Literature DB >> 12819078

Identification of CD8 T-lymphocyte epitopes in OmpB of Rickettsia conorii.

Zhen Li1, C Marcela Díaz-Montero, Gustavo Valbuena, Xue-Jie Yu, Juan P Olano, Hui-Min Feng, David H Walker.   

Abstract

The 1.2-kb DNA fragment of the Rickettsia conorii outer membrane protein B gene (OmpB(451-846)) was subcloned using site-specific PCR primers and expressed as six smaller fragments: OmpB(458-652), OmpB(595-744), OmpB(595-654), OmpB(645-692), OmpB(689-744), and OmpB(739-848). NCTC cells transfected with a mammalian expression vector expressing the fragments OmpB(689-744) and OmpB(739-848) stimulated immune anti-R. conorii CD8 T lymphocytes, suggesting the presence of CD8 T-lymphocyte-stimulating epitopes on these fragments. In order to further characterize the CD8 T-lymphocyte-stimulatory elements, CD8 T-lymphocyte epitopes on OmpB(689-744) and OmpB(739-848) were mapped by overlapping synthetic peptides. The ability of these synthetic peptides to stimulate immune CD8 T lymphocytes was determined by gamma interferon (IFN-gamma) production and cell proliferation after incubation with simian virus 40-transformed murine vascular endothelial cells in the presence of a 20 micro M solution of each synthetic peptide. Five synthetic peptides, SKGVNVDTV (OmpB(708-716)), ANVGSFVFN (OmpB(735-743)), IVSGTVGGQ (OmpB(749-757)), ANSTLQIGG (OmpB(789-797)), and IVEFVNTGP (OmpB(812-820)), induced secretion of IFN-gamma at significantly higher levels than the controls. Three of these five peptides, SKGVNVDTV (OmpB(708-716)), ANSTLQIGG (OmpB(789-797)), and IVEFVNTGP (OmpB(812-820)), also stimulated the proliferation of immune CD8 T lymphocytes. Significantly higher levels of specific cytotoxic T-lymphocyte killing were observed with the same three synthetic peptides, SKGVNVDTV (OmpB(708-716)), ANSTLQIGG (OmpB(789-797)), and IVEFVNTGP (OmpB(812-820)).

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Year:  2003        PMID: 12819078      PMCID: PMC161984          DOI: 10.1128/IAI.71.7.3920-3926.2003

Source DB:  PubMed          Journal:  Infect Immun        ISSN: 0019-9567            Impact factor:   3.441


  38 in total

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2.  Immunization with a portion of rickettsial outer membrane protein A stimulates protective immunity against spotted fever rickettsiosis.

Authors:  P A Crocquet-Valdes; C M Díaz-Montero; H M Feng; H Li; A D Barrett; D H Walker
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3.  Identification of protective components of two major outer membrane proteins of spotted fever group Rickettsiae.

Authors:  C M Díaz-Montero; H M Feng; P A Crocquet-Valdes; D H Walker
Journal:  Am J Trop Med Hyg       Date:  2001-10       Impact factor: 2.345

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Authors:  Gustavo Valbuena; Hui Min Feng; David H Walker
Journal:  Microbes Infect       Date:  2002-05       Impact factor: 2.700

5.  HLA-B*35-restricted CD8 T cell epitopes in the antigen 85 complex of Mycobacterium tuberculosis.

Authors:  M R Klein; S M Smith; A S Hammond; G S Ogg; A S King; J Vekemans; A Jaye; P T Lukey; K P McAdam
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6.  The identification of a common pathogen-specific HLA class I A*0201-restricted cytotoxic T cell epitope encoded within the heat shock protein 65.

Authors:  J Charo; A Geluk; M Sundbäck; B Mirzai; A D Diehl; K J Malmberg; A Achour; S Huriguchi; K E van Meijgaarden; J W Drijfhout; N Beekman; P van Veelen; F Ossendorp; T H Ottenhoff; R Kiessling
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8.  Establishment of a novel endothelial target mouse model of a typhus group rickettsiosis: evidence for critical roles for gamma interferon and CD8 T lymphocytes.

Authors:  D H Walker; V L Popov; H M Feng
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9.  Critical role of cytotoxic T lymphocytes in immune clearance of rickettsial infection.

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10.  Protection of guinea-pigs from experimental Rocky Mountain spotted fever by immunization with baculovirus-expressed Rickettsia rickettsii rOmpA protein.

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1.  The Rickettsia conorii autotransporter protein Sca1 promotes adherence to nonphagocytic mammalian cells.

Authors:  Sean P Riley; Kenneth C Goh; Timothy M Hermanas; Marissa M Cardwell; Yvonne G Y Chan; Juan J Martinez
Journal:  Infect Immun       Date:  2010-02-22       Impact factor: 3.441

2.  Adaptive evolution and recombination of Rickettsia antigens.

Authors:  Francis M Jiggins
Journal:  J Mol Evol       Date:  2006-01-11       Impact factor: 2.395

Review 3.  Vaccination against Bacterial Infections: Challenges, Progress, and New Approaches with a Focus on Intracellular Bacteria.

Authors:  Anke Osterloh
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4.  Expression of members of the 28-kilodalton major outer membrane protein family of Ehrlichia chaffeensis during persistent infection.

Authors:  Jian-zhi Zhang; Hong Guo; Gary M Winslow; Xue-jie Yu
Journal:  Infect Immun       Date:  2004-08       Impact factor: 3.441

5.  Rickettsial outer-membrane protein B (rOmpB) mediates bacterial invasion through Ku70 in an actin, c-Cbl, clathrin and caveolin 2-dependent manner.

Authors:  Yvonne G Y Chan; Marissa M Cardwell; Timothy M Hermanas; Tsuneo Uchiyama; Juan J Martinez
Journal:  Cell Microbiol       Date:  2009-01-07       Impact factor: 3.715

6.  Discovery of novel cross-protective Rickettsia prowazekii T-cell antigens using a combined reverse vaccinology and in vivo screening approach.

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7.  Endothelial Cell Proteomic Response to Rickettsia conorii Infection Reveals Activation of the Janus Kinase (JAK)-Signal Transducer and Activator of Transcription (STAT)-Inferferon Stimulated Gene (ISG)15 Pathway and Reprogramming Plasma Membrane Integrin/Cadherin Signaling.

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Review 8.  New insight into immunity and immunopathology of Rickettsial diseases.

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9.  Adherence to and invasion of host cells by spotted Fever group rickettsia species.

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10.  Surface proteome analysis and characterization of surface cell antigen (Sca) or autotransporter family of Rickettsia typhi.

Authors:  Khandra T Sears; Shane M Ceraul; Joseph J Gillespie; Edwin D Allen; Vsevolod L Popov; Nicole C Ammerman; M Sayeedur Rahman; Abdu F Azad
Journal:  PLoS Pathog       Date:  2012-08-09       Impact factor: 6.823
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