Peptide-specific Cytotoxic T Lymphocyte Responses Research Articles

On the development of a neoantigen vaccine for the prevention of Lynch Syndrome

Lynch Syndrome (LS) is an autosomal dominant genetic condition that causes a high risk of colorectal cancer. The hallmark of LS is genetic instability as a result of mismatch repair (MMR) deficiency, particularly in repetitive low complexity regions called microsatellites (MS). MLH1-/- mice deficient in MMR are prone to developing tumors in the colon, upon oral administration of dextran sodium sulfate (DSS), at a rate of more than 70%. Using this LS mouse model, we found a novel tumor neo-antigen from a deletion mutation of the coding MS in the SENP6 gene that prevented tumorigenesis or hindered tumor growth rate in immunized mice. This was accomplished via high throughput exome sequencing of DSS-induced colorectal tumors in the MLH1-/- mice and predicting the most highly immunogenic mutant gene products processed and presented as antigens in C57BL/6 MHC-I molecules. Throughout our study, we were able to prove the validity of the vaccine by analyzing the colorectal tumors in immunized DSS-treated mice using either our epitope, called Sp6D1, or an unrelated peptide as a negative control. Tumors developed in this context were found to be antigenic and Sp6D1-specific CD8+ tumor infiltrating lymphocytes were detected by flow cytometry and cytotoxic T lymphocytes (CTL) killing assays. Additionally, immunohistochemistry showed that tumor-adjacent tertiary lymphoid organs were a potentially significant source of CD8+ lymphocytes. Altogether, our results indicate that there may be a protective effect to patients carrying LS mutations through the induction of a peptide-specific CTL response from the use of neoepitope vaccination.

Identification of antigenic peptides from novel renal cancer stem-like cell antigen, DNAJB8

ObjectivesTo identify antigenic peptides of cancer stem-like cells (CSCs) antigen, DNAJB8, and establish a mouse CSCs-targeting immunotherapy model. Materials and methodsTo induce DNAJB8-specific immune reaction, we stimulated human CD8+ lymphocytes with antigen-presenting cells pulsed with a cocktail of three candidate HLA-A*24:02 restricted peptides and assessed peptide specific human cytotoxic T lymphocytes (CTLs) induction. One of the antigenic peptides showed identical amino acid sequence as corresponding mouse DNAJB8. We evaluated CTL induction with the peptide immunization in mouse model. ResultsWe confirmed peptide-specific interferon-γ secretions and cytotoxic activities of induced human CTLs. In vivo immunization with the peptide to mice, peptide-specific CTL response could be observed in mouse CD8+ T cells. Furthermore, immunization with the peptide showed significant anti-tumor effects compared with negative controls. ConclusionDNAJB8-derived peptide is a novel candidate for CSCs-targeting immunotherapy, and mouse models can be used to evaluate CSCs-targeting immunotherapy.

Feasibility study of multiple HLA-class IA restricted peptide vaccines (KRM-19) for metastatic triple negative breast cancer (TNBC).

164 Background: Our previous phase II clinical trial has indicated that the therapeutic selected personalized peptide vaccines (PPV) were effective for boosting anticancer immunity and the immune response after PPV was associated with the clinical outcome as a prognostic factor for metastatic breast cancer (mBC). Based on the data from the PPV studies, we have conducted an early phase II study to evaluate the safety and the efficacy of a new regimen using multiple peptide vaccines (KRM-19) for pts with metastatic TNBC. Methods: KRM-19 consisted of 19 mixed peptides which were chosen from the previously reported 31 PPVs according to their anti-tumor immunologic effect and safety profile for mBC pts. All patients had histologically confirmed measurable ER-PgR-Her2- mBC and their human leukocyte antigen (HLA)-A molecules should be each of -A2, A3, A11, A24, A26, A31, or A33. KRM-19 (19mg/ml) was administrated subcutaneously in order with schedule of every week for a total of 6 doses. The concurrent conventional chemo- and/or endocrine therapy was not permitted for the combination, but was available for post-study treatment. Measurement of peptide-specific cytotoxic T lymphocyte (CTL) and IgG responses were conducted before and after vaccination. Levels of IgG reactive to each of the 19 peptides in the pre- and post-vaccination plasma were measured using the LUMINEX system at every 6 vaccinations. Peptide-specific CTL responses were examined by INF-ɤ ELISPOT. Clinical response was evaluated by RECIST criteria. Results: 10 patients with refractory metastatic TNBC received all 6 vaccines and 10/10 patients experienced Grade 1-2 skin reaction at injection site, 5/10 pts had Grade 2-3 liver function disorder, 3/10 and 1/10 pts had Grade 2 bone marrow suppression and nausea, respectively. The clinical responses were assessed in 8 pts included 1 PR case, 4 SD cases, and 3 PD cases. The evaluation of other clinical and immunologic data is underway. Conclusions: Subcutaneous KRM-19 vaccine administration was safe and resulted in a 12.5% objective response and 62.5% clinical benefit rate in TNBC pts, warranting further larger scale study. Clinical trial information: UMIN000014616.

