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BACKGROUND: The interferon-gamma (IFN-gamma) ELISPOT assay is one of the most useful techniques for immunological monitoring of cancer vaccine trials and has gained increased application as a measure of specific T cell activation. However, it does not assess cell-mediated cytotoxicity directly as IFN-gamma secretion is not limited to only cytolytic cells. Granzyme B (GrB) is a key mediator of target cell death via the granule-mediated pathway. Therefore, the release of GrB by cytolytic lymphocytes upon effector-target interaction may be a more specific indicator of CTL and NK cytotoxic ability than IFN-gamma secretion. METHODS: We assessed whether the GrB ELISPOT assay is a viable alternative to the 51Cr-release and IFN-gamma ELISPOT assays for measuring antigen-specific CTL cytotoxicity. Direct comparisons between the three assays were made using human CTL cell lines (alphaEN-EBV and alphaJY) and an in vitro stimulated anti-Flu matrix peptide (FMP)-specific CTL. RESULTS: When the GrB ELISPOT was directly compared to the IFN-gamma ELISPOT and 51Cr-release assays, excellent cross-correlation between all three assays was shown. However, measurable IFN-gamma secretion in the ELISPOT assay was observed only after 1 hour of incubation and cytotoxicity assessed via the 51Cr-release assay after 4 hours, whereas GrB secretion was detectable within 10 min of effector-target contact with significant secretion observed after 1 h. Titration studies demonstrated a strong correlation between the number of effector cells and GrB spots per well. Irrelevant targets or antigens did not induce significant GrB secretion. Additionally, GrB secretion was abrogated when CTL cultures were depleted of CD8+ cells. CONCLUSION: Our findings demonstrate that the GrB ELISPOT assay is a superior alternative to the 51Cr-release assay since it is significantly more sensitive and provides an estimation of cytotoxic effector cell frequency. Additionally, unlike the IFN-gamma ELISPOT assay, the GrB ELISPOT directly measures the release of a cytotolytic protein. Detection of low frequency tumor-specific CTL and their specific effector functions can provide valuable insight with regards to immunological responses.
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BACKGROUND: The desired outcome of cancer vaccination is to induce a potent T cell response which can specifically recognize and eliminate autologous tumor cells in vivo. Accordingly, immunological assays that demonstrate recognition of native tumor cells (tumor-specific) may be more clinically relevant than assays that demonstrate recognition of tumor protein or peptide (antigen-specific). METHODS: Towards this goal, we adapted the IFN-gamma ELISPOT assay to measure immune responses against autologous primary tumor cells in vaccinated cancer patients. As a model system to develop the assay, we utilized peripheral blood mononuclear cells (PBMC) directly isolated from follicular lymphoma patients vaccinated with tumor-derived idiotype protein. RESULTS: After optimizing several variables, we demonstrated that the modified IFN-gamma ELISPOT assay could be used to reliably and reproducibly determine the tumor-reactive T cell frequency in the PBMC of these patients. The precursor frequency of tumor-reactive T cells was significantly higher in the postvaccine PBMC, compared with prevaccine samples in all patients tested. Furthermore, the specificity of these T cells was established by the lack of reactivity against autologous normal B cells. CONCLUSIONS: These results demonstrate the feasibility of quantitating tumor-specific T cell responses when autologous, primary tumor cells are available as targets.
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Chikungunya virus, transmitted by mosquitoes to man, causes an acute illness characterized by fever, rash and striking joint symptoms. US Military investigators developed, manufactured at The Salk Institute-Government Services Division (TSI-GSD), and tested the live, attenuated Chikungunya Vaccine TSI-GSD-218. The manufacturing facility stopped production in 1994. The Chikungunya Vaccine TSI-GSD-218 development effort was terminated in 1998, and materials were archived. In 2005, an alarming outbreak of chikungunya disease began in Africa and spread to islands in the Indian Ocean and throughout much of Asia. Abrupt epidemics with high attack rates and serious, even fatal, complications were reported, and travelers carried the virus to Europe and the Americas. In response to urgent requests, the US Military offered assistance by providing non-exclusive access to the previously stored vaccine production seed materials, bulk vaccine, regulatory documentation, and reports of previous clinical trials. Five companies requested technology transfers. This experience provides lessons about epidemiological unpredictability, preparedness, vaccine manufacturing, the potential global importance of vaccine seed materials and the advisability of a global strategic plan. Consideration should be given to banking of vaccine production seeds, cell substrates, and manufacturing instructions. In view of the manufacturability, attenuation, and immunogenicity of Chikungunya Vaccine TSI-GSD-218, authorities may wish to consider this product as a possible candidate itself, as a comparator vaccine to improve upon, as a seed for inactivated vaccine, or as a source of virus or antigen for neutralization assays or immunoassays.