P388 leukaemia cells resistant to the anthracycline menogaril lack multidrug resistant phenotype.

Menogaril is an anthracycline presently in Phase II clinical trials. Menogaril-resistant mouse leukaemia P388 cells were developed in vitro by 4 months of exposure to step-wise increasing concentrations of menogaril after which resistant cells (P388/MEN) were cloned in 320 ng ml-1 menogaril. P388/MEN cells were 40-fold more resistant to menogaril in vitro compared to P388/O and were also resistant in vivo. Resistance to menogaril was stable for at least 2 months in the absence of the drug. The results indicate that P388/MEN, although resistant to an anthracycline, did not display the typical multidrug resistant phenotype. It was not cross-resistant to several structurally unrelated drugs such as actinomycin D, cisplatin, or vinblastine, but it was cross-resistant to the anthracycline, adriamycin. Uptake and efflux of menogaril was similar in sensitive and resistant cell lines. Also, resistance was not reversed by verapamil. No major karyotypic difference was noted between P388/O and P388/MEN. There was no significant amplification or overexpression of the mdr gene in P388/MEN compared to P388/O. In contrast to P388/MEN, P388 cells resistant to adriamycin displayed the typical multidrug resistant phenotype. Glutathione content of P388/MEN cells was similar to that of P388/O and depletion of glutathione did not potentiate menogaril cytotoxicity. Therefore, we conclude that glutathione is not likely to be involved in menogaril resistance to P388/MEN cells.

Characterization of B16 melanoma cells resistant to the CC-1065 analogue U-71,184.

U-71,184 is a CC-1065 analogue which is highly cytotoxic in vitro and has a broad spectrum of antitumor activity in vivo. Against B16 cells, U-71,184 was 8-fold and 253-fold more potent than Actinomycin D and Adriamycin, respectively. U-71,184 killed 90% of B16 cells at 0.01 ng/ml levels of drug in the medium, which was equivalent to an intracellular concentration of about 8 pg/10(6) cell (= 2 x 10(-8) pmol/cell). A B16 cell line resistant to U-71,184 developed after 3 months of in vitro exposure to gradually increasing concentrations of the drug. The sensitive and resistant cell lines were cloned and a B16/R clone was selected which was 60 to 100 times more resistant to U-71,184 than the cloned sensitive parent (B16/S). Cells grown in the absence of U-71,184 for 2 months retained resistance to the drug. B16/R was slightly cross-resistant only to Adriamycin but not to Actinomycin D, vinblastine, or colchicine. Among alkylating agents, it was slightly cross-resistant to Melphalan but not to 1,3-bis(2-chloroethyl)-1-nitrosourea or cisplatin. B16/R did not overexpress mdr mRNA. Therefore, this cell line does not exhibit the multidrug-resistant phenotype. Most karyotypes of B16/R had a marker chromosome which carried an aberrantly staining region apparently containing repetitive replication of the same segment. Resistance can be partly accounted for by the approximately 10-fold lesser uptake of [3H]-U-71,184 in B16/R, as compared to B16/S. B16/R was cross-resistant in varying degrees to several other CC-1065 analogues. The ratio of the 50% lethal dose of U-71,184 for B16/R, as compared to B16/S, was about 60 (i.e., R/S = 60). In comparison, the following compounds had an R/S ratio of less than 20 (i.e., modest level of cross-resistance to U-71,184): U-68,819, U-73,975, U-75,500, U-75,559, and CC-1065. In contrast, the following compounds had an R/S ratio greater than 20 (i.e., highly cross-resistant to U-71,184): U-71,184 analogues U-71,185, U-73,903, and U-75,012; U-73,975 analogues U-75,613, U-75,032, and U-73,896; and CC-1065 enantiomer U-76,915. We cannot yet explain the difference in the level of cross-resistance between these compounds in vitro. B16/S and B16/R cells were tumorigenic in mice and B16/R was resistant to U-71,184 in vivo. There was no clear indication of cross-resistance of B16/R in vivo to Adriamycin, Actinomycin D, cisplatin, or Melphalan. However, U-73,975, a compound with modest cross-resistance in vitro, was significantly cross-resistant in vivo.

Interaction of CC-1065 and its analogues with mouse DNA and chromatin.

CC-1065 is a potent antitumor antibiotic which is cytotoxic to P388 and L1210 leukemia cells in vitro and in vivo. CC-1065 covalently binds to calf thymus DNA preferentially to adenine-thymine regions at N3 of adenine. Here, we compare CC-1065 interaction with P388-derived chromatin, DNA, and histones as measured by electronic absorption and circular dichroism. Two CC-1065 analogues (U-71,184 and its enantiomer, U-71,185) which show different biological activities from CC-1065 were also studied. The shape and temporal behavior of the induced circular dichroism curves generated by CC-1065 or its analogues bound to chromatin were similar to CC-1065 plus DNA. This suggested that CC-1065 and its analogues bind to the minor groove of chromatin DNA in a manner similar to calf thymus DNA. However, the binding of CC-1065 and its analogues to DNA induced a more intense circular dichroism band than binding to chromatin. The order of interaction for both chromatin and DNA was CC-1065 greater than U-71,184 greater than U-71,185. In contrast to the essentially irreversible binding to DNA after 24-h incubation, binding to chromatin was primarily a reversible interaction, the degree of reversibility being U-71,185 greater than U-71,184 = CC-1065. CC-1065 binds weakly and nonspecifically to histones.

