Your search keyword '"Boon, Thierry"' showing total 10 results

1. Local immunostimulation leading to rejection of accepted male skin grafts by female mice as a model for cancer immunotherapy.

Author

Bourdeaux, Christophe, Lurquin, Christophe, Jacquemart, Isabelle, Lethé, Bernard, Brasseur, Francis, van Baren, Nicolas, Baurain, Jean-François, Dyson, Julian, Van Snick, Jacques, Uyttenhove, Catherine, and Boon, Thierry

Subjects

T cells, TUMOR antigens, IMMUNOREGULATION, TUMOR markers, TUMOR proteins, LABORATORY mice

Abstract

Female mice of inbred strain CBA do not reject syngeneic male skin grafts even though they mount a T-cell response against the malespecific HY antigen. We show that local immunostimulation performed by injecting cytokines and Toll-like receptor ligands in close vicinity to the graft causes rejection. We feel that this approach should be tested in tumor-bearing human patients in combination with antitumor vaccination. Relief of intratumor immunosuppression may increase considerably the fraction of patients who respond to vaccination directed against tumor antigens recognized by T cells. [ABSTRACT FROM AUTHOR]

Published

2014

2. Tumour antigens recognized by T lymphocytes: at the core of cancer immunotherapy.

Author

Coulie, Pierre G., Van den Eynde, Benoît J., van der Bruggen, Pierre, and Boon, Thierry

Subjects

TUMOR antigens, T cells, CANCER patients, IMMUNOTHERAPY, CANCER cells

Abstract

In this Timeline, we describe the characteristics of tumour antigens that are recognized by spontaneous T cell responses in cancer patients and the paths that led to their identification. We explain on what genetic basis most, but not all, of these antigens are tumour specific: that is, present on tumour cells but not on normal cells. We also discuss how strategies that target these tumour-specific antigens can lead either to tumour-specific or to crossreactive T cell responses, which is an issue that has important safety implications in immunotherapy. These safety issues are even more of a concern for strategies targeting antigens that are not known to induce spontaneous T cell responses in patients. [ABSTRACT FROM AUTHOR]

Published

2014

3. Lack of tumor recognition by cytolytic T lymphocyte clones recognizing peptide 195–203 encoded by gene MAGE-A3 and presented by HLA-A24 molecules.

Author

So, Tomoko, Hanagiri, Takeshi, Chapiro, Jacques, Colau, Didier, Brasseur, Francis, Yasumoto, Kosei, Boon, Thierry, and Coulie, Pierre G.

Subjects

CANCER genetics, IMMUNE recognition, T cells, HLA histocompatibility antigens, TUMOR antigens, GENE expression, GENE transfection, CANCER immunotherapy

Abstract

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-A3195–203 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 × 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 × 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-A3195–203 is poorly processed and is not an appropriate target for cancer immunotherapy. [ABSTRACT FROM AUTHOR]

Published

2007

4. Human T Cell Responses Against Melanoma.

Author

Boon, Thierry, Coulie, Pierre G., Van den Eynde, Benoît J., and van der Bruggen, Pierre

Subjects

*T cells, *MELANOMA, *CANCER patients, *TUMORS, *CANCER vaccines

Abstract

Many antigens recognized by autologous T lymphocytes have been identified on human melanoma. Melanoma patients usually mount a spontaneous T cell response against their tumor. But at some point, the responder T cells become ineffective, probably because of a local immunosuppressive process occurring at the tumor sites. Therapeutic vaccination of metastatic melanoma patients with these antigens is followed by tumor regressions only in a small minority of the patients. The T cell responses to the vaccines show correlation with the tumor regressions. The local immunosuppression may be the cause of the lack of vaccination effectiveness that is observed in most patients. In patients who do respond to the vaccine, the antivaccine T cells probably succeed in reversing focally this immunosuppression and trigger a broad activation of other antitumor T cells, which proceed to destroy the tumor. [ABSTRACT FROM AUTHOR]