Identification of HIV protein-derived cytotoxic T lymphocyte (CTL) epitopes for their possible use as synthetic vaccine.

CTL are by far the most important defence mechanisms against viral infections, and many attempts have been undertaken to induce protective CTL in vivo. In order to identify CTL epitopes for their possible use as peptide-vaccine candidates, HIV proteins were screened for peptide sequences which (i) fulfil the binding motif of the HLA-A2.1 molecule, and (ii) are involved in the natural immune response to HIV. From 73 nonameric peptides satisfying the binding motif, 20 peptides were synthesized and their binding to HLA-A2.1 was monitored by measuring the expression of HLA-A2.1 molecules on the cell surface of the mutant cell line T2. To evaluate the involvement in natural HIV infection, strongly binding peptides were used in cytotoxicity assays to assess their capacity to generate a peptide-specific CTL response in vitro. From 20 nonameric peptides synthesized, only five showed strong binding to HLA-A2.1. All five binding peptides had the secondary anchor residues, recently proposed by Ruppert et al. [1] to be required for binding to HLA-A2.1. The discrimination between bound and unbound peptides confirmed the importance of these secondary anchor residues which, beside the known binding motif, may dictate if a peptide can bind to HLA-A2.1 or not. In HIV- donors, no CTL activity against any of the HIV-derived peptides was detectable after a 12-day in vitro stimulation. In contrast, HIV-infected persons showed a cytotoxic response against peptide-labelled target cells, suggesting that they had developed upon HIV infection a cytotoxic immune response against the identified CTL epitopes.

Envelope Determinants of Equine Infectious Anemia Virus Vaccine Protection and the Effects of Sequence Variation on Immune Recognition

A highly effective attenuated equine infectious anemia virus (EIAV) vaccine (EIAV(D9)) capable of protecting 100% of horses from disease induced by a homologous Env challenge strain (EIAV(PV)) was recently tested in ponies to determine the level of protection against divergent Env challenge strains (J. K. Craigo, B. S. Zhang, S. Barnes, T. L. Tagmyer, S. J. Cook, C. J. Issel, and R. C. Montelaro, Proc. Natl. Acad. Sci. USA 104:15105-15110, 2007). An inverse correlation between challenge strain Env variation and vaccine protection from disease was observed. Given the striking differences in protective immunity, we hypothesized that analysis of the humoral and cellular immune responses to the Env protein could reveal potential determinants of vaccine protection. Neutralization activity against the homologous Env or challenge strain-specific Env in immune sera from the vaccinated ponies did not correlate with protection from disease. Cellular analysis with Env peptide pools did not reveal an association with vaccine protection from disease. However, when individual vaccine-specific Env peptides were utilized, eight cytotoxic-T-lymphocyte (CTL) peptides were found to associate closely with vaccine protection. One of these peptides also yielded the only lymphoproliferative response associated with protective immunity. The identified peptides spanned both variable and conserved regions of gp90. Amino acid divergence within the principal neutralization domain and the identified peptides profoundly affected immune recognition, as illustrated by the inability to detect cross-reactive neutralizing antibodies and the observation that certain peptide-specific CTL responses were altered. In addition to identifying potential Env determinants of EIAV vaccine efficacy and demonstrating the profound effects of defined Env variation on immune recognition, these data also illustrate the sensitivity offered by individual peptides compared to peptide pools in measuring cellular immune responses in lentiviral vaccine trials.

