Real time detection of anthrax spores using highly specific anti-EA1 recombinant antibodies produced by competitive panning.

We describe a targeted approach for the production of biological recognition elements capable of fast, specific detection of anthrax spores on biosensor surfaces. The aim was to produce single chain antibodies (scFvs) to EA1, a Bacillus anthracis S-layer protein that is also present, although not identical, in related to Bacillus species. The aim of the work was to produce antibodies that would detect B. anthracis EA1 protein and intact spores with a high degree of specificity, but would not detect other Bacillus species. Existing monoclonal antibodies were evaluated and found to recognise B. anthracis EA1 and S-layer proteins from other closely related Bacillus species. Recombinant anti-EA1 scFvs were isolated from B. anthracis immune library that contained antibody genes raised against B. anthracis spores and purified exosporium. Two approaches for scFv selection were used; standard (non-competitive) panning, and competitive panning. The non-competitive biopanning strategy isolated scFvs that recognised EA1 from B. anthracis, but also cross-reacted with other Bacillus species. In contrast, the competitive panning approach used S-layer proteins from other Bacillus species to generate scFvs that were highly specific to B. anthracis EA1 and demonstrated apparent nanomolar binding affinities. Specific, real time detection of B. anthracis spores was demonstrated with these scFvs using an evanescent wave biosensor, the Resonant Mirror. The approach described can be used to generate specific antibodies to any desired target where homologous proteins also exist in closely related species, and demonstrates clear advantages to using recombinant technology to produce biological recognition elements for detection of biological threat agents.

Improvement of immunodetection of bacterial spore antigen by ultrasonic cavitation.

Ultrasonic cavitation was employed to enhance sensitivity of bacterial spore immunoassay detection, specifically, enzyme-linked immunosorbent assay (ELISA) and resonant mirror (RM) sensing. Bacillus spore suspensions were exposed to high-power ultrasound in a tubular sonicator operated at 267 kHz in both batch and flow modes. The sonicator was designed to deliver high output power and is in a form that can be cooled efficiently to avoid thermal denaturation of antigen. The 30-s batch and cooled flow (0.3 mL/min) sonication achieved an approximately 20-fold increase in ELISA sensitivity compared to unsonicated spores by ELISA. RM sensing of sonicated spores achieved detection sensitivity of approximately 10(6) spores/mL, whereas unsonicated spores were undetectable at the highest concentration tested. Improvements in detection were associated with antigen released from the spores. Equilibrium temperature increase in the tubular sonicator was limited to 14 K after 30 min and was maintained for 6 h with cooling and flow (0.3 mL/min). The work described here demonstrates the utility of the tubular sonicator for the improvement in the sensitivity of the detection of spores and its suitability as an in-line component of a rapid detection system.