Published

2006

5. A MAGE-1 antigenic peptide recognized by human cytolytic T lymphocytes on HLA-A2 tumor cells.

Author

Ottaviani, Sabrina, Yi Zhang, Boon, Thierry, and van der Bruggen, Pierre

Subjects

ONCOGENES, T cells, CANCER cells, CANCER patients, CANCER immunology

Abstract

“Cancer-germline” genes such as those of the MAGE family are expressed in many tumors and in male germline cells, but are silent in normal tissues. They encode shared tumor-specific antigens that have been used in therapeutic vaccination trials of cancer patients. It was previously demonstrated that MAGE-1 peptide KVLEYVIKV was presented by HLA-A 0201 molecules on the surface of a human breast carcinoma cell line, but no human specific CTL had been isolated so far. Here, we have used HLA-A2/MAGE-1 fluorescent multimers to isolate from blood cells three human CTL clones that recognized the MAGE-1 peptide. These clones killed efficiently HLA-A2 tumor cells expressing MAGE-1, whether or not they were treated with IFN-γ, suggesting that the MAGE-1 antigen is processed efficiently by both the standard proteasome and the immunoproteasome. These results indicate that the MAGE-1.A2 peptide can be used for antitumoral vaccination. [ABSTRACT FROM AUTHOR]

Published

2005

6. Correlation between tumor regression and T cell responses in melanoma patients vaccinated with a MAGE antigen.

Author

Lonchayt, Christophe, Bruggent, Pierre van der, Connerotte, Thierry, Hanagiri, Takeshi, Coulie, Pierre, Colau, Didier, Lucas, Sophie, Pel, Aline Van, Thielemans, Kris, Barent, Nicolas van, and Boon, Thierry

Subjects

T cells, TUMORS, CANCER patients, VACCINES, ANTIGENS, CLINICAL trials

Abstract

The cancer-germline gene MAGE-3 codes for tumor-specific anti- gens recognized on many tumors by T lymphocytes. A MAGE-3 antigen presented by HLA-A1 has been used in several vaccination trials on metastatic melanoma patients. Only a small minority of patients have shown evidence of tumor regression. Attempts to correlate the tumor rejections with the cytotoxic T lymphocyte (CTL) response against the vaccine have been hampered by the low level of these responses. In noncancerous individuals, the frequency of the T cell precursors against antigen MAGE-3.A1 is ≈4 x 10-7 CD8 T cells. The diversity of the T cell receptor repertoire of these anti-MAGE-3.A1 precursors was analyzed in one individual. The results indicate that it is very likely that the repertoire comprises >100 clonotypes. On this basis, it is possible to use not only the frequency of CTL precursors in the blood but also the presence of dominant clonotypes to ascertain in patients the existence of anti-AGE-3.A1 responses as low as 10-6 of CD8. With this approach, we observed a correlation between tumor regression and anti-MAGE-3.A1 responses in patients vaccinated with a recombinant virus encoding the antigen and also in patients vaccinated with peptide-pulsed dendritic cells. In contrast for patients showing tumor regression after vaccination with peptide alone, CTL responses were almost never observed. It is possible that even those CTL responses that are below our present detection level can trigger a sequence of events that leads to tumor regression. [ABSTRACT FROM AUTHOR]

Published

2004

7. Tumor-specific shared antigenic peptides recognized by human T cells.

Author

van der Bruggen, Pierre, Yi Zhang, Chaux, Pascal, Stroobant, Vincent, Panichelli, Christophe, Schultz, Erwin S., Chapiro, Jacques, Van den Eynde, Benoit J., Brasseur, Francis, and Boon, Thierry

Subjects

TUMORS, ANTIGENS, CANCER, GENES, T cells

Abstract

Characterizes the tumor-specific shared antigens and the cancer-germline genes that code for these antigens with antitumor cytolytic T lymphocytes obtained from cancer patients. Role of cancer-germline in tumor-specific shared antigens; Role of CD4[sup+] T cells in inducing and maintaining antitumor immunity; Result of the search for antigenic peptides recognized by CD8[sup+] T cells.

