Tatyana M. Timiryasova

Lister strain of vaccinia virus armed with endostatin–angiostatin fusion gene as a novel therapeutic agent for human pancreatic cancer

Survival after pancreatic cancer remains poor despite incremental advances in surgical and adjuvant therapy, and new strategies for treatment are needed. Oncolytic virotherapy is an attractive approach for cancer treatment. In this study, we have evaluated the effectiveness of the Lister vaccine strain of vaccinia virus armed with the endostatin–angiostatin fusion gene (VVhEA) as a novel therapeutic approach for pancreatic cancer. The Lister vaccine strain of vaccinia virus was effective against all human pancreatic carcinoma cells tested in vitro, especially those insensitive to oncolytic adenovirus. The virus displayed inherently high selectivity for cancer cells, sparing normal cells both in vitro and in vivo, with effective infection of tumors after both intravenous (i.v.) and intratumoral (i.t.) administrations. The expression of the endostatin–angiostatin fusion protein was confirmed in a pancreatic cancer model both in vitro and in vivo, with evidence of inhibition of angiogenesis. This novel vaccinia virus showed significant antitumor potency in vivo against the Suit-2 model by i.t. administration. This study suggests that the novel Lister strain of vaccinia virus armed with the endostatin–angiostatin fusion gene is a potential therapeutic agent for pancreatic cancer.

Low-dose vaccinia virus-mediated cytokine gene therapy of glioma.

Recombinant viruses can produce cytokines in tumors mobilizing an immune response to tumor cells. In this study, the authors investigated gene expression, in vivo antitumor efficacy, and safety of attenuated recombinant vaccinia virus (rVV) carrying murine cytokine genes interleukin (IL)-2 (rVV–mIL-2), IL-12 (rVV–mIL-12), and both IL-2 and IL-12 (rVV-2–12) in an athymic nude mice model. Significant tumor inhibition (p < 0.05) was observed in a preestablished subcutaneously implanted C6 glioma model using rVVs at doses ranging from 102 to 107 plaque forming units (PFU). An antitumor effect did not depend on the dose of the rVV–mIL-2 and rVV–mIL-12 viruses. All constructed rVVs induced a high level of cytokine expression in vitro and in vivo. Most groups injected with high doses of recombinant viruses encoding cytokine genes (105 to 107 PFU) showed signs of cytokine toxicity, whereas in the low-dose treatment groups (102 to 103 PFU) toxicity was greatly reduced. The antitumor activity of rVV–mIL-12 was associated with increases in both the percentage and number of natural killer T cells in the spleen. Local detection of interferon-&ggr; and tumor necrosis factor-&agr; was also correlated with tumor growth arrest induced by the treatment. High-dose VV control vector per se induced tumor inhibition by activating Mac-1+ cells in blood, but the antitumor effect was less pronounced compared with rVV-carrying cytokine genes (p < 0.05). These results suggest that attenuated recombinant strains of VV at low doses may potentially be efficient vectors for cancer immunotherapy.

Evaluation of combined vaccinia virus-mediated antitumor gene therapy with p53, IL-2, and IL-12 in a glioma model.

