Relationships between resistance to cross-linking agents and glutathione metabolism, aldehyde dehydrogenase isozymes and adenovirus replication in human tumour cell lines

In a panel of 10 human tumour cell lines with no prior exposure to drugs in vitro, resistance to cisplatin correlated with resistance to the nitrogen mustard derivatives Asta Z-7557 (mafosfamide, an activated form of cyclophosphamide), melphalan and chlorambucil. Simultaneous treatment with ,R-sulfoximine did not enhance the toxicity of cisplatin or Asta Z-7557, and no correlation was found between drug resistance and cellular levels of metallothioneins (as judged by sensitivity to cadmium chloride), glutathione (GSH), GSH reductase, GSH transferase, or γ-glutamyltranspeptidase. The two cell lines most resistant to Asta Z-7557 expressed aldehyde dehydrogenase cytosolic isozyme 1, found also in normal ovary, but not isozyme 3. Treatment of resistant cells with cisplatin or Asta Z-7557 inhibited cellular DNA synthesis and replication of adenovirus 5 to a lesser extent than in sensitive cells. The virus could be directly inactivated by both drugs prior to infection, subsequent replication being inhibited to the same extent in sensitive and resistant cells. In contrast to Asta Z-7557 and other DNA damaging agents, cisplatin was much more toxic to adenovirus ( ₃₇ 0.022–0.048 μM) than to cells ( ₃₇ 0.25–2.5 μM). The adenovirus 5 mutant Ad5ts125 having a G → A substitution was even more sensitive to cisplatin ( ₃₇ 7–8 nM) than wild type virus and another mutant. Cisplatin was detoxified less by sonicated resistant cells than sensitive cells, as judged by inactivation of Ad5ts125 added to the reaction mixture. It can be inferred that (i) the major differences in cellular resistance to cisplatin and Asta Z-7557 in the present material did not involve enhanced DNA repair or protection by metallothioneins or GSH, but were associated with the ability to continue cellular and viral DNA synthesis during treatment, (ii) resistance was not associated with less template damage, and (iii) the adenovirus genome may be a suitable probe for predicting tumour resistance to cisplatin and for elucidating the DNA sequence dependence of cisplatin toxicity.     

Effects of antimetabolites on adenovirus replication in sensitive and resistant human melanoma cell lines.

Methotrexate (MTX), 6-thioguanine (6-TG) and cytosine arabinoside (ara-C) inhibited the replication of adenovirus (viral capacity) more in drug-sensitive than in resistant human melanoma cell lines. By comparison, inhibition of cellular DNA and RNA synthesis after short treatment periods (less than 48 hr) was not a good predictor of cellular sensitivity. MTX, an inhibitor of de novo nucleotide synthesis, was most effective when added to cells just before infection with virus and inhibited viral capacity at doses 10-1000-fold lower than those required to affect cell survival. The MTX-sensitive cell lines, members of a DNA repair deficient group sensitive also to killing by methylating agents (the Mer- phenotype), were not deficient in dihydrofolate reductase but exhibited DNA fragmentation after treatment with MTX for 48 hr. 6-TG and ara-C, inhibitors of purine and pyrimidine salvage, were most inhibitory to viral capacity when added greater than 36 hr before virus infection and were less effective than MTX (doses 5-7-fold and 4-24-fold higher than for cell survival respectively). No correlation was found between MTX sensitivity and sensitivity to 6-TG or ara-C. These results indicate that (i) inhibition of viral capacity is a more comprehensive test of antimetabolite cytotoxicity than inhibition of cellular DNA or RNA synthesis; (ii) the viral capacity assay correctly predicts cellular sensitivity to MTX, 6-TG and ara-C and therefore has potential for application to primary cultures of human tumours; and (iii) MTX-sensitive cell lines and adenovirus replication rely heavily on de novo nucleotide synthesis, which in Mer- cells appears to be linked to a DNA repair defect as yet undefined.     

