Ozone Sensitivity and Catalase Activity in Pigmented and Non-Pigmented Strains of Serratia Marcescens.

BACKGROUND: Ozone exposure rapidly leads to bacterial death, making ozone an effective disinfectant in food industry and health care arena. However, microbial defenses may moderate this effect and play a role in the effective use of oxidizing agents for disinfection. Serratia marcescens is an opportunistic pathogen, expressing genes differentially during infection of a human host. A better understanding of regulatory systems that control expression of Serratia's virulence genes and defenses is therefore valuable. OBJECTIVE: Here, we investigated the role of pigmentation and catalase in Serratia marcescens on survival to ozone exposure. METHOD: Pigmented and non-pigmented strains of Serratia marcescens were cultured to exponential or stationary phase and exposed to 5 ppm of gaseous ozone for 2.5 - 10 minutes. Survival was calculated via plate counts. Catalase activity was measured photometrically and tolerance to hydrogen peroxide was assayed by disk-diffusion. RESULTS: Exposure of S. marcescens to 5 ppm gaseous ozone kills > 90% of cells within 10 minutes in a time and concentration-dependent manner. Although pigmented Serratia (grown at 28°C) survived ozonation better than unpigmented Serratia (grown at 35°C), non-pigmented mutant strains of Serratia had similar ozone survival rates, catalase activity and H2O2 tolerance as wild type strains. Rather, ozone survival and catalase activity were elevated in 6 hour cultures compared to 48 hour cultures. CONCLUSION: Our studies did not bear out a role for prodigiosin in ozone survival. Rather, induction of oxidative stress responses during exponential growth increased both catalase activity and ozone survival in both pigmented and unpigmented S. marcescens.

G-protein modulators alter the swimming behavior and calcium influx of Paramecium tetraurelia.

To assess the potential role of G-proteins in chemokinesis, Paramecium tetraurelia was pre-incubated with the G-protein modulator pertussis toxin. Pertussis toxin pretreatment significantly reduced Paramecium chemoattraction to sodium acetate and ammonium chloride in T-maze behavioral assays and depressed the frequency of avoidance reactions, indicating that heterotrimeric G-proteins may be involved with the motility response. To determine whether G-proteins exert their effect via the ciliary voltage-sensitive calcium channel, we examined responses of P. tetraurelia to the potent voltage-sensitive calcium channel agonist, deltamethrin. Pertussis toxin preincubation significantly reduced the toxic effects of deltamethrin exposure as determined by survival under depolarizing conditions and reduced the duration of backward swimming episodes in behavioral bioassays. Furthermore, non-hydrolyzable analogs of guanine nucleotides altered deltamethrin-stimulated calcium influx via calcium channels in isolated ciliary vesicles. Heterotrimeric G-protein subunits were subsequently detected in ciliary vesicles of P. tetraurelia by antibodies produced against Galpha and Gbeta subunits, and by 32P-ADP-ribosylation, indicating that proteins of the appropriate molecular weight are the target of pertussis toxin in these vesicles. These findings provide additional evidence that heterotrimeric G-proteins are associated with ciliary vesicles and that they play a role in the modulation of swimming behavior and the toxic action of deltamethrin in Paramecium.