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Infection and Immunity, July 2003, p. 3920-3926, Vol. 71, No. 7
0019-9567/03/$08.00+0     DOI: 10.1128/IAI.71.7.3920-3926.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

Identification of CD8 T-Lymphocyte Epitopes in OmpB of Rickettsia conorii

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

Department of Pathology, WHO Collaborating Center for Tropical Diseases, University of Texas Medical Branch at Galveston, Galveston, Texas 77555-0609

Received 6 February 2003/ Returned for modification 12 March 2003/ Accepted 12 April 2003

	ABSTRACT

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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-) production and cell proliferation after incubation with simian virus 40-transformed murine vascular endothelial cells in the presence of a 20 µM 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- 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).

	INTRODUCTION

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Rickettsiae are small (0.3 by 1.0 µm), obligately intracellular bacteria that reside in arthropod hosts in at least part of their life cycle. Tick-transmitted Rocky Mountain spotted fever and louse-borne typhus fever are among the most virulent human infections known. All adequately studied Rickettsia species have a quantitatively major, immunodominant S-layer cell wall protein (OmpB), which is encoded as a 168-kDa precursor that undergoes posttranslational protease modification to the mature 135-kDa molecule (18). The spotted fever group rickettsiae differ from typhus group rickettsiae by possessing an additional major, immunodominant surface protein (OmpA) and have antigenic differences from typhus group rickettsiae in the lipopolysaccharides. OmpA contains a large, central, hydrophilic domain of 6 to 15 nearly identical tandem repeat units comprising 72 to 75 amino acids (aa) each.

We have developed mouse models that conform better to the target cells (endothelium) and pathology (disseminated vascular injury) of rickettsial diseases than previously available models, and they offer opportunities for major important advances in the study of rickettsial immunity (16, 45, 46). Previous studies provided evidence that T lymphocytes are critical in the development of immune protection in rickettsial diseases (9, 23, 26, 28, 29, 43). Recently performed research showed that adoptive transfer of immune CD4 or CD8 T lymphocytes protects mice against lethal disseminated endothelial infection with Rickettsia conorii (15). Depletion of CD8, but not CD4, T lymphocytes converts infection with an ordinarily sublethal dose of R. conorii into an overwhelming fatal rickettsial infection in the majority of animals and a persistent symptomatic infection in the survivors. Thus, the evidence that T lymphocytes, particularly those of the CD8 subset, are crucial effectors of immunity applies broadly within the genus Rickettsia (45). The potential importance of CD4 and CD8 T lymphocytes in human rickettsial infections is emphasized by the presence of large numbers of these cells in eschars of patients with R. conorii infection at the time of immune clearance of the rickettsiae (20).

Vaccination with recombinant OmpA has protected guinea pigs against Rickettsia rickettsii and R. conorii, and purified native OmpB has protected vaccinated guinea pigs against Rickettsia typhi (2, 11, 38, 40). Immunization of mice with recombinant Mycobacterium vaccae expressing rompA_3006-3960 or rompA_2331-3976 and boosted with the homologous proteins (OmpA_755-1301 or OmpA_703-1288, respectively) stimulated partial protection against lethal challenge with R. conorii (10). The fragments OmpA_703-1288, OmpA_1644-2213, OmpB_451-846, and OmpB_754-1308 stimulated T-lymphocyte proliferation and secretion of gamma interferon (IFN-) after primary immunization with DNA and booster immunization with the homologous recombinant proteins, and 100% of mice were protected against lethal challenge by immunization with the combination of the four fragments (12). Based on these findings, it was hypothesized that OmpB contains protective elements and that some such elements are able to stimulate immune CD8 T lymphocytes. The specific aims of this study were to define the CD8 T-lymphocyte-stimulating epitopes of OmpB_451-846 of R. conorii at the oligopeptide level and identify the epitopes processed intracellularly and presented on the cell membrane by endothelial cells for the activation of CD8 T lymphocytes. The health impact of this research is that it will establish the knowledge and principles to enable the production of effective vaccines against rickettsial diseases.

