The obligate intracellular pathogen, Chlamydia trachomatis, establishes an intracellular niche within a host membrane-derived vacuole called the chlamydial inclusion. From within this inclusion, C. trachomatis orchestrates numerous host-pathogen interactions, in part, by utilizing a family of type III secreted effectors, termed inclusion membrane proteins (Incs). Incs are embedded within the inclusion membrane, and some function to recruit host proteins to the inclusion. Two such recruited host proteins are leucine rich repeat Flightless-1 interacting protein 1 (LRRF1/LRRFIP1) and its binding partner Flightless 1 (FLI1/FLII). Previously, LRRF1 has been shown to interact with Inc protein Ct226/CTL0478. This is the first study to examine interactions of FLI1 with candidate Incs or with LRRF1 during infection. We hypothesized that FLI1 recruitment to the inclusion would be dependent on LRRF1 localization. We demonstrated that FLI1 co-immunoprecipitated with Ct226 but only in the presence of LRRF1. Furthermore, FLI1 localized to the inclusion when LRRF1 was depleted via small interfering RNA, suggesting that FLI1 may have an alternative recruitment mechanism. We further developed a series of CRISPRi knockdown and complementation strains in C. trachomatis serovar L2 targeting ct226 and co-transcribed candidate Incs, ct225 and ct224. Simultaneous knockdown of ct226, ct225, and ct224 prevented localization of both FLI1 and LRRF1 to the inclusion, and only complementation of ct226 restored their localization. Thus, we demonstrated Ct226 is critical for FLI1 and LRRF1 localization to the inclusion. Our results also indicate an LRRF1-independent localization mechanism for FLI1, which likely influence their mechanism(s) of action during chlamydial infection.IMPORTANCEChlamydia trachomatis is a leading cause of both bacterial sexually transmitted infections and preventable infectious blindness worldwide. As an obligate intracellular pathogen, C. trachomatis has evolved multiple ways of manipulating the host to establish a successful infection. As such, it is important to understand host-chlamydial protein-protein interactions as these reveal strategies that C. trachomatis uses to shape its intracellular environment. This study looks in detail at interactions of two host proteins, FLI1 and LRRF1, during chlamydial infection. Importantly, the series of CRISPR inference knockdown and complement strains developed in this study suggest these proteins have both independent and overlapping mechanisms for localization, which ultimately will dictate how these proteins function during chlamydial infection.
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