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Abstract The replicative helicase, DnaB, is a central component of the replisome and unwinds duplex DNA coupled with immediate template-dependent DNA synthesis by the polymerase, Pol III. The rate of helicase unwinding is dynamically regulated through structural transitions in the DnaB hexamer between dilated and constricted states. Site-specific mutations in DnaB enforce a faster more constricted conformation that dysregulates unwinding dynamics, causing replisome decoupling that generates excess ssDNA and induces severe cellular stress. This surplus ssDNA can stimulate RecA recruitment to initiate recombinational repair, restart, or activation of the transcriptional SOS response. To better understand the consequences of dysregulated unwinding, we combined targeted genomic dnaB mutations with an inducible RecA filament inhibition strategy to examine the dependencies on RecA in mitigating replisome decoupling phenotypes. Without RecA filamentation, dnaB:mut strains had reduced growth rates, decreased mutagenesis, but a greater burden from endogenous damage. Interestingly, disruption of RecA filamentation in these dnaB:mut strains also reduced cellular filamentation but increased markers of double strand breaks and ssDNA gaps as detected by in situ fluorescence microscopy and FACS assays, TUNEL and PLUG, respectively. Overall, RecA plays a critical role in strain survival by protecting and processing ssDNA gaps caused by dysregulated helicase activity in vivo. 

The genome of prokaryotes can be damaged by a variety of endogenous and exogenous factors, including reactive oxygen species, UV exposure, and antibiotics. To better understand these repair processes and the impact they may have on DNA replication, normal genome maintenance processes can be perturbed by removing or editing associated genes and monitoring DNA repair outcomes. In particular, the replisome activities of DNA unwinding by the helicase and DNA synthesis by the polymerase must be tightly coupled to prevent any appreciable single strand DNA (ssDNA) from accumulating and amplifying genomic stress. If decoupled, vulnerable ssDNA would persist, likely leading to double strand breaks (DSBs) or requiring replication restart mechanisms downstream of a stall. In either case, free 3'-OH strands would exist, resulting from ssDNA gaps in the leading strand or complete DSBs. Terminal deoxyribonucleotide transferase (TdT)-mediated dUTP nick end labeling (TUNEL) can enzymatically label ssDNA ends with bromo-deoxy uridine triphosphate (BrdU) to detect free 3'-OH DNA ends in the E. coli genome. Labeled DNA ends can be detected and quantified using fluorescence microscopy or flow cytometry. This methodology is useful in applications where in situ investigation of DNA damage and repair are of interest, including effects from enzyme mutations or deletions and exposure to various environmental conditions. 

Helicase regulation involves modulation of unwinding speed to maintain coordination of DNA replication fork activities and is vital for replisome progression. Currently, mechanisms for helicase regulation that involve interactions with both DNA strands through a steric exclusion and wrapping (SEW) model and conformational shifts between dilated and constricted states have been examined in vitro . To better understand the mechanism and cellular impact of helicase regulation, we used CRISPR-Cas9 genome editing to study four previously identified SEW-deficient mutants of the bacterial replicative helicase DnaB. We discovered that these four SEW mutations stabilize constricted states, with more fully constricted mutants having a generally greater impact on genomic stress, suggesting a dynamic model for helicase regulation that involves both excluded strand interactions and conformational states. These dnaB mutations result in increased chromosome complexities, less stable genomes, and ultimately less viable and fit strains. Specifically, dnaB : mut strains present with increased mutational frequencies without significantly inducing SOS, consistent with leaving single-strand gaps in the genome during replication that are subsequently filled with lower fidelity. This work explores the genomic impacts of helicase dysregulation in vivo , supporting a combined dynamic regulatory mechanism involving a spectrum of DnaB conformational changes and relates current mechanistic understanding to functional helicase behavior at the replication fork.