One Health genomics of Acinetobacter baumannii reveals sector-specific lineages and permeable ecological barriers

Acinetobacter baumannii is a major cause of severe hospital-acquired infections, with a steadily increasing global prevalence driven by a few clinically adapted lineages. Animals and natural environments also harbor A. baumannii populations, but assessing their connections to clinical lineages is limited by sparse genomic data and a lack of integrated sampling. We conducted a local One Health genomic epidemiology study, sampling, isolating, sequencing, and characterizing several hundred A. baumannii isolates from clinical, animal, and environmental contexts. Within a geographically restricted area, we recovered several globally distributed clinical lineages (international clones, ICs), as well as livestock- and environment-associated lineages shared across Europe, highlighting widespread dissemination beyond clinical settings. Isolates closely related to the emerging clinical lineage IC11 were found in livestock, but no other clinically associated lineages were detected outside clinical contexts. Among these, the epidemic superlineage IC2 was identified in both human and veterinary clinical settings, indicating that similar practices in human and animal medicine select for closely related opportunistic pathogens. We found that hospitals host distinct, antibiotic-sensitive endemic populations capable of causing infection. These populations belong to a diversifying clade spanning clinical and environmental contexts and carry a high load of insertion sequences. Strong plasmid conservation further suggests frequent horizontal gene transfer across ecological compartments. Overall, A. baumannii comprises diverse, context-adapted lineages with a high potential for global spread. Although intercontext transmission appears limited, plasmids may overcome these ecological barriers. Our findings underscore the need for integrated One Health surveillance to better understand transmission pathways and limit the emergence of clinically adapted strains.