NK-mediated elimination of mutant lymphocytes that have lost expression of MHC class I molecules

Mutant cells generated in vivo can be eliminated when mutated gene products are presented as altered MHC/peptide complexes and recognized by T cells. Diminished expression of MHC/peptide complexes enables mutant cells to escape recognition by T cells. In the present study, we tested the hypothesis that mutant lymphocytes lacking expression of MHC class I molecules are eliminated by autologous NK cells. In H-2b/k F1 mice, the frequency of H-2Kb-negative T cells was higher than that of H-2Kk-negative T cells. The frequency of H-2K-deficient T cells increased transiently after total body irradiation. During recovery from irradiation, H-2Kk-negative T cells disappeared more rapidly than H-2Kb-negative T cells. The disappearance of H-2K-deficient T cells was inhibited by administration of Ab against asialo-GM1. H-2Kk-negative T cells showed higher sensitivity to autologous NK cells in vitro than H-2Kb/k heterozygous or H-2Kb-negative T cells. Adding syngeneic NK cells to in vitro cultures prevented emergence of mutant cells lacking H-2Kk expression but had little effect on the emergence of mutant cells lacking H-2Kb expression. Results in the H-2b/k F1 strain correspond with the sensitivity of parental H-2-homozygous cells in models of marrow graft rejection. In H-2b/d F1 mice, there was no significant difference between the frequencies of H-2Kb-negative and H-2Kd-negative T cells, although the frequencies of mutant cells were different after radiation exposure among the strains examined. H-2b/d F1 mice also showed rapid disappearance of the mutant T cells after irradiation, and administration of Ab against asialo-GM1 inhibited the disappearance of H-2K-deficient T cells in H-2b/d F1 mice. Our results provide direct evidence that autologous NK cells eliminate mutant cell populations that have lost expression of self-MHC class I molecules.     

MHC-restricted recognition of autologous melanoma by tumor-specific cytotoxic T cells. Evidence for restriction by a dominant HLA-A allele.

Autologous melanoma-specific CTL recognize a common tumor-associated Ag (TAA) in the context of HLA class I antigens. We have demonstrated that HLA-A2 can be a restricting Ag and, in T cell lines homozygous for HLA-A2, that CTL can be generated by stimulation with HLA-A2 allogeneic melanomas. In the current study, we have investigated T cell lines from patients who are heterozygous at HLA-A region locus, to determine the relative importance of each A-region allele in this MHC-restricted recognition of tumor. We have shown that HLA-A1 can be a restricting Ag, and that allogeneic melanomas expressing HLA-A1 can substitute for the autologous tumor in the generation of HLA-A1-restricted CTL. However, when T cell lines express both HLA-A1 and HLA-A2, the HLA-A2 allele governed restriction of the melanoma TAA. Three autologous-stimulated HLA-A1, A2 CTL lines all demonstrated restriction by the HLA-A2 allele, when examined in cytotoxicity assays, cold-competition assays, and proliferation assays. There was no evidence of restriction by the second HLA-allele, HLA-A1. Although the autologous-stimulated CTL use a single A-region allele for tumor recognition, the autologous HLA-A1, A2 tumors are lysed by both HLA-A1-restricted and HLA-A2-restricted CTL. The dominance of restricting alleles was further demonstrated when HLA-matched allogeneic melanomas were used as the stimulating tumor to generate tumor-specific CTL. Stimulation of the heterozygous (HLA-A1, A2) lymphocytes with HLA-A2-matched allogeneic melanomas resulted in CTL specific for the autologous tumor, and restricted by the HLA-A2 Ag. However, stimulation with an HLA-A1-matched allogeneic melanoma failed to induce tumor-specific CTL restricted by the HLA-A1 Ag. The data suggest there is a dominance of HLA-A region Ag at the level of the T cell, such that only one is restricting in the recognition of the autologous melanoma. At the level of the tumor, however, the TAA is expressed in the context of both HLA-A region alleles. We can generate specific CTL from lymph node cells or PBL and HLA-A region matched allogeneic melanomas; however, because most patients are heterozygous at the HLA-A region locus, an understanding of the dominant restricting alleles must be obtained so that an appropriately matched allogeneic melanoma can be selected.     

