As primary syphilis resolves, most treponemes are cleared from the chancre. However, a few organisms escape the immune response to cause secondary syphilis and ultimately to establish chronic infection. May theories have been proposed to explain Treponema pallidum's capacity for immune evasion, yet none has convincing experimental support. Antigen variation is one of the most intriguing theories, but not candidate antigens have been identified until now. The recent identification of a polymorphic multicopy gene family in T. pallidum that encodes for proteins with predicated amino acid homology to the major sheath protein (msp) of Treponema denticola provides a family of likely candidates. We call these T. pallidum proteins the msp-homologues. The broad goal of this proposal is to determine the cellular location and the function of the msp-homologue proteins.
The specific aims of the project are the following: 1. Determine whether msp-homologues are surface exposed antigens in T. pallidum Nichols strain.
This aim will test the hypothesis that some of the msp-homologues are surface exposed in living organisms. 2. Determine whether msp-homologues are involved in cell attachment and function as porins.
This aim will determine whether the msp-homologue family has a role in two well-recognized mechanisms of pathogenesis of bacterial infections. 3. Determine whether T. pallidum Nichols strain represents a colonal bacterial population or is comprised of subpopulations of treponemes.
This aim will test the hypothesis that, like other spirochetes, T. pallidum strains contain subpopulations that express heterogeneous msp- homologues. 4. Determine whether the msp-homologues undergo antigen variation or phase variation. Antigenic variation is common other pathogenic treponemes and the msp-homologue gene family has characteristics highly suggestive of genetic recombination and reassortment.
This aim will test the hypothesis that individual msp-homologues either change (antigenic variation) or are no longer expressed (phase variation) during the course of infection. The studies proposed in this application will define the role of the msp- homologues in immune evasion and in the pathogenesis of syphilis.
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