Leo Den Engelse

Effects of temperature on the interaction of cisplatin and carboplatin with cellular DNA

Increased levels of cisplatin (cDDP)- and carboplatin (CBDCA)-DNA adducts were detected in cDDP (10 microM)- and CBDCA (6 mM)-treated CC531 cells when the temperature was raised from 37 degrees to 43 degrees. In the case of cDDP, increased DNA adduct formation was already detectable at 38.5 degrees; additional temperature steps led to further increases in DNA modification. Increased CBDCA-DNA adduct formation was observed only at temperatures higher than 40 degrees. In vitro studies on the interaction of CDDP and CBDCA with isolated salmon sperm DNA, however, demonstrated no significant differences in the DNA binding rate between 37 degrees and 43 degrees for cDDP and a minor effect for CBDCA only at 43 degrees, almost totally excluding a direct temperature effect on DNA platination in this temperature range. Furthermore, neither the stability of the formed platinum-DNA adducts nor the rate of adduct loss in CC531 cells was changed at higher temperatures. The observed difference in cellular adduct formation, however, could be related to increased uptake of cDDP and CBDCA into CC531 cells at higher temperatures. In the case of cDDP, a temperature shift from 37 degrees to 38.5 degrees resulted in a significantly higher intracellular platinum concentration (0.03 +/- 0.01 vs 0.071 +/- 0.021 micrograms platinum/10(6) cells, respectively); for CBDCA, temperatures > or = 41.5 degrees were needed to increase the platinum concentration significantly above 37 degree values (0.3 +/- 0.1 vs 0.6 +/- 0.1 micrograms platinum/10(6) cells, respectively). In addition, the increase in DNA adduct formation of cDDP and CBDCA at elevated temperatures was comparable with the increase in cDDP-DNA adducts after a cDDP concentration escalation at 37 degrees, indicating a concentration-dependent increase in cDDP-DNA adducts. It seems that heat affects primarily the cellular uptake of cDDP and CBDCA and not their covalent binding to DNA.

In vivo repair of rat liver DNA damaged by dimethylnitrosamine or diethylnitrosamine.

Effects of hepatocarcinogens dimethylnitrosamine (DMN) and diethylnitrosamine (DEN) on the sedimentation pattern of rat liver DNA in alkaline sucrose gradients were studied with regard to time and dose dependency. Both DMN (10 mg/kg body weight) and den (13.4 or 134 mg/kg) induced appreciably decreased DNA sedimentation rates at 24 h after injection. DMN at 10 mg/kg was as effective in decreasing the DNA sedimentation rate at 24 h after injection as was the higher dose of DEN (134 mg/kg). Sedimentation patterns at 1, 6 and 14 days after injection indicated that damage induced by DEN (134 mg/kg) was repaired at a substantially lower rate than DMN (10 mg/kg) induced damage. When effects of equimolar doses of DMN (10 mg/kg) and DEN (13.4 mg/kg) were compared at 1, 6 and 14 days after injection, it was observed that the more pronounced damage of rat liver DNA induced by DMN was repaired at a faster rate than was the DEN-induced damage. At the molecular level this difference in repair between damage induced by the two nitrosamines is probably related to different DNA alkylation patterns. The relatively persistent nitrosamine-induced DNA lesions (observed especially after DEN administration) are thought to represent phosphotriesters which give rise to single strand DNA breaks at strongly alkaline conditions of lysis on top of the gradient. The results are discussed in relation to the possible significance of alkylation and repair of DNA in the formation of (pre)cancerous lesions in rat liver.

Immunocytochemical analysis of in vivo DNA modification.

In the past decades a large number of DNA adducts induced in the intact animal by alkylating agents have been identified. The formation and repair of these adducts are important determinants, not only of mutagenesis, tumor initiation and DNA-mediated toxicity but probably also of tumor progression. Most studies on in vivo DNA modification have been performed on isolated bulk DNA. More recently, methods have been developed to study the distribution of DNA adducts at the level of either the individual gene or the individual cell. This paper reviews immunocytochemical methods to study the formation and repair of DNA adducts and other DNA modifications at the level of the individual cell. DNA modifications induced by alkylating agents and a variety of other agents including ultraviolet radiation, aromatic amines, polycyclic aromatic hydrocarbons and platinum anti-cancer drugs will be discussed. Up to now, immunocytochemical analysis of in vivo modified DNA has largely concentrated on experimental animals. These studies have revealed striking heterogeneities with regard to formation and/or repair of DNA adducts in tissues from rat, hamster and mouse. Immunocytochemical adduct analysis can be used to identify in a convenient, fast and detailed way cell types, cell stages and sites in which biological effects of the adducts might be expressed. More recently, immunocytochemical analysis of DNA adducts also proved to be feasible on in situ exposed human samples. A number of existing and potential applications in the field of chemical carcinogenesis, experimental chemotherapy and molecular epidemiology are discussed.

Nucleoside analysis of DNA from Trypanosoma brucei and Trypanosoma equiperdum

We have digested trypanosome DNA with a combination of pancreatic DNase I, nuclease P1 and bovine alkaline phosphatase and fractionated the resulting nucleosides on a Supelcosil LC-18-S column by high pressure liquid chromatography. We find less than 0.1% unusual nucleosides, both in Trypanosoma brucei and in a Trypanosoma equiperdum stock, in contrast to a previous report of an unusual nucleoside replacing dC at 1.3% of total nucleosides in T. equiperdum. Our results agree with previous suggestions that the modification of inactive telomeric expression sites for variant-specific surface glycoprotein genes in T. brucei only affects a very small fraction of the total DNA.

Immunocytochemical Analysis of Platinum-DNA Adducts

Interaction with DNA is supposed to play an essential role in the cytostatic effects of platinum anti-tumor drugs like cisplatin (cisDDP) and carboplatin (CBDCA). Clinical resistance to cisplatin and carboplatin, both primary and acquired, might be related to decreased levels of DNA adduct formation and/or increased capacities to repair these adducts. We have studied DNA adduction by cisplatin and carboplatin at the level of the single cell. In the last decade, methods have been developed for the immunocytochemical analysis of DNA modifications induced by a variety of carcinogens, anti-cancer drugs and radiation [see Den Engelse et al., 1990 for review].