We examined the short-term accumulation of cisplatin (DDP) in sensitive 2008 human ovarian carcinoma cells and in a 2- to 3-fold DDP-resistant and accumulation-deficient variant. During the 1st min of exposure to 500 microM DDP, sensitive cells accumulated platinum at a rate of 187 +/- 63 pmol/mg protein per min, whereas resistant cells accumulated platinum at 123 +/- 85 pmol/mg protein per min, a rate that was 66% that of sensitive cells. From 2-10 min of exposure, sensitive and resistant cells accumulated the drug at rates of 51.4 +/- 21.5 and 34.0 +/- 9.70 pmol/mg protein per min, respectively. In resistant cells, this rate again represented 66% that of sensitive cells. For each cell line, the DDP accumulation was 3.6 times faster during the 1st min than it was over 2-10 min. Initial DDP accumulation was linear with drug concentration in each cell line. Efflux measurements were made over a 50-min period after a 10-min load in 500 microM DDP. The loss of platinum was biphasic in each cell line, with an initial, rapidly effluxing component being lost within 10 min in each cell line. The rate constant for loss of platinum from this rapidly effluxing pool, measured after a 10-min loading period in 500 microM DDP, was 0.67 +/- 0.09 s-1 in sensitive cells and 1.03 +/- 0.15 s-1 (a 53% increase) in resistant cells. Between 5 and 50 min of an accumulation time course in 500 microM DDP, the size of the rapidly effluxing platinum pool remained relatively constant in each cell line, with the major contribution to the increase in total platinum over time coming from growth of the slowly effluxing platinum pool. We conclude that diminished retention of platinum in the rapidly effluxing pool of resistant cells is a major determinant of decreased DDP accumulation in these cells.
We have determined the ability of two human ovarian carcinoma cells to over-express metallothioneins (MTs) and the subsequent effect this elevation has on DDP cytotoxicity. Cells of 2008 and COLO 316 human ovarian carcinomas that were resistant to CdCl2 were obtained by stepwise selection and chronic culture in CdCl2 and ZnCl2. The 2008/MT cells were 3.2-fold resistant to CdCl2 and 4.1-fold resistant to DDP; they had 23-fold elevated MTs. The COLO/MT cells were 1.2-fold resistant to CdCl2 and 3.3-fold resistant to DDP, and they had 9-fold elevated MTs. Glutathione (GSH) was also elevated in the Cd-resistant sublines. However, four times more intracellular thiols were contributed by the MTs than by the GSH. 2008 and 2008/MT cells were examined in more detail to elucidate the mechanism of DDP resistance. Depletion of GSH with D,L-buthionine-S,R-sulfoximine (BSO) had no effect on the sensitivity of these cells to either CdCl2 or DDP. Uptake of [195m Pt]DDP in 2008 and 2008/MT cells was identical. Fractionation of the cytosol from [195mPt]DDP-exposed cells on Sephadex G-75 revealed that 17% of the total cellular Pt in 2008/MT cells was associated with the MT fraction, as against 4% in the parent 2008 cells. This increase corresponded to a concomitant loss of Pt from the particulate fraction. Fractionation of 2008 cells selected with DDP (2008/DDP cells) indicated that elevated MTs did not contribute to the DDP resistance of these cells. Only 2% of the total cellular Pt was in the MT fraction in 2008/DDP cells. These results showed that elevation of MTs may be one mechanism of DDP resistance in ovarian carcinoma; however, in vitro selection with DDP does not trigger this mechanism.
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