Abstract
BackgroundThe extensive use of antibiotics in medicine has raised serious concerns about biosafety. However, the effect of antibiotic application on the adaptive evolution of microorganisms, especially to probiotic bacteria, has not been well characterized. Thus, the objective of the current work was to investigate how antibiotic selection forces might drive genome adaptation using Lactobacillus (L.) casei Zhang as a model.MethodsTwo antibiotics, amoxicillin and gentamicin, were consistently applied to the laboratory culture of L. casei Zhang. We then monitored the mutations in the bacterial genome and changes in the minimum inhibitory concentrations (MICs) of these two antibiotics along a 2000-generation-cultivation lasted over 10 months.ResultsWe found an approximately 4-fold increase in the genome mutation frequency of L. casei Zhang, i.e. 3.5 × 10-9 per base pair per generation under either amoxicillin or gentamicin stress, when compared with the parallel controls grown without application of any antibiotics. The increase in mutation frequency is significantly lower than that previously reported in Escherichia (E.) coli. The rate of de novo mutations, i.e. 20 per genome, remained low and stable throughout the long-term cultivation. Moreover, the accumulation of new mutations stopped shortly after the maximum bacterial fitness (i.e. the antibiotic MICs) was reached.ConclusionsOur study has shown that the probiotic species, L. casei Zhang, has high genome stability even in the presence of long-term antibiotic stresses. However, whether this is a species-specific or universal characteristic for all probiotic bacteria remains to be explored.
Highlights
The extensive use of antibiotics in medicine has raised serious concerns about biosafety
Long-term evolution of L. casei Lactobacillus casei Zhang (Zhang) with and without antibiotic exposure We monitored the evolution of L. casei Zhang along a 2000-generation-cultivation under three experimental conditions, i.e. with amoxicillin or gentamicin, and control without any antibiotics
The amoxicillin minimum inhibitory concentrations (MICs) for strain A increased to a maximum level (8 μg/mL) after subculturing for 400 generations, while the gentamicin MIC for strain G reached 32 μg/mL after subculturing for 1200 generations (Tables 1 and 2)
Summary
The extensive use of antibiotics in medicine has raised serious concerns about biosafety. The effect of antibiotic application on the adaptive evolution of microorganisms, especially to probiotic bacteria, has not been well characterized. The evolution of antibiotic resistance in bacteria has long been an important issue because of the wide application of antibiotics in medicine [1]. It has become an affordable tool for characterizing bacterial genome evolution by monitoring the genome changes along long-term laboratory growth. Such approach, The genus Lactobacillus is a major part of the lactic acid bacteria (LAB) group that consists of more than 200 known species and subspecies [5].
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