	MATERIALS AND METHODS

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Rickettsiae. R. conorii (Malish 7 strain), a human isolate from South Africa with an unknown number of passages in yolk sacs of specific-pathogen-free embryonated chicken eggs (CE), was obtained from the American Type Culture Collection (ATCC; Manassas, Va.) and has the following passage history in our laboratory: plaque purification in Vero cells, 30 CE passages, four Vero cell passages, and two further CE passages. Rickettsial suspensions were prepared by homogenization of infected yolk sacs with a Waring blender and diluted to a 10% suspension in sucrose-phosphate-glutamate buffer (SPG; 0.218 M sucrose, 0.0038 M KH₂PO₄, 0.0072 M K₂HPO₄, 0.0049 M monosodium L-glutamic acid, pH 7.0). Aliquots of the stock were kept frozen at -80°C. Rickettsiae were prepared by Renografin density gradient purification from infected Vero cells (African green monkey kidney cells; ATCC) (19). After purification, rickettsiae were killed by exposure to 100°C for 10 min.

Mice. Six- to eight-week-old male C3H/HeN (H-2^k) mice were purchased from Harlan Sprague-Dawley (Indianapolis, Ind.). These mice were seronegative for mouse hepatitis virus and were kept in a P-3 biohazard containment-level animal room after inoculation with rickettsiae.

Cells. The simian virus 40-transformed murine vascular endothelial cell (SVEC) line SVEC4-10 was kindly provided by Michael Edidin (Johns Hopkins University, Baltimore, Md.) (30). The NCTC clone 2555 fibroblast cell line (ATCC) was derived from a C3H/HeN mouse with the same major histocompatibility complex (MHC) class I (H-2^k) haplotype. These cells were maintained in vitro in Dulbecco's modified essential medium (DMEM; GIBCO/BRL, Grand Island, N.Y.) containing 10% bovine calf serum (BCS; HyClone Inc., Logan, Utah), 2 mM L-glutamine, and 0.01 M HEPES buffer. The cells were passaged twice weekly.

Plasmid DNA constructs. A 1.2-kb OmpB_451-846 fragment was PCR amplified from p120R-19, a generous gift from Robert Gilmore (17). p120R-19 contains the majority of the open reading frame for OmpB of R. rickettsii. R. rickettsii and R. conorii share homology in rompB genes of greater than 95%. The OmpB_451-846 fragment was further subcloned by using site-specific PCR primers (Table 1). These fragments were ligated to the mammalian expression vector backbone pcDNA3.1/CT-GFP-TOPO (Invitrogen, Carlsbad, Calif.) and transformed into competent Escherichia coli TOP10 cells according to the manufacturer's instructions. Transformants bearing plasmids containing rickettsial DNA fragments were identified by restriction endonuclease analysis. Orientation and frame relative to the cytomegalovirus promoter were confirmed by DNA sequence analysis with an ABI Prism 377 DNA sequencer (Perkin-Elmer Applied Biosystems, Foster City, Calif.). All plasmid constructs were maintained in the E. coli transformants under ampicillin selection, and large-scale concentrated plasmid preparations (1.5 to 2.2 mg/ml) of these constructs were generated using EndoFree Plasmid Mega kits (Qiagen, Valencia, Calif.) according to the manufacturer's instructions.

R. conorii-specific CD8 T-lymphocyte cell line. A CD8 T-lymphocyte cell line with high specificity for rickettsial antigens was developed by serial in vitro antigen stimulations. Five 6- to 8-week-old C3H/HeN male mice were inoculated intravenously with a sublethal dose of R. conorii (5 x 10² PFU). All mice became ill and recovered by day 9 postinoculation. On that day, the murine spleens were harvested. Cell lines were derived from whole-spleen suspensions and from CD8 T lymphocytes purified from the same spleen suspensions. CD8 T lymphocytes were purified using selective columns (R & D Systems, Minneapolis, Minn.). In vitro stimulation was carried out in six-well plates containing a monolayer of paraformaldehyde-fixed, R. conorii-infected SVECs. Three milliliters of purified CD8 T lymphocytes at a concentration of 6 x 10⁵ cells/ml or 3 ml of spleen suspension at a concentration of 6 x 10⁶ cells/ml was added to each well. Three milliliters containing 6 x 10⁶ gamma-irradiated (2,300-rad) syngeneic naïve splenocytes/ml were added to each well as feeder cells. Plates were incubated at 37°C in a 5% CO₂ atmosphere. Lymphocytes were restimulated every week. Human recombinant interleukin-2 (Roche Molecular Biochemicals, Indianapolis, Ind.) was added to each well at a concentration of 10 U/ml from the second passage onwards.