Multiple mechanisms of adriamycin resistance in the human leukemia cell line CCRF-CEM

CEM cells exhibiting a 25-fold (C25X) or 80-fold (C80X) increase in resistance to adriamycin were isolated and characterized. C25X cells were cross-resistant to daunomycin and etoposide (VP-16) but not to vincristine or colchicine. These cells were not defective in the cellular accumulation of drug and did not contain detectable levels of P-glycoprotein. Continued exposure of C25X cells to adriamycin resulted in increased levels of resistance and additional phenotypic changes. These cells (C80X) now contained high levels of P-glycoprotein and were cross-resistant to a variety of agents including vincristine and colchicine. A fluorometric assay for DNA unwinding was used to measure levels of drug-induced DNA breaks in sensitive and C25X resistant cells. Studies carried out with VP-16, 4'9-acridinyl-aminomethanesulfon-m-anisidide (m-AMSA), adriamycin, or daunomycin showed that the level of drug-induced DNA strand breakage in resistant cells was considerably less than that occurring in drug-treated sensitive cells. These studies, therefore, show that treatment of CEM cells with adriamycin resulted in a nuclear alteration that contributed to drug resistance. They also demonstrate that prolonged treatment of cells with adriamycin resulted in membrane alterations that affect cellular drug accumulation. Adriamycin resistance in CEM cells can thus occur as a result of at least two distinct mechanisms.     

Development and properties of an etoposide-resistant human leukaemic CCRF-CEM cell line

Etoposide (VP-16) and several other unrelated anti-tumour agents appear to act by inhibiting the enzyme DNA topoisomerase II. We report here the development and characterization of an etoposide-resistant human leukaemic CCRF-CEM cell line, CEM/VP-1. The cell line was 15-fold more resistant to etoposide than the parental CEM cells and exhibited cross-resistance to other topoisomerase II inhibitors including teniposide, m-AMSA, and doxorubicin. CEM/VP-1 cells exhibited only a low level cross-resistance to the Vinca alkaloids, vinblastine and vincristine, known inhibitors of mitotic spindle formation. As a first step in defining the mechanism of resistance to etoposide, we compared the levels of topoisomerase II activity and its drug sensitivity in nuclear extracts from the resistant and sensitive CEM cells. As determined by a kinetoplast DNA decatenation assay, the level of DNA topoisomerase II activity in CEM/VP-1 nuclear extracts was approximately 2-fold lower than that in CEM cells, and the activity appeared to be resistant to inhibition by etoposide. Furthermore, the DNA topoisomerase II activity in CEM/VP-1 nuclear extracts did not promote the etoposide-dependent cleavage of pBR322 DNA observed with extract from sensitive cells. These results suggest that etoposide resistance in the CEM/VP-1 cell line may at least in part be due to an altered topoisomerase II, or associated factor, resulting in a reduced ability to induce DNA cleavage in the presence of drug.     

Evaluation of adriamycin induced DNA damage and repair in human and animal cells

Adriamycin induced DNA damage and repair were investigated by the comet assay in four human cell lines (CRL2088, ME18, Lu106, WISH) and five animal cell lines (L929, Balb/3T3, CHO. MDBK, Vero). The results indicated the concentration-dependent induction of DNA strand breaks in all cell lines after adriamycin treatment. Simultaneously, wide differences in sensitivity of cells to the damaging action of adriamycin were observed. The most sensitive were two human cell lines derived from epithelial tissues, Lu106 and WISH. In these lines the breaks induced by adriamycin were not repaired within 6 h postincubation. In two other human cell lines, CRL2088 and ME18, only a small number of DNA breaks appeared after adriamycin exposure and these were very quickly repaired. Among the animal cell lines only the mouse cell line L929 was very sensitive to adriamycin, but most of the induced breaks were repaired within 6 h postincubation. The remaining animal cell lines were less sensitive to DNA damage by adriamycin and all except 3T3, completely repaired the breaks within 6 h postincubation.     