Development of a flow-cytometric HLA-A locus mutation assay for human peripheral blood lymphocytes.

A flow-cytometric technique was developed to measure the frequency of variant lymphocytes lacking expression of HLA-A2 or A24 allele products among donors heterozygous for HLA-A2 or A24. It was found that the variant frequency of lymphocytes in peripheral blood was of the order of 10(-4) and increased with donor age. Molecular analyses of mutant clones revealed that about one-third were derived from somatic recombinations and that the remaining two-thirds did not show any alterations after Southern blotting analysis. In contrast, mutants obtained after in vitro X-ray mutagenesis study were found to be mostly derived from large chromosomal deletions. A small-scale study on atomic bomb survivors did not show a significant dose effect.     

Induction of CD4+ cytotoxic T cells by sensitization with allogeneic melanomas bearing shared or cross-reactive HLA-A.

Human melanoma is an immunogenic neoplasm whereby enhancement of specific cell-mediated immunity can alter tumor progression. HLA-A2-restricted CTL have been demonstrated to kill allogeneic HLA-A2-matched melanoma. We investigated the ability of allogeneic melanoma cells sharing HLA-A antigens to sensitize melanoma patients' lymphocytes to induce HLA-A-restricted CTL to autologous melanoma. PBL from melanoma patients were cocultured with autologous melanoma cells in defined "cocktail medium" to generate melanoma-specific HLA-A-restricted CTL lines. CTL generated by sensitization with allogeneic melanoma bearing shared HLA-A2, A11, A24, or "cross-reactive" HLA-A antigens could kill almost as many autologous melanoma cells as CTL sensitized with autologous melanoma. There are HLA-A antigens that are immunogenically cross-reactive because they share determinant epitopes. CTL were not activated NK or LAK cells. The HLA restriction and melanoma cell specificity of the CTL were demonstrated by cold target inhibition with autologous and allogeneic melanoma and B lymphoblasts. Anti-CD3 and anti-HLA AB inhibited CTL killing of melanoma. The CTL were predominantly CD3+CD4+ TCR alpha/beta+. These studies demonstrate that melanomas being shared or cross-reactive HLA-A can be used for in vitro generation of HLA-restricted CTL that recognize melanoma-associated antigens. The findings have very important implications in human tumor immunotherapy.     

Ionizing radiation and genetic risks. III. Nature of spontaneous and radiation-induced mutations in mammalian in vitro systems and mechanisms of induction of mutations by radiation

This paper (1) presents an analysis of published data on the molecular nature of spontaneously arising and radiation-induced mutations in mammalian somatic cell systems and (2) examines whether the molecular nature and mechanisms of origin of radiation-induced mutations, in mammalian in vivo and in vitro systems, as currently understood, are consistent with expectations based on the biophysical and microdosimetric properties of ionizing radiation. Depending on the test system (CHO cells, human T lymphocytes and human lymphoid cell line TK6), 80-97% of spontaneous HPRT mutations show normal Southern patterns; the remainder is due to gross changes, predominantly partial (intragenic) deletions. Total gene deletions at the HPRT locus are rare except in the TK6 cell line. At the APRT locus in CHO cells, 80-97% of spontaneous mutations are due to base-pair changes, the remainder being, mostly, partial deletions. The latter can extend upstream in the 5' direction but not beyond the APRT gene in the 3' direction. At the human HLA-A locus (T lymphocytes), the percentage of mutations with normal Southern patterns is lower than that for HPRT, and in the range of 50-60%. At the HLA-A locus, mitotic recombination contributes substantially to the mutation spectrum (approximately 30% of mutations recovered) and this is likely to be true of the TK locus in the TK6 cell line as well. With a few exceptions, most of the radiation-induced mutations show altered Southern patterns and are consistent with their being deletions and/or other gross changes (HPRT, 70-90% (CHO); 50-85% (TK6); 50-75% (T lymphocytes); TK, 60-80% (TK6); HLA-A, 80% (T lymphocytes); DHFR, 100% (CHO]. The exceptions are APRT mutations in CHO cells (16-20% of mutants with deletions or other changes) and HPRT mutations in T lymphocytes from A-bomb survivors (15-25%); the latter finding is consistent with the occurrence of in vivo selection against HPRT mutant cells. In cases of HPRT intragenic deletions analyzed (CHO cells and V79 Chinese hamster cells), there is evidence for a non-random distribution of breakpoints. The spontaneous mutation frequencies vary widely, from about 0.04/10(6) cells (sickle cell mutations at the human HBB locus) to 30.8/10(6) cells (HLA-A mutations in T lymphocytes) and are dependent on the locus, the system employed and a number of other factors. Those for the other loci fall between these limits.(ABSTRACT TRUNCATED AT 400 WORDS)     

