of single alkyl carbons, we demonstrate by growth inhibition studies that a single aromatic moiety and a critical degree of lipophilicity (log P > -1) are required for recognition of these simple organic cations by MDR+ cells. Thus, MDR+ cells are not cross-resistant to the nonaromatic guanidiniums but do show cross-resistance to those aromatic pyridiniums with chain lengths > four. Resistance ratios, as determined by comparison of 50% inhibitory doses in MDR- versus MDR+ cells, increase as a function of increasing chain lengths of these latter simple aromatic compounds. Resistance to pyridinium analogues in MDR+ cells is reversible by co-treatment with nontoxic doses of verapamil. Preliminary uptake data with radioactive analogues further implicate the MDR mechanism of lowered drug accumulation in accounting for resistance to the pyridinium homologues. Utilization of these simple organic cations provides a rational basis for better defining the physical chemical properties of more complex compounds processed by the MDR mechanism and suggests a strategy for designing chemotherapeutic agents with reduced susceptibility to MDR.

Alpha-smooth muscle actin expression in cultured cardiac fibroblasts of newborn rat.

Using a panel of monoclonal antibodies to several different cytoskeletal elements in primary cultures derived from newborn rat hearts we report that fibroblasts similar to cardiac-muscle cells expressed the alpha-actin isoform of smooth muscle cells. However, striated muscle alpha-actin or desmin antibodies did not stain cardiac fibroblasts but did stain cardiac-muscle cells. The alpha-smooth muscle actin distributed as a stress fiber and in a cross-striated pattern in cardiac muscle while fibroblasts showed exclusive stress fiber staining. These results suggest that connective tissue cells during development of the heart contain muscle-specific elements which may relate to the organ-specific contractile function with which they are associated.

Cardiostimulatory and antiarrhythmic activity of tubulin-binding agents.

Rhythmic, spontaneously pulsating cardiac cells cultured from newborn rats are immediately stimulated to beat faster by addition of a number of tubulin-binding agents but not by their non-tubulin-binding analogues. The tubulin-binding agents tested include vinblastine, vincristine, navelbine, two analogs of vinblastine (S12362 and S12363), nocodazole, colchicine, and podophylotoxin. In addition to binding tubulin, all of the above agents also depolymerize microtubules. In contrast, taxol, a tubulin-binding agent that stabilizes microtubules, does not stimulate cardiac cells. Moreover, the immediate and ensuing cardiac stimulation by vinblastine at 0.05 microgram/ml is completely blocked by pre- and cotreatment with taxol at 1.0 microgram/ml. The time necessary to reverse the cardiostimulatory effect of vinblastine is significantly longer than that required for nocodazole, further implicating depolymerization of microtubules in the cardiac activity of these agents. All of the tubulin-binding agents tested (including taxol) also immediately reverse adriamycin-induced arrhythmias. By using a monoclonal antibody to alpha-tubulin, typical filamentous microtubules are visualized in cardiac muscle and cocultured non-muscle cells by immunofluorescence. When cells are treated for 2 hr with vinblastine at 0.05 microgram/ml, fluorescence is detected in cross-striated patterns in cardiac muscle cells. Overall, these data open the possibility of uncovering an additional relationship between cytoskeletal elements (other than actin and myosin) and the contractility of cardiac muscle. They also suggest an alternative mechanism for affecting cardiac cell function in vitro (namely, by tubulin-binding agents). If these agents are shown to be cardioactive in vivo, they may provide another approach to the treatment and management of cardiac arrhythmias.

3'-Deamino-3'-morpholino-13-deoxo-10-hydroxycarminomycin conquers multidrug resistance by rapid influx following higher frequency of formation of DNA single- and double-strand breaks.

The mechanism of action of 3'-deamino-3'-morpholino-13-deoxo-10-hydroxycarminomycin (MX2) was examined in a human leukemia cell line (K562) and its Adriamycin (ADM)-resistant subline (K562/ADM). ADM and MX2 showed an equivalent antitumor effect against K562. K562/ADM was highly resistant to ADM. In cellular pharmacokinetic studies, MX2 showed faster and greater influx than did ADM in both K562 and K562/ADM. The efflux of ADM was rapid in K562/ADM but not in K562. On the other hand, the efflux of MX2 was rapid in both cell lines. The formation of DNA single-strand breaks and double-strand breaks by ADM was significantly lower in K562/ADM than K562. On the other hand, formation of those breaks by MX2 was not decreased. Although some of the DNA breaks induced by MX2 were resealed, there was no difference in the degree of resealing in K562 and K562/ADM cells. On the other hand, most of the small number of DNA breaks in K562/ADM induced by ADM were resealed. The topoisomerase II activity in K562 and K562/ADM was not significantly different. It is concluded that MX2 conquers multidrug resistance by rapid influx following a higher frequency of formation of DNA single- and double-strand breaks in K562/ADM cells.

