The Treponema pallidum OMPeome and the quest for a syphilis vaccine.

Authors

  • Everton B. Bettin Department of Medicine, UConn Health, Farmington, Connecticut, USA
  • Andre A. Grassmann Department of Medicine, UConn Health, Farmington, Connecticut, USA
  • Kelly L. Hawley Department of Medicine, UConn Health, Farmington, Connecticut, USA
  • Melissa J. Caimano Department of Medicine, UConn Health, Farmington, Connecticut, USA;
  • Justin D. Radolf Department of Medicine, UConn Health, Farmington, Connecticut, USA

DOI:

https://doi.org/10.5327/DST-2177-8264-1480

Abstract

Despite more than a century of investigation, syphilis vaccine development has long been hindered by the unusual outer membrane of Treponema pallidum subsp. pallidum (TPA) and the historical inability to propagate syphilis spirochetes in vitro. Early observations using the rabbit model established that protective, antibody-mediated immunity is achievable. The recent definition of the repertoire of TPA outer membrane proteins (OMPs) defined the universe of potential targets for protective antibodies and provided a critical foundation for the ongoing syphilis vaccine development. Built on a “learning from nature” approach, the mapping of antibody responses elicited during natural infection against OMPs allowed the identification and prioritization of extracellular loops (ECLs) as vaccine targets. Immunization of animals with protein scaffolds displaying these targets generates high titers of antibodies able to recognize surface-exposed regions of the spirochete. Recent advances in long-term in vitro cultivation and genetic manipulation of TPA have enabled the development of assays to directly evaluate the functional activity of ECL-specific antibodies in promoting opsonophagocytosis, growth inhibition, impairment of motility, and outer membrane disruption. Next-generation platforms are being explored to enhance immunogenicity, simplify production, and facilitate scalable translation of these immunogens toward clinical evaluation. In parallel, researchers are uncovering the sequence variability in OMPs across circulating TPA strains to understand how mutations can affect antibody recognition and global vaccine efficacy. Collectively, these advances position the field to leverage structural, immunological, and microbiological insights to counter the stealth pathogen and, ultimately, achieve an effective syphilis vaccine.

Downloads

Download data is not yet available.

References

Galli, M. & Fois, L. The Centenary Series - STIs Through the Ages: The dawn of the syphilis pandemic in the Old World: history and geography of syphilis in the early sixteenth century. Sex Transm Infect 101, 355-360 (2025).

Waugh, M. The centenary of Treponema pallidum: on the discovery of Spirochaeta pallida. Skinmed 4, 313-315 (2005).

Radolf, J.D. & Kumar, S. The Treponema pallidum outer membrane. Curr Top Microbiol Immunol 415, 1-38 (2018).

Chesney, A.M. Immunity in syphilis. Medicine (Baltimore) 5(1926).

Radolf, J.D. & Lukehart, S.A. Immunology of Syphilis. in Pathogenic Treponemes: Cellular and Molecular Biology (eds. Radolf, J.D. & Lukehart, S.A.) 285-322 (Caister Academic Press, Norfolk, UK, 2006).

Magnuson, H.J., Rosenau, B.J. & Clark, J.W., Jr. The duration of acquired immunity in experimental syphilis. Am J Syph Gonorrhea Vener Dis 33, 297-302 (1949).

Magnuson, H.J. Current concepts of immunity in syphilis. Am J Med 5, 641-654 (1948).

Turner, T.B. Protective antibodies in the serum of syphilitic rabbits. J Exp Med 69, 867-890 (1939).

Turner, T.B., Kluth, F.C. & et al. Protective antibodies in the serum of syphilitic patients. Am J Hyg 48, 173-181 (1948).

Perine, P.L., Weiser, R.S. & Klebanoff, S.J. Immunity to syphilis. I. Passive transfer in rabbits with hyperimmune serum. Infect Immun 8, 787-790 (1973).

Bishop, N.H. & Miller, J.N. Humoral immunity in experimental syphilis. I. The demonstration of resistance conferred by passive immunization. J Immunol 117, 191-196 (1976).

Lukehart, S.A. & Miller, J.N. Demonstration of the in vitro phagocytosis of Treponema pallidum by rabbit peritoneal macrophages. J Immunol 121, 2014-2024 (1978).

Delgado, K.N., et al. Development and utilization of Treponema pallidum expressing green fluorescent protein to study spirochete-host interactions and antibody-mediated clearance: expanding the toolbox for syphilis research. mBio 16, e0325324 (2025).