Our previous studies have shown that vaccinia virus (VV) expressing p53, interleukin-2 (IL-2), and interleukin-12 (IL-12) results in an effective inhibition of subcutaneous glioma growth in mice. We propose that combination therapy of tumors with virus-mediated p53 and cytokine genes offers the prospect of synergistic antitumor response. In this work, the antitumor efficacy of VV-mediated combination of p53, IL-2, and IL-12 genes was evaluated in a nude mouse model. To minimize cytokine-associated toxicity, a virus dose as low as 10 plaque-forming units of VV expressing IL-2 and IL-12 per animal was used alone and together with 2×107 plaque-forming units of VV expressing p53. Intratumoral treatment of established C6 glioma with recombinant viruses rVV-p53, rVV-mIL2, rVV-mIL12, and rVV-2-12 induced the prolonged expression of p53, IL-2, IL-12, and both cytokines simultaneously. The combination of rVV-p53/rVV-mIL12 or rVV-p53/rVV-2-12 resulted in significant tumor inhibition compared to single modality treatment (P<.05). rVV-p53/rVV-2-12 therapy was associated with significant elevation of natural killer, Mac-1+, and NKT cells in blood and interferon-γ and tumor necrosis factor-α expression in tumors. The difference in the inhibition of tumor growth between the rVV-p53/rVV-mIL2 combination and rVV-p53 was statistically insignificant. These data demonstrate that gene therapy based on VV-mediated combination of p53, IL-2, and IL-12 treatment may be a promising adjunctive strategy for glioma treatment. Cancer Gene Therapy (2000) 7, 1437–1447

Replication-deficient vaccinia virus gene therapy vector: evaluation of exogenous gene expression mediated by PUV-inactivated virus in glioma cells

Mild psoralen and UV (PUV) treatments inactivate viral DNA replication, but the virus retains its ability to infect cells. Thus, PUV treatment of vaccinia virus (VV) vectors may increase the safety of gene delivery and extend the duration of gene expression. Although the first studies on PUV‐inactivated VV (PUV‐VV) for the delivery of suicide or cytokine genes to cancer cells were promising, the efficiency and kinetics of exogenous gene expression have not been fully evaluated. Furthermore, these studies should be extended to other gene therapy strategies, e.g. tumor suppressor genes.

Protection of NOD mice from type 1 diabetes after oral inoculation with vaccinia viruses expressing adjuvanted islet autoantigens

Oral administration of autoantigens and allergens can delay or suppress clinical disease in experimental autoimmune and allergic disorders. However, repeated feeding of large amounts of the tolerogens is required over long periods and is only partially effective in animals systemically sensitized to the ingested antigen. Enhanced suppression of type 1 autoimmune diabetes insulitis and hyperglycemia was demonstrated in both naive and immune animals following oral inoculation with plant-based antigens coupled to the cholera toxin B subunit (CTB). Thus, plant-synthesized antigens linked to the CTB adjuvant, can enhance suppression of inflammatory TH1 lymphocyte-mediated autoreactivity in both naive and immune animals. To stimulate adjuvant-autoantigen fusion protein biosynthesis in the gut mucosae, the authors evaluated oral inoculation of juvenile non-obese diabetic (NOD) mice with recombinant vaccinia virus (rVV) expressing fusion genes encoding CTB linked to the pancreatic islet autoantigens proinsulin (INS) and a 55-kDa C-terminal peptide from glutamate decarboxylase (GAD55). Hyperglycemia in both rVV-CTB:: INS and rVV-CTB:: GAD inoculated mice was substantially reduced in comparison with the uninoculated mouse control. Oral inoculation with rVV carrying the CTB::INS fusion gene generated a significant reduction in insulitis. An increase in IgG1 in comparison with IgG2c antibody isotype titers in rVV-CTB::INS infected mice suggested possible activation of autoantigen specific Th2 lymphocytes. The experimental results demonstrate feasibility of using vaccinia virus oral delivery of adjuvanted autoantigens to the mucosae of prediabetic mice for suppression and therapy of type 1 autoimmune diabetes.

Attenuation of a vaccine strain of vaccinia virus via inactivation of interferon viroceptor

Interferons (IFNs) play an important role in host antiviral responses, but viruses, including vaccinia viruses (VV), employ mechanisms to disrupt IFN activities, and these viral mechanisms are often associated with their virulence. Here, we explore an attenuation strategy with a vaccine strain of VV lacking a virus‐encoded IFN‐γ receptor homolog (viroceptor).