The Roles of Wilms' Tumor Gene Peptide-Specific Cytotoxic T Lymphocytes in Immunologic Pathophysiology of Paroxysmal Nocturnal Hemoglobinuria.

It is unclear how a paroxysmal nocturnal hemoglobinuria (PNH) clone expands and bone marrow failure (BMF) occurs in PNH patients, although an immunologic mechanism by human leukocyte antigen (HLA)-restricted cytotoxic T lymphocytes (CTLs) has been suggested. It has been also reported that immunization with HLA-binding peptides of Wilms' tumor gene (WT1) in hematopoietic cells induces a WT1 peptide-specific CTL response, and WT1 RNA is highly expressed in BM mononuclear cells (MNCs) in PNH patients (Shichishima T et al., Blood, 2002). In this study, to clarify some roles of WT1 peptide-specific and HLA-restricted CTLs, the frequencies of peripheral blood (PB) WT1 peptide-specific and HLA-A*2402-restricted CTLs by flow cytometric tetramer analysis and WT1 peptide-stimulated interferon (IFN)-γ-producing MNCs by enzyme-linked immunospot assay in 5 PNH patients with the HLA-A*2402 allele were examined. We also investigated cytotoxicity of WT1 peptide-specific and HLA-A*2402-restricted CTL clone (TAK-1) cells on BM MNCs by 51Cr-releasing assay, colony forming-unit granulocyte-macrophage colony formation of CD34+CD59+ and CD34+CD59− cells, and CD59 expression in viable 7AAD−CD34+ cells by flow cytometry in those patients, and expression of IFN-γ in TAK-1 cells by flow cytometry, after co-incubation of BM cells from them with TAK-1 cells. As controls, 8 healthy volunteers (HV) with the HLA-A*2402 allele and 2 PNH patients and HV without the allele were examined. We found that the frequencies of PB WT1 peptide-specific and HLA-A*2402-restricted CD8+ cells (p<0.005) and WT1 peptide-stimulated IFN-γ-producing MNCs (p<0.02) were significantly higher in PNH patients with the HLA-A*2402 allele (0.255 ± 0.164% and 25.2 ± 15.4 / 5 x 105 cells, respectively) than HV with the allele (0.052 ± 0.025% and 6.6 ± 6.8 / 5 x 105 cells, respectively). In PNH patients or HV, TAK-1 cells significantly killed BM MNCs, suppressed colony formations of CD34+CD59+ and CD34+CD59− cells, and expressed IFN-γ in the absence and presence of a WT1 peptide or only in the presence of the peptide, respectively, in an HLA-A*2402-restricted manner. Reduction rates of colony formation of CD34+CD59− cells from the patients with the HLA-A*2402 allele by TAK-1 cells were significantly less than those of CD34+CD59+ cells in PNH patients, in the absence (38.3 ± 23.0% and 59.0 ± 28.0%, respectively, p<0.01) and presence (74.7 ± 12.8% and 90.6 ± 11.1%, respectively, p<0.002) of a WT1 peptide. After co-incubation of BM MNCs from the patients with TAK-1 cells, proportions of viable CD34+CD59− cells from PNH patients significantly increased in the absence (62.87 ± 27.29%; p<0.01) and presence (62.32 ± 25.73%; p<0.01) of a WT1 peptide compared with those of the controls incubated without TAK-1 cells (52.40 ± 24.58%) in an HLA-A*2402-restricted manner. In conclusion, WT1 peptide-specific and HLA-restricted CTLs may play important roles in the expansion of a PNH clone during immunologic selection and in the occurrence of BMF via IFN-γ in PNH.

