Cytokine gene therapy of gliomas: effective induction of therapeutic immunity to intracranial tumors by peripheral immunization with interleukin-4 transduced glioma cells.

To provide a means for comparing strategies for cytokine gene therapy against intracranial (i.c.) tumors, we generated rat gliosarcoma 9L cells transfected with interleukin-4 (9L-IL4), interleukin-12 (9L-IL12), granulocyte-macrophage colony-stimulating factor (9L-GMCSF) or interferon-alpha (9L-IFNalpha). To simulate direct and highly efficient cytokine gene delivery, cytokine transfected 9L tumors were implanted i.c. into syngeneic rats. i.c. injection led to tumor-outgrowth in the brain and killed most animals, whereas these cell lines were rejected following intradermal (i.d.) injection. Cytokine-expressing i.c. 9L tumors, however, had a greater degree of infiltration by immune cells compared with control, mock-transfected 9L-neo, but to a lesser degree than i.d. cytokine-expressing tumors. Tumor angiogenesis was suppressed in cytokine-transfected tumors. In a prophylaxis model, i.d. vaccination with 9L-IL4 resulted in long-term survival of 90% of rats challenged i.c. with parental 9L; whereas 40% of 9L-GM-CSF, 40% of 9L-IFNalpha and 0% of 9L-IL12-immunized rats were protected. In a therapy model (day 3 i.c. 9L tumors), only i.d. immunization with 9L-IL4 had long-term therapeutic benefits as 43% of rats survived >100 days. These data indicate that peripheral immunization with 9L-IL4 had the most potent therapeutic benefit among various cytokines and approaches tested against established, i.c. 9L tumors.

Direct stimulation of apoptotic signaling by soluble Apo2l/tumor necrosis factor-related apoptosis-inducing ligand leads to selective killing of glioma cells.

Apo2 ligand tumor necrosis factor-related apoptosis-inducing ligand (Apo2L/TRAIL) is a member of the tumor necrosis factor family that interacts with cell surface "death receptors" (DR4 and DR5) to initiate programmed cell death. Apo2L/TRAIL also binds to "decoy" receptors (DcR1 and DcR2) that can antagonize its interaction with DR4 and DR5. In recent studies, Apo2L/TRAIL has been noted to produce selective toxicity toward certain neoplastic cells versus normal cells. The decoy receptors may in part contribute to this selectivity, because they are expressed in various normal tissues but are present at low or undetectable levels in certain types of neoplastic cells. In the current study, we examined the potential therapeutic applicability of recombinant soluble Apo2L/TRAIL by investigating its effects in vitro and in vivo against a series of cell lines derived from malignant gliomas, which are often resistant to conventional treatment modalities. In cell proliferation assays, Apo2L/TRAIL produced a striking decrease in cell numbers, with a median inhibitory concentration of 30-100 ng/ml, in the TP53 wild-type high-grade glioma cell lines U87 and A172, the TP53-mutated T98G, and the TP53-deleted LN-Z308. In contrast, no significant effects were observed in non-neoplastic astrocytes at concentrations up to 3000 ng/ml. Clonogenic assays showed that exposure to Apo2L produced a time-dependent decrease in the viability of glioma-derived cell lines. This correlated with the induction of apoptosis as assessed by a terminal transferase-catalyzed in situ end-labeling assay. Pretreatment of the cells with the caspase inhibitors Acetyl-Asp-Glu-Val-L-aspartic acid aldehyde or Acetyl-Tyr-Val-Ala-Asp-chlormethylketone (200 microM) largely eliminated the effects of Apo2L/TRAIL. Administration of Apo2L/TRAIL (0.3, 1, 3, 10, and 30 mg/kg/day for 7 days via i.p. infusion) to nude mice harboring established intracranial U87 xenografts produced a significant, dose-dependent prolongation of survival versus control animals. Survival in the control group was 27 +/- 1.7 days, compared with more than 50 days in each of the treatment groups (P < 0.001). At the 30 mg/kg dose level, 100% of animals survived for 120 days without evidence of tumor, a substantial improvement in comparison with lower dose levels (P < 0.01). No overt toxicity was apparent even at the highest Apo2L dose. We conclude that soluble Apo2L/TRAIL is effective in inducing apoptosis in high-grade glioma cells in vitro. Because this ligand appears to exhibit selective cytotoxicity for glioma cells versus non-neoplastic cells in vitro and demonstrates significant activity in vivo when administered systemically in an otherwise uniformly fatal central nervous system glioma model system, Apo2L may constitute a useful therapeutic agent for these challenging tumors.

Inhibition of Ras and related guanosine triphosphate-dependent proteins as a therapeutic strategy for blocking malignant glioma growth: II--preclinical studies in a nude mouse model.

