María José Gravisaco

A novel Salmonella Typhi-based immunotherapy promotes tumor killing via an antitumor Th1-type cellular immune response and neutrophil activation in a mouse model of breast cancer

We investigated the use of a live, attenuated Salmonella enterica serovar Typhi vaccine strain as an antitumor immunotherapy. Mice bearing a subcutaneous tumor (LM3 mammary adenocarcinoma) were immunized on three occasions with S. Typhi strain CVD 915 by injection into the tumor, the peritumoral tissue and the draining lymph node areas; this procedure was termed Salmonella multiple treatment (Salmonella MT). Tumor-bearing mice subjected to the Salmonella MT exhibited reduced tumor growth, prolonged survival and reduced incidence of lung metastases, compared to untreated mice. We examined the mechanisms mediating this effect and found that Salmonella MT promoted an antitumor Th1-type response characterized by increased frequencies of IFN-γ-secreting CD4(+) T and CD8(+) T cells with reduction of regulatory T cells in tumor draining lymph nodes. The main cells infiltrating bacteria-treated tumors were activated neutrophils, which can exert an antitumor effect through the secretion of TNF-α. These results demonstrate for the first time the efficacy of an attenuated S. Typhi vaccine strain as a cancer immunotherapeutic agent. By potentiating the host antitumor immune response, this approach could be a powerful adjunct tool for cancer therapy.

Enhancement of anti-tumour immunity in syngeneic mice after MHC class II gene transfection.

The relationship between tumorigenicity and expression of MHC class II molecules in a class II-negative murine leukaemia cell line (LBC) was studied. Analysis of structural DNA sequences encoding MHC class II proteins was performed by Southern blot with DNA isolated from both the original LB tumour and LBC cell line, digested with EcoRI, BamHI and HindIII and hybridised with specific probes for I-A alpha d and I-A beta d chains. Similar patterns were obtained for LB, LBC and normal BALB/c lymphocytes. In vitro treatment with IFN-gamma (20 - 1000 IU ml-1) failed to induce the expression of MHC class II antigens in LBC cell line. LBC cells were tri-transfected by a liposome-mediated protocol with I-A alpha d, I-A beta d genes and pSV2neo. Cells were selected for growth in medium containing Geneticin (G418). Surviving transfectants were cloned and three I-A+ clones were obtained after 20 days (LBCT cells). Syngeneic mice inoculated with 1.0 x 10(3) LBCT (I-A+) cells failed to develop a tumour, whereas the DT50 of mice injected with 1.0 x 10(6) LBCT cells was three times the value for mice injected with LBC cells (I-A-). Furthermore, specific CTL response against tumour cells was significantly enhanced upon priming with irradiated LBC-transfected cells (27 +/- 2%) compared with irradiated LBC cells (15 +/- 1.5%) in a 4 h 51Cr-release assay. It is suggested that neoexpression of MHC class II molecules enhances anti-tumour response by transforming tumour cells into professional antigen-presenting cells (APCs), which may be used to improve tumour-specific immunity in the autologous host.

Characterization of the immunophenotype and the metastatic properties of a murine T-lymphoma cell line. Unexpected expression of cytoplasmatic CD4

SummaryWe report the first characterization of a mouse T-lymphoma cell line that surprisingly expresses cytoplasmatic (cy) cyCD4. Phenotypically, LBC cells are CD5+, CD8+, CD16+, CD24+, CD25+, CD2−/dim, CD3−/dim, TCRβ−/dim, TCRγδ−, CD154−, CD40−, and CD45R−. Coexpress cyTCRβ, cyCD3, cyCD4, and yet lack surface CD4 expression. Transplantation of LBC cells into mice resulted in an aggressive T-lymphoblastic lymphoma that infiltrated lymph nodes, thymus, spleen, liver, ovary, and uterus but not peripheral blood or bone marrow. LBC cells display a modal chromosome number of 39 and a near-diploid karyotype. Based on the characterization data, we demonstrated that the LBC cell line was derived from an early T-cell lymphocyte precursor. We propose that the malignant cell transformation of LBC cells could coincide with the transition stage from late double-negative, DN3 (CD4−, CD8−CD44−/low, CD25+) or DN4 (CD4−/low, CD8−/low, CD44−, CD25−) to double-positive (DP: CD4+CD8+) stage of T-cell development. LBC cells provide a T-lymphoblastic lymphoma model derived from a malignant early T-lymphocyte that can be potentially useful as a model to study both cellular regulation and differentiation of T-cells. In addition, LBC tumor provides a short latency neoplasm to study cellular regulation and to perform preclinical trials of lymphoma-related disorders.