Lymphocyte responses. T-lymphocyte responses were determined by measurement of IFN- secretion and cell proliferation after antigen stimulation. IFN- secretion was measured by use of a quantitative sandwich enzyme-linked immunosorbent assay kit (R & D Systems) according to the manufacturer's instructions. Results reported were the averages of triplicate samples. Standard deviations were determined by using the Microsoft Excel program. Differences among data sets were considered significant if P was ≤0.05; P values were determined by Student's t test with Microsoft Excel. The standard thymidine incorporation assay was used to quantify lymphocyte proliferation. The R. conorii-specific CD8 T-lymphocyte cell line was adjusted to a concentration of 10⁶ cells/ml, and 100 µl per well was aliquoted into 96-well plates. On day 5, 1 µCi of [³H]thymidine was added per well, and the plates were incubated overnight at 37°C. Cells were harvested into GF/B (Packard Instruments Co., Meriden, Conn.) plates. After evaporation to dryness, 30 µl of scintillation fluid was added to each well. [³H]thymidine incorporation was determined in a beta counter (Top Count; Packard Instruments Co.). Lymphocyte proliferation was considered significant if the stimulation index (counts per minute of sample stimulated with antigen/counts per minute of sample without antigen) was greater than 3. These experiments were repeated three times.

Cytotoxic T-lymphocyte (CTL) assays. CTL assays were performed according to the standard method reported previously (3). Since the major target cells of rickettsial infection in humans and in the C3H/HeN mouse model are the endothelial cells, the R. conorii-infected MHC class I-matched endothelial cell line, SVEC4-10 (H-2^k), was chosen as the target cells in the CTL assay (46). The effector cells were a CD8 T-lymphocyte cell line reactive against R. conorii. The percentage of target cell lysis was calculated by the following formula: [(counts per minute of the experiment - counts per minute spontaneously released)/(counts per minute of the maximum release - counts per minute spontaneously released)] x 100.

CD8 T-cell epitope mapping of OmpB_451-846 by using synthetic peptides. The amino acid sequences of polypeptides that stimulate CD8 T-cell activation were further mapped by using overlapping synthetic peptides. Each peptide contained nine amino acid residues, and two adjacent peptides overlapped by four or five residues. The peptides were custom synthesized (Bio-Synthesis Inc., Lewisville, Tex.). We have established a murine CD8 T-cell line reactive against the antigens of R. conorii. These cells were used for T-cell epitope mapping of OmpB. The mouse CD8 T lymphocytes were adjusted to 10⁶ cells/ml, and 0.1 ml was aliquoted into each well of 96-well plates. The synthetic peptides were diluted and added to duplicate wells at a 20 µM concentration. Each well also contained 10⁵ antigen-presenting cells (SVECs) and interleukin-2 (one unit per well). The ability of these peptides to activate CD8 T lymphocytes in vitro was tested by lymphocyte proliferation, IFN- production, and CTL assay.

	RESULTS

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Cloning and expression of rickettsial OmpB_451-846 gene fragments. Overlapping fragments of OmpB_451-846 were amplified by using site-specific PCR primers as three smaller fragments: OmpB_458-652, OmpB_595-744, and OmpB_739-848. The OmpB_595-744 fragment was further subcloned by using site-specific PCR primers into three smaller fragments: OmpB_595-654, OmpB_645-692, and OmpB_689-744 (Fig. 1). Their sizes were as expected. These PCR products were cloned into pcDNA3.1/CT-GFP-TOPO vector. Clones containing these fragments in the right orientation were selected and used to transfect NCTC fibroblast cells.

View larger version (12K): [in this window] [in a new window]   FIG. 1. Stimulation of CD8 T-cell proliferation and IFN- secretion by NCTC cells expressing recombinant proteins derived from OmpB451-846 of R. conorii. ND, not done.

Establishment of a CD8 T-lymphocyte cell line reactive against R. conorii. The R. conorii-specific CD8 T-lymphocyte populations derived from whole-spleen suspensions reached 95% purity (the other 5% may be CD4 lymphocytes from the irradiated feeder cells) after four passages in vitro (Fig. 2). This cell line is a very useful tool for the identification of the rickettsial CD8 T-lymphocyte epitopes.

View larger version (15K): [in this window] [in a new window]   FIG. 2. Flow cytometric analysis of double-stained lymphocyte populations with anti-CD3 antibody conjugated to peridinin chlorophyll- protein and anti-CD8 antibody conjugated to fluorescein isothiocyanate. (A) Population of purified CD8 T lymphocytes after two cycles of in vitro stimulation. (B and C) Splenocyte suspensions in which the population of CD8 T lymphocytes was enhanced by in vitro stimulation after two (B) and four (C) cycles. The CD8 T-lymphocyte population derived from whole-spleen suspensions reached a purity of 95% after four in vitro passages (C).

