<i>Chlamydia trachomatis</i> protein <scp>CT</scp>009 is a structural and functional homolog to the key morphogenesis component <scp>RodZ</scp> and interacts with division septal plane localized <scp>MreB</scp>

Kemege, K.; Hickey, John M.; Barta, Michael L.; Wickstrum, Jason R.; Balwalli, Namita Ashwin; Lovell, Scott; Battaile, Kevin P.; Hefty, P. Scott

doi:10.1111/mmi.12855

Cited by 30 publications

(38 citation statements)

References 68 publications

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“…As seen in Figure 1, we observed using super-resolution structured illumination microscopy (SIM) the polar localization of the major outer membrane protein (MOMP) in the budding daughter cell as previously reported(7). Consistent with its proposed role in division(8), MreB_6xH was localized in a band-like structure across the septum and not in puncta as previously reported(13, 16). Interestingly, when 3D reconstructions were assembled from the SIM images, we observed that MreB_6xH formed ring-like structures at the septum with areas of more intense signal (Fig.…”

Section: Resultssupporting

confidence: 88%

“…Given our hypothesis for the role of chlamydial MreB in directing polarized division, we examined its localization during the first division of an RB. We were unable to detect endogenous MreB with the antibody previously used to image the distribution of MreB in Chlamydia (13). We then attempted to image wild-type and various truncation mutants of MreB using a GFP sandwich (SW) fusion strategy that, in E. coli , was reported to be functional(14) (N-or C-terminal fluorescent protein fusions with MreB display an artifactual localization(15)).…”

Section: Resultsmentioning

confidence: 88%

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Critical Role for the Unique N-Terminus of Chlamydial MreB in Directing Its Membrane Association and Interaction with Elements of the Divisome

Lee

Cox

Ouellette

2019

Preprint

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9Chlamydiae lack the conserved central coordinator protein of cell division FtsZ, a 10 tubulin-like homolog. Current evidence indicates Chlamydia uses the actin-like homolog, 11 MreB, to substitute for the role of FtsZ. Interestingly, we observed MreB as a ring at the 12 septum in dividing cells of Chlamydia. We hypothesize that MreB, to substitute for FtsZ in 13 Chlamydia, must possess unique properties compared to canonical MreB orthologs. 14 Sequence differences between chlamydial MreB and orthologs in other bacteria revealed that 15 chlamydial MreB possesses an extended N-terminal region and the conserved amphipathic 16 helix found in other bacterial MreBs. The extended N-terminal region was sufficient to 17 restore the localization of a truncated E. coli MreB mutant lacking its amphipathic helix to 18 the membrane and was crucial for interactions with cell division components RodZ and FtsK, 19 though the region was not required for homotypic interactions. Importantly, the N-terminal 20 region was sufficient to direct GFP to the membrane when expressed in Chlamydia. A mutant 21 N-terminal region with reduced amphipathicity was unable to perform these functions. From 22 these data, the extended N-terminal region of chlamydial MreB is critical for localization and 23 interactions of this protein. Our data provide mechanistic support for chlamydial MreB to 24 serve as a substitute for FtsZ. 25 Word Count: 200/200 26 27 28 29 30 31 Importance 32Chlamydia trachomatis is an obligate intracellular pathogen, causing sexual 33 transmitted diseases and trachoma. Studying chlamydial physiology, especially its cell 34 division mechanism, is important for developing novel therapeutic strategies for the 35 treatment of these diseases. Since chlamydial cell division has unique features, including a 36 polarized cell division process independent of FtsZ, a canonical cell division coordinator, 37 studying the subject is helpful for understanding undefined aspects of chlamydial growth. In 38 this study, we characterized MreB, a substitute for FtsZ, as a cell division coordinator. It 39 forms a filamentous ring at the septum, like FtsZ in E. coli. We show that the localization of 40 MreB is dependent upon the amphipathic nature of its extended N-terminus. Furthermore, 41 this region is crucial for its interaction with other proteins involved in cell division. Given 42 these results, chlamydial MreB may function as a scaffold for cell divisome proteins at the 43 septum and regulate cell division in this organism. 44 Word count: 150/150 45 48 two morphologically and functionally distinct cellular forms during their developmental 49 cycle: the elementary body (EB) and the reticulate body (RB)(1). The EB is the infectious but 50 non-dividing form whereas the RB is the dividing but non-infectious form. After entering the 51 host cell, Chlamydia remains within a membrane-bound parasitic organelle, termed an 52 inclusion(2). RBs undergo multiple rounds of cell division until they engage a secondary 53 differentiation program and...

