Comparison of intracellular drug retention, DNA damage and cytotoxicity of derivatives of doxorubicin and daunorubicin in a human colon adenocarcinoma cell line (LoVo)

Adriamycin inhibits human RH II/Gu RNA helicase activity by binding to its substrate

RNA helicases are enzymes important in RNA synthesis, processing, transport, and turnover. Human nucleolar RNA helicase II/Gu protein (RH II/Gu) was expressed in a baculovirus system. The purified recombinant RH II/Gu protein has RNA helicase activity on a 5' tailed ds RNA substrate in vitro. We found that Adriamycin, a widely used anticancer drug, inhibited RH II/Gu helicase activity in a dose-dependent manner with an IC(50) of 40 microM. Adriamycin bound to the RNA substrate, and the binding was disrupted by boiling or treatment with 1% SDS, suggesting that the binding of Adriamycin to RNA is reversible. Adriamycin was also found by gel electrophoresis to bind to yeast tRNA to form slow-migrating complexes. These results suggest that Adriamycin can inhibit RNA synthesis or processing by binding to RNA substrates.

A critical evaluation of the mechanisms of action proposed for the antitumor effects of the anthracycline antibiotics adriamycin and daunorubicin

The mechanisms responsible for the antiproliferative and cytotoxic effects of the anthracycline antibiotics doxorubicin (Adriamycin) and daunorubicin (daunomycin) have been the subject of considerable controversy. This commentary addresses the potential role of DNA synthesis inhibition, free radical formation and lipid peroxidation, DNA binding and alkylation, DNA cross-linking, interference with DNA strand separation and helicase activity, direct membrane effects, and the initiation of DNA damage via the inhibition of topoisomerase II in the interaction of these drugs with the tumor cell. One premise underlying this analysis is that only studies utilizing drug concentrations that reflect the plasma levels in the patient after either bolus administration or continuous infusion are considered to reflect the basis for drug action in the clinic. The role of free radicals in anthracycline cardiotoxicity is also discussed.

Cytotoxicity of anthracyclines: correlation with cellular uptake, intracellular distribution and DNA binding

In order to interact with topoisomerase II and induce genotoxicity, anthracyclines have to cross the outer cell membrane and the cytoplasm, enter the nucleus, and bind to the DNA. We incubated sensitive and resistant hematopoietic cells from cell lines and patient cells with daunorubicin, idarubicin, and its active derivative idarubicinol, extracted the anthracyclines from whole cells and nuclei, and determined their concentration fluorimetrically. Additionally, the DNA binding of the drugs was evaluated in the same cells by determining fluorescence resonance energy transfer between the anthracyclines and DNA-bound Hoechst dye 33342. We found a several thousand-fold accumulation of anthracyclines in sensitive and resistant hematopoietic cells; 30-60% of the drugs are found in the nucleus, resulting in 200- to 300-fold differences in concentration between the nucleus and outer fluids. A small proportion of the intracellular or intranuclear anthracyclines is bound to the DNA. The amount of DNA-bound anthracyclines correlates directly to cell death. It takes an additional 10 min for idarubicin and 30 min for daunorubicin to satisfy DNA binding sites after the drugs have arrived in the nucleus. The described methods provide the means to perform ex vivo studies on clinical material.

Interstrand DNA crosslinking induced by anthracyclines in tumour cells

Using a new mild method it is shown for two anthracyclines, Adriamycin and Daunomycin, that these compounds are able to form DNA crosslinks in HeLa S3 cells. It was also found that other anthracyclines: Epirubicin, Rubidazone, Iodorubicin, 3'-deamino-3'-hydroxy-4'-amino-Adriamycin, Aclacinomycin, Marcellomycin, and Cinerubin A, induced crosslinks in the DNA of HeLa S3 cells in a concentration-dependent manner. DNA crosslinks formed by five anthracyclines studied, excluding Iodorubicin, were both alkali and thermally unstable. No DNA crosslinking could be detected when the compounds were added to cell lysates in which cellular enzymes had been inactivated. This implies that metabolic activation is prerequisite for DNA crosslinking by anthracyclines. The kinetics of DNA crosslinks formation by Adriamycin as well as their removal from cellular DNA were also studied. The presented results indicate that all biologically active anthracyclines studied induce DNA crosslinks, and for two of them DNA crosslinking was observed at growth inhibitory concentrations.

