Multidrug Resistance: An Emerging Crisis

Drug efflux pumps play a key role in drug resistance and also serve other functions in bacteria. There has been a growing list of multidrug and drug-specific efflux pumps characterized from bacteria of human, animal, plant and environmental origins. These pumps are mostly encoded on the chromosome, although they can also be plasmid-encoded. A previous article in this journal provided a comprehensive review regarding efflux-mediated drug resistance in bacteria. In the past 5 years, significant progress has been achieved in further understanding of drug resistance-related efflux transporters and this review focuses on the latest studies in this field since 2003. This has been demonstrated in multiple aspects that include but are not limited to: further molecular and biochemical characterization of the known drug efflux pumps and identification of novel drug efflux pumps; structural elucidation of the transport mechanisms of drug transporters; regulatory mechanisms of drug efflux pumps; determining the role of the drug efflux pumps in other functions such as stress responses, virulence and cell communication; and development of efflux pump inhibitors. Overall, the multifaceted implications of drug efflux transporters warrant novel strategies to combat multidrug resistance in bacteria.

The treatment of bacterial infections is increasingly complicated by the ability of bacteria to develop resistance to antimicrobial agents. Antimicrobial agents are often categorized according to their principal mechanism of action. Mechanisms include interference with cell wall synthesis (e.g., beta-lactams and glycopeptide agents), inhibition of protein synthesis (macrolides and tetracyclines), interference with nucleic acid synthesis (fluoroquinolones and rifampin), inhibition of a metabolic pathway (trimethoprim-sulfamethoxazole), and disruption of bacterial membrane structure (polymyxins and daptomycin). Bacteria may be intrinsically resistant to > or =1 class of antimicrobial agents, or may acquire resistance by de novo mutation or via the acquisition of resistance genes from other organisms. Acquired resistance genes may enable a bacterium to produce enzymes that destroy the antibacterial drug, to express efflux systems that prevent the drug from reaching its intracellular target, to modify the drug's target site, or to produce an alternative metabolic pathway that bypasses the action of the drug. Acquisition of new genetic material by antimicrobial-susceptible bacteria from resistant strains of bacteria may occur through conjugation, transformation, or transduction, with transposons often facilitating the incorporation of the multiple resistance genes into the host's genome or plasmids. Use of antibacterial agents creates selective pressure for the emergence of resistant strains. Herein 3 case histories-one involving Escherichia coli resistance to third-generation cephalosporins, another focusing on the emergence of vancomycin-resistant Staphylococcus aureus, and a third detailing multidrug resistance in Pseudomonas aeruginosa--are reviewed to illustrate the varied ways in which resistant bacteria develop.

Schistosoma mansoni infections in mice were treated with subcurative multiple doses of either praziquantel (PZQ) or oxamniquine (OX). With an early exception, the drug treatments commenced when the worms were adult, but before the infections had become fully patent, and the eggs subsequently produced by worms that had survived the drug treatments were used to infect snails. Six or seven drug-treated passages of S. mansoni in mice were completed for each of the drugs, with the amount of drug administered to the infected mice generally being increased with each passage. Eighty percent of the worms of the sixth passage selected for PZQ resistance survived three doses of 300 mg/kg of PZQ given between days 28 and 37 after infection, and 93% of those of the seventh passage survived the same drug dose. In contrast, only 13% of worms of the sixth PZQ-selected passage survived three doses of 200mg/kg of OX given during the same period after infection. Only 11% or fewer worms derived from S. mansoni infections that had not been subjected to any drug pressure survived the 3 x 300 mg/kg PZQ treatments. Worms selected for OX resistance over six passages were completely resistant to three doses of 200 mg/kg, but only 26% survived three doses of 300 mg/kg of PZQ. Therefore, the results indicate that S. mansoni subjected to drug pressure may develop resistance to schistosomicidal drugs over the course of relatively few passages, but that cross-resistance between PZQ and OX does not occur. This is the first demonstration of drug resistance to PZQ, the current drug of choice for human schistosomiasis.