Acinetobacter baumannii is an opportunistic pathogen causing several infections that are increasingly difficult to treat due to its ability to rapidly gain antibiotic resistances. These resistances can arise due to mutations during the DNA damage response (DDR), through the activity of error-prone DNA polymerases, such as DNA polymerase V (DNA Pol V). Currently, the DDR in A. baumannii is not well understood and the regulation of genes encoding multiple copies of DNA Pol V is not fully characterized. Through genome wide mutagenesis, we have identified a novel TetR-like family regulator of genes that encode DNA Pol V, which we have named E rror- p rone p olymerase r egulator, EppR. We have found that EppR represses the expression of the genes encoding DNA Pol V and itself through direct binding to a conserved EppR motif in their promoters. Lastly, we show that EppR also regulates UmuDAb, previously identified as a regulator of genes encoding DNA Pol V. These two gene products are functionally required to ensure regulation of expression of genes encoding DNA Pol Vs and umuDAb. With these results, we propose a co-repressor model for the regulation of genes encoding DNA Pol V and umuDAb.

The nosocomial bacterium Acinetobacter baumannii is protected from antibiotic treatment by acquiring antibiotic resistances and by forming biofilms. Cell attachment, one of the first steps in biofilm formation, is normally induced by environmental metabolites. We hypothesized that vanillic acid, the oxidized form of vanillin, a widely available metabolite with antimicrobial properties, may play a role in A. baumannii cell attachment. We first discovered that A. baumannii actively breaks down VA through the evolutionarily conserved vanABKP genes. These genes are under the control of the repressor VanR, which we show binds directly to VanR binding sites within the vanABKP genes bidirectional promoter. VA in turn counteracts VanR inhibition. We identified a VanR binding site and searched for it throughout the genome especially in pili encoding promoter genes. We found a VanR binding site in the pilus encoding csu operon promoter and showed that VanR binds specifically to it. As expected, a strain lacking VanR overproduces Csu pili and makes robust biofilms. Our study uncovers the role that VA plays in facilitating the attachment of A. baumannii cells to surfaces, a crucial step in biofilm formation. These findings provide valuable insights into a previously obscure catabolic pathway with significant clinical implications.