View larger version (26K): [in this window] [in a new window]   FIG. 3. IFN- secretion by immune CD8 T lymphocytes after incubation with NCTC cells transfected with the vector control pcDNA3.1/CT-GFP-TOPO (GFP) or the vector expressing the polypeptide OmpB458-652, OmpB595-744, or OmpB739-848. The positive control is the IFN- secretion by immune CD8 T lymphocytes after incubation with R. conorii-infected NCTC cells. *, P ≤ 0.05 compared with stimulation by cells transfected with vector only.

View larger version (20K): [in this window] [in a new window]   FIG. 4. IFN- secretion by immune CD8 T lymphocytes after incubation with NCTC cells transfected with the vector control pcDNA3.1/CT-GFP-TOPO (GFP) or the vector expressing the polypeptide OmpB595-654, OmpB645-692, or OmpB689-744. *, P ≤ 0.05 compared with stimulation by cells transfected with vector only.

View larger version (39K): [in this window] [in a new window]   FIG. 5. IFN- secretion by immune CD8 T lymphocytes after stimulation with SVECs incubated with the synthetic peptides. FESTENGLI, an H-2k-restricted epitope from the nucleoprotein of influenza virus, was used as a negative control. *, P ≤ 0.05 compared with stimulation by control peptide.

View larger version (34K): [in this window] [in a new window]   FIG. 6. Cell proliferation of immune CD8 T lymphocytes after stimulation with SVECs incubated with the 20 µM solution of synthetic peptides. FESTENGLI, an H-2k-restricted epitope from the nucleoprotein of influenza virus, was used as a negative control. *, P ≤ 0.05 compared with stimulation by control peptide.

View larger version (14K): [in this window] [in a new window]   FIG. 7. CTL activity directed against SVECs at effector-to-target cell (E:T) ratios of 3, 10, 30, and 100, measured as the percentage of lysis of target cells. Effector cells were an R. conorii-specific CD8 cell line. Target cells are indicated as follows: , R. conorii-infected SVECs, no peptide; , uninfected SVECs, with synthetic peptide IVSGTVGGQ (OmpB749-757); , uninfected SVECs, with synthetic peptide ANSTLQIGG (OmpB789-797); x, uninfected SVECs, with synthetic peptide IVEFVNTGP (OmpB812-820); , uninfected SVECs, with synthetic peptide SKGVNVDTV (OmpB708-716); , uninfected SVECs, with synthetic peptide ANVGSFVFN (OmpB735-743); , uninfected SVECs, no peptide.

	DISCUSSION

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This report represents for the first time the identification of three CD8 T-lymphocyte epitopes in OmpB of R. conorii. These epitopes illustrate an approach to selecting candidate antigens for rickettsial subunit vaccine development. Currently, there is no rickettsial vaccine available that is close to being effective and acceptable. Three vaccines have been developed for prevention of Rocky Mountain spotted fever: a killed rickettsial preparation of infected ticks developed in 1924, a killed rickettsial vaccine from infected yolk sacs of embryonated hen's eggs developed in 1938, and a killed rickettsial vaccine developed from cell culture in the 1970s (7, 8, 22, 37). However, all these vaccines failed to confer effective immune protection (6, 13). The use of molecular approaches to development of rickettsial vaccines is quite clearly making significant progress. Rickettsial vaccine development has been thwarted by the difficulty of manipulating these organisms outside viable host cells. Knowledge of the protective immune effector mechanisms and how to stimulate them is a rational prerequisite to an ultimately successful vaccine regimen (41). Development of rickettsial vaccines will have a significant effect on the prevention of these life-threatening, diagnostically difficult diseases.

The main goal of this study was to identify CD8 T-lymphocyte epitopes of R. conorii. Because CD8 T cells play important roles in resistance to infection with rickettsiae, effective vaccines against rickettsiosis will likely require identification of antigens that contain CD8 T-cell epitopes. CD8 T-cell epitopes consist of 8- or 9-aa peptides that are selected for presentation based on MHC class I allele-specific binding motifs and their ability to survive proteolytic digestion in the host cell. The subunit strategy for development of an effective rickettsial vaccine relies on identification of antigens and the precise epitope recognized by the protective CD8 T cells. In this study, the plasmid vector pcDNA3.1/CT-GFP-TOPO (Invitrogen) was used for the expression of the OmpB fragments in NCTC fibroblast cells. This vector system is associated with fewer toxic effects of intact bacterial proteins in the host cells, since the approach is designed for expression of gene fragments.

