Showing papers by "Timothy L. Ratliff published in 2001"

NK cells are essential for effective BCG immunotherapy

Abstract: Adjuvant intravesical bacillus Calmette-Guerin (BCG) therapy is a well-established and successful adjuvant immunotherapy in the treatment of superficial bladder cancer. Although the function of natural killer (NK) cells in other immunotherapeutic regimens (e.g., lymphokine-activated killer [LAK] cell or interleukin-2 [IL-2] therapy) has been established, the contribution of NK cells to effective BCG immunotherapy is not clear. We used a human in vitro system to analyze the role of NK cells in BCG-induced cellular cytotoxicity. After stimulation of mononuclear cells with BCG for 7 days, these BCG-activated killer (BAK) cells displayed substantial cytotoxicity against bladder tumor cells. Magnetic depletion experiments and fluorescence activated cell sorting revealed that NK cells were the major effector cell population. To address NK cell function in vivo, we studied a syngeneic orthotopic murine bladder cancer model and compared BCG immunotherapy in C57BL/6 wild-type mice, NK-deficient beige mice and mice treated with anti-NK1.1 monoclonal antibody. Four weekly instillations of viable BCG significantly prolonged survival in wild-type mice compared with control mice treated with solvent alone. In contrast, BCG therapy was completely ineffective in NK-deficient beige mice and in mice treated with anti-NK1.1 monoclonal antibody. These findings suggest a key role for NK cells during BCG immunotherapy.

Immunization with type 5 adenovirus recombinant for a tumor antigen in combination with recombinant canarypox virus (ALVAC) cytokine gene delivery induces destruction of established prostate tumors.

Abstract: Prostate-specific antigen (PSA) is expressed by prostate epithelial cells and has a highly restricted tissue distribution. Prostatic malignancies in 95% of patients continue to express PSA, making this antigen a good candidate for targeted immunotherapy. The goals of our studies are to generate a recombinant PSA adenovirus type 5 (Ad5-PSA) that is safe and effectively activates a PSA-specific T-cell response capable of eliminating prostate cancer cells, and to characterize the immunologic basis for this rejection. Here we show that immunization of mice with Ad5-PSA induced PSA-specific cellular and humoral immunity that was protective against a subcutaneous challenge with RM11 prostate cancer cells expressing PSA (RM11psa), but not mock-transfected RM11 tumor cells (RM11neo). Mice immunized with recombinant adenovirus type 5 encoding beta-galactosidase (Ad5-lacZ) did not generate protective immunity. Antitumor activity was predominantly mediated by CD8(+) T lymphocytes. Although Ad5-PSA immunization prior to RM11psa challenge was protective, Ad5-PSA immunization alone was not able to control the growth of existing RM11psa tumors. In contrast, established RM11psa tumors ranging in size from 500 to 1,000 mm(3) were efficiently eliminated if Ad5-PSA priming was followed 7 days later by intratumoral injection of recombinant canarypox viruses (ALVAC) encoding interleukin-12 (IL-12), IL-2, and tumor necrosis factor-alpha. In this case, antitumor immunity was still dominated by CD8(+) T lymphocytes, but natural killer cells became necessary for a maximal response. These data provide information on the effector cell populations in a protective immune response to prostate cancer and demonstrate the utility of an Ad5-PSA vaccine combined with cytokine gene delivery to eliminate large established tumors that are refractory to other interventional methods.

Cutting edge: restoration of the ability to generate CTL in mice immune to adenovirus by delivery of virus in a collagen-based matrix.

Abstract: Viruses are commonly used for the delivery of genes coding for tumor-associated Ags to elicit tumor-specific immune responses. The success of viral vectors has been limited in preclinical and clinical trials in part because of antiviral immunity. We investigated the ability of a collagen-based matrix (Gelfoam; Pharmacia and Upjohn, Kalamazoo, MI) to improve CTL activation by recombinant adenovirus. The data show that coinjection of Gelfoam with type 5 adenovirus recombinant for prostate-specific Ag (Ad5-PSA) enhanced CTL activation. Ad5-PSA priming in Gelfoam also abrogated the inhibitory effects of adenoviral immunity on CTL activation in mice naive to PSA but immune to adenovirus. Finally, Gelfoam enhanced immunization in a self-Ag model using type 5 adenovirus recombinant for membrane-bound OVA (Ad5-mOVA) in rat insulin promoter (RIP)-mOVA-transgenic mice. Thus, Gelfoam enhances CTL activation by recombinant viral vectors in a setting where preformed Ab to the virus is present and also in a tolerant self-Ag model.