Enhanced response to daunomycin of normal, tumor and metastatic cell lines via drug photoactivation

We have compared the cytotoxicity of daunomycin in vitro to highly differentiated normal epithelial cells (Fisher rat thyroid cells, FRTL-5) and to two neoplastic cell lines, a thyroid carcinoma (TK-6) and its lung metastasis (MPTK-6). Whereas the cell lines are equally sensitive to the drug in the dark, if irradiated during incubation with daunomycin (86 J/cm2 at 488 nm), they become more and differently sensitive. Namely, the drug doses producing 50% mortality decrease by factors of about 22, 28 and 16 for FRTL-5, TK-6 and MPTK-6 cell lines, respectively. This result correlates with differences in drug uptake and resistance observed in the normal and neoplastic cell lines.

Oral idarubicin--an anthracycline derivative with unique properties

Idarubicin belongs to a group of anthracyclines in which the methoxyl group in position 4 of the D ring in the aglycone moiety is replaced by a hydrogen atom. Lipophilicity is increased compared with other anthracyclines; as a result, idarubicin is the first anthracycline that can be administered orally while at the same time retaining its antitumor activity. In addition, the lipophilicity enables the transition of the substance, especially of the metabolite, to the cerebrospinal fluid. The metabolite idarubicinol is formed in high concentrations; this is particularly true with oral administration. Compared with all other anthracyclines, it has a very long half-life. It is the first anthracycline metabolite to have the same cytotoxic activity as the parent compound. The cardiotoxicity of idarubicin, being lower than that of other anthracyclines at equally effective doses, is even more reduced with oral administration. Preclinical and clinical experiences with oral idarubicin are reviewed.

Excited singlet state properties of anthracenedione photosensitizers

The absorption, fluorescence and S1 state kinetics of anthracycline antitumour drugs (e.g. daunomycin, adriamycin) and several imino- and/or amino-substituted derivatives are investigated. The study, which includes all anthracyclines which possess photocytocidal activity, is extended to the disubstituted aminoanthracenedione, mitoxantrone, a red-light-absorbing antitumour drug whose activity, both in vitro and in vivo, is enhanced by photoactivation. The S1 state of the anthracycline imino and amino derivatives, in aqueous buffer at pH 7.4, is characterized by bi-exponential decay kinetics which indicates the presence of two ground state populations differing in the extent of hydrogen bonding. The ammonium group of the sugar moiety of anthracyclines contributes to the quenching of the S1 state population through a prototropic mechanism.

Reduced cardiotoxicity and increased cytotoxicity in a novel anthracycline analogue, 4'-amino-3'-hydroxy-doxorubicin

The acute and chronic cardiotoxicity and cytotoxicity of the novel doxorubicin (DXR) derivative 4'-amino-3'-hydroxy-DXR were compared with those of 4'-deoxy-DXR and DXR. In the acute cardiotoxicity study, the ECG and hemodynamic changes recorded in anesthetized rats that had been treated i.v. with 10 mg/kg 4'-amino-3'-hydroxy-DXR or 8.6 mg/kg 4'-deoxy-DXR were significantly less severe than those caused by 13 mg/kg DXR. In the chronic cardiotoxicity study, rats received 3 weekly i.v. injections of 3 mg/kg DXR, 3 mg/kg 4'-amino-3'-hydroxy-DXR, or 2 mg/kg 4'-deoxy-DXR during the first 14 days of the study and were observed for an additional 35-day period. DXR induced severe cardiomyopathy that was characterized by ECG changes in vivo (S alpha T-segment widening and T-wave flattening) and by impairment of the contractile responses (Fmax, +/- dF/dtmax) to adrenaline of hearts isolated from treated animals. 4'-Deoxy-DXR caused a progressive enlargement of the S alpha T segment in vivo and a significant impairment of the -dF/dtmax value in vitro, which were less severe than those produced by DXR. The least cardiotoxic drug was 4'-amino-3'-hydroxy-DXR, which induced minor ECG changes without causing significant alterations in the contractile responses of isolated hearts to adrenaline. On the basis of the drug concentration required to inhibit 50% of the colony formation (IC50) of cell lines in vitro, 4'-amino-3'-hydroxy-DXR was less active than 4'-deoxy-DXR but at least twice as active as DXR against human cancer and murine transformed cell lines. These data indicate that 4'-amino-3'-hydroxy-DXR is significantly less cardiotoxic and more cytotoxic than DXR.