Immunological evaluation of personalized peptide vaccination with gemcitabine for advance pancreatic cancer patients

14029 Background: A phase I clinical study was performed to determine safety and immunogenicity of personalized peptide vaccination with gemcitabine (GEM) in advanced pancreatic cancer patients (APC). Methods: Thirteen human histocompatibility leukocyte antigen (HLA)-A24+ or A2+ patients with unresectable (n=10) or recurrent (n=3) pancreatic cancer were treated with GEM plus up to four peptides that were positive for pre-vaccination measurement of peptide-specific IgG antibodies and/or cytotoxic T lymphocyte (CTL) precursors in the circulation (personalized peptide vaccine). GEM was administered at 1000mg/m2 as a 30-min intravenous infusion once a week for three week, followed by 1 week of rest. All patients were treated on outpatient basis. The cycle was repeated every 8 weeks. Results: Peptide doses of vaccination per week were planned as follows: level 1, 1mg; level 2, 2mg; and level 3, 3mg. The main grade 3 toxicities observed during the first cycle in each level were neutropenia (15%), anemia (23%) and thrombocytopenia (15%). No significant differences in the toxicities were found between each level. There was no dose limiting toxicity (DLT) observed in each level. Augmentation of peptide-specific CTL responses in the post-vaccination peripheral blood mononuclear cells was observed in each level, while increased titer of peptide-specific IgG antibodies was observed in the post-vaccination plasma in level 2 and level 3. Applicable responses were no complete response, two partial responses (15%), and 7 stable diseases (55%). Nevertheless 7 patients of them (54%) were under the second-line chemotherapy, disease control rate was 70%, the median TTP (time to progression) was 18.5 weeks and the MST (median survival time) was 7.6 months in this study. Conclusions: The combination therapy of personalized peptide vaccination with GEM for APC patients is feasible and safe. Because of positive immune responses under a full dose of GEM, the peptide vaccination of 3 mg is recommended. No significant financial relationships to disclose.

Induction of cytotoxic T-lymphocytes by electroporation-enhanced needle-free skin immunization

A needle-free method based on transcutaneous electroporation is described for delivering peptide vaccines. The K b-binding OVA-peptide SIINFEKL was used as an example to induce the peptide-specific cytotoxic T-lymphocytes (CTL) response in mice. A saturated anionic lipid was added during electroporation, and post-pulse electroosmosis was applied to enhance the vaccine delivery. Electroporation was found to stimulate the exodus of Langerhans cells (LC) from the skin. The peptide transported into and through murine skin was measured using a Franz diffusion apparatus. Most peptide was retained in the skin rather than passing through the skin in the process. The peptide was delivered to the dorsal skin of mice by in vivo electroporation. An electroporation-transportable oligonucleotide with CpG motif was used as adjuvant. The efficacy of peptide delivery was comparable to that of intradermally injected with Freund's complete adjuvant (FCA). Peptide-specific CTL response to the vaccine delivered by needle-free electroporation/electroosmosis was equivalent to that delivered by intradermal injection, as determined by production of the peptide-specific IFN-γ in ELISPOT assay.

Identification of an epitope from the epithelial cell adhesion molecule eliciting HLA‐A*2402‐restricted cytotoxic T‐lymphocyte responses

Because the epithelial cell adhesion molecule (Ep-CAM) is expressed in almost all carcinomas and human leucocyte antigen (HLA)-A*2402 is the most common allele in many ethnic groups, including Japanese, the identification of peptide sequences, which elicit HLA-A*2402-restricted Ep-CAM-specific cytotoxic T-lymphocyte (CTL) responses, would facilitate specific immunotherapy for various histological types of carcinomas. An epitope was identified through the following steps: (i) computer-based epitope prediction from the amino acid sequence of Ep-CAM, (ii) major histocompatibility complex (MHC) stabilization assay to determine the affinity of the predicted peptide with HLA-A*2402 molecules, (iii) stimulation of CD8+ T cells with peptide-pulsed dendritic cells and (iv) testing the CTL specificity by means of enzyme-linked immunospot (ELISPOT) assays, CTL assays and MHC/peptide-tetramer staining. Peripheral CD8+ T cells of four of five healthy donors after three rounds of stimulation with the peptide Ep-CAM173-181 (RYQLDPKFI) secreted interferon-gamma in ELISPOT assays when exposed to the peptide. A CTL clone specific to the peptide efficiently lysed Ep-CAM-expressing cancer cell lines in an HLA-A*2402-restricted fashion. Endogenous processing and presentation of the peptide in a lung cancer cell line were confirmed by means of cold target inhibition assays. The CTL clone was also lytic to normal bronchial epithelial cells but to a lesser extent at low effector: target ratios. All these data suggest that the peptide-specific CTL responses may play some roles both in anti-cancer and autoimmune reactions. The peptide should prove useful to study anti-Ep-CAM CTL responses among population possessing HLA-A*2402.