So far, identification of CD8 T-lymphocyte epitopes has been focused mainly on facultatively intracellular bacteria. Four different Listeria monocytogenes epitopes are known to be presented to CTLs by MHC class I H-2K^d molecules (4, 31, 32). These epitopes are derived from bacterial virulence factors, listeriolysin (LLO 91-99), murein hydrolase p60 (p60 217-225 and p60 449-457), and metalloprotease (mpl 84-92). A novel HLA-B*35-restricted CD8 T-cell epitope in Mycobacterium tuberculosis Rv2903c (aa 201 to 209) was identified based on a reverse immunogenetics approach (24). Klein et al. identified three HLA-B*35-restricted CD8 T-cell epitopes, Ag85A (aa 267 to 275), Ag85B (aa 264 to 272), and Ag85C (aa 204 to 212), in the M. tuberculosis antigen 85 complex (25). Smith et al. identified two human HLA-A*0201-restricted CD8 T-cell epitopes, P_48-56 and P_242-250, by spanning the mycobacterial major secreted protein Ag85A (36). Six HLA-A*0201-restricted CTL epitopes were identified by Charo et al. in heat shock protein 65 (hsp65) of mycobacteria (5): Mhsp65(9₄₁₆), Mhsp65(9₃₆₂), Mhsp65(9₃₆₉), Mhsp65(10₉₇), Mhsp65(11₅₀₀), and Mhsp65(9₂₁). Lalvani et al. identified two CD8 T-cell-specific epitopes, ES13 (aa 82 to 90) and ES12 (aa 69 to 76), in the early secretory antigenic target 6 during active tuberculosis (27). Very few studies of CD8 T-lymphocyte epitopes have been reported for obligately intracellular bacteria. Saren et al. (35) identified three Chlamydia pneumoniae CD8 epitopes that were processed and presented on the infected cells. Wizel et al. (47) generated 18 H-2^b binding peptides representing sequences from 12 C. pneumoniae antigen-sensitized target cells for MHC class I-restricted lysis by CD8 CTLs from the spleen and lungs of infected mice. During this study, we combined genetic and biochemical means in an attempt to identify CD8 T-lymphocyte epitopes from OmpB of R. conorii. Our results showed that three synthetic peptides of OmpB_451-846, SKGVNVDTV (OmpB_708-716), ANSTLQIGG (OmpB_789-797), and IVEFVNTGP (OmpB_812-820), induced secretion of IFN- and stimulated the proliferation of immune CD8 T lymphocytes and specific CTL killing at significantly higher levels than the controls did. In our study, at effector/target ratios of 3, 10, and 30, increasing levels of epitope-specific CTL lysis were observed (Fig. 7). Protective immunity against rickettsiae is achieved by a complex interaction of responses mediated by CD4 and CD8 T lymphocytes, macrophages, NK cells, antibodies, cytokines, and chemokines (1, 39). CTL activity, which is expressed by immune CD8 T lymphocytes, appears to be crucial to recovery from rickettsial infection (44). Depletion of CD8 T lymphocytes results in the establishment of persistent R. conorii infection in mice associated with increased mortality after an ordinarily sublethal dose of rickettsiae (15). IFN- secretion by and CTL activity of immune CD8 T lymphocytes are involved, but the specifics are yet to be determined (14).

This research extends the knowledge of the role of OmpB as an immunogen and the relevance of the response of CD8 T lymphocytes to such antigens. Epitopes with strong CD8 stimulatory capability will represent good candidates for rickettsial vaccine development because they stimulate a relevant arm of the immune response against these intracellular bacteria. The identification of potential CD8 T-lymphocyte epitopes at the oligopeptide level was addressed for the H-2^k haplotype. Future progress in subunit vaccine development will require identification of CD8 T-lymphocyte epitopes that stimulate human CD8 T lymphocytes via MHC class I presentation.

	ACKNOWLEDGMENTS

 
This work was supported by a grant from the National Institute of Allergy and Infectious Diseases (AI 21242).

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Pathology, WHO Collaborating Center for Tropical Diseases, University of Texas Medical Branch, 301 University Blvd., Galveston, TX 77555-0609. Phone: (409) 772-2856. Fax: (409) 772-2500. E-mail: dwalker{at}utmb.edu.

Editor: W. A. Petri, Jr.

Present address: Department of Immunology, University of Texas M. D. Anderson Cancer Center, Houston, TX 77030.