Vaccine strategies against Babesia bovis based on prime-boost immunizations in mice with modified vaccinia Ankara vector and recombinant proteins

In this study, a recombinant modified vaccinia virus Ankara vector expressing a chimeric multi-antigen was obtained and evaluated as a candidate vaccine in homologous and heterologous prime-boost immunizations with a recombinant protein cocktail. The chimeric multi-antigen comprises immunodominant B and T cell regions of three Babesia bovis proteins. Humoral and cellular immune responses were evaluated in mice to compare the immunogenicity induced by different immunization schemes. The best vaccination scheme was achieved with a prime of protein cocktail and a boost with the recombinant virus. This scheme induced high level of specific IgG antibodies and secreted IFN and a high degree of activation of IFNγ(+) CD4(+) and CD8(+) specific T cells. This is the first report in which a novel vaccine candidate was constructed based on a rationally designed multi-antigen and evaluated in a prime-boost regime, optimizing the immune response necessary for protection against bovine babesiosis.

Evaluation of different heterologous prime–boost immunization strategies against Babesia bovis using viral vectored and protein-adjuvant vaccines based on a chimeric multi-antigen

Protection against the intraerythrocytic bovine parasite Babesia bovis requires both humoral and cellular immune responses. Therefore, tailored combinations of immunogens targeted at both arms of the immune system are strategies of choice to pursue sterilizing immunity. In this study, different heterologous prime-boost vaccination schemes were evaluated in mice to compare the immunogenicity induced by a recombinant adenovirus, a modified vaccinia Ankara vector or a subunit vaccine all expressing a chimeric multi-antigen. This multi-antigen includes the immunodominant B and T cell epitopes of three B. bovis proteins: Merozoite Surface Antigen - 2c (MSA-2c), Rhoptry Associated Protein - 1 (RAP-1) and Heat Shock Protein 20 (HSP20). Both priming with the adenovirus or recombinant multi-antigen and boosting with the modified vaccinia Ankara vector achieved a high degree of activation of TNFα and IFNγ-secreting CD4(+) and CD8(+) specific T cells 60days after the first immunization. High titers of specific IgG antibodies were also detected at the same time point and lasted up to day 120 of the first immunization. Only the adenovirus - MVA combination triggered a marked isotype skew for the IgG2a antibody subclass meanwhile for the other immune traits analyzed here, both vaccination schemes showed similar performances. The immunological characterization in the murine model of these rationally designed immunogens led us to propose that adenoviruses as well as the bacterially expressed multi-antigen are highly reliable primer candidates to be considered in future experiments in cattle to test protection against bovine babesiosis.

Induction of Anti‐Tumour Immunity in Syngeneic Mice by Leukaemic Cell Line

Induction of anti‐tumour immunity in syngeneic mice by LBC cell line derived from a non‐immunogenic T cell leukaemia was studied. The immunization of BALB/c mice with LBC irradiated cells induced in them anti‐tumour spleen cells, cytotoxic T lymphocytes and anti‐LBC antibodies. The anti‐LBC antibodies reacted with components of 14, 16 and 27kDa present on LB tumour cells, LBC cell line and normal thymocytes, but not with normal lymph node cells. Furthermore, immunization of the autologous hosts with LBC cells partially protected them against subsequent challenge with the original LB leukaemic cells. These findings demonstrate that culture conditions induced modifications in the antigenic properties of the leukaemic cells, allowing LBC cells to stimulate an immune response directed against components expressed at early stages during T cell maturation. These results also suggest that the Immune response is responsible for the prolongation of the survival time of the mice inoculated with the parental leukaemic cells.