Mouse glioma 261 (Gl261) cells are used frequently in experimental glioblastoma therapy; however, no detailed description of the Gl261 tumor model is available. Here we present that Gl261 cells carry point mutations in the K-ras and p53 genes. Basal major histocompatibility complex (MHC)I, but not MHCII, expression was detected in Gl261 cells. The introduction of interferon-γ γ γ γ-encoding genes increased expression of both MHCI and MHCII. A low amount of B7-1 and B7-2 RNA was detected in wild-type cells, but cytokine production did not change expression levels. Gl261 cells were transduced efficiently by adenoviral vectors; the infectivity of retroviral vectors was limited. Low numbers of transplanted Gl261 cells formed both subcutaneous and intracranial tumors in C57BL /6 mice. The cells were moderately immunogenic : prevaccination of mice with irradiated tumor cells 7 days before intracranial tumor challenge prevented tumor formation in approximately 90% of mice. When vaccination was carried out on the day or 3 days after tumor challenge, no surviving animals could be found. In vitro-growing cells were radiosensitive: less than 2 Gy was required to achieve 50% cell mortality. Local tumor irradiation with 4 Gy X-rays in brain tumor-bearing mice slowed down tumor progression, but none of the mice were cured off the tumor. In conclusion, the Gl261 brain tumor model might be efficiently used to study the antitumor effects of various therapeutic modalities, but the moderate immunogenicity of the cells should be considered. (Cancer Sci 2006; 97: 546-553) M alignant brain tumors have a poor outcome, with a median survival of 9 months and only 5-10% of patients surviving 2 years. The conventional therapies for glioblastoma multiforme are surgical removal of the bulk tumor mass, followed by radiotherapy. As complete surgical removal is almost impossible, radiotherapy continues to play a major role in the treatment of malignant gliomas, but these tumors are often radioresistant. The combination of chemotherapy with other modalities provides only modest improvements in survival rates. (1-3) The application of suitable animal models in glioma research is necessary for the development of new therapeutic approaches. An ideal animal model of human glioma should reproduce the major characteristics of this neoplasm: predictable and reproducible in vitro and in vivo growth patterns; infiltrative, but non-metastatic, tumor growth; and poor immunogenicity. A number of animal brain tumor models are being used; however, no model currently available simulates human high-grade gliomas exactly. Tumor models vary in their immunogenicity, growth patterns and invasiveness. For this reason it is important to choose an appropriate animal model depending on the endpoint examined. Most models are derived from rat and several xenograft models, based on the intracer-ebral transplantation of human brain tumors into immune-deficient nude mice, are also available. Murine models of malignant brain tumors are used much less frequently, mainly beca...
The combined therapeutic effect of cytokine-producing cancer cell vaccines and local radiotherapy was studied in a mouse glioma 261 (Gl261) brain tumor model. Brain tumor-bearing mice were treated with cytokine (IL-4, IL-6, IL-7, GM-CSF, TNF-, LIF, LT) producing vaccines made by in vitro transduction of Gl261 cells with the corresponding adenoviral vectors. Vaccines producing either IL-4 or GM-CSF cured 20-40% of mice. The antitumor effect strongly depended on the secreted cytokine level. Vaccination therapy induced specific activation of cytotoxic T lymphocytes measured by cell-mediated cytotoxicity assay. Brain tumors were heavily infiltrated by CD4 + lymphocytes after treatment with IL-4-or GM-CSF-secreting cells. GM-CSF vaccination induced moderate CD8 + infiltration, as well. Depleting either CD4 + or CD8 + lymphocyte subsets abolished the anticancer effect of GM-CSF-expressing cells. Strong synergism was observed by combining cytokine vaccination (GM-CSF, IL-4, IL-12) with local tumor irradiation: about 80-100% of the glioma-bearing mice was cured. The high efficiency of combined treatment was maintained even under suboptimal conditions when neither of the modalities cured any of the mice alone. This suggests that vaccination therapy might open a new potential in the clinical treatment of high-grade gliomas when applied as adjuvant to existing treatment modalities.
The combined therapeutic effect of cytokine-producing cancer cell vaccines and local radiotherapy was studied in a mouse glioma 261 (GI261) brain tumor model. Brain tumor-bearing mice were treated with cytokine (IL -4, IL-6, IL-7, GM-CSF, TNF-alpha, LIF, LT) producing vaccines made by in vitro transduction of GI261 cells with the corresponding adenoviral vectors. Vaccines producing either IL-4 or GM-CSF cured 20-40% of mice. The antitumor effect strongly depended on the secreted cytokine level. Vaccination therapy induced specific activation of cytotoxic T lymphocytes measured by cell-mediated cytotoxicity assay. Brain tumors were heavily infiltrated by CD4+ lymphocytes after treatment with IL-4- or GM-CSF-secreting cells. GM-CSF vaccination induced moderate CD8+ infiltration, as well. Depleting either CD4+ or CD8+ lymphocyte subsets abolished the anticancer effect of GM-CSF-expressing cells. Strong synergism was observed by combining cytokine vaccination (GM-CSF, IL-4, IL-12) with local tumor irradiation: about 80-100% of the glioma-bearing mice was cured. The high efficiency of combined treatment was maintained even under suboptimal conditions when neither of the modalities cured any of the mice alone. This suggests that vaccination therapy might open a new potential in the clinical treatment of high-grade gliomas when applied as adjuvant to existing treatment modalities.
Rat and human ribosomal RNA gene fragments in supercoiled plasmids were examined for S1 nuclease hypersensitivity. In the transcribed portion of genes the number and distribution of S1 sites were found to be species specific. No S1 sites were detected in the promoter regions. In the nontranscribed spacer (NTS), downstream of the 3' end of 28S RNA gene, S1 sites appear to be conserved in rat and human rDNAs. A rat NTS fragment (2987 nucleotides long), containing three S1 sites was sequenced and the S1 sites in this region were localized in polypyrimidine . polypurine simple repeat sequences. Other types of simple sequences, two type 2 Alu repeats and an ID sequence were also found in the sequenced region. The possible role of simple sequences and S1 sites in transcription and in recombination events of rDNA is discussed.
Pregnant mice were irradiated with 0.5 Gy fission neutrons on the eighteenth day of their gestation. The average litter size at birth was unchanged but mortality increased 5-6 fold in the first 3 days. The irradiated mice were the same weight as control mice at birth but showed a progressively increasing weight deficiency up to at least 36 days as compared to controls. Brain weight was 37, 45 and 25 per cent less in 2-, 3- and 52-week old irradiated animals, respectively, and the ratio of brain weight to body weight was 25, 27 and 13 per cent less. The concentrations of DNA, RNA and protein (mg/g wet tissue) were the same in irradiated and control mice in both brain and liver at all three ages. Total DNA, RNA and protein contents of whole brain after irradiation were 56-75 per cent of the control levels. No definite decrease was observed in liver. Histological study at 6 hours after irradiation showed nuclear pyknosis in the central nervous system from definite to very severe according to the part examined. It is concluded that damage to the central nervous system of the 18-day mouse foetus after neutron irradiation is mainly due to killing and/or inhibition of the differentiation of neuroblasts.
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