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Section: Resultssupporting

confidence: 88%

Section: Resultsmentioning

confidence: 88%

Critical Role for the Unique N-Terminus of Chlamydial MreB in Directing Its Membrane Association and Interaction with Elements of the Divisome

Lee

Cox

Ouellette

2019

Preprint

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“…Chlamydiales are amongst the few known bacteria that lack FtsZ, the bacterial tubulin homolog that organizes the divisome complex at midcell to direct septal peptidoglycan synthesis and facilitates cytokinesis (Busiek and Margolin, 2015). Evidence has been provided that the bacterial actin complex, composed of MreB actin and its regulator RodZ, partially substitute for the role of FtsZ in cytokinesis and spatial regulation of septal peptidoglycan synthesis Kemege et al, 2015;Liechti et al, 2016). After a complete replication cycle re-differentiation into elementary bodies takes place in response to unknown signals, and new elementary bodies are released from the cell by either lysis or extrusion.…”

Section: Chlamydialesmentioning

confidence: 99%

Peptidoglycan in obligate intracellular bacteria

Otten

Brilli

Vollmer

et al. 2017

Molecular Microbiology

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SummaryPeptidoglycan is the predominant stress‐bearing structure in the cell envelope of most bacteria, and also a potent stimulator of the eukaryotic immune system. Obligate intracellular bacteria replicate exclusively within the interior of living cells, an osmotically protected niche. Under these conditions peptidoglycan is not necessarily needed to maintain the integrity of the bacterial cell. Moreover, the presence of peptidoglycan puts bacteria at risk of detection and destruction by host peptidoglycan recognition factors and downstream effectors. This has resulted in a selective pressure and opportunity to reduce the levels of peptidoglycan. In this review we have analysed the occurrence of genes involved in peptidoglycan metabolism across the major obligate intracellular bacterial species. From this comparative analysis, we have identified a group of predicted ‘peptidoglycan‐intermediate’ organisms that includes the Chlamydiae, Orientia tsutsugamushi, Wolbachia and Anaplasma marginale. This grouping is likely to reflect biological differences in their infection cycle compared with peptidoglycan‐negative obligate intracellular bacteria such as Ehrlichia and Anaplasma phagocytophilum, as well as obligate intracellular bacteria with classical peptidoglycan such as Coxiella, Buchnera and members of the Rickettsia genus. The signature gene set of the peptidoglycan‐intermediate group reveals insights into minimal enzymatic requirements for building a peptidoglycan‐like sacculus and/or division septum.

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“…This led to the model that peptidoglycan synthesis may drive cytokinesis in this organism (88). Indeed, in C. trachomatis and a related organism, MreB and RodZ (9), which are involved in spatially regulating peptidoglycan incorporation, localize to cell division sites (65, 71, 87). Interestingly, recent observations have suggested that, even in E. coli , FtsZ may not provide the force for membrane invagination and constriction during cell division and that peptidoglycan assembly may instead be the rate-limiting step that deforms the membrane (142), suggesting that cell wall-driven cytokinesis may be a widely conserved mechanism driving bacterial cell division.…”

Section: Introductionmentioning

confidence: 99%

Bacterial Cell Division: Nonmodels Poised to Take the Spotlight

Eswara

Ramamurthi

2017

Annu. Rev. Microbiol.

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The last three decades have witnessed an explosion in mechanistic details on how model bacterial organisms such as Escherichia coli, Bacillus subtilis, and Caulobacter crescentus undergo binary fission. These advances were possible by not only advances in microscopy that allowed cell biological questions to be answered, but also by the clever use of genetic manipulations in these systems in which specific hypothesis could be directly and easily tested. More recently, research using traditionally understudied organisms, or “non-model” systems, has revealed several alternate mechanistic strategies that bacteria use to divide and propagate. In this review, we will highlight these new findings and compare these strategies to cell division mechanisms elucidated in well-established model organisms.

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Chlamydia trachomatis protein CT009 is a structural and functional homolog to the key morphogenesis component RodZ and interacts with division septal plane localized MreB

Cited by 30 publications

References 68 publications

Critical Role for the Unique N-Terminus of Chlamydial MreB in Directing Its Membrane Association and Interaction with Elements of the Divisome

Critical Role for the Unique N-Terminus of Chlamydial MreB in Directing Its Membrane Association and Interaction with Elements of the Divisome

Peptidoglycan in obligate intracellular bacteria

Bacterial Cell Division: Nonmodels Poised to Take the Spotlight

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