Self-peptides with intermediate capacity to bind and stabilize MHC class I molecules may be immunogenic.

Thirty self-peptides were selected on the basis of their predicted binding to H-2b molecules. The binding of peptides was ascertained experimentally by biochemical (KD measurements) and cellular [major histocompatibility complex class I (MHC-I) stabilization] assays. A weak, but significant, correlation between KD measurements and MHC-I stabilization was observed. Mice (n = 99) were immunized with individual peptides. Twenty-eight peptides were found to induce peptide-specific cytotoxic activity, and a total of 84 mice developed significant cytotoxic T lymphocyte (CTL) responses after immunization. Only one of the 21 mice immunized with high-affinity peptides developed a peptide-specific CTL response of 29 lytic units per 106 splenocytes, whereas 11 of the 42 mice immunized with intermediate-affinity peptides developed peptide-specific CTL responses at this level (P < 0.05). These observations suggest the absence of tolerance towards most MHC-I-restricted self-peptides and that strong antiself immunity can be generated preferentially towards self-peptides with an intermediate affinity for MHC-I. These data should be considered in the design of tumour vaccines based on MHC-I-binding self-peptides.

Dendritic cell KLH loading requirements for efficient CD4 + T-cell priming and help to peptide-specific cytotoxic T-cell response, in view of potential use in cancer vaccines

This study focuses on a Keyhole Limpet Hemocyanin (KLH) adjuvant strategy to augment efficacy of dendritic cell-based vaccines that use class I-restricted peptides. Requirements for loading dendritic cells (DC) with KLH were first determined in order to optimally prime CD4 + T cells. These KLH-loaded cells were pulsed with antigenic peptide and cultured with T cells to induce a cytotoxic T lymphocyte (CTL) response against the peptide. Such a concomitant presentation of KLH and peptide by the same DC strongly augmented the peptide-specific CTL response, as compared to the response induced by DC pulsed with the peptide alone. This adjuvant effect was more pronounced for poorly immunogenic antigens. The use of optimised peptide and KLH-loaded DC may improve the efficacy of therapeutic anti-tumour peptide vaccination.

Vigorous Peripheral Blood Cytotoxic T Cell Response during the Acute Phase of Hepatitis C Virus Infection

After infection by hepatitis C virus (HCV), a minority of patients develop acute symptomatic disease and some of them are able to clear the virus. In this study, we analyzed peripheral blood mononuclear cells from nine patients with acute symptomatic disease with respect to their cytotoxic T lymphocyte (CTL) response using a panel of HCV-derived peptides in a semiquantitative secondary in vitro culture system. We could detect early CTL responses in 67% of these patients. The CTL responses were directed against multiple viral epitopes, in particular within the structural (core 2–9, core 35–44, core 131–140, and core 178–187) and nonstructural regions of the virus (NS3 1073–1081, NS3 1406–1415, NS4 1807–1816, NS5 2252–2260, and NS5B 2794–2802). We compared the CTL responses displayed by recently and chronically infected HLA-A2-positive patients. Virus-specific CTLs were detectable in chronic carriers but the percentage of positive peptide-specific CTL responses was significantly higher in recently infected patients (P = 0.002). Follow-up of recently infected patients during subsequent disease development showed a significant decrease in the values and proportions of positive peptide-specific CTL responses (P = 0.002 and 0.013, respectively). Patients with limited viral replication exhibited significantly more vigorous early responses (P = 0.024). These data suggest a protective role for the early antiviral CTL response in HCV infection.

A subdominant CD8(+) cytotoxic T lymphocyte (CTL) epitope from the Plasmodium yoelii circumsporozoite protein induces CTLs that eliminate infected hepatocytes from culture.

