Syngeneic central nervous system transplantation of genetically transduced mature, adult astrocytes.

Advances in the development of highly infectious, replication-deficient recombinant retroviruses provide an efficient means of stable transfer of gene expression. Coupled with ex vivo transduction, surrogate cell populations can be readily implanted into the brain, thus serving as vehicles for delivering selected gene products into the central nervous system (CNS). Here we report that rat astrocytes can be routinely and safely isolated from brain tissue of a living donor by use of short-term gelatin sponge implants. The mature, nontransformed astrocytes were easily expanded, maintained in long-term tissue cultures and were efficiently transduced with an amphotropic retrovirus harboring a heterologous, fused transgene. In vitro retroviral infection rendered the nontransformed cells essentially 100% viable after exposure. The level of efficiency of infection (30-50% effective genome integration of provirus and expression of transgene in target cell populations) and minimal cell toxicity obviated the need to harvest large numbers of target cells. Cultured transduced astrocytes were resilient and exhibited select peptide expression for up to 1 year. Subsequently, transduced astrocytes were used in a series of experiments in which cells were transplanted intracerebrally in syngeneic animals. Post-implantation, astrocytes seeded locally and either insinuated into the surrounding parenchyma in situ or exhibited a variable degree of migration, depending on the anatomic source of astrocytes and the targeted brain implantation site. Transduced astrocytes remained viable in excess of 8 months post-transplantation and exhibited sustained transgenic peptide expression of green fluorescent protein/neomycin phosphotransferase in vivo. The sequential isolation and culture of nontransformed, mature, adult astrocytes and recombinant retrovirus-mediated transduction in vitro followed by brain reimplantation represents a safe and effective means for transferring genetic expression to the CNS. This study lays the foundation for exploring the utility of using a human autologous transplantation system as a potential gene delivery approach to treat neurological disorders. Prepared and utilized in this manner, autologous astrocytes may serve as a vehicle to deliver gene therapy to the CNS.

Hormonal effects on glioblastoma multiforme in the nude rat model.

OBJECT: The authors studied the effect of gender and hormonal status on survival in nude rats implanted with human glioblastoma multiforme (GBM) cell lines. METHODS: Nude rats received intracerebral implants of either wild-type U87MG cells or U87MG cells transfected with the gene for endothelin-1 (U87/ET-1). In the initial study, survival was compared in males and females for each of the two cell lines. The six second-phase study groups were composed of: 1) males; 2) females; 3) ovariectomized females; 4) sham ovariectomized females; 5) ovariectomized rats given 10 microg/day estradiol benzoate for 21 days; and 6) ovariectomized rats given 20 mg/kg/day progesterone for 21 days. All rats in the second phase were implanted with U87/ET-1 cells. Animals were killed when they exhibited initial signs of neurological deterioration. Female nude rats survived longer than male rats implanted with either U87 or U87/ET-1 cells. In the second phase, ovariectomized, male, and progesterone-treated rats died at approximately 19 days, whereas the female, sham-treated, and estrogen-treated animals died 23 to 25 days after tumor cell implantation. CONCLUSIONS: The authors demonstrate that female nude rats implanted with human GBM cells have a survival advantage over male rats and that estrogen provides the advantage.

Intratumoral infusion of topotecan prolongs survival in the nude rat intracranial U87 human glioma model.

Topotecan is a topoisomerase (topo) I inhibitor with promising activity in preclinical studies. We hypothesized that low-dose intratumoral delivery of topotecan would be highly effective for gliomas. Human glioma cell lines (U87, U138 and U373) displayed different sensitivities to topotecan (IC50 range: 0.037 microM to 0.280 microM) in cell culture. The most resistant of the glioma cell lines (U87) was implanted stereotactically into the brains of nude rats. Twelve days later, at which time tumor diameter measured 2 to 2.5 mm, animals were randomized to three groups: group I, intratumoral topotecan infused via osmotic pump (n = 12); group II, intratumoral saline infusion (n = 7); and group III, no treatment (n = 10). Animals were sacrificed when signs of deterioration developed, or at 60 days. Animals in group I had a mean survival time (MST) of > 55 days (range = 40-60); whereas, those in groups II and III had MST of 26.1 (range = 21-31) and 26.5 (range = 20-30) days, respectively. The differences in survival between group I and each of the other groups were statistically significant (p < 0.0001; Logrank Mantel-Cox). None of the animals that survived 60 days had histological evidence of residual tumor at sacrifice. Measurement of topotecan levels in normal brain revealed cytotoxic concentrations up to 4.5 mm from the site of infusion. This study demonstrates that intratumoral topotecan delivered via an osmotic pump prolongs survival in the U87 human glioma model.

An experimental model of human leukemic meningitis in the nude rat.

An experimental animal model of meningeal leukemia was developed in the nude rat, rnu/rnu, using the human-derived acute lymphoblastic leukemia cell line HPB-ALL. Anesthetized rats were placed in a modified stereotaxic frame and then injected intrathecally, at the level of the cisterna magna, with human leukemic cells. Cerebrospinal fluid and tissue samples from brain, spinal cord, heart, liver, kidney, spleen, bone marrow, and cervical lymph nodes were subjected to histopathologic examination and molecular genetic screening by clonotype primer-directed polymerase chain reaction (CPD-PCR). Ninety-three percent of animals (n = 14) developed signs of meningeal irritation leading to death 30 to 63 days postinjection (median, 36.0 days, mean, 38.7); death occurred between 30 and 39 days in 77% of all animals. Leukemic cells progressively infiltrated the pericerebellar and pericerebral subarachnoid space and infiltrated the Virchow-Robin (perivascular) space. The infiltrating meningeal leukemia closely resembled the pathologic presentation in the human condition. By CPD-PCR, leukemic cells were first detected in cerebrospinal fluid (CSF) on day 4 postinjection, were variably present over the ensuing 17 days, and were consistently detected after day 21. At terminal stages, CPD-PCR tissue surveys showed leukemic DNA in all brains and spinal cords and rarely in cervical lymph nodes, but leukemic DNA was not detected in any other tissue screened. Leukemic meningitis was reliably produced with a predictable survival time. Intrathecal administration of leukemic cells was an efficient means of transmitting leukemic meningitis and it compartmentalized the disease to the central nervous system (CNS), eliminating potential complications of systemic illness. The use of human-derived cell lines may render this model more relevant to the development of future therapeutic strategies to treat leukemia and lymphoma that invade the CNS.

In vitro assessment of neurotrophic activity from the striatum of aging rats.

Neurotrophic factors are produced in the striatum following trauma and have a demonstrable effect on in vitro bioassays and on in vivo graft survival. We have previously measured the in vitro effect of these factors following trauma to the striatum of young rats. However, the effect of age on this neurotrophic response has not been evaluated. In this study we report on the in vitro effects of extracts (obtained from gelfoam) removed from striatal cavities 7 days following trauma. Gelfoam extract from aged rats (18-24 months) had a reduced neurite-promoting response in dorsal root ganglia (DRG) and SH-SY5Y (a dopamine-producing neuroblastoma cell line) assays, compared to gelfoam from young rats (2-3 months). In contrast, extracts from both young and old rats showed significant neuroprotection of SH-SY5Y cells from the dopaminergic neurotoxins N-methy-4phenylpyridinium ion (MPP +) and 6-hydroxydopamine (6-OHDA). The results suggest that the striatum of aged individuals may have (1) a diminished capacity of neurite promotion and/ or (2) that neurite outgrowth and neuroprotection may be influenced by different factors or different levels of the same factors. The direct implication is that aged animals would be the most appropriate models to study experimental therapies for Parkinson's disease.