Evolution in spatiotemporal infection patterns of Burkholderia sensu lato lineages in the gut of Riptortus pedestris

Many plants and animals form specific symbioses with microorganisms, relying on bidirectional interactions between hosts and bacteria. However, the knowledge about the evolution of symbiont traits enabling such specificity remains very limited. The bean bug Riptortus pedestris acquires Caballeronia from environmental soil and harbors it in its gut symbiotic organ. This bug- Caballeronia symbiosis is an ideal model to clarify the evolutionary process of symbiotic bacteria because members of their outgroups, such as Paraburkholderia and Pandoraea , can also colonize the host symbiotic organ but are outcompeted when co-inoculated with the native symbiont, Caballeronia . In this study, mechanisms underpinning the competitiveness of Caballeronia inside the insect gut were investigated. First, comparative microscopy revealed that Caballeronia ’s success in the gut is largely attributed to its ability to migrate rapidly to the M4 region through chemotaxis, wherein a cheA insertion mutant showed significantly delayed infection speed and lower competitiveness against wild-type. In addition, Paraburkholderia and Pandoraea frequently formed biofilm-like aggregates in the midgut, which could delay their colonization. By contrast, Caballeronia formed no biofilm-like aggregates, at least inside the insect gut. This study reveals that Caballeronia symbiont has evolved traits like chemotaxis and reaction against AMP to establish an efficient and exclusive symbiotic relationship with their bean bug host. Although the genetic and molecular bases of the chemotaxis and the cell aggregates remain unclear, it is strongly suggested that the dynamic gain and loss of these traits enables Caballeronia to specifically associate with the insect host, R. pedestris .