Kumar, R.; Cordova-Mendez, I.; Litika, F.; Kara, E. D.; Moiz, R.; Burgess, D.; Banerjee, A.; Derbigny, W. A.

Chlamydia trachomatis infection of the female genital tract can result in severe reproductive sequelae, including pelvic inflammatory disease, tubal scarring, and infertility. Type I interferons have been implicated in both host defense and immunopathogenesis during chlamydial infection, with conflicting conclusions across experimental systems. However, the specific contributions of individual interferon subtypes remain poorly defined. Here, we examined the role of interferon beta (IFN-{beta}) in regulating epithelial immune responses and intracellular bacterial development during Chlamydia muridarum infection. Using murine oviduct epithelial (OE) cell lines derived from wild-type, IFN{beta}-deficient, and Toll-like receptor 3 (TLR3)-deficient mice, we demonstrate that IFN-{beta} is a critical epithelial-intrinsic mediator of host defense. Loss of IFN-{beta} led to dysregulation of genes associated with inflammation, immune regulation, and fibrosis, altered chlamydial inclusion morphology, enhanced expression of bacterial genes throughout the chlamydial developmental cycle, and increased chlamydial replication. Importantly, exogenous IFN-{beta} restored both immune mediator production and bacterial control during IFN{beta}-deficiency. Parallel analyses revealed that TLR3 deficiency phenocopied IFN-{beta} loss, supporting a TLR3-IFN-{beta} signaling axis that restricts chlamydial growth. Consistent with these in vitro findings, IFN{beta}-deficient mice exhibited enhanced bacterial burden during genital tract infection. Together, these data establish IFN-{beta} as a protective epithelial mediator during chlamydial infection and demonstrate that type I interferon responses are not functionally uniform. Our findings provide a mechanistic framework to reconcile the protective role of IFN-{beta} with reports of reduced pathology in interferon-/{beta} receptor-deficient models and highlight the importance of dissecting individual interferon pathways in chlamydial immunopathogenesis.