Radiation Enhances the Anti-tumor Effects of Vaccinia-p53 Gene Therapy in Glioma

The overall goal of this study was to analyze the effect and mechanism of radiation in combination with vaccinia viruses (VV) carrying the p53 gene against glioma. Comparison of two alternative treatments of cultured C6 (p53+) and 9L (p53−) rat glioma cells showed significantly reduced survival for both cell lines, especially 9L, when radiation was applied prior to virus versus radiation alone. High p53 protein expression mediated by VV-TK-p53 was measured in infected cells. Single modality treatment of C6 cells with psoralen and UV (PUV)-inactivated VV-TK-p53 (PUV-VV-TK-53) or radiation significantly decreased survival compared with PUV-inactivated L-15 (PUV-L-15) control virus. However, no difference was observed between radiation and combination treatments of C6 cells. In contrast, radiation followed by PUV-VV-TK-53 resulted in dramatic reduction of 9L cell viability, compared to single modality treatment. Flow cytometry analysis of Annexin-V-stained 9L cells showed that radiation and PUV-VV-TK-53 caused a significant decrease in live cells (17.2%) as compared to other treatments and control (61.6–98.3%). Apoptosis was observed in 37.2% of cells, while the range was 0.7–7.8% in other treatment groups; maximal p53 level was measured on day 7 post-infection. In athymic mice bearing C6 tumors, VV-TK-53 plus radiation in both single and multiple therapies resulted in significantly smaller tumors by day 30 compared to the agents given only once. Immunohistochemical analysis of tumor sections demonstrated p53 protein expression over 20 days after VV-TK-53 treatment. Analysis of blood and spleen cells of mice given multiple combination treatments showed significant splenomegaly, leukocytosis, and increased DNA synthesis and response to mitogen. Multiple combination treatments were also associated with significantly elevated natural killer and B cells in the spleen. There were no overt toxicities, although depression in red blood cell and thrombocyte parameters was noted. Collectively, the data demonstrate that radiation significantly improves the efficacy of VV-mediated tumor suppressor p53 therapy and may be a promising strategy for glioma treatment. Furthermore, the results support the conclusion that the mechanisms underlying the enhanced anti-tumor effect of combination treatment include apoptosis/necrosis and upregulation of innate immune defenses.

Lymphocyte activation with localized pGL1-TNF-alpha gene therapy in a glioma model.

The major goal of this study was to evaluate the effects of tumor necrosis factor-α (TNF-α), delivered as pGL1-TNF-α, on hematological variables, as well as C6 tumor growth in athymic mice treated with and without radiation. pGL1-TNF-α was administered intratumorally at low to high doses (15, 150 and 450 µg) in all three phases of this study. In phase A, pGL1-TNF-α expression within tumors was dose dependent and transient, with highest levels seen at 18 h after injection, whereas no TNF-α protein was detected in plasma. Low erythrocyte counts, hemoglobin, and hematocrit were associated with tumor presence, but the reduction in these variables was most striking in the group receiving 450 µg of pGL1-TNF-α, the group that also exhibited thrombocytopenia at 72 h. In phase B, treatment with pGL1-TNF-α at 15 or 150 µg resulted in the greatest degree of splenomegaly, increased spontaneous blastogenesis by splenocytes, and high leukocyte and lymphocyte numbers in the spleen. In these same two groups, flow cytometry analyses of spleen cells showed that high levels of natural killer (panNK+) cells, B (CD19+) lymphocytes, and cells expressing the CD71 and CD25 activation markers were present (p < 0.05). An enhancing effect was also noted in some of the measurements with parental plasmid p WS4 and tumor presence. In phase C, the slowest tumor progression was observed in the groups receiving 15 and 150 µg pGL1-TNF-α together with radiation; tumor volumes were 51 and 43% smaller, respectively, than for PBS-injected controls by the end of the study. Collectively, these results show that localized treatment with pGL1-TNF-α is hematologically nontoxic at low doses and support the premise that activation of lymphocytes may contribute to the antitumor effects of radiation against a highly aggressive brain tumor.

