Abstract
Intercellular communication and self-recognition are critical for coordinating cooperative and competitive behaviors during sociomicrobiological community development. Contact-dependent growth inhibition (CDI) proteins are polymorphic toxin delivery systems that inhibit the growth of non-self neighboring bacteria that lack the appropriate immunity protein. In Burkholderia thailandensis, CDI system proteins (encoded by bcpAIOB genes) also induce cooperative behaviors among sibling (self) cells, a phenomenon called contact-dependent signaling (CDS). Here we describe a mobile genetic element (MGE) that carries the bcpAIOB genes in B. thailandensis E264. It is a ~210 kb composite transposon with insertion sequence (IS) elements at each end. Although the ISs are most similar to IS2 of Escherichia coli, the transposase-dependent intermediate molecule displays characteristics more similar to those of the IS26 translocatable unit (TU). A reaction requiring only the “left” IS-encoded transposase results in formation of an extrachromosomal circular dsDNA intermediate (“the megacircle”) composed of the left IS and the sequences intervening between the ISs. Insertion of the megacircle into the chromosome occurs next to a pre-existing copy of an IS2-like element, recreating a functional composite transposon. We found that BcpA activity is required for megacircle formation, and in turn, megacircle formation is required for CDS phenotypes. Our data support a model in which the bcpAIOB genes function as both helping and harming greenbeard genes, simultaneously enhancing the fitness of self bacteria that possess the same allele plus tightly linked genes that mediate cooperative behaviors, and killing non-self bacteria that do not possess the same bcpAIOB allele. Mobility of the megacircle between cells could allow bacteria invading a community to be converted to self, and would facilitate propagation of the bcpAIOB genes in the event that the invading strain is capable of overtaking the resident community.
Highlights
Bacteria typically live in complex, dynamic, polymicrobial communities, and have evolved mechanisms to cooperate and compete with neighboring microbes to ensure efficient resource utilization and community survival [1,2,3,4]
We provide evidence for a mobile genetic element that carries the genes encoding proteins involved in bacterial killing or cooperation within microbial communities
We show that production of the megacircle requires a functional contact-dependent growth inhibition (CDI)/ contactdependent signaling (CDS) system and that synthesis of the megacircle is necessary for cooperation-associated phenotypes
Summary
Bacteria typically live in complex, dynamic, polymicrobial communities, and have evolved mechanisms to cooperate and compete with neighboring microbes to ensure efficient resource utilization and community survival [1,2,3,4]. One type of interbacterial competitive interaction is mediated by contact-dependent growth inhibition (CDI) systems [6]. CDI systems are composed of two-partner secretion (TPS) pathway proteins and are widespread among Gram-negative bacteria [6,7,8]. They fall into two main classes, Burkholderia-type, which are encoded by bcpAIOB genes, and Escherichia coli-type, which are encoded by cdiBAI genes [8]. Delivery of the C-terminal toxin domain of BcpA or CdiA to a neighboring bacterium upon cell-cell contact results in growth inhibition or death, unless the recipient cell produces the correct BcpI or CdiI immunity protein [8,9,10]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
