Disruption of IgA-mediated aggregation at weaning favors mucus encroachment by commensal bacteria

Disruption of the gut mucus barrier is a critical step in the development of infec-tious or chronic inflammatory diseases. However, there are no clear links between developmental stages, diet, and the mechanical and biochemical properties of mucus. The transition from suckling to weaning is a pivotal stage in the devel-opment of the mucus barrier in mammals, with significant implications for the health and morbidity of mammalian infants. Here, using a novel microfluidic device, we investigate the penetration and organizational properties of motile Escherichia coli bacteria at the mucus interface using purified intestinal mucus collected from cohorts of piglets before and after weaning. In weaned piglets, E. coli penetrate more than 100 µ m into the mucus, a distance greater than the physiological thickness of the mucus layer in vivo . In contrast, for suckling piglets significant bacterial aggregation is observed at the interface, hindering the pene-tration process. Using the supernatant obtained from purified mucus of suckling piglets, we were able to restore bacterial aggregation in weaned piglet mucus and limit penetration. Interestingly, we also achieved the same result using purified human breast milk immunoglobulin A (IgA), which is known to promote bacterial aggregation. Our results emphasize the importance of mucosal immunoglobulin A (IgA) specificity in relation to the mother’s immunological history, which is primarily transmitted through breast milk and lost during weaning. This also might explain why the suckling/weaning transition is, among other issues, a crit-ical window associated with a high incidence of gastrointestinal infections, before autologous IgA-mediated definite protection is acquired. Studying bacterial pen-etration in complex fluids using this new in vitro microfluidic device will pave the way for future research and the development of predictive tools for use in medical research trials.