Yasuo Tohma scite author profile

Loss of heterozygosity (LOH) on chromosome 10 is the most frequent genetic alteration associated with the evolution of malignant astrocytic tumors and it may involve several loci. The tumor suppressor gene PTEN (MMAC1) on chromosome 10q23 is mutated in approximately 30% of glioblastomas (WHO Grade IV). In this study, we assessed the frequency of PTEN mutations in primary glioblastomas, which developed clinically de novo, and in secondary glioblastomas, which evolved from low-grade (WHO Grade II) or anaplastic astrocytomas (WHO Grade III). Nine of 28 (32%) primary glioblastomas contained a PTEN mutation and an additional case showed a homozygous PTEN deletion. This indicates that after overexpression/amplification of the EGF receptor, loss of PTEN function is the most common alteration in primary glioblastomas. In this series, 5 of 28 (18%) primary glioblastomas showed both a PTEN mutation and EGFR amplification. In contrast, only 1 of 25 (4%) secondary glioblastomas contained a PTEN mutation, and none of them showed a homozygous PTEN deletion. The secondary glioblastoma with a PTEN mutation developed from an anaplastic astrocytoma that already carried the mutation. The observation that secondary glioblastomas have a p53 mutation as a genetic hallmark but rarely contain a PTEN mutation supports the concept that primary and secondary glioblastomas develop differently on a genetic level.

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Alterations of cell cycle regulatory genes in primary (de novo) and secondary glioblastomas

Biernat

Tohma

Yonekawa

et al. 1997

Acta Neuropathologica

141

100

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Primary glioblastomas develop rapidly de novo through a genetic pathway characterized by amplification/overexpression of EGFR and of MDM2 genes. Secondary glioblastomas develop more slowly through progression from low grade or anaplastic astrocytoma and show a high incidence of a p53 mutation. In the present study, primary and secondary glioblastomas were analyzed for p16 deletions and CDK4 amplification by differential PCR and for loss of expression of the retinoblastoma (RB) gene by immunohistochemistry. Except for one case, alterations in the structure or expression of p16, CDK4 and RB were mutually exclusive. The overall incidence of aberrant expression of these genes coding for components of the cell-cycling-regulatory system was similar in primary (14/28; 50%) and secondary glioblastomas (9/23; 39%). However, p16 deletions were significantly more frequent in the former (10/28; 36%) than in the latter (1/23, 4%; P = 0.0075), suggesting that this alteration constitutes an additional genetic hallmark of the primary (de novo) glioblastoma.

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Fas Ligand Expression in Glioblastoma Cell Lines and Primary Astrocytic Brain Tumors

Gratas¹,

Tohma²,

Meir³

et al. 1997

Brain Pathology

138

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Fas/APO-1 (CD95) is a cell surface receptor that mediates apoptosis when it reacts with Fas ligand (FasL) or Fas antibody. We previously reported that Fas expression is predominantly induced in perinecrotic glioma cells, suggesting that Fas induction is associated with apoptosis and necrosis formation, a histological hallmark of glioblastomas. In this study, we assessed the expression of FasL in 10 glioblastoma cell lines and in 14 astrocytic brain tumors (three low-grade astrocytomas and 11 glioblastomas). Reverse transcriptase (RT)-PCR revealed that all glioblastoma cell lines and primary astrocytic brain tumors express FasL. Immunohistochemically, FasL was predominantly expressed on the plasma membrane of glioma cells. These results suggest that FasL expression is common in human astrocytic brain tumors and may cause apoptosis of glioma cells if Fas expression is induced.