	REFERENCES

Top Abstract Introduction Materials and Methods Results Discussion References

 

1.	Billings, A. N., H. M. Feng, J. P. Olano, and D. H. Walker. 2001. Rickettsial infection in murine models activates an early anti-rickettsial effect mediated by NK cells and associated with production of gamma interferon. Am. J. Trop. Med. Hyg. 65:52-56.[Abstract]
2.	Bourgeois, A. L., and G. A. Dasch. 1981. The species-specific surface protein antigen of Rickettsia typhi: immunogenicity and protective efficacy in guinea pigs, p. 71-80. In W. Burgdorfer and R. L. Anacker (ed.), Rickettsiae and rickettsial diseases. Academic Press, New York, N.Y.
3.	Brunner, K. T., H. D. Engers, and J. C. Grottini. 1976. The 51Cr-release assay as used for the quantitative measurement of cell-mediated cytolysis in vitro, p. 423. In B. R. Bloom and J. R. David (ed.), In vitro methods in cell-mediated and tumor immunity. Academic Press, New York, N.Y.
4.	Busch, D. H., and E. G. Pamer. 1998. MHC class 1/peptide stability: implications for immunodominance, in vitro proliferation, and diversity of responding CTL. J. Immunol. 160:4441-4448.[Abstract/Free Full Text]
5.	Charo, J., A. Geluk, M. Sundback, 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. M. Ottenhoff, and R. Kiessling. 2001. The identification of a common pathogen-specific HLA class I A*0201-restricted cytotoxic T cell epitope encoded within the heat shock protein 65. Eur. J. Immunol. 31:3602-3611.[CrossRef][Medline]
6.	Clements, M. L., C. L. Wisseman, Jr., T. E. Woodward, P. Fiset, J. S. Dumler, W. McNamee, R. E. Black, J. Rooney, T. P. Hughes, and M. M. Levine. 1983. Reactogenicity, immunogenicity, and efficacy of a chick embryo cell-derived vaccine for Rocky Mountain spotted fever. J. Infect. Dis. 148:922-930.[Medline]
7.	Cox, H. R. 1938. Use of yolk sac of developing chick embryo as medium for growing rickettsiae of Rocky Mountain spotted fever and typhus groups. Public Health Rep. 53:2241-2247.
8.	Cox, H. R. 1948. The preparation and standardization of rickettsial vaccines, p. 203-214. In F. R. Moulton (ed.), Rickettsial diseases of man. American Association for the Advancement of Science, Washington, D.C.
9.	Crist, A. E., Jr., C. L. Wisseman, Jr., and J. R. Murphy. 1984. Characteristics of lymphoid cells that adoptively transfer immunity to Rickettsia mooseri infection in mice. Infect. Immun. 44:55-60.[Abstract/Free Full Text]
10.	Crocquet-Valdes, P. A., C. M. Diaz-Montero, H. M. Feng, H. Li, A. D. T. Barrett, and D. H. Walker. 2002. Immunization with a portion of rickettsial outer membrane protein A stimulates protective immunity against spotted fever rickettsiosis. Vaccine 20:979-988.
11.	Dasch, G. A., and A. L. Bourgeois. 1981. Antigens of the typhus group of rickettsiae: importance of the species-specific surface protein antigens in eliciting immunity, p. 61-69. In W. Burgdorfer and R. L. Anacker (ed.), Rickettsiae and rickettsial diseases. Academic Press, Inc., New York, N.Y.
12.	Diaz-Montero, C. M., H.-M. Feng, P. A. Crocquet-Valdes, and D. H. Walker. 2001. Identification of protective components of two major outer membrane proteins of spotted fever group rickettsiae. Am. J. Trop. Med. Hyg. 65:371-378.[Abstract]
13.	Dupont, H. L., R. B. Hornick, A. T. Dawkins, G. G. Heiner, I. B. Fabrikant, C. L. Wisseman, Jr., and T. E. Woodward. 1973. Rocky Mountain spotted fever: a comparative study of the active immunity induced by inactivated and viable pathogenic Rickettsia rickettsii. J. Infect. Dis. 128:340-344.[Medline]
14.	Feng, H.-M., V. L. Popov, and D. H. Walker. 1994. Depletion of gamma interferon and tumor necrosis factor alpha in mice with Rickettsia conorii-infected endothelium: impairment of rickettsicidal nitric oxide production resulting in fatal, overwhelming rickettsial disease. Infect. Immun. 62:1952-1960.[Abstract/Free Full Text]
