Coselection for resistance to multiple late-generation human therapeutic antibiotics encoded on tetracycline resistance plasmids captured from uncultivated stream and soil bacteria.

AIMS: Transmissible plasmids captured from stream and soil bacteria conferring resistance to tetracycline in Pseudomonas were evaluated for linked resistance to antibiotics used in the treatment of human infections. METHODS AND RESULTS: Cells released from stream sediments and soils were conjugated with a rifampicin-resistant, plasmid-free Pseudomonas putida recipient and selected on tetracycline and rifampicin. Each transconjugant contained a single 50-80 kb plasmid. Resistance to 11 antibiotics, in addition to tetracycline, was determined for the stream transconjugants using a modification of the Stokes disc diffusion antibiotic susceptibility assay. Nearly half of plasmids conferred resistance to six or more antibiotics. Resistance to streptomycin, gentamicin, and/or ticarcillin was conferred by a majority of the plasmids, and resistance to additional human clinical use antibiotics such as piperacillin/tazobactam, ciprofloxacin and aztreonam was observed. MICs of 16 antibiotics for representative sediment and soil transconjugants revealed large increases, relative to the Ps. putida recipient, for 11 of 16 antibiotics tested, including the expanded spectrum antibiotics cefotaxime and ceftazidime, as well as piperacillin/tazobactam, lomefloxacin and levofloxacin. CONCLUSIONS: Resistance to multiple antibiotics-including those typically used in clinical Pseudomonas and enterobacterial infections-can be conferred by transmissible plasmids in streams and soils. SIGNIFICANCE AND IMPACT OF STUDY: Selective pressure exerted by the use of one antibiotic, such as the common agricultural antibiotic tetracycline, may result in the persistence of linked genes conferring resistance to important human clinical antibiotics. This may impact the spread of resistance to human use antibiotics even in the absence of direct selection.

Differential susceptibility of macrophage cell lines to Bacillus anthracis-Vollum 1B.

Bacillus anthracis (BA) is a spore forming bacterium and the causative agent of anthrax disease. Macrophages (Mphis) play a central role in anthrax disease. An important step in disease progression is the ability of BA to secrete lethal toxin (LeTx) that kills Mphis. LeTx is a heterodimer composed of protective antigen (PA) and lethal factor (LF). Researchers have shown that Mphi cell lines demonstrate differential susceptibility to purified LeTx; for example RAW264.7 and J774A.1 Mphis are sensitive to LeTx whereas IC-21 Mphis are resistant. Research has also suggested that exogenous factors, including other BA proteins, can influence the activity of LeTx. For this reason, the objective of the current work was to examine if RAW264.7, J774A.1, and IC-21 Mphis demonstrated differential susceptibility when cultured with a LeTx-producing strain of BA. Here, we co-cultured Mphis with LeTx+ Vollum 1B (V1B) spores for >15 h and assayed for Mphi cell death by morphology, trypan blue (TB) staining, neutral red (NR) activity, and lactate dehydrogenase (LDH) activity in the culture media. Following the addition of V1B spores, necrosis (approximately 50% mortality) was observed in RAW264.7 and J774A.1 Mphis at 7.5 and 10 h, respectively. By 15 h, both RAW264.7 and J774A.1 Mphis demonstrated 100% mortality. In contrast, IC-21 Mphis, under identical culture conditions, remained viable (98%) and activated throughout the course of the experiment (>24 h). The mechanism of RAW264.7 cell death appeared to involve LeTx because the V1B-induced cytotoxicity was dose-dependently reversed by the addition of anti-PA antibody to the culture media. These observations suggest there is differential susceptibility of Mphi cell lines to the LeTx+ V1B strain of BA. Further development of this in vitro model may be useful to further characterize the interactions between Mphis and BA spores.