Development of a large-animal human brain tumor xenograft model in immunosuppressed cats.

A large-animal model was developed to facilitate the noninvasive investigation of the effect on the human glioma-derived D-54 MG (glioblastoma multiforme) continuous cell line of a variety of therapeutic regimens. Twenty random-bred male cats were inoculated intracerebrally with 1 x 10(7) D-54 MG tumor cells after being initiated on one of three preparatory regimens of cyclosporin A p.o. Reproducible success of D-54 MG xenotransplantation (100%, 6 of 6 cats) was achieved only after pretreatment with 120 mg cyclosporin A p.o. (24-30 mg/kg) daily for greater than or equal to 10 days prior to tumor implantation. High-performance liquid chromatography-derived whole blood cyclosporin A 12-h trough levels of greater than or equal to 640 ng/ml were seen in successful implants. Lesions ranging from 2 to 20 mm in diameter were seen in cats sacrificed 27-44 days after implantation with no growth seen in control animals. Histopathological examination revealed the tumors to be well-circumscribed anaplastic intracerebral tumors with some invasion into surrounding host parenchyma. Perivascular lymphocytic cuffing was observed, but intratumoral lymphocytic infiltration was minimal. Gadolinium-EDTA-enhanced nuclear magnetic resonance imaging provided accurate tumor localization in T1-weighted images (TE 26 ms; TR 600 ms). Biochemical tests of kidney, liver, and hematological function were within normal limits, although 10% (2 of 20) of the animals developed gingival hyperplasia, and 5% (1 of 20) developed intussusception. The reproducible growth of the D-54 MG human glioblastoma cell line in a large-animal model eliminates many of the limitations associated with the standard nude mouse/rat model, thereby providing a novel test bed for a variety of imaging modalities as well as for drug immunoconjugate localization and toxicity studies.

Human glioma immunobiology in vitro: implications for immunogene therapy.

OBJECTIVE: Human gliomas are known to be immunosuppressive. Recent reports have suggested novel strategies to overcome this immunosuppression, including immunogene therapy. We examined expression of 10 immunologically important molecules by human gliomas in vitro, and we discuss the implications for immunogene therapy. METHODS: Early passage human glioma cultures and established human glioma cell lines were analyzed by flow cytometry for expression of Class I and II major histocompatibility complex (MHC), B7-2 (CD86), and Fas (CD95). Culture supernatants were assayed by enzyme-linked immunosorbent assay for interleukin (IL)-6, IL-10, IL-12, transforming growth factor beta2, prostaglandin E2, and granulocyte-macrophage colony-stimulating factor levels. RESULTS: All cultures (16 of 16 samples) expressed Class I MHC and Fas, but few expressed Class II MHC (1 of 16 samples) or B7-2 (0 of 16 samples). Nearly all expressed high levels of IL-6 (19 of 21 samples; mean, 36.5 +/- 10.8 ng/10(6) cells/d) and prostaglandin E2 (21 of 21 samples; mean, 15.6 +/- 4.5 ng/10(6) cells/d) levels, and many expressed transforming growth factor beta2 (13 of 21 samples; mean, 8.6 +/- 3.7 ng/10(6) cells/d). Although several cultures (6 of 14 samples) expressed granulocyte-macrophage colony-stimulating factor, expression levels were very low (mean, 0.2 +/- 0.1 ng/10(6) cells/d). Few cultures (4 of 21 samples) expressed measurable IL-10, and none (0 of 22 samples) expressed IL-12. CONCLUSION: Class I MHC and Fas expression suggests that human glioma cells may be susceptible to Class I MHC-dependent cytotoxic T cell recognition and Fas-mediated killing. Unfortunately, transforming growth factor beta2 and prostaglandin E2 probably impair T cell activation, and IL-6 may shift immunity to less effective humoral (T helper 2) responses. Proinflammatory gene expression (B7-2, granulocyte-macrophage colony-stimulating factor, and/or IL-12) is lacking. Together, these results suggest that modifying glioma cells via proinflammatory gene transfer or immunoinhibitory gene suppression might stimulate immune responses that are effective against unmodified tumors.

Improved technique for establishing short term human brain tumor cultures.

Culturing human central nervous system tumors has been difficult compared to other neoplasms. We report improved success rates for establishing short term human brain tumor cultures using a modified tissue processing technique. Eighty-seven brain tumor specimens (56 glioblastomas, 8 mid grade astrocytomas, 8 oligodendrogliomas, 15 other) were obtained from June 1988 to March 1997. The first twenty-three samples were processed by dissection, partial enzyme dissociation, and filtration through a tissue culture sieve. Subsequent samples were processed identically except tumor cells were centrifuged on a density gradient prior to plating. Successful cultures were defined as those surviving greater than three passages in tissue culture and growing to sufficient numbers (>10(6) cells) to allow freezing. Success rate was 42% (10/23) using standard processing methods and 86% (55/64) with the addition of density gradient centrifugation. Glial fibrillary acidic protein (GFAP) and vimentin staining, karyotypes, and growth curves were obtained for representative glioma cultures. All cultures tested were positive for vimentin (29/29) while 62% (18/29) were positive for GFAP. Of four cultures karyotyped (two glioblastomas, two oligodendrogliomas), all but one oligodendroglioma culture exhibited clonal cytogenetic abnormalities. These immunohistochemical and karyotypic results are consistent with the malignant glial origin of these cells. Of note, low passage human glioma cultures grew slower and exhibited more contact inhibition than immortalized human glioblastoma cell lines. Nevertheless, this simple method for establishing short term human brain tumor cultures should aid in further developing human brain tumor pre-clinical models as well as enhancing clinical applications dependent on in vitro human brain tumor cell growth adjust.