FAPP2 gene downregulation increases tumor cell sensitivity to Fas-induced apoptosis.

The gene for phosphatidylinositol-4-phosphate adaptor-2 (FAPP2) encodes a cytoplasmic lipid transferase with a plekstrin homology domain that has been implicated in vesicle maturation and transport from trans-Golgi to the plasma membrane. The introduction of ribozymes targeting the FAPP2 gene in colon carcinoma cells induced their apoptosis in the presence of Fas agonistic antibody. Furthermore, by quantitative PCR we showed that a siRNA specific to FAPP2, but not a randomized siRNA control, reduced FAPP2 gene expression in tumor cells. Transfection of FAPP2 siRNA into human tumor cells then incubated with FasL resulted in reduction of viable cell numbers. Also, FAPP2 siRNA transfected glioma and breast tumor cells showed significant increases in apoptosis upon incubation with soluble FasL, but the apoptosis did not necessarily correlate with increased Fas expression. These data demonstrate a previously unknown role for FAPP2 in conferring resistance to apoptosis and indicate that FAPP2 may be a target for cancer therapy.

Immunoresistant human glioma cell clones selected with alloreactive cytotoxic T lymphocytes: downregulation of multiple proapoptotic factors.

We previously reported the cellular, functional and cytogenetic characterization of immunoresistant (IR) 13-06-IR29 and 13-06-IR30 human glioma cell clones isolated after immunoselection with alloreactive cytotoxic T lymphocytes (aCTL). Relative to the 13-06-MG parental cells, both clones resisted aCTL lysis at multiple effector to target ratios; the resistant phenotype was maintained for 13-41 cell doublings after cloning and when selective pressure was removed; cross-resistance to other inducers of apoptosis/cell death was also observed (Gomez et al, 2006; Gomez and Kruse, 2007). In this study we further characterize the IR clones for factors that may contribute to the resistance. Data obtained by in-vitro quantitative morphologic and 7-amino actinomycin D flow cytometric assays revealed reduced apoptotic cell death when IR clones were coincubated with aCTL, relative to the parental cells. Since changes in apoptosis were observed, we examined the expression patterns of apoptosis-related genes in several extracts of parental cells and IR clones using pathway-specific cDNA microarray analysis. In general, the apoptotic factors were downregulated in the IR clones. From three separate extracts analyzed separately on microarrays, three factors, ATM, caspases 3 and 8, were statistically downregulated in both IR clones. Immunoblotting of the proteins confirmed the findings. Therefore, a possible mechanism for immunoresistance in gliomas may be achieved by the downregulation of one or more genes in the apoptotic pathway.

siRNA Down-regulation of the PATZ1 Gene in Human Glioma Cells Increases Their Sensitivity to Apoptotic Stimuli.

The PATZ1 gene encodes a transcription factor that belongs to the BTB/POZ group of transcriptional regulators and has been implicated as a transcriptional repressor. We cloned cDNA from glioma cell lines and found they expressed transcript variant 2 of PATZ1. We designed a specific siRNA against PATZ1 and showed that this siRNA, but not a control randomized siRNA, reduced PATZ1 expression in glioma cells as determined by quantitative PCR. In a panel of human glioma cell lines incubated with proapoptotic FasL, those transfected with PATZ1 siRNA displayed reduced cell numbers by the MTT colorimetric assay, relative to those transfected with randomized siRNA. Further studies showed that in 10-08-MG, U-251MG, U-87MG, and T98G cells PATZ1 siRNA significantly increased apoptosis in response to incubation with soluble FasL, as shown by a morphologic acridine orange/ethidium bromide apoptotic assay. Using an apoptosis specific cDNA microarray we further demonstrated that down-regulation of PATZ1 by siRNA resulted in the upregulation of death receptor pro-apoptotic genes including caspase 8 and Death Receptor 5 (DR5) in U-373MG cells. Since DR5 is the receptor for TRAIL we tested whether PATZ1 downregulation also sensitized cells to TRAIL-induced apoptosis and found that PATZ1 siRNA, but not control siRNA, sensitized U-251MG and T98G glioma cells to TRAIL-induced apoptosis. Altogether, these data demonstrate a previously unknown role for the transcription factor PATZ1 in conferring resistance to apoptosis and indicate that modulation of PATZ1 expression may be a therapeutic strategy for gliomas.

Catalytic nucleic acid enzymes for the study and development of therapies in the central nervous system: Review Article.

Nucleic acid enzymes have been used with great success for studying natural processes in the central nervous system (CNS). We first provide information on the structural and enzymatic differences of various ribozymes and DNAzymes. We then discuss how they have been used to explore new therapeutic approaches for treating diseases of the CNS. They have been tested in various systems modeling retinitis pigmentosum, proliferative vitreoretinopathy, Alzheimer's disease, and malignant brain tumors. For these models, effective targets for nucleic acid enzymes have been readily identified and the rules for selecting cleavage sites have been well established. The bulk of studies, including those from our laboratory, have emphasized their use for gliomas. With the availability of multiple excellent animal models to test glioma treatments, good progress has been made in the initial testing of nucleic acid enzymes for brain tumor therapy. However, opportunities still exist to significantly improve the delivery and efficacy of ribozymes to achieve effective treatment. The future holds significant potential for the molecular targeting and therapy of eye diseases, neurodegenerative disorders, and brain tumors with these unique treatment agents.

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.