Mucus Architecture and Near-Surface Swimming Affect Distinct Salmonella Typhimurium Infection Patterns along the Murine Intestinal Tract

Mucus separates gut-luminal microbes from the tissue. It is unclear how pathogens like Salmonella Typhimurium (S.Tm) can overcome this obstacle. Using live microscopy, we monitored S.Tm interactions with native murine gut explants and studied how mucus affects the infection. A dense inner mucus layer covers the distal colon tissue, limiting direct tissue access. S.Tm performs near-surface swimming on this mucus layer, which allows probing for colon mucus heterogeneities, but can also entrap the bacterium in the dense inner colon mucus layer. In the cecum, dense mucus fills only the bottom of the intestinal crypts, leaving the epithelium between crypts unshielded and prone to access by motile and non-motile bacteria alike. This explains why the cecum is highly infection permissive and represents the primary site of S.Tm enterocolitis in the streptomycin mouse model. Our findings highlight the importance of mucus in intestinal defense and homeostasis. [Display omitted] •Live imaging of Salmonella near-surface swimming on mouse colon inner mucus layer•Colon inner mucus layer traversal requires mucus breaches and flagellar propulsion•The mouse cecum lacks a continuous mucus layer, leaving epithelium tips uncovered•Exposed cecum epithelium tips are a hotspot for Salmonella infection Using live microscopy, Furter et al. describe how the enteropathogen Salmonella Typhimurium crosses the protective intestinal mucus layer of its murine host. Flagella-driven motility, the mucus architecture, and its distribution determine where the pathogen preferentially infects the gut epithelium.