Rod Dunbar

Mage-3 and Influenza-Matrix Peptide-Specific Cytotoxic T Cells Are Inducible in Terminal Stage HLA-A2.1+ Melanoma Patients by Mature Monocyte-Derived Dendritic Cells

Dendritic cell (DC) vaccination, albeit still in an early stage, is a promising strategy to induce immunity to cancer. We explored whether DC can expand Ag-specific CD8+ T cells even in far-advanced stage IV melanoma patients. We found that three to five biweekly vaccinations of mature, monocyte-derived DC (three vaccinations of 6 × 106 s.c. followed by two i.v. ones of 6 and 12 × 106, respectively) pulsed with Mage-3A2.1 tumor and influenza matrix A2.1-positive control peptides as well as the recall Ag tetanus toxoid (in three of eight patients) generated in all eight patients Ag-specific effector CD8+ T cells that were detectable in blood directly ex vivo. This is the first time that active, melanoma peptide-specific, IFN-γ-producing, effector CD8+ T cells have been reliably observed in patients vaccinated with melanoma Ags. Therefore, our DC vaccination strategy performs an adjuvant role and encourages further optimization of this new immunization approach.

Apoptotic cells overexpress vinculin and induce vinculin-specific cytotoxic T-cell cross-priming.

Here we show that apoptotic cells overexpress vinculin and are ingested by dendritic cells, which subsequently cross-prime vinculin-specific cytotoxic T lymphocytes (CTLs). Successful cross-priming requires that the apoptotic cells provide maturation signals to dendritic cells through CD40–CD40 ligand (CD40L) interactions. If apoptotic cells are CD40L−, the help of a third T cell is needed for priming, indicating a regulatory role for apoptotic cells in determining priming or tolerance. Vinculin-specific CTL priming is also related to apoptosis in vivo, given that in HIV-seropositive individuals, the frequency of specific CTLs depends on the proportion of peripheral CD40L+ apoptotic cells.

A case of primary immunodeficiency due to a defect of the major histocompatibility gene complex class I processing and presentation pathway

INTRODUCTION We report a case of primary immunodeficiency due to a defect of the TAP transporter, an heterodimeric complex which controls the expression of HLA class I molecule by delivering peptides from the cytosol into the lumen of the endoplasmic reticulum. Since childhood, the 36 year old female suffered from recurrent sinusitis/bronchitis. She later developed bronchiectasis and destructive nasal epitheloid granulomata in conjunction with a generalized vasculitic syndrome that did not improve upon immunosuppression and antibiotics. METHODS The class I monomorphic W6/32 was used for cell surface staining and immunoprecipitation of MHC class I molecules. Peptide transport assay was carried out in semi-permeabilized cells with iodinated peptides. Antigen presentation experiments were performed using chromium 51 labelled patient B cell line and EBV specific CTL. TAP1 and TAP2 specific antibodies were used for Western blotting and immunoprecipitation of the TAP complex. RESULTS AND CONCLUSIONS A severe reduction of MHC class I molecules at the cell surface of the B-cell lines was observed, whereas MHC class II expression was not altered. Isoelectric focusing of metabolically labelled MHC class I molecules revealed that class I heavy chains remain unsialylated, consistent with a block of TAP dependent peptide translocation. These conclusions were confirmed by further experiments showing that peptide translocation was completely abolished. We also demonstrated that presentation of viral antigens through endogenous class I molecules was severely impaired. Immunoprecipitation and Western blotting of TAP1/2 complex showed that TAP2 was not detectable. Further, experiments are in progress to identify the site of the mutation.

The use of HLA class I tetramers to design a vaccination strategy for melanoma patients

Summary: Progress in human tumor immunology has recently been accelerated by new assays for antigen‐specific cytotoxic T lymphocytes (CTLs). We have used tetrameric MHC class I complexes (tetramers) to study melanoma‐specific CTLs both in vivo and in vitro, and have utilized the results to optimize vaccination strategies for patients. Tetramers have provided some of the best evidence to date that CTL responses against melanoma antigens arise spontaneously in patients. However, CTL responses to common (nonmutated) melanoma epitopes are generally weak or localized, and occur mostly in advanced metastatic disease, hence justifying early immunotherapeutic approaches. These observations led us to design a polyvalent vaccine construct for early administration to melanoma patients at high risk of progression. To compare possible vaccination protocols, we encoded this construct in several different vectors, and developed novel tetramers to track responses to the human melanoma epitopes in transgenic mice. Priming and boosting with the same poly‐epitope construct encoded in heterologous vectors led to the expansion of CTLs with a single dominant specificity. Separating the antigens for independent presentation by antigen‐presenting cells reversed the effect of immunodominance and induced a powerful polyvalent CTL response. These results provide important pointers for future vaccination trials, and tetramers will form an important tool in the immunomonitoring of these clinical studies.