This study assessed the ability of major metabolites of two types of anthracycline antibiotics, doxorubicin and idarubicin (4-demethoxydaunorubicin) to damage DNA in mouse fibrosarcoma 935.1 cells. Since DNA lesions by anthracyclines may be mediated by topoisomerase II, we also characterized the ability of the drugs to inhibit this enzyme. The C-13 alcohol and aglycone metabolites of doxorubicin and idarubicin were compared to the parent drugs in terms of induction of DNA single strand breaks measured by filter elution. In whole cells, the maximal DNA strand breakage induced by the C-13 alcohol metabolites was similar to that of their respective parent drugs. In isolated nuclei, however, the alcohol metabolites were two times more potent than the parent drugs. The aglycone metabolites produced very little damage in either whole cells or nuclei. The doxorubicin compounds differed markedly from idarubicin drugs in the way their ability to induce DNA breaks was related to cytotoxic activity. Doxorubicin and doxorubicinol cytotoxic effects (50% cell growth inhibition at 0.2 and 4 microM, respectively) coincided (in terms of drug concentrations) with the induction of significant breakage of cellular DNA. In contrast, the concentrations of idarubicin and idarubicinol needed to produce 50% growth inhibition (0.005 and 0.006 microM, respectively) were about 20 times lower than drug levels that induced significant DNA damage. All six compounds inhibited the catalytic activity of isolated topoisomerase II. While the alcohol metabolites produced this inhibition at concentrations similar to those of their parent drugs (5-10 microM), the aglycones were again much less active.(ABSTRACT TRUNCATED AT 250 WORDS)
We have previously shown that a significant portion of the total platinum in the plasma of patients receiving iproplatin is protein-bound. We have also identified cis-dichloro-bis-isopropylamine platinum(II) (CIP) as a major metabolite of iproplatin. To understand the nature of the bound platinum, we carried out in vitro comparative protein-binding studies for iproplatin and CIP. These studies indicate that when CIP is incubated in plasma, protein binding occurs, with a 2.7-h half-life for the disappearance of CIP; the parent complex does not bind and is stable in plasma for at least 48 h. The time dependence of protein binding with CIP suggests the formation of other chemical species from CIP that may be responsible for the observed protein binding. The results indicate that in patients receiving the drug, the reduction of iproplatin to CIP must take place intracellularly and that CIP or its protein-binding derivatives must efflux from the cells into the plasma. Efflux studies carried out to explore this possibility with cells in the whole blood showed that iproplatin was taken up into cells, but the efflux of protein-binding iproplatin metabolites did not occur. To understand further the nature of the metabolites of iproplatin, we carried out 195Pt-NMR (nuclear magnetic resonance) studies with urine from two patients who received a high dose of iproplatin (500 mg/m2). The predominant signals from the 195Pt-NMR corresponded to the divalent platinum complexes and not to quadrivalent complexes, indicating that the iproplatin metabolites in urine are divalent in nature.
The quadrivalent second-generation platinum complex iproplatin and an in vivo divalent metabolite of iproplatin, cis-dichloro-bis-isopropylamine platinum (CIP) were tested for binding to DNA in vitro. DNA binding was determined according to radioactivity measured using [14C]-iproplatin and [14C]-CIP and also by platinum content. Results indicate that (a) iproplatin shows negligible binding to DNA, (b) CIP binds to DNA in a time-dependent fashion, and (c) the isopropylamine ligand is intact when CIP is bound to DNA. Glutathione (GSH) inhibits the binding of CIP to DNA, possibly by inhibiting binding to DNA of the aquated form of CIP.
The acetone-sensitized irradiation using UV-B (ultraviolet light, 280-320 nm; sunlamps) of thymidylyl(3'-->5')deoxyfluorouridine monophosphate produces two main photoproducts. The distribution of these photoproducts is dependent on the pH of the irradiation solution. At pH 6, the cis-syn cyclobutane-type photodimer is the major product, whereas at high pH (8-10) a photoadduct is the major product. These photoproducts have been identified and structurally characterized by H-1 and C-13 NMR spectroscopy. The photoadduct arises from defluorination of the 5-fluorouracil moiety. The structure of the photoadduct maintains the sugar-phosphate backbone of the starting material (d-TpF), and contains a saturated thymine moiety with an added Thy(C6-hydroxyl) and a Thy(C5)-(C5)Ura covalent bond.
Iproplatin is structurally unique among the platinum (Pt) agents in the clinic because it is a quadrivalent complex. On the basis of the redox parameters for the Pt(IV) and Pt(II) oxidation states in a chloride system, it has been suggested that Pt(IV) complexes will be reduced to Pt(II) complexes in a biological environment. To test this hypothesis, uptake and metabolism studies of [14C]-iproplatin were carried out in L1210 cells. The L1210 cells raised in DBA2/J mice were incubated in vitro with 50 and 100 microM [14C]-iproplatin at 37 degrees C in Hanks' balanced salt solution, and total uptake and radioactivity associated with acid-insoluble fractions were measured for up to 3 h. Under these conditions, the uptake of iproplatin was linear with time and increased with increasing concentrations of iproplatin in the medium. At all times measured, greater than 35% of radioactivity was associated with the acid-insoluble fraction, suggesting binding to macromolecules. The [14C]-labelled compounds in neutralized acid extracts of cells were separated by reverse-phase high-performance liquid chromatography (HPLC). Three labelled compounds were detected; based on chromatographic elution times, they appeared to be iproplatin, cis-dichloro-bis-isopropylamine platinum(II) (CIP), the reduction product of iproplatin, and a third compound more polar than iproplatin and CIP. The finding of free CIP and the macromolecular binding of radioactivity in the cells suggests that iproplatin is reduced intracellularly.
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