Bacilus subtilis cells selected for their resistance to rhodamine 6G demonstrated a multidrug-resistance (MDR) phenotype resembling that of mammalian MDR cells. Like MDR in mammalian cells, MDR in bacteria was mediated by the efflux of the drugs from the cells. The bacterial multidrug efflux system transported similar drugs and was sensitive to similar inhibitors as the mammalian multidrug transporter, P-glycoprotein. The gene coding for the bacterial multidrug transporter, like the P-glycoprotein gene in mammalian MDR cells, was amplified in the resistant bacteria. On the other hand, the bacterial multidrug transporter showed no sequence similarity to P-glycoprotein but exhibited an obvious homology to tetracycline efflux pumps and carbohydrate-ion symporters. These results show that the transport of structurally unrelated molecules can be mediated by members of different families of membrane transporters.Mammalian cells selected in culture for resistance to various lipophilic cytotoxic drugs often demonstrate resistance not only to the selective agent but also to a large group of apparently unrelated toxic compounds. This phenomenon, called multidrug resistance (MDR), is based on active efflux of drugs from the cells, performed by a membrane ATPase pump, P-glycoprotein (reviews in refs. 1 and 2). In MDR cells, the mdrl gene coding for this protein is frequently amplified (1). Overexpression of the P-glycoprotein gene is believed to be responsible for clinical drug resistance in many tumors.The most intriguing question in the area of MDR is the mechanism of extremely broad chemical specificity of P-glycoprotein. Its substrates have almost nothing in common, except that most of them bear positive electric charge and all of them are moderately hydrophobic. Some substances, such as reserpine and verapamil, are potent inhibitors of P-glycoprotein activity, apparently by a competition mechanism (3, 4). P-glycoprotein belongs to a large family of membrane ATPase pumps both of eukaryotic and of prokaryotic origin (2). It is, however, the only member of this family with a proven ability to transport multiple drugs. Even close homologues ofP-glycoprotein-the mammalian mdr2 gene product (5) and the yeast STE6 protein (6)-do not share this property. Here we describe MDR in Gram-positive bacteria and characterize the gene of a bacterial multidrug transporter.s MATERIALS AND METHODS Bacteria and Plasmids. Bacillus subtilis BD170 (trpC2, thr-S) and BD224 (trpC2, thr-S, recE4), Escherichia coli JM103, B. subtilis plasmids pCB20 (7) and pUB110, E. coli plasmids pUC19 and pBluescript KS(+) (Stratagene), and shuttle plasmid pMK3 (8) were used in this work.Selection of Resistant Bacteria and Sensitivity Assay. BD170 bacteria were selected with rhodamine 6G in the liquid antibiotic medium 3 (Difco) supplemented with 0.4% glucose.Bacteria were grown at 370C with the drug at 0.5, 1, 2, 3, and 4,g/ml, consecutively. The cultures were diluted 1:100 with fresh drug-containing medium every 1-2 days. The drug concentration was in...
