8-oxo-dGuo ͉ DNA strand breaks ͉ tobacco carcinogens ͉ reactive oxygen species P olycyclic aromatic hydrocarbons (PAHs) are ubiquitous environmental pollutants, which are produced as a result of fossil-fuel combustion and are found in car exhaust and charbroiled and smoked foods (1, 2). They are also present as mixtures in tobacco smoke and are implicated in the causation of human lung cancer (3). To exert their carcinogenic effects, PAHs must be metabolically activated to DNA-damaging agents that will result in the signature mutations in lung cancer. These mutations are G-to-T transversions that either activate the K-ras protooncogene at the 12th and 61st codon (4) or inactivate the p53 tumor suppressor gene at hot spots in its DNA binding domain (5).Using benzo[a]pyrene (B[a]P) as a representative PAH, three pathways of activation have been proposed that lead to these mutations. The first pathway involves the formation of (ϩ)-anti-7␣,8-dihydroxy-9␣,10-epoxy-7,8,9,10-tetrahydroB[a]P {(Ϯ)- anti-B[a]PDE}.In this pathway there is sequential monoxygenation catalyzed by cytochrome P450 (P450) 1A1/1B1 and hydration to form 7␣,8-dihydroxy-7,8-dihydroxy-B[a]P, which undergoes a secondary monoxygenation to form (ϩ)-anti-B[a]PDE (6). This diol-epoxide forms stable (ϩ)-anti-trans-B[a]PDE-N 2 -2Ј-deoxyguanosine (dGuo) adducts, which via trans-lesional bypass DNA polymerases, yield G-to-T transversions (7).The second pathway involves metabolic activation by P450 peroxidases to yield radical cations (8), which can form depurinating adducts that lead to abasic sites. Apurinic/apyrimdinic (AP) sites, if not repaired, can give rise to G-to-T transversions (9). However, it is unlikely that radical cations are sufficiently long-lived to damage DNA in intact cells.The third pathway of PAH activation is the NAD(P ϩ )-dependent oxidation of PAH-trans-dihydrodiols to PAH oquinones catalyzed by dihydrodiol dehydrogenase members of the aldo-keto reductase (AKR) superfamily (10). AKRs divert PAH trans-dihydrodiols to form ketols that spontaneously rearrange to catechols (Scheme 1). The catechols undergo two one-electron oxidation events to produce the corresponding redox-active and electrophilic o-quinones. PAH o-quinones can form stable and depurinating DNA adducts in vitro (11,12), and these adducts may provide a route to G-to-T transversion mutations.In the presence of NAD(P)H, PAH o-quinones also undergo nonenzymatic reduction back to catechols. This event establishes futile redox cycles, which amplify the generation of reactive oxygen species (ROS) at the expense of NADPH and may lead to a prooxidant cellular state. Because a prooxidant state has been associated with tumor initiation and promotion (13), the AKR pathway of PAH activation is attractive in that it could explain how PAHs act as complete carcinogens. In addition, ROS may cause oxidative DNA damage such as 7,8-dihydro-8-oxo-2Ј-deoxyguanosine (8-oxo-dGuo) lesions, which can lead to G-to-T transversions (14). Amplification of ROS by catechol-oquinone interconversion has...