Previous studies indicated that the Plasmodium yoelii circumsporozoite protein (PyCSP) 57-70 region elicits T cells capable of eliminating infected hepatocytes in vitro. Herein, we report that the PyCSP58-67 sequence contains an H-2(d) binding motif, which binds purified K(d) molecules in vitro with low affinity (3, 267 nM) and encodes an H-2(d)-restricted cytotoxic T lymphocyte (CTL) epitope. Immunization of BALB/c mice with three doses of a multiple antigen peptide (MAP) construct containing four branches of amino acids 57 to 70 linked to a lysine-glycine core [MAP4(PyCSP57-70)] and Lipofectin as the adjuvant induced both T-cell proliferation and a peptide-specific CTL response that was PyCSP59-67 specific, H-2(d) restricted, and CD8(+) T cell dependent. Immunization with either DNA encoding the PyCSP or irradiated sporozoites demonstrated that this CTL epitope is subdominant since it is not recognized in the context of whole CSP immunization. The biological relevance of this CTL response was underlined by the demonstration that it could mediate genetically restricted, CD8(+)- and nitric-oxide-dependent elimination of infected hepatocytes in vitro, as well as partial protection of BALB/c mice against sporozoite challenge. These findings indicate that subdominant epitopes with low major histocompatibility complex affinity can be used to engineer epitope-based vaccines and have implications for the selection of epitopes for subunit-based vaccines.

Identification of H-2Kb-restricted T-cell epitopes within the nucleocapsid protein of Hantaan virus and establishment of cytotoxic T-cell clonesThis work was performed at Korea Advanced Institute of Science and Technology and Mogam Biotech Research Institute.

Although neutralizing antibodies against Hantaan virus (HTV) can protect hosts from viral infection, T-cell responses to HTV are also important in host defense against HTV. However, much less is known about cytotoxic T lymphocyte (CTL) responses to HTV. To identify CTL epitopes in the HTV nucleocapsid protein (NP), we selected 7 H-2Kb-motif-fitting peptides. Of these peptides, 3 peptides (NP3, NP4, and NP7) were recognized by CTL responses derived from HTV-immunized mouse splenocytes. NP3 and NP4 peptides were also recognized by HTV-immunized splenocytes after secondary in vitro stimulation with the relevant peptide, but NP7 could not be recognized after in vitro stimulation. These results agree well with peptide immunization studies showing that peptide-specific CTL responses could be induced with NP3 and NP4 but not with NP7 peptide. Furthermore, CTL activity assay using targets, prepared to express the antigen (NP) endogenously, demonstrated that NP3 and NP4 peptides could be presented endogenously. CTL elicited with NP4 peptide retained some cross-reactivity and was difficult to long-term culture. However, NP3-elicited CTL was very specific for NP3 peptide and was stable enough to be cloned. Among many CTL lines elicited with HTV or HTV NP peptides, 6 NP3-specific CTL clones were established and have been maintained more than 2 years. All 6 CTL clones were characterized to be CD3+, CD4−, CD8+, CD25+, CD62L−, and NK1.1−, and to use TCR Vβ6. This preferential usage of TCR Vβ6 indicates that TCR Vβ6 regions are important for recognition of the HTV NP3 epitope (NP221–228, SVIGFLAL) on H-2Kb molecule. Our data demonstrate the definition of mouse CTL epitopes in HTV and the generation of HTV-specific mouse CTL clones. J. Med. Virol. 60:189–199, 2000. © 2000 Wiley-Liss, Inc.

Identification of H-2Kb-restricted T-cell epitopes within the nucleocapsid protein of Hantaan virus and establishment of cytotoxic T-cell clones

