Effects of residual antibiotics in groundwater on Salmonella typhimurium: changes in antibiotic resistance, in vivo and in vitro pathogenicity.

An outbreak-causing strain of Salmonella enterica serovar Typhimurium was exposed to groundwater with residual antibiotics for up to four weeks. Representative concentrations (0.05, 1, and 100 µg L(-1)) of amoxicillin, tetracycline, and a mixture of several other antibiotics (1 µg L(-1) each) were spiked into artificially prepared groundwater (AGW). Antibiotic susceptibility analysis and the virulence response of stressed Salmonella were determined on a weekly basis by using human epithelial cells (HEp2) and soil nematodes (C. elegans). Results have shown that Salmonella typhimurium remains viable for long periods of exposure to antibiotic-supplemented groundwater; however, they failed to cultivate as an indication of a viable but nonculturable state. Prolonged antibiotics exposure did not induce any changes in the antibiotic susceptibility profile of the S. typhimurium strain used in this study. S. typhimurium exposed to 0.05 and 1 µg L(-1) amoxicillin, and 1 µg L(-1) tetracycline showed hyper-virulent profiles in both in vitro and in vivo virulence assays with the HEp2 cells and C. elegans respectively, most evident following 2nd and 3rd weeks of exposure.

A fluorescence resonance energy transfer-based fluorometer assay for screening anti-coxsackievirus B3 compounds.

In view of the need to develop a simple and rapid method to screen for antiviral therapeutic agents, a fluorescence resonance energy transfer (FRET)-based reporter system consisting of engineered mammalian cells expressing a cyan fluorescent protein-yellow fluorescent protein (CFP-YFP) pair linked by a short peptide containing the cleavage site of viral protease 2A (2A(pro)) was developed. By detecting the 2A(pro) produced early during the virus infection cycle, the CFP-YFP pair effectively identifies infectious coxsackievirus B3 (CVB3), a picornavirus that causes viral myocarditis in humans. The reporter system was used to screen a library of 2000 drugs and natural products for potential antiviral compounds. The reporter cells were treated with the test compounds, challenged with CVB3, and then examined using a fluorometer at 24h post-infection. Sixty-four compounds, mostly therapeutic drugs, antimicrobial compounds and compounds with unknown functions, caused at least 50% inhibition of 2A(pro) activity. Three known antiviral compounds, cosmosiin, ribavirin and baicalein, were also identified in the screening. The developed method is an effective strategy for rapid screening, and identifies compounds that inhibit CVB3 2A(pro). This method should be a valuable aid in the antiviral drug discovery effort.

Label-free chemiresistive immunosensors for viruses.

We report development, characterization, and testing of chemiresistive immunosensors based on single polypyrrole (Ppy) nanowire for highly sensitive, specific, label free, and direct detection of viruses. Bacteriophages T7 and MS2 were used as safe models for viruses for demonstration. Ppy nanowires were electrochemically polymerized into alumina template, and single nanowire based devices were assembled on a pair of gold electrodes by ac dielectrophoretic alignment and anchored using maskless electrodeposition. Anti-T7 or anti-MS2 antibodies were immobilized on single Ppy nanowire using EDC-NHS chemistry to fabricate nanobiosensor for the detection of corresponding bacteriophage. The biosensors showed excellent sensitivity with a lower detection limit of 10(-3) plaque forming unit (PFU) in 10 mM phosphate buffer, wide dynamic range and excellent selectivity. The immunosensors were successfully applied for the detection of phages in spiked untreated urban runoff water samples. The results show the potential of these sensors in health care, environmental monitoring, food safety and homeland security for sensitive, specific, rapid, and affordable detection of bioagents/pathogens.