A similarity in peptide cross-reactivity between alloantigen- and nominal antigen-induced CD8+ T cell responses in vitro

Raising tumor-specific allorestricted T cells in vitro for adoptive transfusion is expected to circumvent host tumor tolerance. However, it has been assumed that alloreactive T cell clones activated in vitro ranges from peptide-specific with high avidity to peptide-degenerate with low avidity. In this study, we examined the peptide specificity and cross-reactivity of T cell responses in vitro to an allogeneic epitope and a nominal epitope with a modified co-culture of lymphocytes and autologous monocytes. After binding to the monocyte via the interaction of its Fc part and the cell surface IgG Fc receptor type I (FcγRI), a fusion protein consisting of the extracellular domains of HLA-A2 molecule and the Fc region of IgG1 (the dimer) introduced a single epitope into the co-culture. The dimer-coated monocytes stimulated the proliferation of autologous CD8⁺ T cells after co-culturing. The CD8⁺ T cell responses were self-HLA-restricted for HLA-A2-positive (HLA-A2+ve) samples and allo-HLA-restricted for HLA-A2-negative (HLA-A2-ve) samples, since the co-cultural bulks stained with HLA-A2 tetramers, human interferon-gamma (IFN-γ) production in response to T cell receptor (TCR) ligands, and cytotoxicity against a panel of target cells exhibited peptide-specific properties. Two HLA-A2-restricted peptides with sequence homology were included, allowing the comparison of cross-reactivity between allo-antigen- and nominal antigen-induced CD8⁺ T cell responses. Interestingly, the allo- and self-HLA-restricted CD8⁺ T cell responses were similar in the peptide cross-reactivity, although the allorestricted T cell response seemed, overall, more intensive and had higher binding affinity to specific tetramer. Our findings indicated the alloreactive T cells raised by the co-culture in vitro were as peptide specific and cross-reactive as the self-HLA-restricted ones.     

Modulation of HLA-A*0201-restricted T cell responses by natural polymorphism in the IE1(315-324) epitope of human cytomegalovirus

Cytotoxic T lymphocytes play a central role in the control of persistent human CMV (HCMV) infection and reactivation. In healthy virus carriers, the specific CD8(+) CTL response is almost entirely directed against the virion tegument protein pp65 and/or the 72-kDa major immediate early protein, IE1. Studies that included a large panel of HCMV(+) donors suggested that immunorelevance of pp65 and IE1 was directly related with individual HLA haplotype difference. Nevertheless, there are no data on the incidence of HCMV natural polymorphism on virus-specific CTL responses. To assess the impact of IE1 polymorphism on CTL response, we have sequenced in 103 clinical isolates the DNA region corresponding to IE1(315-324), an immunodominant epitope presented by HLA-A*0201 molecules. Seven peptidic variants were found with extensive difference in their frequencies. The response of four HLA-A*0201-restricted anti-IE1 T lymphocyte clones, which were previously generated from one donor against autologous B lymphoblastoid cells expressing a recombinant clinical variant of IE1, was then evaluated using target cells loaded with mutant synthetic peptides or expressing rIE1 variants. One of four clones, which have been sorted 19 times among 22 clones targeted against IE1(315-324), recognized six of the seven tested variant epitopes. All three other clones showed distinct reactivity patterns to target cells loaded with the different mutant peptides or expressing IE1 variants. Therefore, in the HLA-A2 context, clonal expansions of anti-IE1 memory CTLs may confer a protection against HCMV successive infections and reactivations by killing cells presenting most of the naturally occurring IE1(315-324) epitope variants.     