Radolf, J.D., et al. Treponema pallidum, the syphilis spirochete: making a living as a stealth pathogen. Nat Rev Microbiol (2016).

Radolf, J.D., Norgard, M.V. & Schulz, W.W. Outer membrane ultrastructure explains the limited antigenicity of virulent Treponema pallidum. Proc Natl Acad Sci U S A 86, 2051-2055 (1989).

Cox, D.L., Chang, P., McDowall, A.W. & Radolf, J.D. The outer membrane, not a coat of host proteins, limits antigenicity of virulent Treponema pallidum. Infect Immun 60, 1076-1083 (1992).

Cox, D.L., Akins, D.R., Porcella, S.F., Norgard, M.V. & Radolf, J.D. Treponema pallidum in gel microdroplets: a novel strategy for investigation of treponemal molecular architecture. Mol Microbiol 15, 1151-1164 (1995).

Deka, R.K., et al. Crystal structure of the Tp34 (TP0971) lipoprotein of Treponema pallidum: implications of its metal-bound state and affinity for human lactoferrin. J Biol Chem 282, 5944-5958 (2007).

Weinstock, G.M., Hardham, J.M., McLeod, M.P., Sodergren, E.J. & Norris, S.J. The genome of Treponema pallidum: new light on the agent of syphilis. FEMS Microbiol Rev 22, 323-332 (1998).

Fraser, C.M., et al. Complete genome sequence of Treponema pallidum, the syphilis spirochete. Science 281, 375-388 (1998).

Cox, D.L., et al. Surface immunolabeling and consensus computational framework to identify candidate rare outer membrane proteins of Treponema pallidum. Infect Immun 78, 5178-5194 (2010).

Koebnik, R., Locher, K.P. & Van Gelder, P. Structure and function of bacterial outer membrane proteins: barrels in a nutshell. Mol Microbiol 37, 239-253 (2000).

Hawley, K.L., et al. Structural modeling of the Treponema pallidum OMPeome: a roadmap for deconvolution of syphilis pathogenesis and development of a syphilis vaccine. J Bacteriol 203, e0008221 (2021).

Delgado, K.N., et al. Pyrococcus furiosus thioredoxin (PfTrx) scaffolds displaying extracellular loops of Treponema pallidum outer membrane proteins: “learning from nature” in the search for syphilis vaccine candidates. in 2023 STI and HIV World Congress (Chicago, IL, 2023).

Liu, A., et al. New pathways in syphilis vaccine development. Sex Transm Dis (2024).

Carpenter, E.P., Beis, K., Cameron, A.D. & Iwata, S. Overcoming the challenges of membrane protein crystallography. Curr Opin Struct Biol 18, 581-586 (2008).

Hayashi, S., Buchanan, S.K. & Botos, I. The name Is barrel, beta-barrel. Methods Mol Biol 2778, 1-30 (2024).

Abramson, J., et al. Accurate structure prediction of biomolecular interactions with AlphaFold 3. Nature (2024).

Cramer, P. AlphaFold2 and the future of structural biology. Nat Struct Mol Biol 28, 704-705 (2021).

Canali, E., et al. A high-performance thioredoxin-based scaffold for peptide immunogen construction: proof-of-concept testing with a human papillomavirus epitope. Sci Rep 4, 4729 (2014).

Delgado, K.N., et al. Extracellular loops of the Treponema pallidum FadL orthologs TP0856 and TP0858 elicit IgG antibodies and IgG(+)-specific B-cells in the rabbit model of experimental syphilis. mBio 13, e0163922 (2022).

Moody, M.A. Persons with early syphilis make antibodies that differentially recognize extracellular loops of Treponema pallidum outer membrane proteins. in STI & HIV 2023 World Congress (Chicago, IL, 2023).

Delgado, K.N., et al. Antibodies directed against extracellular loops of FadL orthologs disrupt outer membrane integrity and neutralize infectivity of Treponema pallidum, the syphilis spirochete. Frontiers in Immunology Volume 16 - 2025(2026).

Delgado, K.N., et al. Immunodominant extracellular loops of Treponema pallidum FadL outer membrane proteins elicit antibodies with opsonic and growth-inhibitory activities. PLoS Pathog 20, e1012443 (2024).