Proton Radiation and TNF-α/Bax Gene Therapy for Orthotopic C6 Brain Tumor in Wistar Rats

High-grade tumors of the brain remain virtually incurable with current therapeutic regimens, new approaches to augment existing therapies need to be explored. The major goal of this pilot study was to evaluate the feasibility of gene therapy using plasmid DNA encoding tumor necrosis factor-α and bax together with proton radiation in an immunocompetent animal model with orthotopic brain tumor. C6 glioma cells were stereotactically implanted into the left hemibrain of Wistar rats (day 0). On day 5, the appropriate groups received intratumoral pGL1-TNF-α and pGL1-Bax (10 μg each), parental plasmid pWS4 (20 μg), or PBS. Hemibrain proton irradiation (10 Gy, 90 MeV, single fraction) was delivered 18–20 hr later. Rats were euthanized when signs of illness appeared. In addition, a subset of animals from each group was euthanized on day 9 for immune and other assays. By day 9, 25%, 20%, and 10% of rats treated with PBS, pWS4, or pGL1-TNF-μ/pGL1-Bax, respectively, had been euthanized due to weight loss or other signs of illness, whereas all rats treated with pGL1-TNF-μ/pGL1-Bax + radiation or radiation alone were healthy (P<0.05). At this same time, the pGL1-TNF-μ/pGL1-Bax + radiation group had significantly elevated lymphocyte percentages (P<0.005 or less) and a relatively high level of lymphocytic infiltrate within tumors. Although the rats treated with pGL1-TNF-μ/pGL1-Bax had the highest levels of activated T helper (CD4+/CD71+) and T cytotoxic (CD8+/CD71+) cells, the values were not significantly different compared to the pWS4-injected control group. Splenocytes in all tumor cell-injected groups had higher mean values for DNA and protein synthesis compared to the non-tumor cell injected control group, whereas oxygen radical production by phagocytes was consistently higher in groups injected with plasmid or treated with radiation. Body, hemibrain, and spleen masses, white blood cell, red blood cell and platelet counts, hemoglobin, hematocrit, and transforming growth factor-β1 levels in plasma were similar among groups. The results demonstrate that treatment with pGL1-TNF-α/pGL1-Bax combined with proton hemibrain irradiation is safe under the conditions used. Overall, these data support further investigation of this unique combination therapy.

Evaluation of TNF-α/Bax Gene Therapy and Radiation against C6 Glioma Xenografts

Successful therapy of high-grade tumors of the brain is likely to require a combination of new therapeutic approaches. The major goal of the present study was to construct a plasmid-based bax gene vector (pGL1-Bax) and evaluate its expression in vitro and in vivo using athymic mice with subcutaneously growing C6 glioma. Preliminary experiments of efficacy and safety were also performed using pGL1-Bax alone and in combination with previously constructed pGL1-TNF-α, as well as with radiation. pGL1-Bax was expressed by C6 cells and was correlated with apoptosis, indicating that the construct and the bax protein were functional. Although intratumoral injections of pGL1-Bax alone, up to total doses of 450 μg, did not significantly affect tumor growth, consistently smaller tumors were obtained when pGL1-TNF-α plus pGL1-Bax were injected 16–18 hr prior to tumor irradiation. Furthermore, in mice with two tumors, one treated and one untreated, progression of the untreated tumor was delayed in the animals receiving all three modalities. No prohibitive toxicities were noted, based on mouse body weights and in vitro assays of blood and spleen. Significant increases in spleen mass, total leukocyte counts, percentage of granulocytes, spontaneous blastogenesis, and CD71-expressing B cells were primarily associated with tumor presence and not treatment type. Overall, the results are promising and suggest that TNF-α/Bax gene therapy may be beneficial against highly malignant tumors of the brain. To our knowledge, this is the first report of bax gene therapy used together with radiation in an in vivo glioma model.