Although neutralizing antibodies against Hantaan virus (HTV) can protect hosts from viral infection, T-cell responses to HTV are also important in host defense against HTV. However, much less is known about cytotoxic T lymphocyte (CTL) responses to HTV. To identify CTL epitopes in the HTV nucleocapsid protein (NP), we selected 7 H-2K(b)-motif-fitting peptides. Of these peptides, 3 peptides (NP3, NP4, and NP7) were recognized by CTL responses derived from HTV-immunized mouse splenocytes. NP3 and NP4 peptides were also recognized by HTV-immunized splenocytes after secondary in vitro stimulation with the relevant peptide, but NP7 could not be recognized after in vitro stimulation. These results agree well with peptide immunization studies showing that peptide-specific CTL responses could be induced with NP3 and NP4 but not with NP7 peptide. Furthermore, CTL activity assay using targets, prepared to express the antigen (NP) endogenously, demonstrated that NP3 and NP4 peptides could be presented endogenously. CTL elicited with NP4 peptide retained some cross-reactivity and was difficult to long-term culture. However, NP3-elicited CTL was very specific for NP3 peptide and was stable enough to be cloned. Among many CTL lines elicited with HTV or HTV NP peptides, 6 NP3-specific CTL clones were established and have been maintained more than 2 years. All 6 CTL clones were characterized to be CD3+, CD4-, CD8+, CD25+, CD62L-, and NK1.1-, and to use TCR Vbeta6. This preferential usage of TCR Vbeta6 indicates that TCR Vbeta6 regions are important for recognition of the HTV NP3 epitope (NP221-228, SVIGFLAL) on H-2K(b) molecule. Our data demonstrate the definition of mouse CTL epitopes in HTV and the generation of HTV-specific mouse CTL clones.

The memory cytotoxic T-lymphocyte (CTL) response to human cytomegalovirus infection contains individual peptide-specific CTL clones that have undergone extensive expansion in vivo.

Human cytomegalovirus (HCMV)-specific CD8(+) cytotoxic T lymphocytes (CTL) appear to play an important role in the control of virus replication and in protection against HCMV-related disease. We have previously reported high frequencies of memory CTL precursors (CTLp) specific to the HCMV tegument protein pp65 in the peripheral blood of healthy virus carriers. In some individuals, the CTL response to this protein is focused on only a single epitope, whereas in other virus carriers CTL recognized multiple epitopes which we identified by using synthetic peptides. We have analyzed the clonal composition of the memory CTL response to four of these pp65 epitopes by sequencing the T-cell receptors (TCR) of multiple independently derived epitope-specific CTL clones, which were derived by formal single-cell cloning or from clonal CTL microcultures. In all cases, we have observed a high degree of clonal focusing: the majority of CTL clones specific to a defined pp65 peptide from any one virus carrier use only one or two different TCRs at the level of the nucleotide sequence. Among virus carriers who have the same major histocompatibility complex (MHC) class I allele, we observed that CTL from different donors that recognize the same peptide-MHC complex often used the same Vbeta segment, although other TCR gene segments and CDR3 length were not in general conserved. We have also examined the clonal composition of CTL specific to pp65 peptides in asymptomatic human immunodeficiency virus-infected individuals. We have observed a similarly focused peptide-specific CTL response. Thus, the large population of circulating HCMV peptide-specific memory CTLp in virus carriers in fact contains individual CTL clones that have undergone extensive clonal expansion in vivo.

Anthrax toxin as a molecular tool for stimulation of cytotoxic T lymphocytes: disulfide-linked epitopes, multiple injections, and role of CD4(+) cells.

We have previously demonstrated that anthrax toxin-derived proteins, protective antigen (PA) and the amino-terminal portion of lethal factor (LFn), can be used in combination to deliver heterologous molecules to the cytosol of mammalian cells. In this study we examined the ability of an LFn-peptide disulfide-linked heterodimer to prime cytotoxic T lymphocytes (CTL) in the presence of PA. A mutant of LFn that contains a carboxy-terminal reactive cysteine was generated. This form of LFn could be oxidized with a synthetic cysteine containing peptide to form a heterodimer of the protein and peptide. Mice injected with the heterodimer plus PA mounted a peptide-specific CTL response, indicating that this molecule functioned similarly to the genetically fused forms used previously. We also report the results of an analysis of two aspects of this system important for the development of experimental vaccines. First, CD4 knockout mice were unable to generate a CTL response when treated with PA plus an LFn-epitope fusion protein, suggesting that CD4(+) helper responses are essential for stimulating specific CTL with the PA-LFn system. Second, we now show that primary injection with this system does not generate any detectable antibody response to the vaccine components and that prior immunization has no effect on priming a CTL response to an unrelated epitope upon subsequent injection.

The adjuvant effect of a non-toxic mutant of heat-labile enterotoxin of Escherichia coli for the induction of measles virus-specific CTL responses after intranasal co-immunization with a synthetic peptide.