Cellular uptake and efflux and cytostatic activity of 4'-O-tetrahydropyranyladriamycin in adriamycin-sensitive and resistant tumor cell lines

Cellular uptake and cytostatic activity of 4'-O-tetrahydropyranyladriamycin (THP) in various sublines resistant to anthracycline antibiotics of mouse lymphoblastoma L5178Y, Chinese hamster ovary (CHO) and mouse leukemia P388 cells were studied. All the sublines resistant to adriamycin (ADR) showed slightly decreased uptake of THP as compared with each sensitive lines, but THP was still taken up much more quickly than ADR by each of the ADR-resistant cell lines. Efflux of both anthracycline glycosides from the ADR-resistant P388 cells was faster than that from the ADR-sensitive P388 cells. The percentage of THP retained at equilibrium was higher than that of ADR in both ADR-resistant and -sensitive P388 cells. Cytotoxicity of THP to ADR-resistant cell lines was considerably lower compared with that for each of the sensitive lines but THP inhibited growth of ADR-resistant tumor cells at a concentration about 10 times lower than that for ADR. Thus THP was taken up more quickly, effluxed more slowly than ADR from the ADR-resistant cells, and showed stronger cytostatic activity than ADR on the cells.     

BCL6 inhibition sensitizes solid tumors to TopoⅡ inhibitors

TopoisomeraseⅡinhibitors(TopoⅡi) are commonly used as chemotherapy by inducing accumulation of DNA double-strand breaks(DSBs). However, therapeutic resistance often occurs during treatment and largely restricts their clinical efficacy. As a proto-oncogene in diffuse large B-cell lymphoma, B cell lymphoma6(BCL6) is widely expressed in majority of tumors and drives the malignant phenotype by binding to hundreds of target genes involved in cell proliferation, senescence and anti-apoptosis. Recent work has identified that BCL6 serves as a central component of stress responses and tumorigenesis where inhibition of BCL6 might potentiate drug sensitivity. Therefore, we hypothesize that BCL6 might be involved in Topo Ⅱi sensitivity in solid tumors.To gain a more systematic insight into cellular response to Topo Ⅱ i, we profiled cell sensitivity to etoposide and doxorubicin, two well-validated Topo Ⅱ i under clinical application, and probed Topo Ⅱ i-induced BCL6 expression in 17 solid cancer cell lines derived from lung,colorectal and pancreatic tumor cells. Our results showed that BCL6 expression level was dramatically upregulated in resistant cells, whereas it was marginally altered in sensitive cells. As expected, these events also were concurrent with differentially expressed genes between etoposide-treated sensitive cells and resistant cells. Increased BCL6 expression was also observedin mice bearing HCT116-xenograftsupon etoposide treatment and associated with decreased TopoⅡi sensitivity.Based on these observations, we tested the combinational effects of BCL6 inhibitors(BI3802 and Takeda) and etoposide in resistant cancer cells. i) Resistant cell lines were more sensitive to etoposide in the presence of BCL6 inhibitors, ii) Combination of BCL6 inhibitor and etoposide shows about 50-60% reduction in colony formation compared to each drug alone, iii) Synchronous inhibition of BCL6 and TopoⅡ induces more cell apoptosis in etoposide-resistant cell lines. Moreover, to determine whether drug combination can increase DNA-damage induced cell death, we exposed resistant cells to combinatorial regimens, and found that exposure to BI3802 and etoposideled to a remarkable increase in DNA DSBs, as indicated by higher expression of phospho-Histone 2 AX.Overall, our data demonstrate a critical role of BCL6 in Top Ⅱ i sensitivity and validate acombinatorial approach for the treatment of solid tumors.     

