Judy Kantor

Acquisition of CD80 (B7-1) by T cells

Activation of T cells usually requires two signals. Signal 1 is mediated via a peptide-MHC on the APC; signal 2 is mediated via a costimulatory molecule on the APC surface. We demonstrate here that naive CD4+ T cells actually acquire the costimulatory molecule CD80 (B7-1) from syngeneic APCs after activation. This phenomenon was demonstrated showing acquisition of CD80 by T cells from CD80/CD86 (B7-2) knockout mice, and by treating T cells with cyclohexamide to further rule out endogenous expression of CD80 by T cells. Moreover, no CD80 mRNA could be detected in T cells that had acquired CD80. The amount of acquisition of CD80 by T cells was shown to be directly related to both the strength of signal 1 and the amount of CD80 on the APC. Specificity of this acquisition was also shown by the lack of acquisition by T cells from CD28 knockout mice (implicating CD28 in this process), the lack of acquisition of CD40 (another molecule on the APC surface) by T cells, and confocal microscopy studies. We demonstrate for the first time that 1) naive T cells, following acquisition of CD80 from APCs, were themselves shown to be capable of acting as APCs; and 2) memory T cells that have acquired CD80 from APCs undergo apoptosis in the presence of increased levels of signal 1. Thus we demonstrate both immunostimulatory and immunoregulatory functions as a result of CD80 acquisition by different T cell populations.

The use of combination vaccinia vaccines and dual-gene vaccinia vaccines to enhance antigen-specific T-cell immunity via T-cell costimulation

Several recombinant vaccinia viruses are currently being evaluated to induce antigen-specific immunity to a variety of infectious disease agents and tumor associated antigens. T-cell costimulation is extremely important in enhancing T-cell responses, and recombinant vaccines have now been shown to be effective vectors to express a range of these molecules. Both combination vaccines (an admixture of a recombinant vaccinia virus expressing a specific target antigen and a recombinant vaccinia virus expressing a costimulatory molecule) and dual-gene vaccines expressing both transgenes on the same vector have been shown capable of effectively enhancing antigen-specific responses via T-cell costimulation. In this report, we compare for the first time the use of both types of approaches to enhance antigen-specific T-cell responses, and we demonstrate the importance of route of vaccine administration and vaccine dose in attaining optimal T-cell responses. These studies should have direct bearing on the design of vaccine clinical trials for infectious agents and/or tumor associated antigens, in which T-cell costimulatory molecules will be employed to enhance antigen-specific T-cell responses via the use of either combination or dual-gene vaccinia vaccines.

Strategies for the development of recombinant vaccines for the immunotherapy of breast cancer

SummaryThe development of recombinant vaccines for specific immunotherapy of carcinoma represents a novel approach for the treatment of breast cancer and other tumor types. This article reviews the various parameters that should be considered in the development of recombinant vaccines. Several breast cancer associated antigens are also discussed which may provide potential target molecules. The human carcinoembryonic antigen (CEA), which is expressed on approximately 50% of breast cancers, represents one such target for immunotherapy. To enhance the immunogenicity of this antigen, a recombinant CEA-vaccinia vaccine, designated rV-CEA, was produced. To study the effects of this vaccine in an animal model, a murine colon carcinoma cell line was transduced with CEA and transplanted into immunocompetent mice for protection and therapy studies. Pre-clinical toxicity studies were also conducted in non-human primates. The results of these studies showed the rV-CEA vaccine to be immunogenic and safe in both rodents and primates, and to elicit good anti-tumor responses in the rodent model. In a Phase I clinical trial in metastatic breast, lung, and colorectal cancer patients involving three immunizations of rV-CEA, at three dose levels, enhancement of T-cell and antibody responses to vaccinia virus proteins were observed with no toxicity. Specific T-cell responses were studied via stimulation of peripheral blood lymphocytes with specific peptide epitopes from the CEA molecule. These studies demonstrated clear cut differences in establishment of T-cell lines pre- versus post-immunization. The T-cell lines were shown to be CD8+ and/or CD4+/CD8+, to lyse EBV transformed B-cells transduced with the CEA gene, and to lyse CEA positive carcinoma cells in a HLA restricted manner. Thus, in a Phase I clinical trial the rV-CEA vaccine has been shown to stimulate a CTL response specific for CEA defined epitopes in cancer patients.

