Masahiro Toda

Implantation of dendritic cells in injured adult spinal cord results in activation of endogenous neural stem/progenitor cells leading to de novo neurogenesis and functional recovery

We report a treatment for spinal cord injury involving implantation of dendritic cells (DCs), which act as antigen‐presenting cells in the immune system. The novel mechanisms underlying this treatment produce functional recovery. Among the immune cells tested, DCs showed the strongest activity inducing proliferation and survival of neural stem/progenitor cells (NSPCs) in vitro. Furthermore, in DC‐implanted adult mice, endogenous NSPCs in the injured spinal cord were activated for mitotic de novo neurogenesis. These DCs produced neurotrophin‐3 and activated endogenous microglia in the injured spinal cord. Behavioral analysis revealed the locomotor functions of DC‐implanted mice to have recovered significantly as compared to those of control mice. Our results suggest that DC‐implantation exerts trophic effects, including activation of endogenous NSPCs, leading to repair of the injured adult spinal cord.

Isolation of cancer stem-like cells from a side population of a human glioblastoma cell line, SK-MG-1

Accumulating evidence suggests that in several types of brain tumors, including glioma, only a phenotypic subset of tumor cells called brain cancer stem cells (BCSCs) may be capable of initiating tumor growth. Recently, the isolation of side population (SP) cells using Hoechst dye has become a useful method for obtaining cancer stem cells in various tumors. In this study, we isolated cancer stem-like cells from human glioma cell lines using the SP technique. Flow cytometry analysis revealed that SK-MG-1, a human glioblastoma cell line, contained the largest number of SP cells among the five glioma cell lines that were analyzed. The SP cells had a self-renewal ability and were capable of forming spheres in a neurosphere culture medium containing EGF and FGF2. Spheres derived from the SP cells differentiated into three different lineage cells: neurons, astrocytes and oligodendrocytes. RT-PCR analysis revealed that the SP cells expressed a neural stem cell marker, Nestin. The SP cells generated tumors in the brains of NOD/SCID mice at 8weeks after implantation, whereas the non-SP cells did not generate any tumors in the brain. These results indicate that SP cells isolated from SK-MG-1 possess the properties of cancer stem cells, including their self-renewal ability, multi-lineage differentiation, and tumorigenicity. Therefore, the SP cells from SK-MG-1 may be useful for analyzing BCSCs because of the ease with which they can be handled and their yield.

Preferential expression and frequent IgG responses of a tumor antigen, SOX5, in glioma patients.

We previously reported to identify SOX5 as a glioma antigen by serological screening using a testis cDNA library. The present study was designed to analyze SOX5 expression, its immunoreactivity, and the correlation between SOX5 IgG responses and clinical features in glioma patients to evaluate the possibility of its use as a diagnostic marker. Quantitative RT‐PCR and Western blot analysis revealed that SOX5 was expressed in glioma tissues, but not in normal adult tissues, except in the testis. An immunohistochemical analysis showed that SOX5 was expressed in glioma cells, but only a few SOX5‐positive cells were detected in non‐neoplastic tissues from the cerebral cortex. IgG antibodies against SOX5 were detected in sera from 8 of the 27 glioma patients (27.6%), 0 of the 14 patients with other brain diseases (0%), 1 of the 54 other cancer patients (1.9%) and 1 of the 37 healthy individuals (2.7%). Patients with glioblastoma (GBM) who showed IgG responses against SOX5 exhibited significantly better survival periods than GBM patients without SOX5 antibodies. In summary, SOX5 is aberrantly expressed in glioma and can be recognized as a glioma antigen using IgGs from the sera of glioma patients. Furthermore, there is a statistically significant correlation between the presence of SOX5 IgGs and survival in GBM patients, suggesting that the glioma antigen SOX5 may be useful not only as a diagnostic marker, but also as a prognositic marker in glioma patients.

Functional recovery after spinal cord injury in mice through activation of microglia and dendritic cells after IL-12 administration.

We have previously reported that the transplantation of dendritic cells (DCs) brings about functional recovery after spinal cord injury in mice through the activation of endogenous microglia/macrophages and neural stem/progenitor cells. In this study, the effect of interleukin‐12 (IL‐12), which is secreted from DCs, was evaluated for the treatment of spinal cord injury in mice. Administration of IL‐12 into the injured site significantly increased the number of activated microglia/macrophages and DCs as well as the expression of brain‐derived neurotrophic factor surrounding the lesion site. Immunohistochemical analyses showed that de novo neurogenesis and remyelination were induced by IL‐12 treatment. Furthermore, an open field test using Basso‐Beattie‐Brenham scoring revealed a significant improvement of locomotor function in mice treated with IL‐12. These results suggest that IL‐12 administration into the injured spinal cord results in a functional recovery through the activation of microglia/macrophages and DCs.