Anthracyclines and their C-13 alcohol metabolites: growth inhibition and DNA damage following incubation with human tumor cells in culture

Anthracyclines are important antitumor agents used in the treatment of solid tumors, lymphomas, and acute lymphoblastic as well as myelocytic leukemias. The clinical utility of agents such as doxorubicin and daunorubicin and their well-characterized cardiotoxicity have prompted many efforts to develop analogs that retain the desired spectrum of activity but are less cardiotoxic. One such analog is idarubicin (4-demethoxydaunorubicin), which is currently under study in the treatment of adult and pediatric leukemias. The major circulating metabolite of idarubicin is the alcohol product of ketoreductase biotransformation, idarubicinol. Following the administration of idarubicin to adult or pediatric patients, systemic exposure to idarubicinol is greater than that to idarubicin. Moreover, we have also documented the presence of idarubicinol in the cerebrospinal fluid of pediatric patients who have received idarubicin. Idarubicinol has been reported to have greater cytotoxic activity than other anthracycline alcohol metabolites, which are regarded as much less active products of metabolism. We therefore evaluated the growth-inhibitory and DNA-damaging activities of idarubicin, daunorubicin, doxorubicin, epirubicin, and their alcohol metabolites against three relevant (CCRF-CEM lymphoblastic leukemia, K562 myelogenous leukemia, and U87-MG glioblastoma) human tumor cell lines. We found that whereas idarubicin was 2-5 times more potent than the other three anthracycline analogs against these tumor cell lines, idarubicinol was 16-122 times more active than the other alcohol metabolites against the same three cell lines. In addition, idarubicinol and the parent drug idarubicin were equipotent, unlike the other anthracycline alcohol metabolites, which were much less cytotoxic than the corresponding parent drugs. We also assessed the ability of the four parent drugs and their alcohol metabolites to induce DNA single-strand breaks. Idarubicin was more potent than the other three anthracycline analogs and idarubicinol was much more effective than the other alcohol metabolites in inducing DNA damage. These studies in human leukemia and human glioblastoma cell lines support the hypothesis that idarubicinol plays an important role in the antitumor activity of idarubicin and that the activities of idarubicin and idarubicinol are related to their ability to damage DNA.

Comparative activity of doxorubicin and its major metabolite, doxorubicinol, on V79/AP4 fibroblasts: a morphofunctional study

Doxorubicin (DXR), an anthracycline antineoplastic drug, is mainly metabolized to the C-13 dihydroderivative doxorubicinol (DXR-ol), which displays cytotoxic activity on various cell lines. To better characterize the cytotoxic activity of this metabolite, we have studied the effect of DXR (0.1-10 micrograms/ml) or DXR-ol (1-100 micrograms/ml) on the transformed fibroblast cell line V79/AP4 by means of the clonogenic assay, cytofluorescence, and light and electron microscopy. Both DXR and DXR-ol displayed a dose-dependent inhibition of colony formation with an IC50 factor DXR-ol/DXR of 19.5. A striking nuclear fluorescence was observed after DXR but not after DXR-ol. A low number of mitoses and a decrease in nucleoli staining affinity were the most evident alterations induced by DXR. Electron microscopy showed both nuclear and cytoplasmic changes in DXR treated cells: nucleolar segregation, cytoplasmic vacuoles, and mitochondrial swelling with dense needle-shaped material were observed. Exposure to formic acid confirmed the calcific nature of the mitochondrial bodies. Only the highest dose of DXR-ol brought about nuclear and cytoplasmic ultrastructural changes similar to those induced by DXR. Our data describe new in vitro findings on the cytotoxicity and morphological alterations induced by both DXR and DXR-ol, with a lower activity of DXR-ol against V79/AP4 fibroblasts.

