Outer Membrane Vesiculation Facilitates Surface Exchange and In Vivo Adaptation of Vibrio cholerae

Gram-negative bacteria release outer membrane vesicles into the external milieu to deliver effector molecules that alter the host and facilitate virulence. Vesicle formation is driven by phospholipid accumulation in the outer membrane and regulated by the phospholipid transporter VacJ/Yrb. We use the facultative human pathogen Vibrio cholerae to show that VacJ/Yrb is silenced early during mammalian infection, which stimulates vesiculation that expedites bacterial surface exchange and adaptation to the host environment. Hypervesiculating strains rapidly alter their bacterial membrane composition and exhibit enhanced intestinal colonization fitness. This adaptation is exemplified by faster accumulation of glycine-modified lipopolysaccharide (LPS) and depletion of outer membrane porin OmpT, which confers resistance to host-derived antimicrobial peptides and bile, respectively. The competitive advantage of hypervesiculation is lost upon pre-adaptation to bile and antimicrobial peptides, indicating the importance of these adaptive processes. Thus, bacteria use outer membrane vesiculation to exchange cell surface components, thereby increasing survival during mammalian infection. [Display omitted] •Phospholipid transport of Vibrio cholerae is silenced upon host entry•Reduced transporter activity triggers OMV release and increases colonization fitness•Increased vesiculation accelerates modulation of cell surface composition•Hypervesiculation leads to faster adaptation to host defense mediators Upon infection, Vibrio cholerae must alter its surface profile to evade host defenses and adapt to the gastrointestinal environment. Zingl et al. show that increased release of outer membrane vesicles upon host entry allows the bacteria to rapidly modify their cell surface, thus increasing in vivo adaptation and colonization fitness.