OBJECTIVE: Preliminary studies have demonstrated that the Ras family and related guanosine triphosphate-dependent proteins are overactivated in malignant gliomas and that inhibition of the activation of such proteins, by blockade of their post-translational processing, reduces tumor cell growth in vitro. The current study evaluates the utility of this therapeutic strategy in vivo, using preclinical glioma model systems. METHODS: We examined the efficacy against U-87 human malignant glioma cells, in both subcutaneous and intracranial nude mouse models, of selective peptidomimetic inhibitors of farnesyltransferase (FTI-276) and geranylgeranyltransferase (GGTI-297), which are involved in critical steps in the post-translational processing of Ras and related guanosine triphosphate-dependent proteins. For the subcutaneous model, 2 x 10(5) U-87 cells were implanted; after measurable tumors were detected on Day 7, animals were treated with either FTI-276, GGTI-297, or vehicle, administered by continuous infusion for 7 days. Differences in tumor volumes among the treatment groups were examined for significance using a Student's t test. For the intracranial model, 2 x 10(5) U-87 cells were implanted in the right frontal lobe and treatment was initiated on Day 7. In initial studies, animals received a 7-day course of either FTI-276, GGTI-297, or vehicle. In subsequent studies, a 28-day treatment period was used. Comparisons of survival times among treatment groups were performed using a rank-sum test. RESULTS: Although the two agents exhibited comparable antiproliferative activities in previous in vitro studies, an obvious difference in efficacy was apparent in this study. Whereas the geranylgeranyltransferase inhibitor failed to improve survival rates, compared with those observed for control animals, in either the subcutaneous or intracranial model, the farnesyltransferase inhibitor produced objective regression of tumor growth in the subcutaneous model and significant prolongation of survival times in the intracranial model, without apparent toxicity. In the subcutaneous model, tumor volumes for the control, GGTI-297-treated, and FTI-276-treated animals on Day 28 after implantation were 621+/-420, 107+/-104, and 18.5+/-12.7 mm3, respectively (P < 0.05). In the 7-day-treated intracranial model, survival times for the control, GGTI-297-treated, and FTI-276-treated groups were 27.7+/-2.9, 29.8+/-2.1, and 43.6+/-2.7 days, respectively (P < 0.001). In the 28-day-treated intracranial model, survival times for the control, GGTI-297-treated, and FTI-276-treated groups were 29.2+/-3.7, 28.3+/-3.9, and 58.7+/-6.2 days, respectively, with five of six animals in the latter group surviving more than 55 days after tumor implantation (P < 0.001). CONCLUSION: These studies demonstrate that farnesyltransferase inhibition is effective in diminishing the growth of human glioma cells in vivo. Evaluation of this treatment approach in clinical trials is warranted.

Potent topoisomerase I inhibition by novel silatecans eliminates glioma proliferation in vitro and in vivo.

Although topoisomerase inhibitors, such as camptothecin and topotecan, have been widely used in the treatment of nonglial tumors, their application for gliomas has been limited by poor efficacy relative to toxicity that may in part reflect limited bioavailability and blood stability of these agents. However, the potential promise of this class of agents has fostered efforts to develop new, more potent, and less toxic inhibitors that may be clinically relevant. Using a cascade radical annulation route to the camptothecin family, we developed a series of novel camptothecin analogues, 7-silylcamptothecins ("silatecans"), that exhibited potent inhibition of topoisomerase I, dramatically improved blood stability, and sufficient lipophilicity to favor blood-brain barrier transit. We explored the efficacy of a series of these agents against a panel of five high-grade glioma cell lines to identify a promising compound for further preclinical testing. One of the most active agents in our systems (DB67) inhibited tumor growth in vitro with an ED50 ranging between 2 and 40 ng/ml, at least 10-fold more potent than the effects observed with topotecan, and at least comparable with those of SN-38, the active metabolite of CPT-11. Because DB67 also exhibited the highest human blood stability of any of the agents examined, this agent was then selected for in vivo studies. A dose-escalation study of this agent in a nude mouse U87 glioma model system demonstrated a concentration-dependent effect, with tumor growth inhibition at day 28 postimplantation (the day control animals began to require sacrifice because of large tumor size) of 61 +/- 7% and 73 +/- 3% after administration of DB67 doses of 3 and 10 mg/kg/day, respectively, for 5 days beginning on postimplantation day 7. Animals that continued treatment with 10 mg/kg/day in three additional 21-day cycles all remained progression free after >90 days of follow-up but later developed enlarging tumors after treatment was stopped. However, a slightly higher dose (30 mg/kg/day) induced complete tumor regression after only two cycles in all study animals and was effective even if treatment was delayed until large, bulky tumors had developed. Application of the 30 mg/kg/day dose to treat established intracranial glioma xenografts led to long-term (>90 day) survival in six of six animals, whereas all controls died of progressive disease (P < 0.00001). No apparent toxicity was encountered in any of the treated animals. In summary, the present studies indicate that silatecans may hold significant promise for the treatment of high-grade gliomas and provide a rationale for proceeding with further preclinical evaluation of their efficacy and safety versus commercially available camptothecin derivatives.

Application of signal transduction inhibition as a therapeutic strategy for central nervous system tumors.

During the last decade, rapid progress has been made in understanding the molecular pathways underlying the proliferation of both normal and neoplastic cells. The processes by which messages to initiate protein synthesis, cell cycle progression, and even cell death are transmitted from the cell surface or the cytoplasm to the nucleus are broadly referred to as 'signal transduction'. These multistep pathways involve a host of proteins that interact with other proteins in overlapping cascades that flow downstream in a stepwise fashion from the cell membrane to the nucleus. Inappropriate overactivation or underactivation of various components of such signaling pathways can contribute to pathological processes, such as neoplasia. Conversely, molecular and pharmacological interventions that target and attempt to reverse the aberrant state of activation can potentially be of therapeutic benefit. The present article provides a background for understanding the contribution of signal transduction pathways to the proliferation of normal and neoplastic cells and describes ways in which targetted inhibition of selected signaling pathway components has been exploited to inhibit tumor growth in vitro and in vivo. Because most studies to date involving central nervous system (CNS) tumors have focused on gliomas, in view of their frequency in both the pediatric and adult age groups, the discussion of therapeutic applications for CNS neoplasia will deal primarily with these lesions. However, the basic concepts presented are generalizable to most tumor types and have been successfully applied in vitro in medulloblastomas as well. Ultimately, the translation of such strategies to the treatment of patients with malignant brain tumors may provide novel approaches for improving the poor outlook associated with these neoplasms.