Abstract
Bacillus subtilis DinG/XPD-like paralogues, DinG and YpvA, have been implicated in overcoming replication stress. DinG possesses a DEDD exonuclease and DNA helicase domains, whereas YpvA lacks the DEDD exonuclease domain. We report that DinG·Mg(2+) (hereafter referred to as DinG) degrades linear single-stranded (lss) DNA with 3'→5' polarity and binds lssDNA with higher affinity than its exonuclease-deficient mutant DinG D10A E12A. DinG's ssDNA-dependent ATPase activity neither stimulates nor inhibits DNA degradation. When bound to the 3'-end of forked DNA, DinG destabilises and degrades the substrate; however, in the presence of ATP, DinG dissociates before reaching the duplex junction. DinG degrades the RNA strand within RNA-DNA hybrids but does not cleave lssRNA unless complexed with Mn(2+). DinG removes genomic R-loops, as RnhC and PcrA do. DinG physically interacts with RecA and PolA and functions in the same pathway as translesion synthesis (TLS) DNA polymerases (DNAPs) to respond to both spontaneous and methyl methanesulphonate (MMS)-induced mutagenesis. DinG-mGold forms spontaneous foci at or near replication forks, which become enriched following MMS or rifampicin treatment. We propose that DinG contributes to mitigating replication stress by degrading R-loop barriers and facilitating TLS, potentially via RecA-linked mechanisms.