Background: Why resistance to specific antibiotics emerges and spreads rapidly in some bacteria confronting these drugs but not others remains a mystery. Resistance to erythromycin in the respiratory pathogens Staphylococcus aureus and Streptococcus pneumoniae emerged rapidly and increased problematically. However, resistance is uncommon amongst the classic Bordetella species despite infections being treated with this macrolide for decades. Objectives: We examined whether the apparent progenitor of the classic Bordetella spp., Bordetella bronchiseptica, is able to rapidly generate de novo resistance to antibiotics and, if so, why such resistance might not persist and propagate. Methods: Independent strains of B. bronchiseptica resistant to erythromycin were generated in vitro by successively passaging them in increasing subinhibitory concentrations of this macrolide. Resistant mutants obtained were evaluated for their capacity to infect mice, and for other virulence properties including adherence, cytotoxicity and induction of cytokines. Results: B. bronchiseptica rapidly developed stable and persistent antibiotic resistance de novo. Unlike the previously reported trade-off in fitness, multiple independent resistant mutants were not defective in their rates of growth in vitro but were consistently defective in colonizing mice and lost a variety of virulence phenotypes. These changes rendered them avirulent but phenotypically similar to the previously described growth phase associated with the ability to survive in soil, water and/or other extra-mammalian environments. Conclusions: These observations raise the possibility that antibiotic resistance in some organisms results in trade-offs that are not quantifiable in routine measures of general fitness such as growth in vitro, but are pronounced in various aspects of infection in the natural host.
Background: Why resistance to specific antibiotics emerges and spreads rapidly in some bacteria confronting these drugs but not others remains a mystery. Resistance to erythromycin in the respiratory pathogens Staphylococcus aureus and Streptococcus pneumoniae emerged rapidly and increased problematically. However, resistance is uncommon amongst the classic Bordetella species despite infections being treated with this macrolide for decades. Objectives: We examined whether the apparent progenitor of the classic Bordetella spp., Bordetella bronchiseptica, is able to rapidly generate de novo resistance to antibiotics and, if so, why such resistance might not persist and propagate. Methods: Independent strains of B. bronchiseptica resistant to erythromycin were generated in vitro by successively passaging them in increasing subinhibitory concentrations of this macrolide. Resistant mutants obtained were evaluated for their capacity to infect mice, and for other virulence properties including adherence, cytotoxicity and induction of cytokines. Results:B. bronchiseptica rapidly developed stable and persistent antibiotic resistance de novo. Unlike the previously reported trade-off in fitness, multiple independent resistant mutants were not defective in their rates of growth in vitro but were consistently defective in colonizing mice and lost a variety of virulence phenotypes. These changes rendered them avirulent but phenotypically similar to the previously described growth phase associated with the ability to survive in soil, water and/or other extra-mammalian environments. Conclusions: These observations raise the possibility that antibiotic resistance in some organisms results in trade-offs that are not quantifiable in routine measures of general fitness such as growth in vitro, but are pronounced in various aspects of infection in the natural host.
Authors: Julian Parkhill; Mohammed Sebaihia; Andrew Preston; Lee D Murphy; Nicholas Thomson; David E Harris; Matthew T G Holden; Carol M Churcher; Stephen D Bentley; Karen L Mungall; Ana M Cerdeño-Tárraga; Louise Temple; Keith James; Barbara Harris; Michael A Quail; Mark Achtman; Rebecca Atkin; Steven Baker; David Basham; Nathalie Bason; Inna Cherevach; Tracey Chillingworth; Matthew Collins; Anne Cronin; Paul Davis; Jonathan Doggett; Theresa Feltwell; Arlette Goble; Nancy Hamlin; Heidi Hauser; Simon Holroyd; Kay Jagels; Sampsa Leather; Sharon Moule; Halina Norberczak; Susan O'Neil; Doug Ormond; Claire Price; Ester Rabbinowitsch; Simon Rutter; Mandy Sanders; David Saunders; Katherine Seeger; Sarah Sharp; Mark Simmonds; Jason Skelton; Robert Squares; Steven Squares; Kim Stevens; Louise Unwin; Sally Whitehead; Bart G Barrell; Duncan J Maskell Journal: Nat Genet Date: 2003-08-10 Impact factor: 38.330
Authors: Anne M Buboltz; Tracy L Nicholson; Mylisa R Parette; Sara E Hester; Julian Parkhill; Eric T Harvill Journal: J Bacteriol Date: 2008-06-13 Impact factor: 3.490
Authors: Dawn L Taylor-Mulneix; Liron Bendor; Bodo Linz; Israel Rivera; Valerie E Ryman; Kalyan K Dewan; Shannon M Wagner; Emily F Wilson; Lindsay J Hilburger; Laura E Cuff; Christopher M West; Eric T Harvill Journal: PLoS Biol Date: 2017-04-12 Impact factor: 8.029
Authors: Monica C Gestal; Laura K Howard; Kalyan Dewan; Hannah M Johnson; Mariette Barbier; Clare Bryant; Illiassou Hamidou Soumana; Israel Rivera; Bodo Linz; Uriel Blas-Machado; Eric T Harvill Journal: Sci Rep Date: 2019-12-30 Impact factor: 4.379