Oncolytic herpes virus with defective ICP6 specifically replicates in quiescent cells with homozygous genetic mutations in p16.

Oncolytic herpes simplex viruses (HSVs), in clinical trials for the treatment of malignant gliomas, are assumed to be selective for tumor cells because their replication is strongly attenuated in quiescent cells, but not in cycling cells. Oncolytic selectivity is thought to occur because mutations in viral ICP6 (encoding a viral ribonucleotide reductase function) and/or gamma34.5 function are respectively complemented by mammalian ribonucleotide reductase and GADD34, whose genes are expressed in cycling cells. However, it is estimated that only 5-15% of malignant glioma cells are in mitosis at any one time. Therefore, effective replication of HSV oncolytic viruses might be limited to a subpopulation of tumor cells, since at any one time the majority of tumor cells would not be cycling. However, we report that an HSV with defective ICP6 function replicates in quiescent cultured murine embryonic fibroblasts obtained from mice with homozygous p16 deletions. Furthermore, intracranial inoculation of this virus into the brains of p16-/- mice provides evidence of viral replication that does not occur when the virus is injected into the brains of wild-type mice. These approaches provide in vitro and in vivo evidence that ICP6-negative HSVs are 'molecularly targeted,' because they replicate in quiescent tumor cells carrying specific oncogene deletions, independent of cell cycle status.

Cryopreservation of alginate-encapsulated recombinant cells for antiangiogenic therapy.

The potential benefit of continuous local administration of antiangiogenic proteins to CNS tumors in vivo has recently been demonstrated using endostatin-producing recombinant cells encapsulated in alginate beads. Due to the treatment potential of transplanted alginate-encapsulated cells producing therapeutic proteins, we describe a successful method of cryopreservation (CP) of such beads, in which cellular viability, alginate structure, and protein secretion were maintained. Alginate beads containing human embryonic kidney cells (HEK 293 cells) stably transfected with the gene encoding for endostatin were cryopreserved in dimethyl sulfoxide (DMSO) using a slow freezing procedure. Briefly, the DMSO concentration was gradually increased prior to the freezing procedure. The cryotubes were further supercooled to -7.5 degrees C and nucleated. Thereafter, the samples were cooled at a rate of 0.25 degrees C/min and stored in liquid nitrogen. The viability of the encapsulated cells was assessed using confocal microscopy quantification (CLSM) technique and a MTS assay. The cell cycle distribution inside the beads was assessed by DNA flow cytometry and endostatin production was determined by an endostatin-specific ELISA assay, both prior to and after CP. CLSM measurements showed sustained esterase activity in the beads after thawing, with only a slight transient decrease 24 h after CP. The MTS assay verified these findings by displaying similar variations of intracellular dehydrogenase activity. Flow cytometric analyses revealed no cryorelated disturbances in cellular ploidy. Furthermore, ELISA measurements showed a well-preserved endostatin production after CP. In conclusion, this work describes the successful CP of alginate-encapsulated recombinant cells secreting a therapeutic protein. Together with previous published reports, these results further substantiate the feasibility and potential of cell encapsulation therapy in the treatment of malignant tumors.

Cell encapsulation technology as a therapeutic strategy for CNS malignancies.

Gene therapy using viral vectors has to date failed to reveal its definitive clinical usefulness. Cell encapsulation technology represents an alternative, nonviral approach for the delivery of biologically active compounds to tumors. This strategy involves the use of genetically engineered producer cells that secrete a protein with therapeutic potential. The cells are encapsulated in an immunoisolating material that makes them suitable for transplantation. The capsules, or bioreactors, permit the release of recombinant proteins that may assert their effects in the tumor microenvironment. During the last decades, there has been significant progress in the development of encapsulation technologies that comprise devices for both macro- and microencapsulation. The polysaccharide alginate is the most commonly used material for cell encapsulation and is well tolerated by various tissues. A wide spectrum of cells and tissues has been encapsulated and implanted, both in animals and humans, indicating the general applicability of this approach for both research and medical purposes, including CNS malignancies. Gliomas most frequently recur at the resection site. To provide local and sustained drug delivery, the bioreactors can be implanted in the brain parenchyma or in the ventricular system. The development of comprehensive analyses of geno- and phenotypic profiles of a tumor (genomics and proteomics) may provide new and important guidelines for choosing the optimal combination of bioreactors and recombinant proteins for therapeutic use.