Edmondson, D.G. & Norris, S.J. In vitro cultivation of the syphilis spirochete Treponema pallidum. Curr Protoc 1, e44 (2021).

Gupta, R., et al. Platforms, advances, and technical challenges in virus-like particles-based vaccines. Front Immunol 14, 1123805 (2023).

Mohsen, M.O. & Bachmann, M.F. Virus-like particle vaccinology, from bench to bedside. Cell Mol Immunol 19, 993-1011 (2022).

Barbier, A.J., Jiang, A.Y., Zhang, P., Wooster, R. & Anderson, D.G. The clinical progress of mRNA vaccines and immunotherapies. Nat Biotechnol 40, 840-854 (2022).

Qamsari, M.M., Rasooli, I., Chaudhuri, S., Astaneh, S.D.A. & Schryvers, A.B. Hybrid antigens expressing surface loops of ZnuD from Acinetobacter baumannii Is capable of inducing protection against infection. Front Immunol 11, 158 (2020).

Fegan, J.E., et al. Utility of hybrid transferrin binding protein antigens for protection against pathogenic Neisseria species. Front Immunol 10, 247 (2019).

Verhoeven, G.S., Alexeeva, S., Dogterom, M. & den Blaauwen, T. Differential bacterial surface display of peptides by the transmembrane domain of OmpA. PLoS One 4, e6739 (2009).

Bettin, E.B., et al. Comparison of Single- and Multi-Valent Scaffolds Displaying Treponema Pallidum Outer Membrane Protein ECL Candidate Syphilis Vaccinogens. in STI & HIV 2025 World Congress, Vol. 22 (Montreal, Canada, 2025).

Luthra, A., et al. A homology model reveals novel structural features and an immunodominant surface loop/opsonic target in the Treponema pallidum BamA ortholog TP_0326. J Bacteriol 197, 1906-1920 (2015).

Kumar, S., et al. Sequence variation of rare outer membrane protein β-barrel domains in clinical strains provides insights into the evolution of Treponema pallidum subsp. pallidum, the syphilis spirochete. MBio 9, e01006-01018 (2018).

Bliven, K.A. & Maurelli, A.T. Evolution of Bacterial Pathogens Within the Human Host. Microbiol Spectr 4(2016).

Sena, A.C., et al. Clinical and genomic diversity of Treponema pallidum subspecies pallidum to inform vaccine research: an international, molecular epidemiology study. Lancet Microbe, 100871 (2024).

Bettin, E.B., et al. Sequence variability of BamA and FadL candidate vaccinogens suggests divergent evolutionary paths of Treponema pallidum outer membrane proteins. bioRxiv, 2025.2004.2021.649848 (2025).

Beale, M.A., et al. Global phylogeny of Treponema pallidum lineages reveals recent expansion and spread of contemporary syphilis. Nature Microbiology 6, 1549-1560 (2021).

Pospisilova, P., et al. Analysis of Treponema pallidum subsp. pallidum predicted outer membrane proteins (OMPeomes) in 21 clinical samples: variant sequences are predominantly surface-exposed. mSphere, e0021325 (2025).

Salazar, J.C., et al. Treponema pallidum genetic diversity and its implications for targeted vaccine development: A cross-sectional study of early syphilis cases in Southwestern Colombia. PLoS One 19, e0307600 (2024).

Lu, S., et al. Characterization of Treponema pallidum Dissemination in C57BL/6 Mice. Frontiers in Immunology 11(2021).

Silver, A.C., et al. MyD88 deficiency markedly worsens tissue inflammation and bacterial clearance in mice infected with Treponema pallidum, the agent of syphilis. PLoS One 8, e71388 (2013).

Ferguson, M.R., et al. Use of Epivolve phage display to generate a monoclonal antibody with opsonic activity directed against a subdominant epitope on extracellular loop 4 of Treponema pallidum BamA (TP0326). Front Immunol 14, 1222267 (2023).

Downloads

Published

2026-01-19

How to Cite

1.
Bettin EB, Grassmann AA, Hawley KL, Caimano MJ, Radolf JD. The Treponema pallidum OMPeome and the quest for a syphilis vaccine. DST [Internet]. 2026 Jan. 19 [cited 2026 Jan. 24];. Available from: https://www.bjstd.org/revista/article/view/1480

Issue

2026: Preprint

Section

Editorial

License

Copyright (c) 2026 Brazilian Journal of Sexually Transmitted Diseases

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.