Resistance against natural killer cell cytotoxicity: analysis of mechanisms.

Target cell resistance against natural killer (NK) cell-mediated cytotoxicity obstructs NK cell-based immunotherapy of leukaemia. Several mechanisms of resistance have been described. Because of lack of simple assays for analysing these mechanisms, their relative impact on a given effector-target pair is mostly unknown. We here analysed the combination of the Granzyme B (GrB) enzyme-linked immunospot assay (ELISPOT) for the assessment of NK cell reactivity and cytotoxicity assays to estimate target cell escape mechanisms. Target cell recognition failure leads to negative GrB ELISPOT results, whereas target cell resistance shows positive GrB ELISPOT results in the absence of cytotoxicity. We confronted NK cells with the sensitive target cell line K562, and with the resistant cell lines ML2, SupB15 and Raji. ML2 cells sufficiently activated GrB-release whilst being resistant against cytotoxic granules of NK cells. Partial resistance of Raji results from the interaction of HLA class I with inhibitory killer immunglobulin-like receptors (KIR) on the NK cells. Failure of target recognition by HLA class I-KIR interaction, lacking ligands to stimulatory NK cell receptors and partial resistance to cytotoxic granules all contributed to resistance of SupB15. In conclusion, revealing the mechanisms of resistance against NK cell-mediated cytotoxicity may allow improving the results of NK-based immunotherapy.

Identification of peptide vaccine candidates for prostate cancer patients with HLA-A3 supertype alleles.

PURPOSE: The peptide vaccine candidates identified to date have been focused on the HLA-A2 and HLA-A24 alleles. The HLA-A11, HLA-A31, and HLA-A33 alleles share binding motifs and belong to an HLA-A3 supertype family. In this study, we attempted to identify CTL-directed peptide candidates, derived from prostate-related antigens and shared by HLA-A11+, HLA-A31+, and HLA-A33+ prostate cancer patients. EXPERIMENTAL DESIGN: Based on the binding motif to the HLA-A3 supertype alleles, 42 peptides were prepared from prostate-specific antigen (PSA), prostate-specific membrane antigen (PSMA), and prostatic acid phosphatase (PAP). These peptides were first screened for their ability to be recognized by immunoglobulin G (IgG) of prostate cancer patients and subsequently for the potential to induce peptide-specific and prostate cancer-reactive CTLs from peripheral blood mononuclear cells (PBMC) of cancer patients with the HLA-A11, HLA-A31, and HLA-A33 alleles. RESULTS: Five peptide candidates, including the PSA(16-24), PAP(155-163), PAP(248-257), PSMA(207-215), and PSMA(431-440) peptides, were frequently recognized by IgGs of prostate cancer patients. These peptides efficiently induced peptide-specific and prostate cancer-reactive CTLs from PBMCs of cancer patients with the HLA-A11, HLA-A31, and HLA-A33 alleles. Antibody blocking and cold inhibition experiments revealed that the HLA-A3 supertype-restricted cytotoxicity against prostate cancer cells could be ascribed to peptide-specific and CD8+ T cells. CONCLUSIONS: We identified prostate-related antigen-derived new peptide candidates for HLA-A11-, HLA-A31-, and HLA-A33-positive prostate cancer patients. This information could facilitate the development of a peptide-based anticancer vaccine for patients with alleles other than HLA-A2 and HLA-A24.

Identification of peptide vaccine candidates sharing among HLA-A3+, -A11+, -A31+, and -A33+ cancer patients.

PURPOSE: Only a few studies have been reported on CTL epitope peptides restricted with alleles other than HLA-A2 and -A24. The HLA-A11, -A31, and -A33 alleles share similar binding motifs with HLA-A3 and -A68 alleles, and, thus, are classified as an HLA-A3 supertype. This study tried to identify CTL epitope peptides as vaccine candidates sharing by HLA-A3(+), -A11(+), -A31(+), and -A33(+) cancer patients. EXPERIMENTAL DESIGN: Seven peptides possessing the ability to induce HLA-A31-restricted and tumor-reactive CTLs were examined for their ability to induce HLA-A3-, -A11-, and -A33-restricted and tumor-reactive CTLs from peripheral blood mononuclear cells (PBMCs) of 18 epithelial cancer patients. The five reference peptides all have the ability to induce CTL activity restricted with one of the HLA-A3 supertypes, and, thus, were also examined as positive controls. RESULTS: Three peptides (2 from beta-tublin5- and 1 from CGI37-derived peptides) induced tumor-reactive CTLs in PBMCs of HLA-A3(+), -A11(+), and -A33(+) cancer patients with various frequencies (17-50%). One RLI- or KIAA0036-derived peptide induced tumor-reactive CTLs in PBMCs of HLA-A3(+) and -A11(+) or HLA-A11(+) and -A33(+) cancer patients also with various frequencies (22-67%), respectively, whereas the other peptide induced CTL activity in only HLA-A33(+) patients. Among the five reference peptides tested, one peptide, TRP2-197, induced CTL activity in both HLA-A11(+)- and -A33(+)-restricted manners. CONCLUSIONS: We identified new peptide vaccine candidates for HLA-A3, -A11, -A31, and -A33 positive cancer patients. This study may facilitate the development of both basic and clinical studies of peptide-based immunotherapy for cancer patients with other alleles of HLA-A2 and -A24.

