DNA cytosine methylation at the lexA promoter of Escherichia coli is stationary phase specific.

The bacterial DNA damage response pathway (SOS response) is composed of a network of genes regulated by a single transcriptional repressor, LexA. The lexA promoter, itself, contains two LexA operators, enabling negative feedback. In Escherichia coli, the downstream operator contains a conserved DNA cytosine methyltransferase (Dcm) site that is predicted to be methylated to 5-methylcytosine (5mC) specifically during stationary phase growth, suggesting a regulatory role for DNA methylation in the SOS response. To test this, we quantified 5mC at the lexA locus, and then examined the effect of LexA on Dcm activity, as well as the impact of this 5mC mark on LexA binding, lexA transcription, and SOS response induction. We found that 5mC at the lexA promoter is specific to stationary phase growth, but that it does not affect lexA expression. Our data support a model where LexA binding at the promoter inhibits Dcm activity without an effect on the SOS regulon.

Effect of mismatch repair on the mutational footprint of the bacterial SOS mutator activity.

The bacterial SOS response to DNA damage induces an error-prone repair program that is mutagenic. In Escherichia coli, SOS-induced mutations are caused by the translesion synthesis (TLS) activity of two error-prone polymerases (EPPs), Pol IV and Pol V. The mutational footprint of the EPPs is confounded by both DNA damage and repair, as mutations are targeted to DNA lesions via TLS and corrected by the mismatch repair (MMR) system. To remove these factors and assess untargeted EPP mutations genome-wide, we constructed spontaneous SOS mutator strains deficient in MMR, then analyzed their mutational footprints by mutation accumulation and whole genome sequencing. Our analysis reveals new features of untargeted SOS-mutagenesis, showing how MMR alters its spectrum, sequence specificity, and strand-bias. Our data support a model where the EPPs prefer to act on the lagging strand of the replication fork, producing base pair mismatches that are differentially repaired by MMR depending on the type of mismatch.