Effects of verapamil on the cellular accumulations and toxicity of several antitumor drugs in 9-hydroxy-ellipticine-resistant cells

9-OH-Ellipticine (9-OH-E)-resistant cells are not only resistant to the DNA topoisomerase II inhibitors, but also to some other antitumor agents, such as actinomycin D (AD), adriamycin (ADM), daunorubicin and vincristine. It was previously shown that a decreased uptake accounts for the cross-resistance of these cells to AD and ADM which then suggested that the 9-OH-E-resistant cells might display some of the properties usually associated with the multidrug resistance phenotype. In this work, we have examined the effects of verapamil, a drug which is known to overcome the multidrug resistance, on the toxicity and the cellular accumulation of four cytotoxic agents: 9-OH-E, 2N-methyl-9-hydroxy-ellipticinium (NMHE), AD and ADM, either on 9-OH-E resistant cells or on a multidrug resistant subline derived from the same sensitive parental cells. Verapamil inhibited the cellular accumulation of the ellipticine derivatives in the sensitive DC-3F cells, and the toxicity of these drugs on these cells was correspondingly decreased. On either one of the resistant cell lines, verapamil had no effect on the toxicity and the cellular accumulation of 9-OH-E. In contrast, in the presence of verapamil, the cellular accumulation of NMHE by the 9-OH-E and the multidrug resistant cells was about 50% and 300% increased, respectively. The increased NMHE cellular concentration in the multidrug resistant cells was associated with an 8-fold increased toxicity. The major structural characteristics which might account for this difference between the sensitivities of both ellipticine derivatives to the effects of verapamil on the multidrug resistant cells is the presence of a positive charge on the nitrogen in position 2 of the 6H-pyridocarbazole molecule. Finally, verapamil circumvented partially the cross-resistance of DC-3F/9-OH-E cells to AD and ADM by increasing the accumulation of these drugs inside the cells.     

Comparative studies of adriamycin and 28-Deacetyl sendanin onin vitro growth inhibition of human cancer cell lines

The limonoid compound (28-deacetyl sendanin) isolated from the fruit of Melia toosendan SIEB. et ZUCC. was evaluated on anticancer activity. According to a standard in vitro cytotoxicity assay, eight human cancer cell lines and SRB assay were introduced for present evaluation. As a positive standard, adriamycin was tested in parallel. The cell lines were originated from six different organs. In view of dose-response profiles to 28-deacetyl sendanin, the most sensitive cells were SF-539 and PC-3 which were derived from CNS and prostate, respectively. In contrast, all the cell lines responded similarly to adriamycin to give rise to nearly identical dose-response profiles. By comparison of Gl50 between 28-deacetyl sendanin and adriamycin, six cell lines were more sensitive to 28-deacetyl sendanin and two were more resistant. As a result, 28-deacetyl sendanin had more sensitive and selective inhibitory effects on in vitro growth of human cancer cell lines in a comparison with adriamycin.     

Synthesis and antitumour activities of quinolone antineoplastic agents.

DNA topoisomerases, found in all prokaryotic and eukaryotic cells, play a key role in controlling the topological state of DNA. Quinolone antibacterial agents have been shown to be inhibitors of DNA gyrase, a bacterial topoisomerase II enzyme. The eukaryotic topoisomerase II is the target of various cytotoxic agents such as adriamycin and etoposide. Recently, several quinolones having C-8 fluoro and C-8 chloro substituents have been found to have cytotoxic activities and to interact with mammalian topoisomerase II. In searching for an antitumour agent of the quinolone class, we identified several quinolones having excellent in vitro cytotoxic activity. A-74932 also possesses good activity in vivo against both systemic tumour and subcutaneously implanted murine solid tumours as well as human tumour xenografts. The chemical synthesis as well as biological properties of A-74932 are described.     

Inhibition in maturation of nascent DNA fragments in cultured mouse FM3A cells after treatment with DNA-damaging agents

The effect of DNA-crosslinking agents (cisplatin and mitomycin C), a DNA-intercalating agent (adriamycin) or monofunctional psoralen (4-Met-4', 5'-dihydropsoralen plus near-ultraviolet radiation) on DNA replication in cultured mouse FM3A cells was studied by sedimentation of the pulse-labeled DNA in an alkaline sucrose gradient. There was no inhibition of the maturation process of the nascent DNA 1 h after treatment of the cells with cisplatin, mitomycin C or adriamycin. However, this process was inhibited progressively during further incubation for 4 to 16 h without the agents, and accumulation of the nascent DNA fragments was observed. In the case of DNA-crosslinking agents, this inhibition may be correlated with an increase in the number of DNA-crosslinks formed during incubation. However, direct inhibition of maturation was not likely since the number was small, up to 4.9 per 10(9) Da. After treatment of cells with monofunctional psoralen, no inhibition of maturation of the nascent DNA fragments was observed. In all cases, there was no degradation of DNA during incubation.     

