Functional interplay between (p)ppGpp and RNAP in Acinetobacter baumannii

The (p)ppGpp-dependent stress response is required for pathogenic bacteria to survive both outside and inside the host but the mechanisms behind this survival are mostly unknown. In this study, we characterize the (p)ppGpp metabolism in the opportunistic pathogen multi-drug-resistant Acinetobacter baumannii. We show that two stressful conditions potentially encountered during infection – iron starvation and polymyxin exposure – induce (p)ppGpp production. The absence of (p)ppGpp led to multiple consequences on the physiology of A. baumannii, including an increase of surface motility, a decrease in catalase activity, a poor survival upon nutrient starvation, a rapid killing during desiccation and a strong attenuation in a Galleria mellonella model of infection. Using a motility suppressor screen, we isolated multiple independent stringent mutations in rpoB and rpoC that suppress the (p)ppGpp-dependent phenotypes. By combining the suppressor screen with deep sequencing, we isolated dozens of additional mutants, expanding the list of putative stringent RNAP mutations described so far. Furthermore, our transcriptomic data reveal that (p)ppGpp deeply impacts the transcriptional landscape of A. baumannii on solid surface to induce many stress-related genes, including catalase and hydrophilins critical for tolerance to desiccation. This work highlights the functional interplay between (p)ppGpp and RNAP in the successful survival of A. baumannii in the environment but also during infection. Overall design: Determination of (p)ppGpp-dependent regulons in Acinetobacter baumannii WT, DrelA and DrelA rpoB_R557C suppressor mutant cells grown on LB low agar plates and in LB liquid medium