Immunization with a syngeneic tumor infected with recombinant vaccinia virus expressing granulocyte-macrophage colony-stimulating factor (GM-CSF) induces tumor regression and long-lasting systemic immunity.

Summary A recombinant vaccinia virus encoding the gene for granulocyte-macrophage colony-stimulating factor (rV-GM-CSF) was used to infect the poorly immunogenic murine colon adenocarcinoma cell line, MC-38. Infection of MC-38 tumor cells with rV-GM-CSF completely suppressed the growth of the MC-38 primary tumors, whereas progressively growing tumors were formed in mice injected with MC-38 cells infected with wild type V-Wyeth. Irradiation of the recipient B6 mice before implantation of rV-GM-CSF-infected tumor cells resulted in the development of progressively growing tumors. Moreover, in vivo T-cell depletion studies revealed that growth suppression of the rV-GM-CSF-infected tumor cells was dependent on the presence of both CD4+ and CD8+ T-cell subsets. Subsequent studies established that this immunity was long-lasting and antigen specific, as demonstrated by the protection of rV-GM-CSF-immunized mice from MC-38 tumor challenge but not from challenge with another syngeneic tumor cell type. No such effects were observed when MC-38 tumor cells were infected with recombinant vaccinia viruses expressing interleukin (IL)-2 or IL-6. The results demonstrate that paracrine release of biologically active murine GM-CSF by tumor cells infected with rV-GM-CSF enhances the intrinsic immunogenicity of a poorly immunogenic murine tumor. Presumably the augmentation of tumor immunogenicity induces an antigen-specific T-cell-dependent antitumor response that prevents the formation of primary tumors and protects mice from tumor challenge. Thus in this experimental model, GM-CSF functions as a highly effective vaccine adjuvant.

Induction of Anti-Tumor Immunity Elicited by Tumor Cells Expressing a Murine LFA-3 Analog via a Recombinant Vaccinia Virus

T cell activation requires binding of the T cell receptor to the major histocompatibility molecule-peptide complex in the presence of adhesion and/or costimulatory molecules such as B7-1 (CD80), B7-2 (CD86), ICAM-1 (CD54), and LFA-3 [corrected]. The major ligand of CD2 is CD48, the murine analog of human leukocyte function-associated antigen 3 (LFA-3). To determine the effect of LFA-3 expression on the immunogenicity of tumor cells, we constructed a recombinant vaccinia virus containing the murine LFA-3 gene (designated rV-LFA-3). rV-LFA-3 was shown to be functional in vitro in terms of expression of LFA-3, T cell proliferation, adhesion, and cytotoxicity. Subcutaneous inoculation of rV-LFA-3-infected murine colon adenocarcinoma tumor cells (MC38) into immunocompetent syngeneic C57BL/6 mice resulted in complete lack of tumor growth. Inoculation of MC38 cells infected with equal doses of control wild-type vaccinia virus resulted in tumor growth in all animals. In addition, partial immunological protection was demonstrated against subsequent challenge with uninfected parental tumor cells up to 56 days after vaccination with rV-LFA-3-infected cells. Anti-tumor memory was also demonstrated by using gamma-irradiated MC38 cells and cells from another carcinoma model (CT26). These studies demonstrate that expression of LFA-3 via a poxvirus vector can be used to induce anti-tumor immunity.

