An NlpC/P60 protein catalyzes a key step in peptidoglycan recycling at the intersection of energy recovery, cell division and immune evasion in the intracellular pathogen<i>Chlamydia trachomatis</i>

Reuter, Jula; Otten, Christian; Jacquier, Nicolas; Lee, Junghoon; Mengin‐Lecreulx, Dominique; Loeckener, Iris; Mayer, Robert J.; Corona, Federico; Dannenberg, Julia; Aeby, Sébastien; Buehl, Henrike; Greub, Gilbert; Vollmer, Waldemar; Schneider, Tanja; Henrichfreise, Beate

doi:10.1101/2022.11.17.516864

Cited by 2 publications

(2 citation statements)

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“…Notably, induction of knockdown in the E.V. control strain demonstrated a ~48% decrease in infectious progeny (uninduced 6.08x10 6 IFU/mL; induced 2.79x10 6 IFU/mL; Figure 3E), consistent with increased energy requirements likely associated with dCas12 expression (59). For the L2/ct226 KD strain, infectious progeny were reduced by 69% following knockdown (uninduced 1.87x10 7 IFU/mL; induced 4.14x10 6 IFU/mL; Figure 3E).…”

Section: Chlamydial Knockdown and Complement Strains Targeting Ct226 ...mentioning

confidence: 75%

FLI1 localization to the chlamydial inclusion involves multiple mechanisms

Sturd,

Wood,

Durham

et al. 2023

Preprint

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Following entry into a host cell, the obligate intracellular pathogen, Chlamydia trachomatis, establishes an intracellular niche within a membrane derived vacuole called the chlamydial inclusion. The resulting inclusion membrane is modified by the pathogen and is a hybrid host-chlamydial structure. From within this intracellular niche, C. trachomatis must orchestrate numerous host-pathogen interactions to surreptitiously acquire nutrients from its host and to limit detection by the host innate immune system. C. trachomatis mediates many of these interactions with the host, in part, by using a family of type III secreted membrane proteins, 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). LRRF1 interacts with Inc protein Ct226. However, interactions of FLI1 with candidate Incs or with LRRF1 during infection have not been defined. We hypothesized that FLI1 recruitment to the inclusion would be dependent on LRRF1 localization. To test this hypothesis, we used siRNA targeting lrrf1 or fli1, revealing that FLI1 can localize to the inclusion independently of LRRF1. Therefore, to further characterize FLI1 localization, we developed and characterized a series of CRISPRi knockdown and complementation strains in C. trachomatis serovar L2 that target ct226 and co-transcribed candidate Incs, ct225 and ct224, to understand the mechanisms of FLI1 and LRRF1 localization to the inclusion. Our results indicate that FLI1 is recruited to the inclusion by multiple mechanisms.

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Section: Chlamydial Knockdown and Complement Strains Targeting Ct226 ...mentioning

confidence: 75%

FLI1 localization to the chlamydial inclusion involves multiple mechanisms

Sturd,

Wood,

Durham

et al. 2023

Preprint

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“…In contrast, topA transcripts were increased approximately two-fold in strain L2/Nt at 24 h pi after adding aTC. The biological relevance of this increase is unknown but may relate to a slight delay in developmental cycle progression when overexpressing the dCas12 (27).…”

Section: Resultsmentioning

confidence: 99%

Targeted repression of DNA topoisomerase I by CRISPRi reveals a critical function for it in theChlamydia trachomatisdevelopmental cycle

Shen

Gao

Swoboda

et al. 2023

Preprint

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Chlamydia trachomatis is an obligate intracellular bacterium that is responsible for the most prevalent bacterial sexually transmitted infections. Changes in DNA topology in this pathogen have been linked to its pathogenicity-associated developmental cycle. Here, evidence is provided that the balanced activity of DNA topoisomerases (Topos) contributes to Chlamydia developmental processes. Utilizing catalytically inactivated Cas12 (dCas12) based-clustered regularly interspaced short palindromic repeats interference (CRISPRi) technology, we demonstrate targeted knockdown of chromosomal topA transcription in C. trachomatis without detected toxicity of dCas12. Repression of topA impaired the growth of C. trachomatis mostly through disruption of its differentiation from a replicative form to an infectious form. Consistent with this, expression of late developmental genes of C. trachomatis was downregulated while early genes maintained their expression. Importantly, the growth defect associated with topA knockdown was rescued by overexpressing topA at an appropriate degree and time, directly linking the growth patterns to the levels of topA expression. Interestingly, topA knockdown had pleiotropic effects on DNA gyrase expression, indicating a potential compensatory mechanism for survival to offset TopA deficiency. C. trachomatis with topA knocked down displayed hypersensitivity to moxifloxacin that targets DNA gyrase in comparison with the wild type. These data underscore the requirement of integrated topoisomerase actions to support the essential development and transcriptional processes of C. trachomatis. Importance: We used genetic and chemical tools to demonstrate the relationship of topoisomerase activities and their obligatory role for the chlamydial developmental cycle. Successfully targeting the essential gene topA with a CRISPRi approach, using dCas12, in C. trachomatis indicates that this method will facilitate the characterization of the essential genome. These findings have an important impact on our understanding of the mechanism(s) by which well-balanced topoisomerase activities enable C. trachomatis to adapt to unfavorable growth conditions imposed by antibiotics.

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An NlpC/P60 protein catalyzes a key step in peptidoglycan recycling at the intersection of energy recovery, cell division and immune evasion in the intracellular pathogenChlamydia trachomatis

Cited by 2 publications

References 64 publications

FLI1 localization to the chlamydial inclusion involves multiple mechanisms

FLI1 localization to the chlamydial inclusion involves multiple mechanisms

Targeted repression of DNA topoisomerase I by CRISPRi reveals a critical function for it in theChlamydia trachomatisdevelopmental cycle

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