Human alloreactive CTL interactions with gliomas and with those having upregulated HLA expression from exogenous IFN-gamma or IFN-gamma gene modification.

By flow cytometry, a panel of 18 primary glioma cell explants exhibited high expression of class I HLA-A, B, C, but class II HLA-DR expression was absent. Freshly isolated normal brain cells displayed little or no HLA antigens. Alloreactive cytotoxic T lymphocytes (aCTL), sensitized to the HLA of the patient, were generated in a one-way mixed lymphocyte response (MLR). The specificity of aCTL was confirmed to be to target cells (patient glioma cells or lymphoblasts) expressing the relevant HLA antigens. However, nontumor patient-specific aCTL did not lyse normal brain cells. Titration of antibodies to HLA class I into cytotoxicity assays blocked lysis of gliomas by aCTL, confirming aCTL T cell receptor (TCR) interactions with the class I antigen on gliomas. Furthermore, aCTL interactions with glioma cells caused their apoptosis. Coincubations of aCTL with gliomas resulted in upregulated cytokine secretion. Importantly, dexamethasone, an immunosuppressive steroid used for brain edema, did not affect aCTL lytic function against tumor, indicating that steroid-dependent patients may benefit from the immunotherapy. We also explored the use of interferon-gamma (IFN-gamma) to increase aCTL tumor recognition. Coincubation of gliomas with exogenous IFN-gamma (500 U/ml, 48 h) caused a 3-fold upregulation of HLA class I and a slight induction of class II antigen expression. Gene-modified glioma cells producing IFN-gamma similarly displayed upregulated HLA expression. Glioma cells incubated with exogenous IFN-gamma or IFN-gamma-transduced glioma cells were more susceptible to lysis by aCTL than their parental counterparts, thus supporting the concept of combining IFN-gamma cytokine gene therapy with adoptive aCTL immunotherapy for brain tumor treatment.

Ribozyme to proliferating cell nuclear antigen to treat proliferative vitreoretinopathy.

PURPOSE: A DNA-RNA chimeric ribozyme was developed that targets the mRNA of a cell cycle regulatory protein, proliferating cell nuclear antigen (PCNA). The hypothesis was that inhibition of PCNA, essential in DNA replication, would decrease the proliferation of cells that are involved in formation of granuloma after surgical procedures in the eye. The ability of intravitreous injection of this ribozyme to prevent or inhibit development of proliferative vitreoretinopathy (PVR) was tested in a dispase-induced rabbit PVR model. METHODS: Rabbit genomic DNA encoding PCNA was cloned and sequenced. The cleavage of rabbit PCNA by the chimeric ribozyme was tested in vitro. Delivery of the ribozyme to rabbit retinal pigment epithelial (RPE) or fibroblast cells and its effects on proliferation of fibroblasts were examined. The stability of the ribozyme in vitreous fluid and serum was studied as well. In the dispase-induced rabbit model of PVR, the ability of the PCNA ribozyme to prevent or inhibit development of PVR and retinal detachment (RD) was tested. Experimental groups receiving intravitreous PCNA ribozyme, with or without a lipid vehicle, were compared with sham-treated control groups. Progression of PVR in rabbit eyes was followed by indirect ophthalmic examination and observations documented by fundoscopic photography, gross pathology, and histopathology. RESULTS: The chimeric ribozyme targeted a specific sequence in the rabbit PCNA that was identical with that in the human. In vitro cleavage assays confirmed the ability of the ribozyme to cleave the mRNA of PCNA. The catalytic efficiency in vitro, calculated as k(2)/K(m)(app), was 0.26 microM(-1) x min(-1). In vitro studies with fluoresceinated ribozyme indicated that lipid vehicles facilitated delivery of the ribozyme into cells causative of PVR (RPE and fibroblasts); however, the PCNA ribozyme decreased the proliferation of fibroblasts, with or without lipid vehicle. The ribozyme displayed good stability in vitreous fluid, whereas, it degraded quite rapidly in serum. In animal experiments, rabbits in sham-treated groups usually exhibited development of severe PVR characterized by focal traction or RD. Animals in the PCNA ribozyme-treated groups usually did not exhibit an RD. If they did have RD, it was small and localized, or focal tractions developed that did not progress to the degree that the sham-treated animal eyes did over the follow-up period. The in vivo use of a lipid delivery vehicle resulted in a precipitate; however, an effective naked ribozyme dose was identified that did not cause this side effect. CONCLUSIONS: In addition to validating the newly developed dispase PVR rabbit model, the results indicate that ribozyme targeted against the cell cycle agent PCNA is efficacious in the treatment or prevention of PVR in the rabbit eye. These experiments suggest that chimeric ribozyme targeted against PCNA may have a therapeutic or preventative role in humans.

Gamma interferon transduced 9L gliosarcoma. Cytokine gene therapy and its relevance to cellular therapy with alloreactive cytotoxic T lymphocytes.

In earlier studies, we demonstrated that intratumoral infusions of alloreactive cytotoxic T lymphocytes (aCTL), sensitized to the major histocompatibility complex (MHC) antigens of the host, effectively retarded the intracranial growth of Fischer 9L gliosarcoma. We further demonstrated that continuous in vitro exposure to gamma-interferon (gammaIFN) upregulates MHC on 9L gliosarcoma cells and that they were better targets of anti-Fischer aCTL. We hypothesized that the efficacy of cellular therapy with aCTL could be further improved by in situ transduction of the tumor with retroviral vectors coding for gammaIFN, which would generate continuous secretion of the cytokine and maintain upregulated MHC expression by the tumor cells. 9L gliosarcoma and Herpes simplex virus thymidine kinase (tk) transductants of those cells were transduced with a retrovirus carrying the murine gammaIFN gene. By limiting dilution, clones of these cells, designated 9Lgamma 7, 9Lgamma tk8, and 9Lgamma tk10, which produced similar levels of gammaIFN (383-411 ng gammaIFN/10(6) cells/24 h) were isolated. The production of gammaIFN by one clone, 9Lgamma 7, was stable when monitored over 6 weeks in vitro. The clones also demonstrated upregulated MHC class I expression, and the tk-transduced clones maintained their sensitivity to ganciclovir. Compared to the wildtype cells, 9Lgamma 7 had approximate 6- and 1.5-fold increases in the relative antigen densities of MHC I and II, respectively. Addition of exogenous gammaIFN to 9Lgamma 7 cultures did not significantly increase the MHC expression. In cytotoxicity assays, 9Lgamma 7 cells, or 9Lgamma 7 incubated with exogenous gammaIFN, were better targets of aCTL than the parental 9L cells. The growth rate of 9Lgamma-transduced cells was decreased compared to the wildtype cells both in vitro and in vivo. Proliferation studies with transwell plated 9L, 9Lgamma 7, and 9Lgamma tk10 cells in various combinations revealed that the secreted cytokine itself caused a decrease in proliferation. However, the transduced cells exhibited a much reduced growth rate, which likely was a consequence of redirected metabolic activity of the cells. In vivo growth of the 9L and 9Lgamma 7 tumors in rat brains given identical inoculums similarly demonstrated significantly reduced 9Lgamma 7 tumor volumes at various timepoints, indicative of slower growth of the gammaIFN-producing tumors.