T cells of atomic bomb survivors respond poorly to stimulation by Staphylococcus aureus toxins in vitro: does this stem from their peripheral lymphocyte populations having a diminished naïve CD4 T-cell content?

We found previously that the peripheral CD4 T-cell populations of heavily exposed A-bomb survivors contained fewer na?ve T cells than we detected in the corresponding unexposed controls. To determine whether this demonstrable impairment of the CD4 T-cell immunity of A-bomb survivors was likely to affect the responsiveness of their immune systems to infection by common pathogens, we tested the T cells of 723 survivors for their ability to proliferate in vitro after a challenge by each of the Staphylococcus aureus toxins SEB, SEC-2, SEC-3, SEE and TSST-1. The results presented here reveal that the proliferative responses of T cells of A-bomb survivors became progressively weaker as the radiation dose increased and did so in a manner that correlated well with the decreasing CD45RA-positive (na?ve) [but not CD45RA-negative (memory)] CD4 T-cell percentages that we found in their peripheral blood lymphocyte (PBL) populations. We also noted that the T cells of survivors with a history of myocardial infarction tended to respond poorly to several (or even all) of the S. aureus toxins, and that these same individuals had proportionally fewer CD45RA-positive (na?ve) CD4 T cells in their PBL populations than we detected in survivors with no myocardial infarction in their history. Taken together, these results clearly indicate that A-bomb irradiation led to an impairment of the ability of exposed individuals to maintain their na?ve T-cell pools. This may explain why A-bomb survivors tend to respond poorly to toxins encoded by the common pathogenic bacterium S. aureus.     

Shared human melanoma antigens. Recognition by tumor-infiltrating lymphocytes in HLA-A2.1-transfected melanomas.

Three predominantly CD8+ CTL lines, TIL 501, TIL 620, and TIL 660, were generated from three HLA-A2+ melanoma patients by culturing tumor-infiltrating lymphocytes in 1000 U/ml IL-2. These tumor-infiltrating lymphocytes lysed 12 of 18 HLA-A2+ autologous and allogeneic melanomas, but none of 20 HLA-A2-negative melanomas. They also did not lyse the MHC class I negative lymphoma-leukemia cell lines, Daudi, K562, or HLA-A2+ non-melanoma cell lines including PHA or Con A-induced lymphoblast, fibroblast, EBV-transformed B cell, Burkitt's B cell lymphoma, and colon cancer cell lines. Autologous and allogeneic melanoma lysis was inhibited by anti-CD3, by anti-MHC class I, and by anti-HLA-A2 mAb, indicating recognition of shared tumor Ag among melanoma cell lines in a TCR-dependent, HLA-A2-restricted manner. Six HLA-A2-negative melanoma cell lines obtained from five HLA-A2-negative patients were co-transfected with the HLA-A2.1 gene and pSV2neo. All 17 cloned transfectants expressing cell surface HLA-A2 molecules, but none of 12 transfectants lacking HLA-A2 expression, were lysed by these three HLA-A2-restricted, melanoma-specific CTL. Lysis of the HLA-A2+ transfectants was inhibited by anti-CD3, by anti-MHC class I, and by anti-HLA-A2 mAb, indicating recognition of shared tumor Ag on transfectants in a TCR-dependent, HLA-A2-restricted manner. These results identify the HLA-A2.1 molecule as an Ag-presenting molecule for melanoma Ag. They also suggest that common melanoma Ag are expressed among melanoma patients regardless of HLA type. These findings have implications for the development of melanoma vaccines that would induce antitumor T cell responses.     

rIL 2-induced proliferation of human circulating NK cells and T lymphocytes: synergistic effects of IL 1 and IL 2