Inhibition of Murine Prostate Tumor Growth and Activation of Immunoregulatory Cells With Recombinant Canarypox Viruses

Abstract: BACKGROUND Immunization with modified tumor cells carrying recombinant immunomodulatory genes is being explored as cancer immunotherapy. In this study, we examine whether canarypox ALVAC viruses carrying immunostimulatory cytokine genes (granulocyte-macrophage colony-stimulating factor, interleukin 2, interleukin 12, and tumor necrosis factor-alpha) can induce antitumor immunity (to rechallenge) in the RM-1 model of a highly aggressive, weakly immunogenic murine prostate cancer. METHODS For antitumor activity studies, RM-1 murine prostate cancer cells were infected with the parental ALVAC virus or one or two recombinant ALVAC-cytokine viruses and then injected into male C57BL/6 mice. For rechallenge studies, other mice were first given an injection subcutaneously with irradiated (nonproliferating) recombinant ALVAC-infected RM-1 cells and then (10 days later) with untreated RM-1 cells. For the determination of which immune cells were required for antitumor activity, mice were immunodepleted of CD4, CD8, or natural killer (NK) NK1.1 cells with the corresponding monoclonal antibodies and were then given an injection of ALVAC-cytokine-infected RM-1 cells. For all experiments, tumor outgrowth and animal survival were monitored. RESULTS After subcutaneous injection into mice, RM-1 cells infected with one (except ALVAC-interleukin 2) or two ALVAC-cytokine recombinants had statistically significantly greater antitumor activity than RM-1 cells infected with parental ALVAC (P<.001 for all; two-sided test). The antitumor activity of RM-1 cells infected with any two ALVAC-cytokine recombinants was greater than, but not statistically significantly different from, that of RM-1 cells infected with any one ALVAC-cytokine recombinant. NK1.1 cells were necessary for antitumor activity, but tumor-specific CD4(+) regulatory T cells were also induced that inhibited CD8(+) RM-1-specific cytotoxic T cells, resulting in the lack of immunity to a rechallenge by RM-1 cells. DISCUSSION Canarypox viruses can transfer immunostimulatory cytokine genes into RM-1 prostate cancer cells. When such cells were injected into mice, the cytokines induced an antitumor response against this highly aggressive, weakly immunogenic tumor. This response, however, did not protect the mouse against a rechallenge with RM-1 cells because suppressor CD4(+) T cells were induced that inhibited tumor-specific CD8(+) cytotoxic T cells.

Vaccines in urologic malignancies.

Abstract: The prospect of activating the immune system to combat neoplastic disease has stimulated the interest of clinicians and scientists for over 100 years. Despite a few notable exceptions (especially with urologic malignancies), immunotherapy has not fully reached its considerable therapeutic potential for the treatment of cancer. Tumors undoubtedly express antigens that may act as targets for antitumor immunity, and advances in molecular biology and tumor immunology have recently revived the possibility of a cancer vaccine. This improved understanding has resulted in numerous successes with active immunotherapy in animal models and has facilitated the clinical testing of cancer vaccines. Ongoing advances in the identification of unique, tumor-specific antigens and their presentation to stimulate T cells will be necessary for the emergence of these novel vaccine therapies for cancer patients. Herein we review the current concepts of tumor immunology, including observations on cell types probably involved with the immune surveillance of tumors, the presentation and recognition of “foreign” antigens, and possible mechanisms of tumor escape from the immune response, all of which are critical to the understanding of new initiatives for cancer vaccine therapy. Finally, we review some of the successes and limitations of vaccine therapy for urologic malignancies.

Biomarker distribution after injection into the canine prostate: implications for gene therapy.

Abstract: Objective To evaluate the distribution of biomarkers after transrectal injection into the canine prostate and to report a method for enhancing the distribution of gene expression. Materials and methods Carbon black was first used to evaluate the histopathological distribution in canine prostate of single or multiple injections via the transurethral, transperineal and transrectal routes. The distribution of canarypox virus (ALVAC) vector-delivered gene expression was then compared using both fluid-phase injection techniques and delivery in a solid carrier composed of a gelatine sponge matrix. Results After transurethral administration, carbon black was detected as scattered particles in ducts and acini, mostly in the periphery of the gland. Direct transrectal injection of carbon black resulted in a localized collection at the site of injection, with only a minimal peri-acinar distribution. Transrectal injection of the fluid-phase (virus suspended in diluent) ALVAC vector encoding the β-galactosidase gene resulted in a similar distribution, with limited gene expression at the site of injection and in the needle track. Delivery of the same number of virus particles in the gelatine sponge matrix resulted in qualitatively greater gene expression. Conclusions Direct injection of the canine prostate with biomarkers, including viral vectors, in the fluid-phase results in very localized gene expression, while the distribution was more widespread after delivery in a gelatine sponge matrix.