Identification of HLA-A2- and A24-restricted T-cell epitopes derived from SOX6 expressed in glioma stem cells for immunotherapy†

Malignant gliomas are the most aggressive human primary brain tumors and are currently incurable. Immunotherapies have the potential to target glioma and glioma stem cells (GSCs) that are resistant to conventional therapies. We previously identified SOX6 as a human glioma antigen and demonstrated that vaccination with SOX6 DNA induced cytotoxic T lymphocytes (CTLs) specific for glioma, thereby exerting therapeutic antitumor responses in glioma‐bearing mice. In this study, we attempted to identify SOX6‐derived peptides as specific targets for effective and safe T‐cell‐mediated immunotherapy targeting SOX6‐positive glioma and GSCs. In vitro stimulation with human leukocyte antigen (HLA)‐A*2402 (A24)‐restricted peptides, RFENLGPQL (SOX6504) and PYYEEQARL (SOX6628) or the HLA‐A*0201 (A2)‐restricted peptide, ALFGDQDTV (SOX6447) was capable of inducing SOX6 peptide‐specific CTLs in peripheral blood mononuclear cells derived from healthy donors and glioma patients. These CTLs were able to lyse a majority of glioma cell lines and a GSC line derived from human glioblastoma in an HLA Class I‐restricted and an antigen‐dependent manner. Furthermore, peptide vaccines of SOX6628, which was conserved in the murine SOX6 protein and expected to bind to major histocompatibility complex (MHC) H‐2d, induced CTLs specific for SOX6628 in H‐2d mice. Normal autologous cells from mice, in which SOX6‐specific immune responses were generated, were not destroyed. These results suggest that these SOX6 peptides are potnetially immunogenic in HLA‐A24 or ‐A2 positive glioma patients and should be considered as a promising strategy for safe and effective T‐cell‐based immunotherapy of patients with gliomas.

Intracarotid injection of granulocyte–macrophage colony-stimulating factor induces neuroprotection in a rat transient middle cerebral artery occlusion model

Granulocyte-macrophage colony-stimulating factor (GM-CSF) was found to promote collateral flow in patients with coronary artery disease and also to induce arteriogenesis in a rat hypoperfusion brain model. Activated macrophages have been shown to induce vascular proliferation and play an important role in ischemic stroke. In this study, we examined the therapeutic effect of GM-CSF on the ischemic brain by activating microglia/macrophages. Rats were subjected to 1-h intraluminal middle cerebral artery occlusion (MCAO) and received an intracarotid injection of GM-CSF (5 ng) or saline immediately after reperfusion. Infarct volume, neurological function and histological findings were assessed 48 h later. An intracarotid injection of GM-CSF reduced the infarct volume and improved neurological function at 48 h after reperfusion. Histological analysis revealed that the number of activated microglia/macrophages to be increased and the number of apoptotic cells to be decreased in the area of the penumbra. These results suggest that intracarotid injection of GM-CSF may have a therapeutic effect on brain ischemia via activation of microglia/macrophages.

Activation of dendritic-like cells and neural stem/progenitor cells in injured spinal cord by GM-CSF.

Previously, we demonstrated that implanted dendritic cells (DCs) in the injured spinal cord of adult mice exert a neurotrophic effect, resulting in the activation of endogenous neural stem/progenitor cells (NSPCs) and neurogenesis. Granulocyte-macrophage colony stimulating factor (GM-CSF), which is an essential cytokine for the generation of DCs from haematopoietic progenitor cells, has been shown to be beneficial for the treatment of spinal cord injury (SCI). In the present study, to evaluate the mechanisms underlying this therapeutic efficacy of GM-CSF, we investigated the effects of GM-CSF on the DC-like cells and NSPCs in the injured spinal cord. When GM-CSF was injected into the injured spinal cords of mice, the numbers of DC-like cells and activated microglia/macrophages around the lesion site increased, accompanied by an increase in BDNF expression. A significant increase in endogenous NSPCs was observed around the lesion site in the GM-CSF-treated mice compared with that in the controls. A neurosphere forming assay revealed that GM-CSF also induced the proliferation of NSPCs in vitro. Moreover, injection of GM-CSF into the lesion immediately after the SCI resulted in early recovery of the locomotor function of the injured mice. In conclusion, GM-CSF activated DC-like cells and NSPCs in the injured spinal cord, which was probably involved in its beneficial effects in cases of spinal cord injury.