Cells participating in the rIL 2-induced proliferation of resting PBMC were identified by using different methods of cell purification. NK cells recovered in the light density fraction of Percoll gradients responded, as already known, directly to rIL 2 by strong proliferation. In contrast, large T lymphocytes co-purifying with NK cells, and small T cells sedimenting in the high density area of the Percoll gradients, were virtually unresponsive when cultivated in the sole presence of rIL 2. However, the addition of either irradiated autologous monocytes or highly purified IL 1 allowed both kinds of T cells to undergo cell division. Stringent elimination of possibly contaminating NK cells (NKH-1+) and/or activated T cells (TNKTAR, Tac+, HLA-DR+) from the high density T cells by complement lysis did not impair rIL 2-induced cell proliferation, indicating entire responsiveness of these cells to the synergistic action of IL 1 plus IL 2. Both high density CD4+ and CD8+ participated in this phenomenon, with an apparent advantage for CD4+ cells. All Tac+ cells emerging in a 6-day culture of these cells expressed the WT31 antigen, which indicates that T cells involved in rIL 2-induced proliferation are conventional mature T cells. The relative precursor frequencies of NK cells, large T lymphocytes, and small T lymphocytes that proliferated in response to rIL 2 were analyzed by limiting dilution analysis. The frequencies of clonal growth of NK cells and low density T lymphocytes were approximately the same (1/103 vs 1/185), whereas that of high density T cells was four times lower (1/458). Thus, we clearly demonstrate that resting T cells, defined as such by morphological, density, and phenotypic criteria, are able to proliferate in response to IL 2 in the presence of IL 1 without antigenic or mitogenic triggering.     

The human liver contains multiple populations of NK cells, T cells, and CD3+CD56+ natural T cells with distinct cytotoxic activities and Th1, Th2, and Th0 cytokine secretion patterns.

The human liver contains significant numbers of T cells, NK cells, and lymphocytes that coexpress T and NK cell receptors. To evaluate their functional activities, we have compared the cytotoxic activities and cytokines produced by normal adult hepatic CD3+CD56- (T) cells, CD3-CD56+ (NK) cells, and CD3+CD56+ (natural T (NT)) cells. In cytotoxicity assays using immunomagnetic bead-purified NK cell, T cell, and NT cell subpopulations as effectors, fresh hepatic NK cells lysed K562 targets, while NT cells could be induced to do so by culturing with IL-2. Both NT and T cells were capable of redirected cytolysis of P815 cells using Abs to CD3. Flow cytometric analysis of cytokine production by fresh hepatic lymphocyte subsets activated by CD3 cross-linking or PMA and ionomycin stimulation indicated that NT cells and T cells could produce IFN-gamma, TNF-alpha, IL-2, and/or IL-4, but little or no IL-5, while NK cells produced IFN-gamma and/or TNF-alpha only. The majority of NT cells produced inflammatory (Th1) cytokines only; however, approximately 6% of all hepatic T cells, which included 5% of Valpha24 TCR-bearing NT cells and 2% of gammadeltaTCR+ cells, simultaneously produced IFN-gamma and IL-4. The existence of such large numbers of cytotoxic lymphocytes with multiple effector functions suggests that the liver is an important site of innate immune responses, early regulation of adaptive immunity, and possibly peripheral deletion of autologous cells.     

Role of human circulating and tumor-infiltrating lymphocytes in cancer defense and treatment

We have analyzed the anticancer efficacy of various subsets of human circulating and tumor-infiltrating lymphocytes (TIL). These studies showed that circulating natural killer (NK) cells mediate the most potent oncolytic activity against a variety of tumor targets, after enrichment or stimulation with interleukin-2 (IL-2). Interestingly, NK cell oncolytic activity was directed also against tumor targets frequently designated as 'NK-resistant'. This indicates that NK cells display a broader spectrum of killing than is commonly recognized. TIL did not display any tumoricidal activity when unstimulated, but acquired cytotoxic potential after activation with IL-2. Comparative studies of TIL and circulating lymphocytes from patients with ovarian cancer demonstrated that these two groups of lymphocytes manifested similar levels of cytotoxicity and the same spectrum of target cell killing. No specificity in autologous tumor cell killing was displayed by TIL; instead, TIL were effective against autologous as well as allogeneic tumor targets. The lack of TIL tumor specificity was not detected only in ovarian tumors, but was manifested also in renal- and squamous-cell cancers. Characterization studies demonstrated that the primary oncolytic cells in the periphery and among TIL are NK cells. T lymphocytes displayed some, but rather negligible cytotoxic activity. In contrast, when IL-2-activated NK and T cells were analyzed for lytic activity against normal hematopoietic cells, T cells displayed high levels of bone marrow killing. The anti-bone marrow lytic activity of IL-2-activated T lymphocytes may be harmful after therapy with conventionally prepared lymphokine-activated killers. In light of these observations, new directions to adoptive immunotherapy are discussed.     