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Extent of DNA platination, loss of cell viability, DNA fragmentation, and impairment of cellular mitochondrial oxygen consumption are measures of drug cytotoxicity. We measured and compared these effects for cisplatin, oxaliplatin and carboplatin. Because reaction with intracellular thiols may be responsible for drug resistance, we also determined the rates of Pt drug reactions with metallothionein. Jurkat cells were exposed at 37 degrees C to 25 microM Pt drugs for 3 h. Pt-DNA adducts were determined at the end of the incubation period by atomic absorption spectroscopy. Viability, DNA fragmentation, and cellular respiration (microM O2/min/10(6) cells) were determined 24 h post drug exposure. The average amount of Pt-DNA adducts (Pt atoms/10(6) nucleotides) produced by cisplatin was 43.4, by oxaliplatin 4.8 and by carboplatin 1.5. Cisplatin decreased the rate of respiration by approximately 63% and oxaliplatin by approximately 37%. DNA fragmentation by cisplatin and oxaliplatin was very similar. Carboplatin produced an unnoticeable effect on cellular respiration, and only approximately 10% of the DNA fragmentation was produced by cisplatin or oxaliplatin. Although, for a given drug, all four measures of cytotoxicity were proportional, this did not hold for comparisons between the drugs. The rate constants (M-1 s-1) for reaction of cisplatin, oxaliplatin and carboplatin with Cd/Zn thionein were 0.75, 0.44 and 0.012, respectively. For comparison, the rate constants (M-1 s-1) for reaction of cisplatin, oxaliplatin and carboplatin with glutathione were 0.027, 0.038 and 0.0012, respectively. The low reactivity of carboplatin with metallothionein and glutathione suggests that its low cytotoxic activities are not due to reaction of Pt2+ with cellular thiols. Despite a tenfold difference in Pt-DNA adducts between cisplatin and oxaliplatin, the cytotoxicities of these compounds are very similar, suggesting that oxaliplatin lesions are more potent than cisplatin lesions. The results demonstrate a large influence of the ligands occupying Pt coordination spheres on the chemical and biologic activities of Pt drugs.
For Jurkat cells in culture exposed to cisplatin (1), we measured the number of platinum adducts on DNA and showed that it is proportional to the AUC, the area under the concentration vs time curve, for cisplatin. The number of platinum-DNA adducts is measured immediately following exposure to drug. The AUC is calculated either as the product of the initial cisplatin concentration and the exposure time or as the integral under the concentration vs time curve for the unreacted dichloro species, which decreases exponentially. We also show that the number of adducts correlates with decreases in respiration, with the amount of DNA fragmentation, and with cell viability, all measured 24 h after exposure to the drug. To study the reactions of cisplatin at concentrations approaching clinical relevance (65 microM), we use two-dimensional [1H15N]HSQC NMR and the 15N-labeled form of the drug, cis-Pt(15NH3)2Cl2, 1. In the absence of cells, 1 reacts with components of the growth medium and also transforms slowly (k(h) = 0.205 h-1 at 37 degrees C) into the chloro-aquo species, cis-[Pt(15NH3)2Cl(H2O)]+ (2), which at the pH of the medium (pH 7.15), is mainly in the deprotonated chloro-hydroxy form, cis-Pt(15NH3)2Cl(OH) (4). The concentration of 2 (4), as measured by HSQC NMR, decreases due to reaction with components of the medium. In the presence of 5 million or more cells, the concentration of 1 decreases with time, but the NMR signal for 2 (4) is not seen because it is rapidly removed from solution by the cells, keeping its concentration very low. These experiments confirm that the species preferentially removed from the medium by cells is 2 (4) and not 1. Our findings are discussed in the context of a kinetic model for platination of nuclear DNA by cisplatin, which includes aquation of cisplatin outside the cell, passage of 2 (4) through the cell membrane, reaction of reactive platinum species (RPS) in the cytosol with thiols, formation of adducts between RPS and accessible sites on genomic DNA, and removal of platinum from DNA by repair. Some of the rate constants involved are measured, but others can only be estimated. Calculations with this model show that little of the platinum reacts with intracellular thiols before reaching the nuclear DNA, indicating that binding to thiols is not important in cisplatin resistance. The model also predicts the circumstances under which the amount of platination of nuclear DNA is proportional to AUC.
