Whole lymphoma B cells allow efficient cross-presentation of antigens by dendritic cells.

BACKGROUND: In order to compensate for the paucity of defined tumor antigens (Ag) in non-Hodgkin's lymphomas, a promising approach might be the use of whole tumor cells as a source of tumor Ag to pulse antigen-presenting cells (APC). However, it is not presently known how the tumor cells should be delivered to APC to optimize the cross-presentation of tumor Ag to anti-tumor CD8 T cells. We aimed to compare CD20-opsonized, apoptotic and necrotic human tumor cells for their capacity to induce endocytosis and cross-presentation of tumor-associated Ag by dendritic cells (DC) or macrophages. METHODS: Endocytosis of human tumor-derived material by macrophages or DC was monitored by flow cytometry. We used a previously described influenza model and studied cross-presentation of viral Ag as cellular surrogate tumor-associated Ag by APC after endocytosis of lymphoma B cells treated by inactivated influenza virus. RESULTS: Optimal endocytosis was obtained when tumor cells were opsonized by an anti-CD20 antibody and, as expected, macrophages were more phagocytic than DC. However, Ag from opsonized, apoptotic and live cells, but not from necrotic lymphoma cells, were efficiently cross-presented by DC but not by macrophages. DISCUSSION: We have developed a new model with human primary lymphoma cells to study the cross-presentation of tumor-associated Ag by APC. The results we have obtained support the use of whole lymphoma cells from patients to pulse DC to induce an anti-tumor immune response.

Preparation of purified lymphoma cells suitable for therapy.

BACKGROUND: Very few tumoral Ags have yet been isolated in NHL B cells. It is nevertheless possible to use whole tumor cells as a source of tumor Ags. We describe the purification of large numbers of human NHL B cells directly from lymph node or spleen biopsies, and different preparations allowing their use in a clinical setting. METHODS: The purification procedure consists of the negative selection of tumor B cells: cells to be eliminated are opsonized by CD2 Abs, and then coupled to magnetic beads for separation by the Isolex 300 magnetic separator. RESULTS: The mean yield of the purification was 74% for CD19+ cells, with a mean purity of 87%, dependent on the initial fraction of tumor cells in the biopsy. Using this procedure, a large number of purified tumor cells can be recovered from a biopsy in sterile conditions. We also describe treatments of B cells that can enhance their uptake by APCs, a critical step in anti-tumor immunotherapy strategies. Cells were opsonized by rituximab, or induced in apoptosis by irradiation, or necrosis by heating. Cell lysates were directly prepared from purified tumor cells. DISCUSSION: These procedures were reproducible on every lymphoma cell, and treated cells were phagocytosed by APCs. The methodology described here allows the evaluation of the immunological potential of apoptotic, necrotic, opsonized lymphoma cells, or their lysates, in a clinical setting.

Mechanisms of action of extracorporeal photochemotherapy in the control of GVHD: involvement of dendritic cells.

Despite the fact that extracorporal photochemotherapy (ECP) is now broadly used for the treatment of graft versus host disease or T-cell lymphomas, the mechanisms of its action remain enigmatic. This work provides a synthesis of the main results suggesting the initiation by ECP of an immune reaction responsible for the down modulation of pathogenic T-cell functions, with a special focus on the role of dendritic cells in this phenomenon.

Preparation of autologous leukemia and lymphoma vaccines expressing alpha-gal epitopes.

This study describes a novel method for increasing the immunogenicity of autologous tumor vaccines in leukemia and lymphoma patients by exploiting the natural anti-Gal antibody for in situ targeting of the vaccinating cells to antigen-presenting cells (APCs). Incubation of leukemia or lymphoma cells with neuraminidase and recombinant alpha 1,3-galactosyltransferase results in the synthesis of many alpha-gal epitopes (Gal alpha 1-3Gal beta 1-4GlcNAc-R) on their cell membranes. Vaccination with such processed tumor cells results in the binding of the natural anti-Gal immunoglobulin G (IgG) antibody to these epitopes and opsonization of these cells for effective phagocytosis by APCs, such as dendritic cells and macrophages. These APCs may transport the vaccine to adjacent draining lymph nodes for subsequent effective processing and presentation of tumor-associated antigens (TAA) peptides to activate TAA-specific helper and cytotoxic T cells. Once the TAA-specific cytotoxic T cells are activated, they can leave the lymph node, circulate in the body, and seek metastatic cells expressing TAA to destroy them. Alternatively, activated helper T cells may provide the help required for B cells to produce antibodies to TAA on the leukemia or lymphoma cells. Because every patient receives his or her own TAA within the vaccinating cells, such vaccines are customized for the patient. These autologous tumor vaccines may be used as an adjuvant treatment that complements currently used treatment regimens by providing the immune system with an additional opportunity to be exposed effectively to autologous TAA.

Identification of a leukemic counterpart of the plasmacytoid dendritic cells.

This work aims to demonstrate that CD4(+)CD56(+) malignancies arise from transformed cells of the lymphoid-related plasmacytoid dendritic cell (pDC) subset. The analysis of malignant cells from 7 patients shows that in all cases, like pDCs, leukemic cells are negative for lineage markers CD3, CD19, CD13, CD33, and CD11c but express high levels of interleukin-3 receptor alpha chain (IL-3Ralpha), HLA-DR, and CD45RA. Tumor cells produce interferon-alpha in response to influenza virus, while upon maturation with IL-3 they become a powerful inducer of naive CD4(+) T-cell proliferation and promote their T-helper 2 polarization. As pDCs, leukemic cells also express pre-Talpha and lambda-like 14.1 transcripts, arguing in favor of a lymphoid origin. In addition, malignant cells express significant levels of CD56 and granzyme B. Overall, those observations suggest that CD4(+)CD56(+) leukemic cells could represent the malignant counterpart of pDCs, both of which are closely related to B, T, and NK cells.

From the study of tumor cell immunogenicity to the generation of antitumor cytotoxic cells in non-Hodgkin's lymphomas.

The question of the immunogenicity of non-Hodgkin's lymphoma (NHL) B cells has been investigated in an attempt to support the development of new immunotherapeutic treatments for this disorder, which remains resistant to conventional treatments in most cases. In the present review, we report and discuss our new findings in the field of NHL B cell immunogenicity. One aspect of our work is the description of the expression and functions of membrane molecules associated with antigen presentation. The expression levels of adhesion molecules was measured, and the relevance of this expression to the sensitivity of malignant B cells to cell-mediated lysis was studied. Since the T cell response relies on the expression of both HLA class I and II molecules, we also investigated whether or not these molecules were present at the surface of NHL B cells. Subsequently, we asked whether antitumor CTL and LAK cells could be developed and analyzed the mechanisms of cell lysis involved. Since the generation of a T cell response requires the expression of the costimulatory molecules CD80 and CD86, we investigated their in vivo expression and their modulation in vitro during contact with responding T lymphocytes. The understanding of the immunogenicity of NHL B cells has enabled us to develop a new culture protocol to induce antitumor specific autologous CTL. The originality of NHL B cells--unlike most other tumor cells--is to be able to function as antigen presenting cells (APC) and to activate a T cell response in the absence of other professional APC. Over the next few years, these findings should allow the generation of anti-NHL specific T cells for adoptive immunotherapy and for the identification of NHL-associated antigens.