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Necrogenesis and Fas/APO-1 (CD95) Expression in Primary (de novo) and Secondary Glioblastomas

Tohma

Gratas

Meir³

et al. 1998

J Neuropathol Exp Neurol

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Glioblastomas may develop rapidly without clinical and histopathological evidence of a less malignant precursor lesion (de novo or primary glioblastoma) or through progression from low-grade or anaplastic astrocytoma (secondary glioblastoma). Primary glioblastomas typically show overexpression of EGFR, but rarely p53 mutations, while secondary glioblastomas frequently carry a p53 mutation, but usually lack overexpression of EGFR, suggesting that these glioblastoma subtypes develop through distinct genetic pathways. In the present study, we assessed the expression of Fas/APO-1 (CD95), an apoptosis-mediating cell membrane protein, and its relation to necrosis phenotype in primary and secondary glioblastomas. Large areas of ischemic necroses were observed in all 18 primary glioblastomas, but were significantly less frequent in secondary glioblastomas (10 of 19, 53%; p = 0.0004). Fas expression was predominantly observed in glioma cells surrounding large areas of necrosis and was thus significantly more frequent in primary glioblastomas (18 of 18, 100%) than in secondary glioblastomas (4 of 19, 21%; p < 0.0001), suggesting that these clinically and genetically defined subtypes of glioblastoma differ in the extent and mechanism of necrogenesis. Necrosis and microvascular proliferation are histologic hallmarks of the glioblastoma. Following incubation of glioblastoma cell lines under hypoxic/anoxic conditions for 24-48 hours, Fas mRNA levels remained unchanged, whereas VEGF expression was markedly upregulated. This suggests that in contrast to VEGF Fas expression is not induced by ischemia/hypoxia. Analysis of Fas mRNA levels in a glioblastoma cell line containing a p53 mutation and an inducible wild-type p53 gene showed little difference under induced and noninduced conditions, suggesting that in glioblastomas, Fas expression is not directly linked to the p53 status.

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Prostaglandin D Synthase (β-Trace) in Human Arachnoid and Meningioma Cells: Roles as a Cell Marker or in Cerebrospinal Fluid Absorption, Tumorigenesis, and Calcification Process

et al. 1997

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Glutathione-independent prostaglandin D synthase (PGDS) is an enzyme responsible for biosynthesis of prostaglandin D2 in the CNS and is identical to a major cerebrospinal fluid protein, beta-trace. Although PGDS has been identified recently in rat leptomeninges, little information is available about human meninges or meningiomas. Here, we report PGDS to be expressed consistently in 10 human arachnoid and arachnoid villi and in 21 meningiomas by immunohistochemistry, Western blot, and reverse transcription (RT)-PCR analyses. In arachnoid, PGDS immunoreactivity was seen in arachnoid barrier cells but was negligible in arachnoid trabecula and pia mater. In contrast, in arachnoid villi, PGDS was seen in core arachnoid cells rather than in the cap cell cluster or arachnoid cell layer. Meningioma cells also showed intense immunoreactivity in the perinuclear region, and it was often concentrated within meningocytic whorls and around calcifying psammoma bodies. Immunoelectron microscopic data, when compared with the ultrastructure, showed that PGDS was localized at rough endoplasmatic reticulum of arachnoid and meningioma cells. Western blot showed a 29 kDa immunoreactive band indicating PGDS, but the extent of expression was variable from case to case, which was compatible with immunohistochemical data. RT-PCR revealed PGDS gene expression in all meningiomas studied, regardless of histological subtypes, and also in human arachnoid villi. Because human arachnoid and meningioma cells exclusively express PGDS, it can be considered their specific cell marker. These results show functional differences in various types of meningeal cells attributable to differences in PGDS expression.

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Yasuo Tohma

PTEN (MMAC1) Mutations Are Frequent in Primary Glioblastomas (de novo) but not in Secondary Glioblastomas

Alterations of cell cycle regulatory genes in primary (de novo) and secondary glioblastomas

Fas Ligand Expression in Glioblastoma Cell Lines and Primary Astrocytic Brain Tumors

Necrogenesis and Fas/APO-1 (CD95) Expression in Primary (de novo) and Secondary Glioblastomas

Prostaglandin D Synthase (β-Trace) in Human Arachnoid and Meningioma Cells: Roles as a Cell Marker or in Cerebrospinal Fluid Absorption, Tumorigenesis, and Calcification Process

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