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Competition between commensal protists shapes gut mucosal immunity in mice

ABSTRACT: Intestinal protists are emerging as key modulators of host immunity and microbial ecology, yet their roles remain poorly defined. Here, we investigated the role of two distinct protists, the amoeba Entamoeba muris, and the parabasalid, Tritrichomonas, to determine how they shape gut immunity in vivo individually and together. Unlike the well-characterized inducer of type 2 immunity, Tritrichomonas, which activates the tuft cell–IL-25–ILC2 circuit in the small intestine, E. muris failed to elicit robust immune responses in the intestine or colon. However, introduction of E. muris into mice naturally colonized by Tritrichomonas spp., or co-infection with E. muris and Tritrichomonas spp. suppressed the Tritrichomonas-induced type-2 response in the small intestine. Fecal and cecal qPCR suggest that E. muris may outcompete Tritrichomonas spp., with reduced protist loads in the cecum and possibly diminished succinate-driven tuft cell activation. We also identified sex-specific differences in the intestinal response to primary Tritrichomonas spp. colonization which have not previously been described. These findings reveal that E. muris can dampen existing type-2 immune circuits without triggering overt inflammation, underscoring its role as an immunomodulatory agent. This work provides a framework for understanding how commensal protists interact within the gut ecosystem and shape mucosal immunity in the absence of pathogenicity.

ORGANISM(S): Mus musculus

PROVIDER: GSE320380 | GEO | 2026/03/02

REPOSITORIES: GEO

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