Relevance of the chemical charge of rhodamine dyes to multiple drug resistance.

Previously, we have shown that multiple drug resistant (MDR) Friend leukemia cells (FLC) are cross-resistant to the positively-charged dye, Rhodamine 123 (Rho 123), and that this resistance can be reversed by verapamil (VER). In the present study we used two zwitterionic rhodamine analogs, Rhodamine 116 and Rhodamine 110, and another positively-charged analog, Rhodamine 6G, to determine whether drug accumulation, resistance and modulation were affected by changes in the charge of these compounds. While there was no differential sensitivity between sensitive and resistant FLC to zwitterionic rhodamines, there was marked differential toxicity between these cell types for the positively-charged analogs. The IC50 values were 1000- and 100-fold greater in resistant than in sensitive cells for Rho 123 and Rho 6G respectively. Intracellular drug accumulation was significantly higher in sensitive as compared to resistant cells for both Rho 123 and Rho 6G, but little difference in drug uptake between these two cell types was observed for Rho 110 and Rho 116. It was also found that the intracellular to extracellular ratio of the positively-charged compounds was greater than unity in both sensitive and resistant cells whereas for the zwitterionic analogs this ratio was less than 1. Furthermore, this ratio of drug uptake was found to be significantly higher for Rho 6G than for Rho 123, which correlated with the high oil:water partition coefficient of Rho 6G (115.6). In MDR cells, verapamil increased Rho 123 and Rho 6G accumulation by 9.4- and 8.6-fold respectively. In addition, IC50 values in resistant cells were reduced greater than 100-fold for Rho 6G and greater than 1000-fold for Rho 123 in the presence of 10 micrograms/ml of verapamil. In contrast, less than 2-fold reduction of IC50 values for both of the zwitterionic analogs could be obtained under the same conditions. These results indicate that the chemical charge of rhodamines plays an important role in their differential accumulation, cytotoxicity and sensitivity to modulators such as verapamil, in sensitive and multi-drug resistant cells. The data also suggest that increased lipophilicity of the positively-charged rhodamines may increase their ability to accumulate in, and subsequently kill, MDR cells.

Potentiation of adriamycin accumulation and effectiveness in adriamycin-resistant cells by aclacinomycin A.

Variants of Friend leukemia cells (FLC) selected for resistance to either adriamycin (ADM), daunorubicin (DNR) or aclacinomycin A (ACM) by step-wise exposure to each drug, were found to be cross-resistant to ADM and DNR but not to ACM. In addition, an epithelial cell line isolated from normal monkey kidney (CV-1) was found to be intrinsically resistant to ADM and DNR but not to ACM. In contrast, a human breast carcinoma cell line (MCF-7) was found to be sensitive to all three compounds. In these latter cell lines as well as in the FLC variants, lowered intracellular amounts of ADM and DNR correlated with resistance, but ACM levels were the same in sensitive and resistant cells. When cells with either acquired or intrinsic resistance were treated with ACM in combination with ADM or DNR, significant increases in the intracellular amounts of these latter compounds were found. Increased drug accumulation in resistant cells treated this way was accompanied by increased cytotoxicity. When resistant cells were exposed to ACM in combination with other anthracyclines, similar results were obtained. In comparison, these phenomena were not observed when either one of the sensitive cell types (parental FLC and MCF-7) were treated similarly. Since ADM and DNR resistant cells are sensitive to ACM and their resistance circumvented by ACM, this drug may have important clinical applications when used in combination with other anthracyclines.

Effect of verapamil on rhodamine 123 mitochondrial damage in adriamycin resistant cells.

Mitochondrial damage was found in Friend leukemia cells treated with rhodamine 123 (Rho 123). In contrast, when cells resistant to the drug were similarly treated, mitochondria were unaffected. These results correlated with higher levels of Rho 123 in sensitive as compared to resistant cells. However, when resistant cells were co-treated with verapamil, intracellular Rho 123 levels reached those of sensitive cells. At these levels mitochondrial damage and subsequent cytotoxicity in resistant cells were the same as in sensitive cells. These data suggest that differences in Rho 123 mitochondrial damage and subsequent cytotoxicity in sensitive and resistant cells result entirely from increased intracellular drug levels and not from differences in mitochondrial sensitivity or other mechanisms.