Vaccination with a recombinant vaccinia vaccine containing the B7-1 co-stimulatory molecule causes no significant toxicity and enhances T cell-mediated cytotoxicity

B7‐1 is a co‐stimulatory molecule that provides a second signal for T‐cell activation. Several studies have demonstrated that vaccination with a vector containing genes encoding B7‐1 and an antigen appears to be efficacious at promoting immune responsiveness to the antigen. To evaluate the safety of such a protocol and determine the effect of the B7‐1 vector on immune responsiveness, female C57BL/6 mice were administered Wyeth wild‐type vaccinia virus (V‐WT) or V‐WT containing the gene for B7‐1 (rV‐B7‐1) as a single s.c. injection or 3 monthly s.c. injections. Immunologic parameters were evaluated in half of the mice and general toxicity in the other half. Immunologic end points included determination of splenic lymphocyte phenotypes, mitogen‐induced T‐ and B‐cell proliferation, T‐cell proliferation in response to alloantigens, cell‐mediated cytotoxicity (CMC), natural killer cell activity and serum anti‐nuclear antibody (ANA) titers. No significant signs of general toxicity were noted. The primary immunologic effect was an increase in the ability of spleen cells to lyse allogeneic targets and to proliferate in response to allogeneic stimulation. Numbers of splenic CD8+ cells were also increased. These effects were more pronounced after 3 vaccinations than after a single vaccination. Minimal differences in ANA were observed between mice immunized with V‐WT and rV‐B7‐1. In addition, no serum antibodies against B7‐1 were detected in any mice. The data suggest that vaccination with rV‐B7‐1 augments CMC with minimal toxicity. Int. J. Cancer 85:508–517, 2000.

CELL-FREE TRANSCRIPTION OF HUMAN BONE MARROW CHROMATIN

The fractionation of the rabbit reticulocyte (which is essentially the cytoplasm of the red blood cell) is shown in FIGURE 1. As was discussed earlier, the cell-free translational system can faithfully synthesize globin from a messenger RNA template. On the bottom line of FIGURE 1 are shown the various cytoplasmic components of the cell including the messenger RNA, ribosomes, initiation factors, elongation factors, tRNA, etc. Other studies in this volume indicate that the defect in thalassemia is present in the messenger RNA and that all other translational components appear to be normal in thalassemic cells. Elegant studies by Bank and colleagues1.18 as well as similar studies by Forget and his colleagues 2, indicate that the absolute amount of p-globin mRNA is decreased in /3 thalassemia, and a-globin mRNA is decreased in a thalassemia.

Low-level transforming activity of an activated Ras gene under the control of a vaccinia virus p40 promoter is abrogated by truncation of the Ras cDNA

Many human cancers have been shown to contain activated forms of the Ras proto-oncogene. Mutations comprising amino acid changes at codons 12, 13 and 61 therefore represent unique targets for cancer immunotherapy. Recombinant Vaccinia viruses encoding point mutated Ras oncogenes have raised issues concerning the safety and transforming ability of these recombinant vaccines. Vaccinia virus, a representative of the orthopox virus genus, is a large DNA virus that is cytopathogenic and that replicates in the cytoplasm of the infected cell. However, it remains unclear whether orthopox viruses are capable of genetic interactions with infected cells. Our studies show that DNA isolated from cells infected with a recombinant Vaccinia virus expressing mutated Ras constituted a poor reagent for transfection into NIH3T3 cells for transformation analysis. Stable integration of a recombinant Vaccinia virus expressing mutant Ras DNA was not detected in recipient cells. This study also demonstrates that the crossover plasmids used to generate the recombinant virus where the activated Ras gene is under the control of a Vaccinia virus early promoter had low but detectable transforming efficiency in the NIH3T3 transformation assay. Analysis of the transfected cells indicated that Ras transcription was initiated upstream of the Vaccinia virus promoter. The introduction of wobble mutations as well as the truncation of the Ras protein removed the transforming capabilities of the crossover vector. This study demonstrates the potential problems and solutions in the use of point mutated oncogenes in live vectors for cancer vaccine development.