Adaptation delay causes a burst of mutations in bacteria responding to oxidative stress

ABSTRACT

Understanding the interplay between phenotypic plasticity and genetic adaptation is a long-standing focus of evolutionary biology. In bacteria, the oxidative stress response limits the formation of mutagenic reactive oxygen species (ROS) under diverse stress conditions. This suggests that the dynamics of the oxidative stress response are closely tied to the timing of the mutation supply that fuels genetic adaptation to stress. Here, we explored how mutation rates change in real-time in Escherichia coli cells during continuous hydrogen peroxide treatment in microfluidic channels. By visualising nascent DNA replication errors, we uncovered that sudden oxidative stress causes a burst of mutations. We developed a range of single-molecule and single-cell microscopy assays to determine how these mutation dynamics arise from phenotypic adaptation mechanisms. Signalling of peroxide stress by the transcription factor OxyR rapidly induces ROS scavenging enzymes. However, an adaptation delay leaves cells vulnerable to the mutagenic and toxic effects of hydroxyl radicals generated by the Fenton reaction. Resulting DNA damage is counteracted by a spike in DNA repair activities during the adaptation delay. Prior stress exposure or constitutive OxyR induction allowed cells to avoid the burst of mutations. Similar observations for alkylation stress show that mutation bursts are a general phenomenon associated with adaptation delays.