ABSTRACTϪ (4), a cisplatin species that forms in culture media and probably also in blood. Analysis of the HSQC NMR peak intensity for 4 in the presence of different numbers of Jurkat cells reveals that each cell is capable of modifying 0.0028 pmol of 4 within ϳ0.6 h. The amounts of platinum taken up by the cell, weakly bound to the cell surface, remaining in the culture medium, and bound to genomic DNA were measured as functions of time of exposure to different concentrations of drug. The results show that most of the 4 that has been modified by the cells remains in the culture medium as a substance of molecular mass Ͻ3 kDa, which is HSQC NMR silent, and is not taken up by the cell. These results are consistent with a hitherto undocumented extracellular detoxification mechanism in which the cells rapidly modify 4, which is present in the culture medium, so it cannot bind to the cell. Because there is only a slow decrease in the amount of unmodified 4 remaining in the culture medium after 1 h, Ϫ1.1 Ϯ 0.4 M h Ϫ1 , the cells subsequently lose their ability to modify 4. These observations have important implications for the mechanism of action of cisplatin.
In this work, we measured the effects of pharmacological concentrations of cisplatin (cis-diaminedichloroplatinum II) on mitochondrial function, cell viability, and DNA fragmentation in Jurkat cells. The exposure of cells to 0-25 microM cisplatin for 3 h had no immediate effect on cellular mitochondrial oxygen consumption, measured using a palladium-porphyrin oxygen sensing phosphor. Similarly, the cell viability as measured by trypan blue staining was unchanged immediately following exposure to the drug, and no small DNA fragments, characteristic of drug-induced apoptosis, appeared. At 24 h after exposure to cisplatin, cellular respiration and viability decreased relative to controls and the amount of small DNA fragments, measured using quantitative agarose gel electrophoresis, was proportional to the concentration of cisplatin present during the drug exposure period. The small DNA fragments showed the banding pattern (with a spacing of approximately 300 bp) characteristic of drug-induced cell death by apoptosis. The changes in respiration and DNA fragmentation correlated linearly with the amount of platinum bound to DNA, determined by atomic absorption spectroscopy immediately following drug exposure. The oxygen consumption by beef heart mitochondria was not affected 0-24 h after exposure to 25 microM cisplatin or to solutions containing the monoaquated form of the drug, suggesting that the drug does not attack the mitochondrial respiratory chain directly. Cells exposed to the peptide benzyloxycarbonyl-val-ala-asp-fluoromethyl ketone, which blocks apoptosis by the caspase pathway, showed a decrease in cisplatin-induced DNA fragmentation but not in the impairment of cellular respiration. Thus, although apoptosis is caspase-dependent, the impairment of cellular respiration is independent of the caspase system. Collectively, these results suggest that alteration in mitochondrial function is a secondary effect of cisplatin cytotoxicity in Jurkat cells.
ABSTRACT:The kinetics of the reactions of glutathione (GSH) with 4-hydroperoxycyclophosphamide (4OOH-CP) and acrolein, a metabolite of 4OOH-CP, were investigated in a cell-free medium (pH ϳ7.5) and peripheral blood mononuclear cells. The ability of the thiol drugs, sodium 2-mercaptoethane sulfonate (mesna) and S-2-(3-aminopropylamino)ethanethiol (WR-1065), to affect the reactions of cellular GSH with the alkyalting agents was also studied. The amount of unreacted thiols in the various reactions was determined by derivatization with monobromobimane, followed by separation of fluorescent-labeled thioether adducts using high-pressure liquid chromatography. The second-order rate constants (k 2 ) for reactions of GSH, mesna, and WR-1065 with 4OOH-CP in solution were 38 ؎ 5, 25 ؎ 5, and 880 ؎ 50 M , respectively. The apparent rate constants for reactions of cellular GSH with acrolein and 4OOH-CP were smaller than those obtained in solution. Assuming that the k 2 is the same inside and outside cells, we estimate the first-order rate constant (k 1 ) for transfer of 4OOH-CP and acrolein across the cell membrane as ϳ0.01 and ϳ0.04 s ؊1 , respectively. WR-1065 was more effective than mesna in blocking depletion of cellular GSH (because it passes into the cell more quickly and has higher reaction rates with the alkylators than the latter compound). When WR-1065 and mesna were used together, the protection against cellular depletion of GSH was additive. Our results are relevant to the administration of thiol drugs with highdose alkylating agents.
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