The AlternativeTranslational Profile That Underlies the Immune-Evasive State of Persistence in Chlamydiaceae Exploits Differential Tryptophan Contents of the Protein Repertoire

Lo, Chien-Chi; Xie, Gary; Bonner, Carol A.; Jensen, Roy A.

doi:10.1128/mmbr.05013-11

Cited by 20 publications

(41 citation statements)

References 144 publications

(147 reference statements)

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“…C. trachomatis has a degraded cytotoxin, mostly nonfunctional, although differences in functionality at the serovar level have been reported (66). C. muridarum has three paralogous cytotoxin copies (67) and produces functional cytotoxins. Since C. muridarum and C. trachomatis show a difference in their responses to IFN-␥ (32), a cytokine that plays an important role in the early clearance of Chlamydia from the genital tract (68), both species will probably also differ in their responses to other cytokines.…”

Section: Mouse Modelsmentioning

confidence: 99%

Animal Models for Studying Female Genital Tract Infection with Chlamydia trachomatis

2013

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Chlamydia trachomatis is a Gram-negative obligate intracellular bacterial pathogen. It is the leading cause of bacterial sexually transmitted disease in the world, with more than 100 million new cases of genital tract infections with C. trachomatis occurring each year. Animal models are indispensable for the study of C. trachomatis infections and the development and evaluation of candidate vaccines. In this paper, the most commonly used animal models to study female genital tract infections with C. trachomatis will be reviewed, namely, the mouse, guinea pig, and nonhuman primate models. Additionally, we will focus on the more recently developed pig model. Chlamydia trachomatis, a Gram-negative obligate intracellular bacterium, is the leading cause of bacterial sexually transmitted disease. World Health Organization values for 2008 estimated an annual increase of over 100 million genital tract infections with C. trachomatis worldwide (1). The incidence of cases is increasing in many countries (1, 2). Genital tract infections with C. trachomatis can cause cervicitis in women and urethritis in men. However, these infections remain largely subclinical in approximately 70% of women and 50% of men and consequently are often not detected (3). Untreated infections may lead to pelvic inflammatory disease, tubal scarring, ectopic pregnancy, infertility, and chronic pelvic pain in women, epididymitis in men, and infant pneumonia in children (4-7). Uncomplicated chlamydial infections can be treated easily with antibiotics, but once infection and pathology are established, treatment may be less effective. Asymptomatic individuals can be identified through screening programs, but this approach is likely to be too costly for developing countries. A vaccination program would be much cheaper and have a greater impact in controlling C. trachomatis infections worldwide. Computer modeling suggests that even a partially efficacious chlamydial vaccination program would rapidly reduce the prevalence of genital infection (8). Animal models are indispensable for the study of C. trachomatis infections and the development and evaluation of candidate vaccines. Various animal models have been developed, including mouse (9, 10), guinea pig (11, 12), nonhuman primate (13,14), pig (15), rat (16), and rabbit (17) models. Here, the most commonly used animal models to study female genital tract infections with C. trachomatis will be reviewed, namely, the mouse, guinea pig, and nonhuman primate models. Additionally, we will focus on the more recently developed pig model. MOUSE MODELSMice are the most commonly used animals to study genital chlamydial infections. The advantages of the mouse model are their small size, ease of handling, availability in sufficient amounts, and low cost. Moreover, there are many well-characterized inbred and knockout mouse strains available (18). The female mouse genital tract is susceptible to infection with both Chlamydia muridarum (9) and C. trachomatis (10), which has resulted in the establishment of two murine mod...

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Section: Mouse Modelsmentioning

confidence: 99%

Animal Models for Studying Female Genital Tract Infection with Chlamydia trachomatis

2013

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“…While this provocative hypothesis seems to fit the C. trachomatis data best, it may also be partly supported by the limited C. pneumoniae data that are available. Lo et al (121) reported that MurA is a low-tryptophan-containing enzyme, making it more suited to expression during persistence. Indeed, when Timms et al (123) evaluated murA transcription in the IFN-␥ model of C. pneumoniae, they found that it was upregulated 2-fold under these conditions.…”

Section: Subtle Variations In the Tryptophan Content Of Key Chlamydiamentioning

confidence: 99%

“…Several reviews have emerged recently (121,122) suggesting that the chlamydial genus as a whole may have evolved a mechanism that mutes or downregulates selected gene products via the tryptophan levels in these key proteins. Those proteins that are required during the acute or active growth phase (i.e., normal development of Chlamydia) have higher tryptophan content, since tryptophan availability is less of an issue in this stage of growth.…”

Section: Subtle Variations In the Tryptophan Content Of Key Chlamydiamentioning

confidence: 99%

Evolution to a Chronic Disease Niche Correlates with Increased Sensitivity to Tryptophan Availability for the Obligate Intracellular Bacterium Chlamydia pneumoniae

