Streptomycin and nalidixic acid elevate the spontaneous genome-wide mutation rate in Escherichia coli.

Since antibiotic resistance is a growing public health problem worldwide, it is important to understand how antibiotics and spontaneous mutations cooperate and shape the genome-wide mutation rate and spectrum. Here, we quantitatively evaluate genome-wide mutational profiles of Escherichia coli after long-term subinhibitory exposure to a broad-spectrum (streptomycin) and a narrow-spectrum antibiotic (nalidixic acid), using a mutation accumulation design combined with whole-genome resequencing of replicate lines as a mutagenicity test. We determined that, while the genome-wide mutation rate is slightly higher in the streptomycin-treated lines compared to the control lines, there is a significant increase in the nalidixic acid-treated lines. Our findings suggest that both broad and narrow-spectrum antibiotics may elevate the mutation rates in E. coli, but mechanisms of action may affect the consequence, thus contribute to accelerating the rate of adaptation and conferring antibiotic resistance.