15.	Feng, H.-M., V. L. Popov, G. Yuoh, and D. H. Walker. 1997. Role of T-lymphocyte subsets in immunity to spotted fever group rickettsiae. J. Immunol. 158:5314-5320.[Abstract]
16.	Feng, H.-M., J. Wen, and D. H. Walker. 1993. Rickettsia australis infection: a murine model of a highly invasive vasculopathic rickettsiosis. Am. J. Pathol. 142:1471-1482.[Abstract]
17.	Gilmore, R. D., Jr., W. Cieplak, Jr., P. F. Policastro, and T. Hackstadt. 1991. The 120 kilodalton outer membrane protein (rOmp B) of Rickettsia rickettsii is encoded by an unusually long open reading frame: evidence for protein processing from a large precursor. Mol. Microbiol. 5:2361-2370.[CrossRef][Medline]
18.	Hackstadt, T., R. Messer, W. Cieplak, and M. G. Peacock. 1992. Evidence for proteolytic cleavage of the 120-kilodalton outer membrane protein of rickettsiae: identification of an avirulent mutant deficient in processing. Infect. Immun. 60:159-165.[Abstract/Free Full Text]
19.	Hanson, B. A., C. L. Wisseman, Jr., A. Waddell, and D. J. Silverman. 1981. Some characteristics of heavy and light bands of Rickettsia prowazekii on Renografin gradients. Infect. Immun. 34:596-604.[Abstract/Free Full Text]
20.	Herrero-Herrero, J. I., D. H. Walker, and R. Ruiz-Beltran. 1987. Immunohistochemical evaluation of the cellular immune response to Rickettsia conorii in taches noires. J. Infect. Dis. 155:802-805.[Medline]
21.	Jerrells, T. R. 1988. Mechanisms of immunity to Rickettsia species and Coxiella burnetii, p. 79-100. In D. H. Walker (ed.), Biology of rickettsial diseases. CRC Press, Inc., Boca Raton, Fla.
22.	Kenyon, R. H., and C. E. Pedersen, Jr. 1975. Preparation of Rocky Mountain spotted fever vaccine suitable for human immunization. J. Clin. Microbiol. 1:500-503.[Abstract/Free Full Text]
23.	Kenyon, R. H., and C. E. Pedersen, Jr. 1980. Immune responses to Rickettsia akari infection in congenitally athymic nude mice. Infect. Immun. 28:310-313.[Abstract/Free Full Text]
24.	Klein, M. R., A. S. Hammond, S. M. Smith, A. Jaye, P. T. Lukey, and K. P. W. J. McAdam. 2002. HLA-B*35*-restricted CD8+-T-cell epitope in Mycobacterium tuberculosis Rv 2903c. Infect. Immun. 70:981-984.[Abstract/Free Full Text]
25.	Klein, M. R., S. M. Smith, A. S. Hammond, G. S. Ogg, A. S. King, J. Vekemans, A. Jaye, P. T. Lukey, and K. P. McAdam. 2001. HLA-B*35-restricted CD8 T cell epitopes in the antigen 85 complex of Mycobacterium tuberculosis. J. Infect. Dis. 183:928-934.[CrossRef][Medline]
26.	Kokorin, I. N., E. A. Kabanova, E. M. Shirokova, E. G. Abrosimova, N. N. Rybkina, and V. I. Pushkareva. 1982. Role of T lymphocytes in Rickettsia conorii infection. Acta Virol. 26:91-97.[Medline]
27.	Lalvani, A., R. Brookes, R. J. Wilkinson, A. S. Malin, A. A. Pathan, P. Andersen, H. Dockrell, G. Pasvol, and A. V. S. Hill. 1998. Human cytolytic and interferon -secreting CD8+ T lymphocytes specific for Mycobacterium tuberculosis. Proc. Natl. Acad. Sci. USA 95:270-275.[Abstract/Free Full Text]
28.	Montenegro, N. R., D. H. Walker, and B. C. Hegarty. 1984. Infection of genetically immunodeficient mice with Rickettsia conorii. Acta Virol. 28:508-514.[Medline]
29.	Murphy, J. R., C. L. Wisseman, Jr., and P. Fiset. 1978. Mechanisms of immunity in typhus infection: some characteristics of intradermal Rickettsia mooseri infection in normal and immune guinea pigs. Infect. Immun. 22:810-820.[Abstract/Free Full Text]
30.	O'Connell, K. A., and M. Edidin. 1990. A mouse lymphoid endothelial cell line immortalized by simian virus 40 binds lymphocytes and retains functional characteristics of normal endothelial cells. J. Immunol. 144:521-525.[Abstract]
