Chun Hong Tan scite author profile

Infections caused by the obligate intracellular pathogen Chlamydia trachomatis have a marked impact on human health. C. trachomatis serovariants are the leading cause of bacterial sexually transmitted disease and infectious preventable blindness. Despite decades of effort, there is no practical vaccine against C. trachomatis diseases. Here we report that all C. trachomatis reference serotypes responsible for sexually transmitted disease and blinding trachoma synthesize a highly conserved surface-exposed antigen termed polymorphic membrane protein D (PmpD). We show that Ab specific to PmpD are neutralizing in vitro. We also present evidence that Ab against serovariable-neutralizing targets, such as the major outer membrane protein, block PmpD neutralization. This finding suggests that a decoy-like immune evasion strategy may be active in vivo whereby immunodominant type-specific surface antigens block the neutralizing ability of species-common PmpD Ab. Collectively, these results show that PmpD is a previously uncharacterized C. trachomatis species-common pan-neutralizing target. Moreover, a vaccine protocol using recombinant PmpD to elicit neutralizing Ab in the absence of immunodominant type-specific Ab might be highly efficacious and surpass the level of protection achieved through natural immunity.Chlamydia ͉ autotransporter ͉ neutralizing target ͉ surface antigen ͉ vaccine

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Chlamydia trachomatis-Infected Patients Display Variable Antibody Profiles against the Nine-Member Polymorphic Membrane Protein Family

Tan

et al. 2009

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Genomic analysis of the Chlamydiaceae has revealed a multigene family encoding large, putatively autotransported polymorphic membrane proteins (Pmps) with nine members in the sexually transmitted pathogen Chlamydia trachomatis. While various pathogenesis-related functions are emerging for the Pmps, observed genotypic and phenotypic variation among several chlamydial Pmps in various Chlamydia species has led us to hypothesize that the pmp gene repertoire is the basis of a previously undetected mechanism of antigenic variation. To test this hypothesis, we chose to examine the serologic response of C. trachomatis-infected patients to each Pmp subtype. Immune serum samples were collected from four populations of patients with confirmed C. trachomatis genital infection: 40 women with pelvic inflammatory disease from Pittsburgh, PA; 27 and 34 adolescent/young females from Oakland, CA, and Little Rock, AR, respectively; and 58 adult male patients from Baltimore, MD. The Pmp-specific antibody response was obtained using immunoblot analysis against each of the nine recombinantly expressed Pmps and quantified by densitometry. Our results show that nearly all C. trachomatis-infected patients mount a strong serologic response against individual or multiple Pmp subtypes and that the antibody specificity profile varies between patients. Moreover, our analysis reveals differences in the strengths and specificities of the Pmp subtype-specific antibody reactivity relating to gender and clinical outcome. Overall, our results indicate that the Pmps elicit various serologic responses in C. trachomatis-infected patients and are consistent with the pmp gene family being the basis of a mechanism of antigenic variation.

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Variable expression of surface-exposed polymorphic membrane proteins inin vitro-grownChlamydia trachomatis

Tan

Hsia

Shou

et al. 2010

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Altered developmental expression of polymorphic membrane proteins in penicillin-stressed Chlamydia trachomatis

Carrasco

Tan

Rank

et al. 2011

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Late C. trachomatis inclusions express each member of the surface-exposed polymorphic membrane protein family (Pmp subtypes A through I) with a reproducible distribution of fully-on, fully-off and intermediate phenotypes. This observation is consistent with observed variable Pmp antibody profiles in C. trachomatis-infected patients and has led to the hypothesis that the pmp gene family forms the basis of a phase variation-like mechanism of antigenic variation. Here we investigate and compare the developmental expression of each of the nine pmp genes under conditions of optimal in vitro growth with that under conditions that promote prolonged survival of chlamydiae when exposed to penicillin-induced stress. We demonstrate that the pmp gene family includes distinct transcriptional units that are differentially expressed along development and differentially responsive to stress. In particular, our results indicate that expression of pmpA, pmpD and pmpI is uniquely unaffected by stress, suggesting that the PmpA, PmpD and PmpI proteins play a critical role in the pathogenesis of C. trachomatis.

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Chun Hong Tan

Social–environmental drivers inform strategic management of coral reefs in the Anthropocene

Chlamydia trachomatispolymorphic membrane protein D is a species-common pan-neutralizing antigen

Chlamydia trachomatis-Infected Patients Display Variable Antibody Profiles against the Nine-Member Polymorphic Membrane Protein Family

Variable expression of surface-exposed polymorphic membrane proteins inin vitro-grownChlamydia trachomatis

Altered developmental expression of polymorphic membrane proteins in penicillin-stressed Chlamydia trachomatis

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