Differences in the nuclear matrix phosphoproteins of a wild-type and nitrogen mustard-resistant rat breast carcinoma cell line.

Using polyclonal antibodies raised against a rat liver nuclear envelope protein, lamin protein A, the nuclear matrix proteins of a Walker 256 rat mammary carcinoma wild-type (WS) and a selected cell line with acquired resistance to nitrogen mustards (WR) were found to possess antigenic determinants which were recognized by the antibodies. In one-dimensional immunoblotting analysis, the nuclear matrix protein fractions of both cell lines revealed a common band at Mr 75,000; however only the WS nuclear matrix protein fraction contained a broad band at approximately Mr 70,000. Two-dimensional gel blotting studies of these proteins showed that this Mr 70,000 WS protein had a pI of approximately 7.5. Immunoprecipitation analysis revealed that the altered mobility of this protein could be a function of phosphorylation. The nuclear matrix proteins from both WS and WR cells were shown to bind 3':5'-cyclic adenylic acid (cAMP), as judged by photoaffinity labeling and gel electrophoresis studies. The WS nuclear matrix proteins showed a quantitatively greater level of cAMP binding compared to WR, with predominant binding to proteins with molecular weights of 45,000, 55,000, and 70,000. In WR cells, there was no cAMP binding in the Mr 70,000 region. These data indicate that the Mr 70,000 nuclear matrix lamin proteins are antigenically similar in WS and WR but differ in that the WR protein is hypophosphorylated and does not bind cAMP.

Poly(adenosine diphosphate-ribosylation) of nuclear matrix proteins in alkylating agent resistant and sensitive cell lines.

Using Walker 256 breast carcinoma cell lines either with or without acquired resistance to alkylating agents, the structural framework proteins of the nucleus, the nuclear matrix proteins, were found to be effective acceptors for poly(ADP-ribose). Incubation of isolated nuclei with nicotinamide adenine [32P] dinucleotide ([32P] NAD), followed by the isolation of the nuclear matrix, demonstrated that two polypeptides of approximate molecular weight (Mr) 105 000 and 116 000 were extensively poly(ADP-ribosylated). By an in vitro [32P] NAD assay, the nuclear matrix fraction was found to maintain approx. 15% of the total nuclear matrix activity of poly(ADP-ribose) polymerase. Confirmation that the trichloroacetic acid (TCA) precipitable material represented ADP-ribose units was achieved by enzymatic digestion of the nuclear matrix preparation with snake venom phosphodiesterase (SVP). Within 15 min, greater than 85% of the 32P label was digested by SVP and the final digestion products were found to be phosphoribosyl-AMP (PR-AMP) and adenosine 5'-monophosphate (5'-AMP) by thin layer chromatographic analysis. The average polymer chain length was estimated to be 6-7 ADP-ribose units. Because poly(ADP-ribose) polymerase has a putative role in DNA repair, a comparison of the nuclear matrix fractions from Walker resistant and sensitive tumor cell lines was made. In both cell lines, the quantitative and qualitative patterns of the nuclear matrix associated poly(ADP-ribosylation) were similar.

Enhanced nitrosourea cytotoxicity in cell culture by sodium butyrate.

In HeLa S3 cells, sodium butyrate was found to potentiate the cytotoxicity of chloroethylnitrosoureas and alkylating agents in vitro. Using a soft-agar colony-forming assay, 2.5 and 5.0 mM sodium butyrate pretreatment for 22 h increased the cell killing efficacy of both methyl- and chloroethylnitrosoureas by between 30 and 70%. The potentiation of cytotoxicity of bifunctional nitrogen mustards by butyrate was less than that of nitrosoureas, with a 15-30% increased cell kill at 5 mM butyrate. Sodium butyrate per se reduced plating efficiency and caused growth delay if residual levels (calculated at 100 microM for starting concentrations of 5 mM) were not removed by washing prior to plating.

Acquired drug resistance is accompanied by modification in the karyotype and nuclear matrix of a rat carcinoma cell line.

A Walker 256 breast carcinoma cell line (WR) exhibiting a greater than 20-fold resistance to alkylating agents has been selected from a parent cell line (WS). Karyotypic heterogeneity was apparent, with a number of differences evident between WR and WS cells. The modal chromosome number for WS is 62; for WR, 54; double minutes were found only in WR, whereas spontaneous chromosomal aberrations were present in approx. 40% of the WS cells. No similar aberrations were observed in WR. Using SDS-gel electrophoresis and subsequent silver staining, differences in the profile of nuclear matrix proteins in WR and WS were observed. A diffuse band at approx. 70 kD in the WS was absent in WR cells. This protein was phosphorylated, together with a number of the other major matrix polypeptides. Levels of phosphorylated matrix proteins were approximately equivalent in both WR and WS cell lines, but matrix protein phosphorylation levels were approx. 2-fold higher than corresponding values for bulk nuclear proteins. Selective pressure of drug exposure has resulted in enhanced genetic stability in WR cells and observed karyotype differences are accompanied by modifications in the structural proteins of the nuclear matrix. Whether the observed differences are the cause or result of drug resistance remains to be established.