Frequency analysis of tumor-reactive cytotoxic T lymphocytes in peripheral blood of a melanoma patient vaccinated with autologous tumor cells

A limiting-dilution assay was developed and used to determine the frequency of autologous tumor-reactive cytotoxic T lymphocytes (CTL) in peripheral blood of a melanoma patient MZ2, who has been free of detectable disease since several years. In this patient, the frequencies of tumor-reactive CTL spontaneously varied only by a factor of 1.5. After vaccinations with autologous mutagenized and lethally irradiated tumor cells a two- to tenfold increase in frequencies of tumor-reactive CTL was found within the first 2 weeks. Thereafter, CTL frequencies returned to values measured prior to vaccinations. We conclude, that the limiting-dilution assay applied in this study can detect changes in the T cell response to autologous tumor cells. The frequency of tumor-reactive CTL determined with this approach can serve as an immunological parameter for monitoring the T cell response to autologous tumor cells in individual cancer patients receiving tumor cell vaccinations.     

Analysis of cellular immune response to EBV by using cloned T cell lines

Eight cloned T cell lines specific for Epstein Barr virus-transformed B lymphocytes were derived. In the presence of the autologous virus-infected B cells, the T cell lines show HLA-restricted cytotoxic activity and also secrete alpha-interferon in sufficient amounts to inhibit infection and transformation. Four of these clones showed restriction to a single HLA locus (two for A3, and two for B7) and three showed exquisite self-restriction lysing only autologous targets. These seven clones expressed the classical cell surface phenotype of cytotoxic T cells being T3, 8, 11, and la-positive and T4-negative. An eighth clone that lacked the T8 surface marker appeared to recognize both B7 and BW51. HLA restriction was confirmed: 1) by the ability of a monoclonal antibody against an HLA-A,B,C framework antigen (W6-32) to block the cytotoxicity; 2) the failure of the clones to lyse Daudi, an EBV-positive, HLA-A,B, C-negative cell line; and 3) successful competition of the cytotoxicity by autologous but not allogeneic cold targets. The cloned T cells do not kill EBV-negative targets such as autologous pokeweed mitogen blasts and cell lines including CEM and the natural killer cell target K562. The results suggest T cell clones may be generated against an EBV-associated membrane antigen on transformed B cells, perhaps equivalent to the lymphocyte-determined membrane antigen, and that the recognition is restricted by a single HLA determinant. We propose that single T cells can play multiple roles in controlling EBV infection in vitro and in vivo including the elimination of transformed cells by cytotoxicity and the prevention by secreted interferon of further re-infection and transformation.     

Unusually high frequencies of HIV-specific cytotoxic T lymphocytes in humans

CTL specific for the HIV belong to the CD8 subset of T lymphocytes, and their activity is restricted by class I HLA transplantation Ag. In this report, HIV-specific CTL and their precursor cells were quantified by limiting dilution analysis. CTL were recovered from the lungs, lymph nodes, and blood of asymptomatic seropositive carriers and of patients with AIDS. HIV was found to be very immunogenic. High frequencies of both HIV-specific CTL and CTL precursor cells were detected in infected individuals. These CTL killed autologous HIV-infected macrophages and T4 lymphoblasts. They also killed doubly transfected P815-A2-env-LAV mouse tumor cells, which express the human HLA-A2 gene and the HIV-1 env gene. In the longitudinal studies of two HIV-infected patients, CTL and CTL precursor cell frequencies decreased as the clinical and immunologic status of the patients deteriorated. Most surprisingly, PBL from seronegative donors also responded to HIV stimulation in vitro and generated large numbers of HLA-restricted, HIV-specific CTL.     