Huston

Barker

Chacko

2014

Journal of Bacteriology

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bThe chlamydiae are obligate intracellular parasites that have evolved specific interactions with their various hosts and host cell types to ensure their successful survival and consequential pathogenesis. The species Chlamydia pneumoniae is ubiquitous, with serological studies showing that most humans are infected at some stage in their lifetime. While most human infections are asymptomatic, C. pneumoniae can cause more-severe respiratory disease and pneumonia and has been linked to chronic diseases such as asthma, atherosclerosis, and even Alzheimer's disease. The widely dispersed animal-adapted C. pneumoniae strains cause an equally wide range of diseases in their hosts. It is emerging that the ability of C. pneumoniae to survive inside its target cells, including evasion of the host's immune attack mechanisms, is linked to the acquisition of key metabolites. Tryptophan and arginine are key checkpoint compounds in this host-parasite battle. Interestingly, the animal strains of C. pneumoniae have a slightly larger genome, enabling them to cope better with metabolite restrictions. It therefore appears that as the evolutionarily more ancient animal strains have evolved to infect humans, they have selectively become more "susceptible" to the levels of key metabolites, such as tryptophan. While this might initially appear to be a weakness, it allows these human C. pneumoniae strains to exquisitely sense host immune attack and respond by rapidly reverting to a persistent phase. During persistence, they reduce their metabolic levels, halting progression of their developmental cycle, waiting until the hostile external conditions have passed before they reemerge.

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“…Indeed, RalR strongly activates the transcription of two genes encoding the surface-associated proteins, RalG and Aap (Fig. 5), which contain significantly more tryptophan, 2.4 to 2.6% versus 1.5%, which is the average of the complete E. coli proteome (63). Tryptophan residues are known to help translocation of surface proteins through cell membranes and serve as anchors on the periplasmic side of the membrane (64).…”

Section: Discussionmentioning

confidence: 99%

“…In E. coli, the transcription of the trpEDCBA, mtr, and tnaAB operons is tightly controlled by endogenous levels of tryptophan via TrpR-mediated repression and/or a transcriptional termination mechanism known as attenuation (61,62). Low levels of tryptophan cause an increased expression of trpEDCBA and mtr and reduced expression of tnaAB and vice versa (61)(62)(63). Further analysis using EMSA and promoter-lacZ fusions indicated that RalR neither binds to the regulatory regions of these operons nor directly regulates their expression (data not shown).…”

Section: Discussionmentioning

confidence: 99%

Control of Bacterial Virulence by the RalR Regulator of the Rabbit-Specific Enteropathogenic Escherichia coli Strain E22

et al. 2013

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dAtypical enteropathogenic Escherichia coli (aEPEC) causes endemic diarrhea, diarrheal outbreaks, and persistent diarrhea in humans, but the mechanism by which aEPEC causes disease is incompletely understood. Virulence regulators and their associated regulons, which often include adhesins, play key roles in the expression of virulence factors in enteric pathogenic bacteria. In this study we identified a transcriptional regulator, RalR, in the rabbit-specific aEPEC strain, E22 (O103:H2) and examined its involvement in the regulation of virulence. Microarray analysis and quantitative real-time reverse transcription-PCR demonstrated that RalR enhances the expression of a number of genes encoding virulence-associated factors, including the Ral fimbria, the Aap dispersin, and its associated transport system, and downregulates several housekeeping genes, including fliC. These observations were confirmed by proteomic analysis of secreted and heat-extracted surface-associated proteins and by adherence and motility assays. To investigate the mechanism of RalR-mediated activation, we focused on its most highly upregulated target operons, ralCDEFGHI and aap. By using primer extension, electrophoretic mobility shift assay, and mutational analysis, we identified the promoter and operator sequences for these two operons. By employing promoter-lacZ reporter systems, we demonstrated that RalR activates the expression of its target genes by binding to one or more 8-bp palindromic sequences (with the consensus of TGTGCACA) located immediately upstream of the promoter core regions. Importantly, we also demonstrated that RalR is essential for virulence since infection of rabbits with E22 carrying a knockout mutation in the ralR gene completely abolished its ability to cause disease. Enteropathogenic Escherichia coli (EPEC) is among the most important diarrheal pathogens infecting children and is also a major cause of persistent diarrhea and diarrhea-associated mortality (1, 2). The hallmark of EPEC pathogenicity is colonization of the intestine accompanied by the formation of characteristic "attaching-and-effacing" (A/E) lesions on the surface of intestinal epithelial cells (3,4). A 35-kb chromosomal pathogenicity island, termed the locus of enterocyte effacement (LEE), encodes the genetic determinants required for A/E lesion formation (5-8).EPEC can be further categorized into two subgroups, typical EPEC (tEPEC) and atypical EPEC (aEPEC) (9), which differ from each other in terms of their genetic characteristics, serotypes, and virulence factors (10,11). By definition, all EPEC strains carry the LEE, but tEPEC strains also carry an EPEC adherence factor plasmid (pEAF), which encodes a type IV-like bundle-forming pilus (Bfp) that facilitates the adherence of tEPEC cells to the intestinal mucosa and allows them to form microcolonies on epithelial cells in vitro and in vivo (11). Apart from Bfp, pEAF also encodes two transcriptional activators, PerA and PerC. The former activates transcription of bfpA (the gene for the major structur...

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The AlternativeTranslational Profile That Underlies the Immune-Evasive State of Persistence in Chlamydiaceae Exploits Differential Tryptophan Contents of the Protein Repertoire

Cited by 20 publications

References 144 publications

Animal Models for Studying Female Genital Tract Infection with Chlamydia trachomatis

Animal Models for Studying Female Genital Tract Infection with Chlamydia trachomatis

Evolution to a Chronic Disease Niche Correlates with Increased Sensitivity to Tryptophan Availability for the Obligate Intracellular Bacterium Chlamydia pneumoniae

Control of Bacterial Virulence by the RalR Regulator of the Rabbit-Specific Enteropathogenic Escherichia coli Strain E22

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