Published

2002

8. Immunosurveillance against Cancer and Immunotherapy — Synergy or Antagonism?

Author

Boon, Thierry and van Baren, Nicolas

Subjects

*CANCER prevention, *IMMUNE response, *TUMORS, *T cells

Abstract

The article presents the authors' views on immunosurveillance against cancer. According to the authors, the immune system eliminates many types of cancers at an early stage. The authors say that in humans, there has been an increase of tumors in transplant recipients who received immunosuppressive treatment. According to the authors, many T lymphocytes are often found in tumors, but this does not prove that an immune response slows down the progression of the tumor.

Published

2003

9. Neogenesis of Lymphoid Structures and Antibody Responses Occur in Human Melanoma Metastases.

Author

Cipponi, Arcadi, Mercier, Marjorie, Seremet, Teofila, Baurain, Jean-François, Théate, Ivan, van den Oord, Joost, Stas, Marguerite, Boon, Thierry, Coulie, Pierre G., and van Baren, Nicolas

Subjects

*LYMPHOID tissue, *MELANOMA, *METASTASIS, *B cells, *DENDRITIC cells, *IMMUNOGLOBULINS, *T cells, *PATIENTS

Abstract

Lymphoid neogenesis, or the development of lymphoid structures in nonlymphoid organs, is frequently observed in chronically inflamed tissues, during the course of autoimmune, infectious, and chronic graft rejection diseases, in which a sustained lymphocyte activation occurs in the presence of persistent antigenic stimuli. The presence of such ectopic lymphoid structures has also been reported in primary lung, breast, and germline cancers, but not yet in melanoma. In this study, we observed ectopic lymphoid structures, defined as lymphoid follicles comprising clusters of B lymphocytes and follicular dendritic cells (DC), associated with high endothelial venules (HEV) and clusters of T cells and mature DCs, in 7 of 29 cutaneous metastases from melanoma patients. Some follicles contained germinal centers. In contrast to metastatic lesions, primary melanomas did not host follicles, but many contained HEVs, suggesting an incomplete lymphoid neogenesis. Analysis of the repertoire of rearranged immunoglobulin genes in the B cells of microdissected follicles revealed clonal amplification, somatic mutation and isotype switching, indicating a local antigen-driven B-cell response. Surprisingly, IgA responses were observed despite the nonmucosal location of the follicles. Taken together, our findings show the existence of lymphoid neogenesis in melanoma and suggest that the presence of functional ectopic lymphoid structures in direct contact with the tumor makes the local development of antimelanoma B- and T-cell responses possible. [ABSTRACT FROM AUTHOR]

Published

2012

10. An Antigenic Peptide Produced by Peptide Splicing in theProteasome.

Author

Vigneron, Nathalie, Stroobant, Vincent, Chapiro, Jacques, Ooms, Annie, Degiovanni, Gérard, Morel, Sandra, Bruggen, Pierre van der, Boon, Thierry, and Eynde, Benoit J. Van den

Subjects

*T cells, *PEPTIDES, *AMINO acids, *LEUCOCYTES, *MAJOR histocompatibility complex, *NEUROENDOCRINE tumors

Abstract

CDS T lymphocytes recognize peptides of 8 to 10 amino acids presented by class I molecules of the major histocompatibility complex. Here, CDS T lymphocytes were found to recognize a nonameric peptide on melanoma cells that comprises two noncontiguous segments of melanocytic glycoprotein gp100[supPMEL17]. The production of this peptide involves the excision of four amino acids and splicing of the fragments. This process was reproduced in vitro by incubating a precursor peptide of 13 amino acids with highly purified proteasomes. Splicing appears to occur by transpeptidation involving an acylenzyme intermediate. Our results reveal an unanticipated aspect of the proteasome function of producing antigenic peptides. [ABSTRACT FROM AUTHOR]

Published

2004