Comparative analysis of DC fused with allogeneic hepatocellular carcinoma cell line HepG2 and autologous tumor cells as potential cancer vaccines against hepatocellular carcinoma

Fusions of patient-derived dendritic cells (DCs) and autologous tumor cells induce T-cell responses against autologous tumors in animal models and human clinical trials. These fusion cells require patient-derived tumor cells, which are not, however, always available. Here we fused autologous DCs from patients with hepatocellular carcinoma (HCC) to an allogeneic HCC cell line (HepG2). These fusion cells co-expressed tumor-associated antigens (TAAs) and DC-derived costimulatory and MHC molecules. Both CD4⁺ and CD8⁺ T cells were activated by the fusion cells. Cytotoxic T lymphocytes (CTLs) induced by the fusion cells were able to kill autologous HCC by HLA-A2- and/or HLA-A24-restricted mechanisms. CTL activity against shared TAAs indicates that the presence of alloantigens does not prevent the development of CTLs with activity against autologous HCC cells. These fusion cells may have applications in anti-tumor immunotherapy through cross-priming against shared tumor antigens and may provide a platform for adoptive immunotherapy.     

Identification of melanoma-specific peptide epitopes by HLA-A2.1-restricted cytotoxic T lymphocytes

HLA-A2.1-associated peptides, extracted from human melanoma cells, were used to study epitopes for melanoma-specific HLA-A2.1-restricted cytotoxic T lymphocytes （CTLs） by epitope reconstitution, active peptide sequence characterization and synthetic peptide verification. CTL were generated from tumor-involved nodes by in vitro stimulation, initially with autologous melanoma cells and subsequently with allogeneic HLA-A2.1 positive melanoma cells. The CTLs could lyse autologous and aUogeneic HLA-A2. 1 positive melanomas, but not HLA-A2.1 negative melanomas or HLA-A2.1 positive non-melanomas. The lysis of melanomas could be inhibited by anti-CD3, anti-HLA class I and anti-HLA-A2.1 monoclonal antibodies. HLA-A2.1 molecules were purified from detergent-solubilized human melanoma cells by immunoaffinity column chromatography and further fractionated by reversed phase high performance liquid chromatography. The fractions were assessed for their ability to reconstitute melanoma-specific epitopes with HLA-A2.1 positive antigen-processing mutant T2 cells. Three reconstitution peaks were observed in lactate dehydrogenase release assay. Mass spectrometry and ion-exchange high performance liquid chromatography analysis were used to identify peptide epitopes. Peptides with a mass-to-charge ratio of 948 usually consist of nine amino acid residues. The data from reconstitution experiments confirmed that the synthetic peptides contained epitopes and that the peptides associated with HLA-A2.1 and recognized by melanoma-specific CTL were present in these different melanoma cells. These peptides could be potentially exploited in novel peptide-based antitumor vaccines in immunotherapy for CTL.     

Exosomes as potent cell-free peptide-based vaccine. I. Dendritic cell-derived exosomes transfer functional MHC class I/peptide complexes to dendritic cells

Current immunization protocols in cancer patients involve CTL-defined tumor peptides. Mature dendritic cells (DC) are the most potent APCs for the priming of naive CD8(+) T cells, eventually leading to tumor eradication. Because DC can secrete MHC class I-bearing exosomes, we addressed whether exosomes pulsed with synthetic peptides could subserve the DC function consisting in MHC class I-restricted, peptide-specific CTL priming in vitro and in vivo. The priming of CTL restricted by HLA-A2 molecules and specific for melanoma peptides was performed: 1) using in vitro stimulations of total blood lymphocytes with autologous DC pulsed with GMP-manufactured autologous exosomes in a series of normal volunteers; 2) in HLA-A2 transgenic mice (HHD2) using exosomes harboring functional HLA-A2/Mart1 peptide complexes. In this study, we show that: 1). DC release abundant MHC class I/peptide complexes transferred within exosomes to other naive DC for efficient CD8(+) T cell priming in vitro; 2). exosomes require nature's adjuvants (mature DC) to efficiently promote the differentiation of melanoma-specific effector T lymphocytes producing IFN-gamma (Tc1) effector lymphocytes in HLA-A2 transgenic mice (HHD2). These data imply that exosomes might be a transfer mechanism of functional MHC class I/peptide complexes to DC for efficient CTL activation in vivo.     

