YwqL (EndoV), ExoA and PolA act in a novel alternative excision pathway to repair deaminated DNA bases in Bacillus subtilis.

Adriana G Patlán,Luis G Brieba,Luz I Valenzuela-García,Pedro L Vargas-Arias,Marcelo Barraza-Salas,Víctor M Ayala-García,Jimena Meneses-Plascencia,Peter Setlow,Mario Pedraza-Reyes

doi:10.1371/journal.pone.0211653

Adriana G Patlán, Luis G Brieba + Show 7 more

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DNA deamination generates base transitions and apurinic/apyrimidinic (AP)-sites which are potentially genotoxic and cytotoxic. In Bacillus subtilis uracil can be removed from DNA by the uracil DNA-glycosylase through the base excision repair pathway. Genetic evidence suggests that B. subtilis YwqL, a homolog of Endonuclease-V (EndoV), acts on a wider spectrum of deaminated bases but the factors that complete this pathway have remained elusive. Here, we report that a purified His6-YwqL (hereafter BsEndoV) protein had in vitro endonuclease activity against double-stranded DNAs containing a single uracil (U), hypoxanthine (Hx), xanthine (X) or an AP site. Interestingly, while BsEndoV catalyzed a single strand break at the second phosphodiester bond towards the 3'-end of the U and AP lesions, there was an additional cleavage of the phosphodiester bond preceding the Hx and X lesions. Remarkably, the repair event initiated by BsEndoV on Hx and X, was completed by a recombinant B. subtilis His6-DNA polymerase A (BsPolA), but not on BsEndoV-processed U and AP lesions. For the latter lesions a second excision event performed by a recombinant B. subtilis His6-ExoA (BsExoA) was necessary before completion of their repair by BsPolA. These results suggest the existence of a novel alternative excision repair pathway in B. subtilis that counteracts the genotoxic effects of base deamination. The presence of this novel pathway in vivo in B. subtilis was also supported by analysis of effects of single or multiple deletions of exoA, endoV and polA on spontaneous mutations in growing cells, and the sensitivity of growing wild-type and mutant cells to a DNA deaminating agent.

Highlights

Deamination of DNA bases is one of the most common types of genetic insults in all organisms
To counteract the adverse effects of U, bacteria and mammals rely on repair proteins termed uracil DNA glycosylases (Ung) [7], which catalyze the cleavage of the glycosidic bond that connects U with the deoxyribose moiety, generating an apurinic/apyrimidinic (AP) site; this non-coding lesion is further processed by components of the canonical base excision repair pathway (BER) [7,8,9]
B. subtilis strains deficient for Ung and/or BsEndoV exhibit, significantly decreased ability to contend with the genotoxic effects of spontaneous and induced DNA deamination, suggesting that these enzymes are important in maintaining genomic integrity in this bacterium [18]

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Introduction

Deamination of DNA bases is one of the most common types of genetic insults in all organisms. Some bacteria and archaea have a repair protein able to recognize and hydrolyze double-stranded DNA containing a wide spectrum of genetic lesions, including uracil, additional deaminated bases, AP sites, mismatches, flap structures and pseudo-Y structures [10,11,12,13]. In E. coli, this enzyme, encoded by the nfi gene (EC: 3.1.21.7), has been termed endonuclease V (EndoV) [14,15] This Mg2+-dependent enzyme catalyzes the incision of the second phosphodiester bond towards the 3’ end of the lesion [13], constituting the first step of an Alternative Excision Repair (AER) pathway [6,16]. Fundamental aspects of catalysis, function and structure of EndoV homologs from distinct organisms have been compiled in an excellent recent review [17]

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