Additive cytotoxic effect of apoptin and chemotherapeutic agents paclitaxel and etoposide on human tumour cells

Gene therapy experiments in animal models have shown that apoptin expression results in tumour regression without any significant side effects. Therefore, apoptin is regarded as a potential anticancer drug for clinical applications. In this study, we analysed whether chemotherapeutic agents combined with apoptin treatment could result in enhanced cytotoxicity in human tumour cell cultures. Combined treatment with recombinant adenovirus AdAptVP3 expressing apoptin and etoposide clearly showed an additive cytotoxic effect on human osteosarcoma U2OS cells. Paclitaxel treatment combined with apoptin expression significantly inhibited the survival of p53-positive human osteosarcoma U2OS and non-small lung carcinoma A549 cells, p53-negative human osteosarcoma Saos-2 cells and p53-mutant human prostate cancer Du145 cells, already at low doses of the chemotherapeutic agent. Our results indicate that the cytotoxicity-enhancing action by the tumour-specific apoptin in combination with chemotherapeutic agents might offer an effective and safe antitumour therapeutics.     

Uptake and retention of adriamycin and daunorubicin by sensitive and anthracycline-resistant sublines of P388 leukemia.

Sublines of P388 leukemia completely resistant to adriamycin (P388/ADR) or daunorubicin (P388/DAU) in vivo were studied in vitro. These sublines were more resistant to the cytotoxic effects of adriamycin (800-fold relative to sensitive parental cell line, P388/S) than to daunorubicin (18-fold for P388/ADR and 56-fold for P388/DAU). When the effects of the drugs on thymidine incorporation were compared in vitro in sensitive and resistant cells, it was observed that slightly higher levels of the drugs were required to inhibit nucleic acid synthesis in the resistant cells. The shift in inhibitory concentration was much less than the shift in cytotoxic concentration, particularly for adriamycin. The uptake and efflux of [G-³H]daunorubicin and [14-¹⁴C]adriamycin were studied. At low concentrations uptake of both drugs was impaired in the resistant sublines, whereas, at high concentrations a difference in uptake between sensitive and resistant cells was not evident. Resistance did not appear to be related to the difference in the rate of uptake. A markedly enhanced efflux of the drugs from the resistant cells was observed which correlated well with the difference in sensitivity of the sublines to adriamycin and daunorubicin. Enhancing the uptake of adriamycin by increasing the pH of the incubation medium and thereby increasing the proportion of non-ionized drug available for diffusion into the cells or by modifiying the cell membrane by the addition of Tween 80 failed to reverse resistance. The binding of daunorubicin to isolated nuclei from P388/S and P388/ADR cells was essentially similar. It is concluded that these anthracycline-resistant cell lines are resistant by virtue of decreased retention of the drugs.     

DNA topoisomerase II inhibition by peroxisomicine A(1) and its radical metabolite induces apoptotic cell death of HL-60 and HL-60/MX2 human leukemia cells