Lack of tumor recognition by cytolytic T lymphocyte clones recognizing peptide 195–203 encoded by gene <Emphasis Type="Italic">MAGE-A3</Emphasis> and presented by HLA-A24 molecules

Gene MAGE-A3 encodes tumor-specific antigenic peptides recognized by T cells on many tumors. MAGE-A3 peptides presented by HLA class I molecules have been identified using CD8 lymphocytes stimulated with cells that either expressed gene MAGE-A3 or were pulsed with candidate peptides. One antigen identified with the latter method is peptide MAGE-A3(195-203) IMPKAGLLI, presented by HLA-A24 molecules. It has been used to vaccinate advanced cancer patients. Here, we have used HLA/peptide tetramers to detect T cells recognizing this peptide. Their frequency was estimated to be 2 x 10(-8) of the blood CD8 cells in non-cancerous HLA-A24(+) individuals, which is tenfold lower than the reported frequencies of T cells against other MAGE peptides. In the blood of a patient vaccinated with MAGE-A3, the estimated frequency was 5 x 10(-7). Anti-MAGE-3.A24 cytolytic T cell clones were derived, that lysed peptide-pulsed cells with half-maximal effect at the low concentration of 500 pM. However, these CTL did not recognize a panel of HLA-A24(+) tumor cells that expressed MAGE-A3 at levels similar to those found in HLA-A1(+) tumor cells recognized by anti-MAGE-3.A1 CTLs. Furthermore, 293-EBNA cells transfected with MAGE-A3 and HLA-A24 constructs were hardly recognized by the anti-MAGE-3.A24 CTL clones. These results suggest that peptide MAGE-A3(195-203) is poorly processed and is not an appropriate target for cancer immunotherapy.     

Generation of tumor-reactive CTL against the tumor-associated antigen HER2 using retrovirally transduced dendritic cells derived from CD34+ hemopoietic progenitor cells

Ag-specific CD8+ CTL are crucial for effective tumor rejection. Attempts to treat human malignancies by adoptive transfer of tumor-reactive CTL have been limited due to the difficulty of generating and expanding autologous CTL with defined Ag specificity. The current study examined whether human CTL can be generated against the tumor-associated Ag HER2 using autologous dendritic cells (DC) that had been genetically engineered to express HER2. DC progenitors were expanded by culturing CD34+ hemopoietic progenitor cells in the presence of the designer cytokine HyperIL-6. Proliferating precursor cells were infected by a retroviral vector encoding the HER2 Ag and further differentiated into CD83+ DC expressing high levels of MHC, adhesion, and costimulatory molecules. Retroviral transduction of DC resulted in the expression of the HER2 molecule with a transduction efficiency of 15%. HER2-transduced DC correctly processed and presented the Ag, because HLA-A*0201-positive DC served as targets for CTL recognizing the HLA-A*0201-binding immunodominant peptide HER2(369-377). HER2-transduced DC were used as professional APCs for stimulating autologous T lymphocytes. Following repetitive stimulation, a HER2-specific, HLA-A*0201-restricted CTL line was generated that was capable of lysing HLA-A*0201-matched tumor cells overexpressing HER2. A CD8+ T cell clone could be generated that displayed the same specificity pattern as the parenteral CTL line. The ability to generate and expand HER2-specific, MHC class I-restricted CTL clones using HER2-transduced autologous DC in vitro facilitates the development of adoptive T cell transfer for patients with HER2-overexpressing tumors without the requirement of defining immunogenic peptides.