Project Details
Description
The scientific premise of this CRC proposal rests upon our three decades of work defining the molecular
architecture of the outer membrane (OM) of Treponema pallidum subsp. pallidum (TPA), coupled with our
recent successes combining bioinformatics, biophysical techniques, and localization methods with live TPA to
topologically characterize TPA outer membrane proteins (OMPs) and define the syphilis spirochete's
`OMPeome'--its repertoire of OMPs. Its central hypothesis is that the principal targets for a syphilis vaccine
reside within TPA's repertoire of rare outer membrane proteins (OMPs). The projects in the proposal employ
three different, but closely integrated, strategies to exploit this novel application of reverse vaccinology to develop
a syphilis vaccine with global efficacy. Project 1 is `immune-agnostic', selecting leading vaccine candidates based
on genomic sequences, bioinformatics, biophysical analysis, and structural modeling. Project 2 takes its cue
from the human immune system: since the large majority of untreated individuals do eventually control TPA
infection, it stands to reason that OMPs targeted by opsonic antibodies6-9 should be excellent vaccine candidates.
Project 3 borrows a page from the Center for HIV/AIDS Vaccine Immunology and Immunogen Discovery
(CHAVI-ID) `book', using state-of-the art recombinant B cell and phage technology to generate broadly reactive,
opsonic monoclonal antibodies directed against surface-exposed loops of TPA OMPs. The extraordinary deep
sequencing capabilities of the Genetics and Genomics core will provide the data needed to tailor these
approaches for efficacy on a global scale. This CRC, led by two senior investigators, established collaborators
with complementary clinical and research backgrounds, pulls together (a) the unique capabilities of the
Spirochete Research Laboratories at UConn Health; (b) the world-class B cell technology and vaccine research
infrastructure of the Duke Human Vaccine Institute (DHVI); (c) the international health infrastructure and
expertise of the University of North Carolina Institute for Global Health and Infectious Diseases; and (d) the
unparalleled knowledge of TPA genomics at Masaryk University to achieve our long-term objective. The
Administrative Core will provide the managerial oversight needed to integrate these capabilities and
resources to strengthen existing collaborations and foster new ones within the Center and with other CRCs. The
ultimate strength of this CRC is the diversity and complementarity of approaches, technologies, resources, and
expertise it marshals to interrogate the TPA OMPeome to achieve our long-term goals. An effective syphilis
vaccine would represent a triumph of biomedical research over an ailment that for more than five centuries has
exacted a heavy toll on humanity4,5 and that has defied conventional public health strategies for containment. If
successful, the scientific and public health impact of our approach to reverse vaccinology will extend well beyond
syphilis, establishing a paradigm applicable to other recalcitrant organisms.
architecture of the outer membrane (OM) of Treponema pallidum subsp. pallidum (TPA), coupled with our
recent successes combining bioinformatics, biophysical techniques, and localization methods with live TPA to
topologically characterize TPA outer membrane proteins (OMPs) and define the syphilis spirochete's
`OMPeome'--its repertoire of OMPs. Its central hypothesis is that the principal targets for a syphilis vaccine
reside within TPA's repertoire of rare outer membrane proteins (OMPs). The projects in the proposal employ
three different, but closely integrated, strategies to exploit this novel application of reverse vaccinology to develop
a syphilis vaccine with global efficacy. Project 1 is `immune-agnostic', selecting leading vaccine candidates based
on genomic sequences, bioinformatics, biophysical analysis, and structural modeling. Project 2 takes its cue
from the human immune system: since the large majority of untreated individuals do eventually control TPA
infection, it stands to reason that OMPs targeted by opsonic antibodies6-9 should be excellent vaccine candidates.
Project 3 borrows a page from the Center for HIV/AIDS Vaccine Immunology and Immunogen Discovery
(CHAVI-ID) `book', using state-of-the art recombinant B cell and phage technology to generate broadly reactive,
opsonic monoclonal antibodies directed against surface-exposed loops of TPA OMPs. The extraordinary deep
sequencing capabilities of the Genetics and Genomics core will provide the data needed to tailor these
approaches for efficacy on a global scale. This CRC, led by two senior investigators, established collaborators
with complementary clinical and research backgrounds, pulls together (a) the unique capabilities of the
Spirochete Research Laboratories at UConn Health; (b) the world-class B cell technology and vaccine research
infrastructure of the Duke Human Vaccine Institute (DHVI); (c) the international health infrastructure and
expertise of the University of North Carolina Institute for Global Health and Infectious Diseases; and (d) the
unparalleled knowledge of TPA genomics at Masaryk University to achieve our long-term objective. The
Administrative Core will provide the managerial oversight needed to integrate these capabilities and
resources to strengthen existing collaborations and foster new ones within the Center and with other CRCs. The
ultimate strength of this CRC is the diversity and complementarity of approaches, technologies, resources, and
expertise it marshals to interrogate the TPA OMPeome to achieve our long-term goals. An effective syphilis
vaccine would represent a triumph of biomedical research over an ailment that for more than five centuries has
exacted a heavy toll on humanity4,5 and that has defied conventional public health strategies for containment. If
successful, the scientific and public health impact of our approach to reverse vaccinology will extend well beyond
syphilis, establishing a paradigm applicable to other recalcitrant organisms.
Status | Finished |
---|---|
Effective start/end date | 1/5/19 → 30/4/24 |
Links | https://projectreporter.nih.gov/project_info_details.cfm?aid=10806303 |
Funding
- National Institute of Allergy and Infectious Diseases: US$75,383.00
- National Institute of Allergy and Infectious Diseases: US$18,704.00
- National Institute of Allergy and Infectious Diseases: US$2,334,857.00
- National Institute of Allergy and Infectious Diseases: US$2,175,925.00
- National Institute of Allergy and Infectious Diseases: US$2,162,304.00
- National Institute of Allergy and Infectious Diseases: US$2,148,172.00
ASJC Scopus Subject Areas
- Structural Biology
- Immunology
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