Peroxisomicine A(1) (T-514) is a dimeric anthracenone first isolated from the plant Karwinskia humboldtiana. The compound presents a high and selective toxicity toward liver and skin cell cultures and is currently the subject of preclinical studies as an antitumor drug. To date, the molecular basis for its diverse biological effects remains poorly understood. To elucidate its mechanism of action, we studied its interaction with DNA and its effects on human DNA topoisomerases. Practically no interaction with DNA was detected. Peroxisomicine was found to inhibit topoisomerase II but not topoisomerase I. DNA relaxation and decatenation assays indicated that the drug interferes with the catalytic activity of topoisomerase II but does not stimulate DNA cleavage, in contrast to conventional topoisomerase poisons such as etoposide. Two human leukemia cell lines sensitive or resistant to mitoxantrone were used to assess the cytotoxicity of the toxin and its effect on the cell cycle. In both cases, peroxisomicine treatment was associated with a loss of cells from every phase of the cell cycle and was accompanied by a large increase in the sub-G1 region which is characteristic of apoptotic cells. The cell cycle changes were more pronounced with the sensitive HL-60 cells than with the resistant HL-60/MX2 cells (with reduced topoisomerase II activity), in agreement with the cytotoxicity measurements. Treatment of HL-60 cells with T-514 stimulated the cleavage of the poly(ADP-ribose) polymerase by intracellular proteases such as caspase-3. The cytometry and Western blot analyses reveal that peroxisomicine induces apoptosis in leukemia cells. In addition, we characterized a catabolite of peroxisomicine, named T-510R, in the form of a highly stable radical metabolite. The electron spin resonance and mass spectrometry data are consistent with the formation of an anionic semiquinonic radical. The oxidized product T-510R inhibits topoisomerase II with a reduced efficiency compared to the parent toxin and was found to be about 3-4 times less toxic to both the sensitive and resistant leukemia cell lines than T-514. Collectively, the results suggest that topoisomerase II inhibition plays a role in the cytotoxicity of the plant toxin peroxisomicine. Inhibition of topoisomerase II may serve as an inducing signal triggering the apoptotic cell death of leukemia cells exposed to the toxin. The dihydroxyanthracenone unit may represent a useful chemotype for the preparation of topoisomerase II-targeted anticancer agents.     

Characterization of camptothecin-resistant Chinese hamster lung cells.

Three camptothecin-resistant sublines (V79r, IRS-1r and IRS-2r) of V79 cells and their irradiation-sensitive mutants, IRS-1 and IRS-2, were developed by stepwise, continuous exposure to camptothecin (CPT). The degree of resistance varied among these cells. Based on the biochemical characterizations of these resistant cell lines, the mechanisms which could be responsible for the resistance to CPT were proposed to be: (a) a decrease in the intracellular accumulation of CPT with or without alteration of DNA topoisomerase I, (b) a decrease in the amount of DNA topoisomerase I, or (c) a decrease in the sensitivity of DNA topoisomerase I to CPT. The resistant cells which exhibited down-regulation of DNA topoisomerase I were collaterally sensitive to etoposide (VP-16) and its analogue, 4'-demethy-4 beta-(4"-fluoroanilino)-4-desoxypodophyllotoxin, despite the fact that there were equal amounts of DNA topoisomerase II in the parental and in the resistant cell lines. Alternating the usage of CPT and VP-16 for the treatment of cancer is indicated.     

DA-125, a new antitumor agent,inhibits topoisomerase ii as topoisomerase poison and dna intercalator simultaneously

DA-125, a novel derivative of adriamycin, is known for its anti-cancer activity. In this study, the inhibitory mechanism of DA-125 on topoisomerase was investigated in the simian virus 40 (SV40) replicating CV-1 cell by studying the SV40 DNA replication intermediates and DNA-topoisomerase complexes. DNA-protein complexes that were formed in the drug-treated cells were quantitated by using a glass filter assay. SV40 DNA replication intermediates that were accumulated in the drug-treated CV-1 cell were analyzed in a high resolution gel. DA-125 did not accumulate B-dimers of SV40 DNA replication intermediates which were found in the adriamycin-treated CV-1 cells. DA-125 induced a dose-dependent formation of the DNA-protein complexes, while adriamycin did not. When adriamycin and etoposide (VP16) were added to the SV40-infected cells at the same time, adriamycin blocked the formation of the DNA-protein complexes induced by VP16 in a dose-dependent manner. However, DA-125 blocked the formation of the DNA-protein complexes induced by VP16 up to the maximum level of the DNA-protein complexes that were induced by DA-125 alone. Adriamycin and DA-125 did not inhibit the formation of the DNA-protein complexes that were caused by camptothecin, a known topoisomerase I poison. DA-125 is bifunctional in inhibiting topoisomerase II because it simultaneously has the properties of the topoisomerase II poison and the DNA intercalator. As a topoisomerase II poison, DA-125 alone induced dose-dependent formation of the DNA-protein complexes. However, as a DNA intercalator, it quantitatively inhibited the formation of the DNA-protein complexes induced by a strong topoisomerase II poison VP16. Furthermore considering that the levels of the DNA-protein complex induced by VP16 were decreased by DA-125 in terms of the topoisomerase II poison, we suggest that DA-125 has a higher affinity to the drug-binding sites of DNA than VP16 has.     

