Chlamydia trachomatis is the etiological agent of several significant diseases of humans including trachoma, the leading cause of infectious blindness worldwide. It is also the most common cause of sexually transmitted disease in the USA. Other species of medical importance include C. pneumoniae, a causative agent of upper respiratory tract infections and possibly associated with atherosclerosis, and C. psittaci, which is primarily a pathogen of animals but occasionally is transmitted to humans. The Host-Parasite Interactions Section studies the fundamental cellular and molecular biology of intracellular pathogens. Efforts have been primarily with the genus Chlamydia and include two basic research areas: i.) the cellular interactions that promote entry and intracellular growth;primarily those controlled by secreted chlamydial effector proteins and ii.) global regulation of chlamydial gene expression by histone-like proteins. Establishment of a protected intracellular niche is a critical stage of the chlamydial developmental cycle. We have therefore focused much of our efforts over the last several years upon events occurring within these early stages of infection. Many of these events are unique among intracellular pathogens but common to the genus Chlamydia. The experimental approaches are heavily weighted toward cell biology, proteomics, and functional analysis of protein-protein interactions. An improved understanding of the distinct developmental stages and the cellular responses to them may suggest novel means of chemotherapeutic or immunologic intervention of chlamydial diseases. Chlamydiae occupy a unique vacuolar niche within the host cell. The chlamydial inclusion, unlike vacuoles containing other intracellular pathogens, is not interactive with endocytic vesicular trafficking pathways but is instead fusogenic with an incompletely understood exocytic pathway which delivers sphingomyelin and cholesterol from the Golgi apparatus to the plasma membrane. Entry into this pathway is an active process on the part of the chlamydiae as both de novo transcription and translation are required. Virtually all of these interactions are specific and localized to the inclusion. This specificity strongly suggests modification of the exposed inclusion membrane. Examples of cis-acting modifications to the nascent inclusion membrane include: evasion of lysosomal fusion, interactions with microtubules to deliver the nascent inclusion to the peri-Golgi region and microtubule organizing center, initiation of fusion with exocytic vesicular traffic from the Golgi apparatus, and recruitment of, but not fusion with, recycling endosomes containing transferrin and its receptor. Many of these interactions are temporally associated with the exposure of inclusion membrane proteins to the host cell cytoplasm by a chlamydial type III secretion system. Another example of a chlamydial proteins controlling localized events could include the recruitment of actin to promote entry. A type III secreted protein, termed Tarp, is translocated and tyrosine phosphorylated while EBs are still extracellular. Tarp has been associated with the actin recruitment which is required for chlamydial internalization. Chlamydial Tarp and the inclusion membrane proteins define at least two distinct stages in chlamydial development where secreted effectors may play important roles in defining the outcome of infection. In the case of Tarp, a pre-existing effector protein is secreted across the plasma membrane from extracellular EBs, while inclusion membrane proteins require de novo synthesis and are secreted across the inclusion membrane from the RBs within. Identification of secreted effector molecules and their functions will continue to provide insights into the many adaptations chlamydiae utilize as successful pathogens. Nascent chlamydial inclusions migrate towards the minus end of microtubules and aggregate at the MTOC utilizing the minus-end-directed microtubule motor dynein. This interaction leads to disruption of normal centrosomal positioning leading to centrosome number defects. The association of the chlamydial inclusion membrane with centrosomes leads to failures in centrosomal partitioning and/or cytokinesis.Centrosome supernumerary defects have been implicated in chromosome instability and loss of cell cycle control in early tumors and most aggressive carcinomas. The hypothesis that bacterial infections can contribute to cancer has endured for some time, but unlike viral induced cancers, specific oncogenes and molecular mechanisms have not been clearly established. The interaction of chlamydiae with dynein and centrosomes suggests a mechanism by which chlamydial infection, through induction of abnormal centrosome numbers, may be a contributing factor in chromosome instability ultimately leading to transformation and tumor development. Chlamydial histone H1-like proteins, Hc1 and Hc2, act as globalregulators of chlamydial gene expression by virtue of dramatic effects on DNA structure. The chlamydial histones are transcribed late in the developmental cycle as RBs differentiate to EBs. The mechanisms of histone release from the chlamydial chromatin at the initiation of development had been unknown. By utilizing a heterologous screening protocol in E. coli, we identified two novel means of regulation of histone activity. The affinity of histone for DNA appears to be disrupted early in infection by the synthesis of a small metabolite in the non-mevalonate pathway of isoprenoid biosynthesis. In the course of the screening procedure, we also identified a small regulatory RNA that specifically inhibits translation of Hc1.

Project Start
Project End
Budget Start
Budget End
Support Year
19
Fiscal Year
2009
Total Cost
$1,192,952
Indirect Cost
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State
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Nguyen, Phu Hai; Lutter, Erika I; Hackstadt, Ted (2018) Chlamydia trachomatis inclusion membrane protein MrcA interacts with the inositol 1,4,5-trisphosphate receptor type 3 (ITPR3) to regulate extrusion formation. PLoS Pathog 14:e1006911
Tolchard, James; Walpole, Samuel J; Miles, Andrew J et al. (2018) The intrinsically disordered Tarp protein from chlamydia binds actin with a partially preformed helix. Sci Rep 8:1960
Grieshaber, Scott; Grieshaber, Nicole; Yang, Hong et al. (2018) Impact of Active Metabolism on Chlamydia trachomatis Elementary Body Transcript Profile and Infectivity. J Bacteriol 200:
Wesolowski, Jordan; Weber, Mary M; Nawrotek, Agata et al. (2017) Chlamydia Hijacks ARF GTPases To Coordinate Microtubule Posttranslational Modifications and Golgi Complex Positioning. MBio 8:
Weber, Mary M; Lam, Jennifer L; Dooley, Cheryl A et al. (2017) Absence of Specific Chlamydia trachomatis Inclusion Membrane Proteins Triggers Premature Inclusion Membrane Lysis and Host Cell Death. Cell Rep 19:1406-1417
Weber, Mary M; Noriea, Nicholas F; Bauler, Laura D et al. (2016) A Functional Core of IncA Is Required for Chlamydia trachomatis Inclusion Fusion. J Bacteriol 198:1347-55
Weber, Mary M; Bauler, Laura D; Lam, Jennifer et al. (2015) Expression and localization of predicted inclusion membrane proteins in Chlamydia trachomatis. Infect Immun 83:4710-8
Mital, Jeffrey; Lutter, Erika I; Barger, Alexandra C et al. (2015) Chlamydia trachomatis inclusion membrane protein CT850 interacts with the dynein light chain DYNLT1 (Tctex1). Biochem Biophys Res Commun 462:165-70
Bauler, Laura D; Hackstadt, Ted (2014) Expression and targeting of secreted proteins from Chlamydia trachomatis. J Bacteriol 196:1325-34
Ronzone, Erik; Wesolowski, Jordan; Bauler, Laura D et al. (2014) An ?-helical core encodes the dual functions of the chlamydial protein IncA. J Biol Chem 289:33469-80

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