31.	Pamer, E. G. 1994. Direct sequence identification and kinetic analysis of an MHC class I-restricted Listeria monocytogenes CTL epitope. J. Immunol. 152:686-694.[Abstract]
32.	Pamer, E. G., J. T. Harty, and M. J. Bevan. 1991. Precise prediction of a dominant class I MHC-restricted epitope of Listeria monocytogenes. Nature 353:852-855.[CrossRef][Medline]
33.	Raoult, D., P. Zuchelli, P. J. Weiller, C. Charrel, J. L. San Marco, H. Gallais, and P. Casanova. 1986. Incidence, clinical observations and risk factors in the severe form of Mediterranean spotted fever among patients admitted to hospital in Marseilles 1983-1984. J. Infect. 12:111-116.[CrossRef][Medline]
34.	Ricketts, H. T., and L. Gomez. 1908. Studies on immunity in Rocky Mountain spotted fever. First communication. J. Infect. Dis. 5:221-244.
35.	Saren, A., S. Pascolo, S. Stevanovic, T. Dumrese, M. Puolakkainen, M. Sarvas, H.-G. Rammensee, and J. M. Vuola. 2002. Identification of Chlamydia pneumoniae-derived mouse CD8 epitopes. Infect. Immun. 70:3336-3343.[Abstract/Free Full Text]
36.	Smith, S. M., R. Brookes, M. R. Klein, A. S. Malin, P. T. Lukey, A. S. King, G. S. Ogg, A. V. S. Hill, and H. M. Dockrell. 2000. Human CD8+ CTL specific for the mycobacterial major secreted antigen 85A. J. Immunol. 165:7088-7095.[Abstract/Free Full Text]
37.	Spencer, R. R., and R. R. Parker. 1925. Rocky Mountain spotted fever: vaccination of monkeys and man. Public Health Rep. 40:2159-2167.
38.	Sumner, J. W., K. G. Sims, D. C. Jones, and B. E. Anderson. 1995. Protection of guinea-pigs from experimental Rocky Mountain spotted fever by immunization with baculovirus-expressed Rickettsia rickettsii rOmpA protein. Vaccine 13:29-35.[CrossRef][Medline]
39.	Valbuena, G., H.-M. Feng, and D. H. Walker. 2002. Mechanisms of immunity against rickettsiae. New perspectives and opportunities offered by unusual intracellular parasites. Microbes Infect. 4:625-633.[CrossRef][Medline]
40.	Vishwanath, S., G. A. McDonald, and N. G. Watkins. 1990. A recombinant Rickettsia conorii vaccine protects guinea pigs from experimental boutonneuse fever and Rocky Mountain spotted fever. Infect. Immun. 58:646-653.[Abstract/Free Full Text]
41.	Walker, D. H. 1988. Role of the composition of rickettsiae in rickettsial immunity: typhus and spotted fever groups, p. 101-109. In D. H. Walker (ed.), Biology of rickettsial diseases. CRC Press, Inc., Boca Raton, Fla.
42.	Walker, D. H. 1990. The role of host factors in the severity of spotted fever and typhus rickettsioses. Ann. N. Y. Acad. Sci. 590:10-19.[Medline]
43.	Walker, D. H., and F. W. Henderson. 1978. Effect of immunosuppression on Rickettsia rickettsii infection in guinea pigs. Infect. Immun. 20:221-227.[Abstract/Free Full Text]
44.	Walker, D. H., J. P. Olano, and H.-M. Feng. 2001. Critical role of cytotoxic T lymphocytes in immune clearance of rickettsial infection. Infect. Immun. 69:1841-1846.[Abstract/Free Full Text]
45.	Walker, D. H., V. L. Popov, and H.-M. Feng. 2000. Establishment of a novel endothelial target mouse model of a typhus group rickettsiosis: evidence for critical roles for gamma interferon and CD8 T lymphocytes. Lab. Investig. 80:1361-1372.[Medline]
46.	Walker, D. H., V. L. Popov, J. Wen, and H.-M. Feng. 1994. Rickettsia conorii infection of C3H/HeN mice: a model of endothelial-target rickettsiosis. Lab. Investig. 70:358-368.[Medline]
47.	Wizel, B., B. C. Starcher, B. Samten, Z. Chroneos, P. F. Barnes, J. Dzuris, Y. Higashimoto, E. Appella, and A. Sette. 2002. Multiple Chlamydia pneumoniae antigens prime CD8+ Tc1 responses that inhibit intracellular growth of this vacuolar pathogen. J. Immunol. 169:2524-2535.[Abstract/Free Full Text]

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