The multiple drug resistance of neoplastic cells is mediated by overexpression of the human MDR1 gene, which encodes the transmembrane efflux pump P-glycoprotein. In both cell lines and human tumors the MDR phenotype closely correlates with MDR1 mRNA and P-glycoprotein levels. Reversion of the MDR phenotype was attempted in human colorectal adenocarcinoma doxorubicin (Dx)-resistant cells (Lo Vo/Dx) by long-term administration of an equimolecular mixture of three unmodified ODNs (18mer) targeted to adjacent binding sites of the MDR1 mRNA and carried by a synthetic cationic lipid (DOTAP). Three different experimental parameters were used to evaluate the antimessenger agent's effectiveness in comparison with a random sequence ODN: the level of cell resistance to Dx; the level of P-glycoprotein (determined by flow cytometry); the level of MDR1 mRNA (determined by quantitative RT-PCR). Experimental data indicate that the level of both the MDR1 mRNA and the P-glycoprotein is reduced by approximately 50% by treatment of Lo Vo/Dx cells with a 10 microM total concentration of the aODN mixture every 24 h for 15 days. In agreement with these findings, sensitivity to Dx of the antimessenger agent-treated Lo Vo/Dx cells was almost doubled in comparison with random sequence ODN-treated controls.