The glioma-associated gangliosides 3'-isoLM1, GD3 and GM2 show selective area expression in human glioblastoma xenografts in nude rat brains.

This work describes the in vivo expression and distribution of glioma-associated gangliosides (GD3, GM2, 3'-isoLM1) in a novel human brain tumour nude rat xenograft model. In this model, the tumours, which are established directly from human glioblastoma biopsies, show extensive infiltrative growth within the rat brain. This model therefore provides an opportunity to study ganglioside expression not only within the macroscopic tumour, but also in brain areas with tumour cell infiltration. The ganglioside expression was studied by confocal microscopy of immunostained brain sections using antiganglioside monoclonal antibodies. Xenografts from four human glioblastoma multiformes were established in rats and the brains removed after 3-4 months. Ganglioside GD3 was expressed in the tumour parenchyma while ganglioside 3'-isoLM1 was more abundantly expressed in the periphery of the tumour associated with areas of tumour cell invasion. GM2 expression was only seen in one tumour, where it was located within the main tumour mass. Double staining with a pan antihuman monoclonal antibody (3B4) and the antiganglioside monoclonal antibodies confirmed that the ganglioside expression was associated with tumour cells. This work supports the concept of different biological roles for individual gangliosides and indicates that antibodies or ligands directed against GD3 and 3'-isoLM1 might be complementary when applied in the treatment of human glioblastomas.

lacZ-neoR transfected glioma cells in syngeneic rats: growth pattern and characterization of the host immune response against cells transplanted inside and outside the CNS.

The rat glioma cell lines BT4C and BT4Cn were stably transfected with the bacterial lacZ-neomycin resistance (neoR) gene construct. Both transfected (BT4ClacZ and BT4CnlacZ) and untransfected cell lines were injected intracerebrally and subcutaneously into rats. Survival time, morphology, growth rate and immunological properties of the tumors were studied. Survival time was significantly prolonged after intracerebral implantation of the transfected cell lines. No similar response was found in nude rats, indicating an immunological response towards the lacZ-neoR-transfected cells in immunocompetent animals. Morphological observations showed that the lacZ-neoR-transfected gliomas were smaller and had a distinct boundary with the normal brain tissue, whereas the parental cell lines revealed a more diffuse growth pattern. Immunostaining showed a higher proportion of immunocompetent cells infiltrating the lacZ-neoR-transfected tumors. After s.c. injection, the lacZ-neoR-transfected BT4C cell line had a prolonged lag phase before assuming a growth rate similar to that of the parental cells. The BT4CnvlacZ tumors initially grew fastest, but then disappeared within 3 weeks. A similar response was observed with mock-transfected tumor cells. A (3)HTdR-incorporation assay on spleen cells from rats transplanted s.c. with BT4CnvlacZ cells showed a 10-fold increase in cell activation as compared with rats with BT4Cn tumors. A humoral response towards the transfected cells was verified by Western-blot analyses.

Retroviral transfection of the lacZ gene from Liz-9 packaging cells to glioma spheroids.