The intranasal route has been shown to be effective for immunization. However, immunization via this route may require the use of potent and safe adjuvant. The construction of non-toxic mutants of heat labile enterotoxin of Escherichia coli (LT), which is a potent mucosal adjuvant, is a major breakthrough for the development of mucosal vaccines. In this study we have assessed the ability of an LT mutant (LTK63) to act as an adjuvant following intranasal co-immunization with a peptide corresponding to a measles virus cytotoxic T lymphocyte (CTL) epitope. LTK63 was more effective at potentiating the in vivo induction of peptide-specific and measles virus-specific CTL responses than was administration of the peptide in saline. A concentration of 10 micrograms/dose of LTK63 was found to be the most effective in potentiating the in vivo priming of peptide-specific and measles virus-specific CTL responses. These findings highlight the potential of the non-toxic mutant of LT as a safe mucosal adjuvant for use in humans.

Dendritic cells as carriers for a cytotoxic T-lymphocyte epitope-based peptide vaccine in protection against a human papillomavirus type 16-induced tumor.

Previously we have demonstrated that two doses of a cytotoxic T lymphocyte (CTL) epitope-based peptide vaccine of human papillomavirus type 16 (HPV 16) E7 aa 49-57 elicit protection against outgrowth of HPV 16-transformed tumor cells (C3 cells) in B6 mice. Incomplete Freund's adjuvant (IFA), as a carrier, was used to induce this response. To avoid side effects caused by the use of external adjuvants, we have now investigated the effectiveness of highly purified spleen dendritic cells (DC) that efficiently induce primary peptide-specific CTL responses in vitro, as physiological carriers for the HPV 16 E7(49-57) peptide-based vaccine. This is the first report demonstrating that mice immunized once i.v. with syngeneic spleen DCs pulsed with the HPV 16 E7(49-57) peptide in vitro were protected against the outgrowth of C3 tumor cells. In comparison, a single injection of the HPV 16 E7(49-57) peptide in IFA s.c. also resulted in effective induction of tumor-specific immunity in vivo. In both immunization protocols, protective tumor-specific immunity was mediated by CTL that recognized HPV 16 E7(49-57) peptide-pulsed target cells, as well as C3 cells in vitro. Peptide affinity of the CTL induced by both protocols was similar. Thus under the conditions tested, a single injection of spleen DCs pulsed with a CTL epitope-based peptide in vitro elicited tumor-antigen-specific CTL in vivo, which protected mice against a subsequent tumor inoculation. This result indicates that spleen DCs pulsed with a CTL epitope can effectively serve as a tumor-specific vaccine.

Cytotoxic T lymphocyte response to hepatitis C virus-derived peptides containing the HLA A2.1 binding motif.

The HLA class I-restricted cytotoxic T lymphocyte (CTL) response is a major defense mechanism in viral infections. It has been suggested that the CTL response may contribute to viral clearance and liver cell injury during hepatitis C virus (HCV) infection. To test this hypothesis requires an understanding of the characteristics of HCV-specific cytotoxic effector cells and identification of the target antigens to which they respond. To begin this process we stimulated peripheral blood mononuclear cells (PBMC) from a group of HLA-A2 positive patients with chronic hepatitis C with a panel of 130 HCV-derived peptides containing the HLA-A2 binding motif. Effector cells were tested for their capacity to lyse HLA-A2-matched target cells that were either sensitized with peptide or infected with a vaccinia virus construct containing HCV sequences. Using this approach we have identified nine immunogenic peptides in HCV, three of which are derived from the putative core protein, three from the nonstructural (NS) 3 domain, two from NS4 and one from NS5. Selected responses were shown to be HLA-A2 restricted, mediated by CD8+ T cells and to recognize endogenously synthesized viral antigen. Unexpectedly, peptide-specific CTL responses could also be induced in sero-negative individuals, suggesting in vitro activation of naive CTL precursors. The precursor frequency of peptide-specific CTL was 10 to 100-fold higher in infected patients compared to uninfected controls, and the responses were greatly diminished by removal of CD45 RO+ (memory) T cells. Further quantitative studies are clearly required to establish whether a correlation exists between the HCV-specific CTL response and the clinical course of this disease. Definition of the molecular targets of the human CTL response to HCV creates this opportunity, and may also contribute to the development of a T cell-based HCV vaccine.