Identification of an epigenetically silenced gene, RFX1, in human glioma cells using restriction landmark genomic scanning.

To identify the CpG islands differentially methylated in human glioma, we performed restriction landmark genomic scanning with a CpG methylation-sensitive enzyme. We found 12 spots, the intensity of which was entirely lost or decreased in both the human glioma tissues examined as compared with that in matched normal lymphocytes, indicating aberrant methylation of these CpG islands in gliomas. The expression of RFX1, one of the genes associated with the methylated CpG islands, was frequently decreased in human glioma cell lines and tissues. We also demonstrated that the isolated CpG island located in the seventh intron of the RFX1 gene had enhancer activity and was hypermethylated in all of the glioma tissues and cell lines analysed, but not in normal brains or lymphocytes. Treatment of glioma cells with a demethylating agent, 5-azacytidine, resulted in the expression of RFX1, indicating that the silencing of the RFX1 gene may be attributable to its methylation. RFX1 has been implicated in transcriptional downregulation of the proto-oncogene c-myc. By expression of the RFX1 gene, the cellular proliferative activity of glioma cells was suppressed. Taken together, these results suggest that the RFX1 gene may be epigenetically silenced in human gliomas and involved in glioma tumorigenesis.

Functional analysis of HOXD9 in human gliomas and glioma cancer stem cells.

BackgroundHOX genes encode a family of homeodomain-containing transcription factors involved in the determination of cell fate and identity during embryonic development. They also behave as oncogenes in some malignancies.ResultsIn this study, we found high expression of the HOXD9 gene transcript in glioma cell lines and human glioma tissues by quantitative real-time PCR. Using immunohistochemistry, we observed HOXD9 protein expression in human brain tumor tissues, including astrocytomas and glioblastomas. To investigate the role of HOXD9 in gliomas, we silenced its expression in the glioma cell line U87 using HOXD9-specific siRNA, and observed decreased cell proliferation, cell cycle arrest, and induction of apoptosis. It was suggested that HOXD9 contributes to both cell proliferation and/or cell survival. The HOXD9 gene was highly expressed in a side population (SP) of SK-MG-1 cells that was previously identified as an enriched-cell fraction of glioma cancer stem-like cells. HOXD9 siRNA treatment of SK-MG-1 SP cells resulted in reduced cell proliferation. Finally, we cultured human glioma cancer stem cells (GCSCs) from patient specimens found with high expression of HOXD9 in GCSCs compared with normal astrocyte cells and neural stem/progenitor cells (NSPCs).ConclusionsOur results suggest that HOXD9 may be a novel marker of GCSCs and cell proliferation and/or survival factor in gliomas and glioma cancer stem-like cells, and a potential therapeutic target.

Downregulation of uPARAP mediates cytoskeletal rearrangements and decreases invasion and migration properties in glioma cells.

To identify molecular therapeutic targets for glioma, we performed gene expression profiling by using a complementary DNA (cDNA) microarray method and identified the urokinase plasminogen activator receptor-associated protein (uPARAP/Endo180) as a gene expressed highly in glioma tissue compared with the normal brain tissue. The uPARAP is an endocytic receptor for collagen. In certain cell types, uPARAP occurs in a complex with the urokinase plasminogen activator receptor (uPAR) where it fulfills other functions in addition to collagenolysis. Quantitative PCR analysis using a cDNA panel revealed higher expression levels of uPARAP in glioma tissue compared with normal brain tissue. Western blot analysis revealed that the uPARAP protein was expressed in glioma samples and two glioma cell lines, KNS42 and KNS81, but not expressed in control tissue from the normal brain. Introduction of small interfering RNA-targeted uPARAP into the two different glioma cell lines, KNS42 and KNS81, resulted in downregulation of uPARAP expression, and it significantly suppressed glioma cell migration and invasion in vitro. Control glioma cells showed small cell bodies, whereas uPARAP siRNA-treated glioma cells exhibited large and flat morphology. Most of the polymeric actin in the control glioma cells was concentrated in the lamellipodia that are observed in mobile cells. In contrast, in the uPARAP siRNA-treated glioma cells, polymeric actin became organized in stress fibers and the lamellipodia disappeared, characteristic of immobile cells. Our present study suggests that uPARAP may be involved in glioma cell invasiveness through actin cytoskeletal rearrangement. downregulation of uPARAP may be a novel anti-invasion therapeutic strategy for malignant gliomas.