Despite the development of numerous vectors for gene transfection to gliomas, patient survival length remains unaffected in clinical trials. For glioma gene therapy to be successful, the extent of gene transfer to the solid tumor tissue has to be high. In the present work we review some of the vector types and strategies so far utilized in experimental and clinical glioma gene therapy. Since gene transfer efficacy into solid glioma tissue is unknown for many vectors, we studied the gene transfer efficacy into multicellular spheroids derived from a human glioma cell line GaMg as well as into spheroids derived from human glioma biopsies (glioblastoma multiforme, GBM). A replication deficient retroviral vector from the Liz 9 packaging cell line was used for transfer of the bacterial beta-galactosidase lacZ gene into the target tissue. Gene transfer was obtained by adding medium containing virus from the producer cells to the target tissue. The experiments were also conducted with EGF (epidermal growth factor) added to the medium. The data show that the transfection rate ranged from 0-4.5% where the transfection efficacy was higher in spheroids after the addition of EGF. Most of the transfected cells were found at the surface, but transfected cells could also be observed in the center of the spheroids. We conclude that using this vector system, the transfection efficacy was low, even if the number of replicating cells was increased by adding EGF. The findings are consistent, and may partly explain, the lack of effect using this vector system during in vivo studies.

Release of replication-deficient retroviruses from a packaging cell line: interaction with glioma tumor spheroids in vitro.

The present study describes how various growth conditions affect gene expression and virus production from a retroviral packaging cell line (Liz 9), grown as monolayers and as multicellular spheroids. In addition, to study the direct interaction between packaging cells and tumor tissue of glioma origin, Liz 9 spheroids were confronted with tumor spheroids derived from a human glioma cell line, GaMg. The results show a progressive gene transfer into the tumor tissue, with 9% transfection efficacy after 5 days of co-culture. In comparison, no gene transfer was observed when the Liz 9 spheroids were confronted with normal brain-cell aggregates. The Liz 9 spheroids established from early-passage cultures (passages 7-14) showed limited growth during 28 days, whereas those initiated from late-passage monolayer cultures (passages 39-49) showed extensive growth. Flow-cytometric DNA profiles of monolayers and of spheroids indicated no difference in cell-cycle distribution or ploidy between early and late passages. A cell-viability assay using scanning confocal microscopy revealed mostly viable cells in the Liz 9 spheroids, with only a few dead cells scattered within the structures. The lacZ-gene expression was maintained in early- and in late-passage cultures. In comparison, in Liz 9 early-passage monolayers, the virus titer was 3.1 x 10(4) +/- 0.4 x 10(4) CFU/ml, whereas no virus titer was found in late-passage cultures. The virus titer from the Liz 9 spheroids was found to be between 10(3) and 10(4) CFU/ml. It is concluded that the virus production from packaging cells may vary, depending on passage number and tissue-culture conditions. In the present study, this is demonstrated by a complete loss in virus titer during prolonged culture of packaging cells. In addition, the 3-dimensional confrontation system described allows direct visualization of how packaging cells interact with tumor tissue. Thus, the co-culture system represents a model for studying the efficiency of packaging cells in transfecting heterogeneous tumor tissue in vitro.

Proliferation, migration and invasion of human glioma cells exposed to paclitaxel (Taxol) in vitro.

Paclitaxel (Taxol), an anti-cancer drug derived from Taxus species, was tested for its anti-migrational, anti-invasive and anti-proliferative effect on two human glioma cell lines (GaMg and D-54Mg) grown as multicellular tumour spheroids. In addition, the direct effect of paclitaxel on glioma cells was studied using flow cytometry and scanning confocal microscopy. Both cell lines showed a dose-dependent growth and migratory response to paclitaxel. The GaMg cells were found to be 5-10 times more sensitive to paclitaxel than D-54Mg cells. Paclitaxel also proved to be remarkably effective in preventing invasion in a co-culture system in which tumour spheroids were confronted with fetal rat brain cell aggregates. Control experiments with Cremophor EL (the solvent of paclitaxel for clinical use) in this study showed no effect on tumour cell migration, cell proliferation or cell invasion. Scanning confocal microscopy of both cell lines showed an extensive random organization of the microtubules in the cytoplasm. After paclitaxel exposure, the GaMg and the D-54Mg cells exhibited a fragmentation of the nuclear material, indicating a possible induction of apoptosis. In line with this, flow cytometric DNA histograms showed an accumulation of cells in the G2/M phase of the cell cycle after 24 h of paclitaxel exposure. After 48 h, a deterioration of the DNA histograms was observed indicating nuclear fragmentation.