Abstract
The epithelial layer of the gastrointestinal tract contains invaginations, called glands or crypts, which are colonized by symbiotic and pathogenic microorganisms and may function as designated niches for certain species. Factors that control gland colonization are poorly understood, but bacterial chemotaxis aids occupation of these sites. We report here that a Helicobacter pylori cytoplasmic chemoreceptor, TlpD, is required for gland colonization in the stomach. tlpD mutants demonstrate gland colonization defects characterized by a reduction in the percent of glands colonized, but not in number of bacteria per gland. Consistent with TlpD’s reported role in reactive oxygen species (ROS) avoidance, tlpD mutants showed hallmarks of exposure to large amounts of ROS. To assess the role of host-generated ROS in TlpD-dependent gland colonization, we utilized mice that lack either the ability to generate epithelial hydrogen peroxide or immune cell superoxide. tlpD gland colonization defects were rescued to wild-type H. pylori levels in both of these mutants. These results suggest that multiple types of innate immune generated ROS production limit gland colonization and that bacteria have evolved specific mechanisms to migrate through this gauntlet to establish in the glands.
Classification: Biological sciences; microbiology
Significance statement Microbial colonization of the gastrointestinal tract occurs at distinct sites within the tissue including glandular structures found in the stomach and intestine. Multiple lines of evidence suggest that glands supply niches that promote chronic microbial colonization, a process that is critical for symbiotic and pathogenic bacteria to maintain themselves. In this report, we show that host-produced reactive oxygen species (ROS) constrain gland colonization by the gastric pathogen Helicobacter pylori. A bacterial cytoplasmic chemoreceptor, TlpD, allows H. pylori to avoid ROS and enhances H. pylori’s ability to colonize a broad swath of glands. We propose that hosts limit gland access and spread by producing ROS, and bacteria counter with chemotactic responses that allow navigation through this gauntlet.