Multidrug resistance in a small cell lung cancer line: rapid selection with etoposide and differential chemosensitization with cyclosporin A.

We developed a multidrug resistant small cell lung cancer line, VPR-2, by exposing H69 parent cells to etoposide (20 microM) for 1 h daily for 3 days every 21-28 days, a schedule similar to that used in the clinic. Resistance (20-fold) to the cytostatic and DNA cleavage activities of etoposide emerged after the third treatment, and this phenotype was stable in the absence of drug exposure for 2.5 years. VPR-2 cells exhibited cross resistance to intercalating agents and vinca alkaloids, but remained sensitive to X-radiation, cisplatin and 5-fluorouracil. The human mdr1 gene was overexpressed in the resistant line, but steady-state concentrations of etoposide were reduced only 1.5-fold. Topoisomerase II catalytic and etoposide stimulated DNA cleavage activity in nuclear extracts from both lines were identical despite retention of a 3-fold level of resistance to etoposide-induced strand breaks in isolated nuclei from VPR-2 cells. Cyclosporin A and verapamil, both of which bind to P-glycoprotein, enhanced accumulation of etoposide in VPR-2 cells, and H69 cells to a lesser extent. Yet only cyclosporin A was effective in differentially enhancing etoposide cytostasis in VPR-2 relative to H69. In VPR-2 whole cells, cyclosporin A enhanced etoposide-induced DNA single-strand break frequency 9-fold but had no effect in isolated nuclei. Rapid selection of this line with a clinically relevant drug exposure schema and stability of the resistant phenotype suggest these cells may have been a steady subpopulation of the parent line through years of serial passage in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential effects of NAD, nicotinamide and related compounds upon growth and nucleoside incorporation in human cells

Two human melanoma cell lines, MM96 and MM127, were found to be highly sensitive to the toxicity of adenosine (D50 100-150 micrograms/ml) compared with other melanoma lines. HeLa cells and a lymphoblastoid line (D50 greater than 500 micrograms/ml). The MM127 line was also sensitive to NAD (D50 41 micrograms/ml) compared with the other lines (D50 greater than 400 micrograms/ml), and accumulated three-fold more NAD-derived isotopic label. Nicotinamide exhibited little toxicity in any cell type (D50 greater than 400 micrograms/ml); 25-100 micrograms/ml nicotinamide greatly increased the plating efficiency of melanoma cells and fibroblasts when low levels of foetal calf serum were used. The toxicity of DNA-damaging agents (alkylating agents and u.v.) in melanoma cells was not reduced in the presence of NAD, adenosine or nicotinamide. Studies of the effects of the latter compounds upon the incorporation of deoxynucleosides showed that: (a) melanoma cells have lower purine pools than fibroblasts; (b) [3H]deoxyguanosine incorporation was inhibited more than [3H]deoxyadenosine incorporation; (c) incorporation of [3H]deoxyadenosine and [3H]deoxyguanosine into RNA was inhibited by adenosine, thus providing a method for determination of guanine-specific DNA repair; and (d) NAD enhanced thymidine incorporation in intact melanoma cells but not in fibroblasts, in a pattern similar to the release from template restriction previously reported for permeabilised tumour cells.