Intrinsic genetic instability of normal human lymphocytes and its implication for loss of heterozygosity.

A combination of flow cytometry and microsatellite analysis was used to investigate loss of expression of HLA-A and/or HLA-B alleles and concurrent LOH at polymorphic chromosome 6 loci both in freshly isolated lymphocytes (in vivo mutations) and in lymphocytes cultured ex vivo. The fraction of in vivo mutants that showed LOH at 6p appeared to vary from 0%-49% for various donors. During culturing ex vivo, HLA-A(-) cells arose at a high rate and showed simultaneous loss of expression at the linked HLA-B locus. Up to 90% of the ex vivo arisen HLA-A2(-) cell population showed LOH of multiple 6p markers, and 50% had lost heterozygosity at 6q. This ex vivo spectrum resembles that found in HLA-A2 mutants obtained from lymphoblastoid cells. The HLA-A2 mutants present in vivo may reflect only a small fraction of the mutants that can be detected ex vivo. In normal lymphocytes, in vivo only mitotic recombination appears to be sustained, indicating the importance of this mechanism for tumor initiation in normal cells. Although mutations resulting in LOH at both chromosome 6 arms were shown to result in nonviable cells in normal lymphocytes, they have been shown to result in viable mutants in lymphoblastoid cells. We hypothesize that these types of mutations also occur in vivo but only survive in cells that already harbor a mutated genetic background. In light of the high rate at which these types of mutations occur, they may contribute to cancer progression.

HLA-B8 and HLA-A3 coexpressed with HLA-B8 are associated with a reduced risk of the development of chronic myeloid leukemia. The Chronic Leukemia Working Party of the EBMT.

Chronic myeloid leukemia (CML) is characterized by the chromosomal translocation t(9;22) resulting in the chimeric bcr-abl oncogene that encodes the P210 fusion protein, which contains a unique amino acid sequence. If peptides derived from the leukemia-specific part of P210 are expressed in HLA molecules on the cell membrane of leukemic cells, an immunological response may occur. Recent studies using synthetic peptides identical to the bcr-abl fusion region showed that some peptides are capable of binding to HLA-A3, -A11, and -B8 molecules. Cytotoxic T-cell responses have been induced against bcr-abl-derived synthetic peptides bound to HLA-A3 and -B8. We hypothesized that if antigen processing of the P210 fusion protein leads to presentation of peptides from the fusion region by major histocompatibility complex (MHC) molecules in vivo, this may be reflected in a diminished incidence of CML in individuals expressing HLA-A3, -A11, or -B8. Consequently, lower frequencies of these antigens would be expected in patients with CML compared with unaffected individuals. A case-control study and a meta-analysis were performed to test this hypothesis. The multicenter case-control study compared patients with CML from the data base of the European Group for Blood and Marrow Transplantation (EBMT) with unaffected individuals from the registry of Bone Marrow Donors Worldwide. Patients and controls were matched per country. The meta-analysis consisted of five studies reported in the literature. The multicenter case-control study consisting of 1,899 patients and 512, 363 bone marrow donors as controls yielded odds ratios (ORs) of 0.90 (95% confidence interval [CI], 0.80 to 1.00) for HLA-A3, 1.16 (95% CI, 1.02 to 1.33) for HLA-A11, and an OR of 0.73 (95% CI, 0.65 to 0. 82) for HLA-B8. Coexpression of HLA-A3 and HLA-B8 gave an OR of 0.51 (95% CI, 0.40 to 0.67). This can be translated in a protective effect of 27% for HLA-B8, 10% for HLA-A3, and 49% protection for the combination of HLA-A3 and HLA-B8. The meta-analysis comprising 463 CML patients and 4,912 controls showed a 29% risk reduction for individuals expressing HLA-B8 (OR of 0.71; 95% CI, 0.52 to 0.97), but an OR of 1.19 (95% CI, 0.90 to 1.56) for HLA-A3 and an OR of 1. 09 (95% CI, 0.80 to 1.50) for HLA-A11. In conclusion, these results indicate that HLA-B8 expression, in particular when HLA-A3 is coexpressed, is associated with a diminished incidence of CML. A biological mechanism may be that presentation of bcr-abl breakpoint peptides in these HLA molecules can induce a protective immune response.

Stable inheritance of an HLA-"blank" phenotype associated with a structural mutation in the HLA-A*0301 gene.

A serological family study identified an HLA-A "blank" segregating through three generations of apparently healthy individuals. The HLA-A*0301 allele was assigned by DNA genotyping in each of the three individuals. Complete absence of cellular expression of the HLA-A3 antigen was associated with a 6 nucleotide deletion in exon 3 of the A*0301 gene. The in-frame deletion of nucleotides 373-378 results in the absence of residues C101 and D102 from the mature HLA-A heavy chain. Cysteine 101 is involved in the formation of the highly conserved disulfide bridge in the alpha 2 domain of the class I molecule, and deletion of this residue is believed to be highly disruptive to proper folding and function of the class I molecule.