Doxorubicin and m-AMSA induced DNA damage in blast cells from AML patients

We investigated m-AMSA or doxorubicin (Dx) induced DNA single-strand breaks (DNA-SSB) in myeloid leukemia cells obtained from 8 adult patients suffering from AML. Highly purified AML cells were stimulated to proliferate with the addition of the appropriate growth factor (GCT) and exposed to different concentrations of m-AMSA or Dx for 1 or 4 h, respectively. DNA-SSB were determined by alkaline elution techniques. Either the kinetics or the amounts of DNA-SSB caused by both topoisomerase II inhibitors were variable among different cases. By increasing m-AMSA concentrations there was a concomitant increase in DNA-SSB up to a plateau at the highest concentrations. Dx induced DNA-SSB followed a bell shape curve with a decrease in the number of breaks at the highest concentrations that was evident in most cases. The interindividual variability of Dx-induced DNA-SSB was not correlated with intracellular Dx concentrations as assessed by flow cytometry. No correlation was evident between the amount of DNA breaks induced by m-AMSA and that induced by Dx. These data suggest that AML cells derived from different patients are not necessarily cross-sensitive or cross-resistant to topoisomerase II inhibitors with different chemical structures such as amsacrine or anthracyclines.

Cytotoxicity and DNA damage caused by 4-demethoxydaunorubicin and its metabolite 4-demethoxy-13-hydroxydaunorubicin in human acute myeloid leukemia cells

4-Demethoxydaunorubicin (4-DMDR) and its major metabolite 4-demethoxy-13-hydroxydaunorubicin (4-DMDRol) were investigated for their cytotoxicity and mode of action against human leukemic cells. The drug and its metabolite appeared to be equally potent as both inhibitors of cell proliferation and inducers of DNA double-strand breaks in the OCI AML-3 cell line and cells derived directly from patients with acute myeloid leukemia (AML). This suggests that 4-DMDRol plays an important role in the antileukemic activity of 4-DMDR.

Decrease of liver energy charge, ATP and glutathione at concomitant intraarterial administration of adriamycin and degradable starch microspheres in rat

Adriamycin (Adr) and degradable starch microspheres (DSM) were infused either combined or each separately into the hepatic artery in rats. Liver ATP, GTP, UDP-glucuronic acid, UDP-N-acetyl-hexosamine and energy charge and glutathione were decreased 20 min later with combined treatment but not by Adr or DSM when infused alone. the nucleotide levels were normalized 60 min after the combined treatment. After one week, the Adr rats showed a less weight gain than controls. The Adr + DSM rats lost weight. Only minor changes were found in the livers at microscopical examination at this time.

DNA damage and cytotoxicity of mitoxantrone and doxorubicin in doxorubicin-sensitive and -resistant human colon carcinoma cells

The effects of mitoxantrone (Mx) and doxorubicin (Dx) on cytotoxicity and DNA damage as assayed by alkaline elution were studied in two human colon adenocarcinoma cell lines sensitive (LoVo) and resistant (LoVo/Dx) to doxorubicin. Mx was more cytotoxic than Dx to LoVo cells and was partially cross-resistant in LoVo/Dx. In LoVo cells, Mx produced about 5 times more DNA single-strand breaks (DNA-SSB) than Dx, but both drugs caused an equal number of DNA double-strand breaks (DNA-DSB). In LoVo/Dx cells, the number of DNA-DSB was very low for both Dx and Mx, but DNA-SSB were about 20 times higher for Mx. In LoVo cells, the number of DNA-DSB and protein-associated SSB were similar at equitoxic concentrations. For LoVo/Dx, the partial cross-resistance of Mx might be explained by the much higher number of DNA-SSB produced by this drug.