All reovirus subtypes show oncolytic potential in primary cells of human high-grade glioma.

Reoviridae are non-human pathogenic viruses. The family of reoviridae consists of 4 different subtypes. Many studies have proven that the Dearing subtype 3 has oncolytic potential. This potential is related to the RAS protein expression in tumour cells. The aim of this study, was to investigate whether all reovirus subtypes have oncolytic potential and whether there are differences in their efficacy, in particular for high-grade glioma. To evaluate the oncolytic potential, we performed an in vitro head-to-head study for all reovirus subtypes in 5 primary cell cultures of high-grade gliomas. The oncolytic activity was determined using end-point titration with observation of the cytopathogenic effect. For measurement of RAS activity, we performed an immunofluorescent detection stain on all cell cultures. For quantification of the virus, an RT-PCR measurement for all subtypes was performed. All reovirus subtypes showed oncolytic activity in the observed glioma biopsies. These observations correlated with RAS overexpression in the observed cells. All glioma biopsies overexpressed the RAS protein. The quantitative oncolytic potential differed in relation to the single observed cell culture and in relation to the chosen reovirus subtype. To our knowledge, this is the first study showing oncolytic activity for all reovirus subtypes. We show the relationship and correlation between RAS protein overexpression and vulnerability of cells to reovirus. Efficacy of the different subtypes is interindividually different and cannot be forecast.

[Chromosomal alterations in juvenile angiofibromas]. / Chromosomale Alterationen beim juvenilen Angiofibrom.

INTRODUCTION: Despite their benign histological appearance, juvenile angiofibromas, which occur mainly in adolescent males, have a locally aggressive growth pattern. beta-catenin-mutations represent their only known genetic abnormality. MATERIAL AND METHODS: Angiofibroma tissue from seven patients was available for comparative genomic hybridization (CGH). RESULTS: In six out of the seven angiofibromas, CGH detected various abnormalities on 18 different chromosomes. Frequent chromosomal gains were observed on chromosomes 4q, 6q, and 8q. In four out of seven angiofibromas a complete loss of the chromosome Y was detected. CONCLUSIONS: CGH is a suitable method for the examination of angiofibromas for genetic alterations. Considering the sex distribution of this neoplasm, the frequent loss of chromosome Y is of particular interest.

Frequent mitotic errors in tumor cells of genetically micro-heterogeneous glioblastomas.

Glioblastoma multiforme (GBM) is characterized by intratumoral heterogeneity as to both histomorphology and genetic changes, displaying a wide variety of numerical chromosome aberrations the most common of which are monosomy 10 and trisomy 7. Moreover, GBM in vitro are known to have variable karyotypes within a given tumor cell culture leading to rapid karyotype evolution through a high incidence of secondary numerical chromosome aberrations. The aim of our study was to investigate to what extent this mitotic instability of glioblastoma cells is also present in vivo. We assessed the spatial distribution patterns of numerical chromosome aberrations in vivo in a series of 24 GBM using two-color in situ hybridization for chromosomes 7/10, 8/17, and 12/18 on consecutive 6-microm paraffin-embedded tissue slides. The chromosome aberration patterns were compared with the histomorphology of the investigated tumor assessed from a consecutive HE-stained section, and with the in vitro karyotype of cell cultures established from the tumors. All investigated chromosomes showed mitotic instability, i.e., numerical aberrations within significant amounts of tumor cells in a scattered distribution through the tumor tissue. As to chromosomes 10 and 17, only monosomy occurred, as to chromosome 7 only trisomy/polysomy, apparently as a result of selection in favor of the respective aberration. Conversely, chromosomes 8, 12, and 18 displayed scattered patterns of monosomy as well as trisomy within a given tumor reflecting a high mitotic error rate without selective effects. The karyotypes of the tumor cell cultures showed less variability of numerical aberrations apparently due to clonal adaptation to in vitro conditions. We conclude that glioblastoma cells in vivo are characterized by an extensive tendency to mitotic errors. The resulting clonal diversity of chromosomally aberrant cells may be an important biological constituent of the well-known ability of glioblastomas to preserve viable tumor cell clones under adaptive stress in vivo, in clinical terms to rapidly recur after antitumoral therapy including radio- or chemotherapy.

Genetic imbalances in preinvasive tissue of hypopharynx provide evidence for cytogenetic heterogeneity.

Multiple chromosomal aberrations have been reported in head and neck squamous cell carcinoma (HNSCC). But less information is available on specific patterns of chromosomal amplifications which distinguish different areas of head and neck tumors. To elucidate genetic mechanisms causing the aggressive growth and high proliferation of hypopharyngeal squamous cell carcinoma (SCC), we performed reverse chromosome painting (RCP) on a total of eight hypopharyngeal SCC including invasive carcinoma and preinvasive tissue. Five hypopharyngeal invasive carcinomas showed amplifications on chromosome 3q. Furthermore, we detected gains on chromosomes 11q and 6p. Compared to the histologically classified preinvasive tissues, we found amplified alterations on chromosome 6p, 11q and 12q, but none of them showed gains on chromosome 3q. This observed heterogeneity in hypopharyngeal SCC might reflect a specific role of chromosome 3q as a late event in the highly invasive capacity of these SCC.

DNA amplification on chromosome 7q in squamous cell carcinoma of the tongue.

Squamous cell carcinoma of the head and neck exhibit a highly variable picture of chromosomal aberrations. In the present study the clearly defined anatomical region of the tongue was analyzed for potentially specific patterns of chromosomal alterations. Fresh tumor samples from 18 patients afflicted by squamous cell carcinoma of the tongue constituted the clinical basis of the present investigation. The tumor samples were analyzed on the basis of comparative genomic hybridization (CGH), a molecular cytogenetic FISH-approach. Gains in DNA copy numbers were detected as the predominant imbalance on chromosomes 7q (9/18), 3q (48/18), 16p (7/18) and 20q (7/18). The regions of minimal overlap on these chromosomes were mapped to 7q11.2q11.3 and 3q26. A conspicuous finding was the frequent detection of amplifications in the 7q11 region. Gains in the 7q region have been rarely reported in CGH studies of tumors derived from different regions of the head and neck. Amplifications on 7q could thus be specifically linked with the tongue region and could correlate with specific clinical factors of this tumor entity.

Distribution of epidermal growth factor receptor protein correlates with gain in chromosome 7 revealed by comparative genomic hybridization after microdissection in glioblastoma multiforme.

In a recent study, 23 microdissected areas of 10 glioblastoma multiforme (GBM) were investigated for quantitative genomic aberrations using comparative genomic hybridization (CGH). To validate the chromosomal aberrations, as revealed by CGH after microdissection, parallel tissue sections were stained immunohistochemically with an antibody that detects both wild-type epidermal growth factor receptor (EGFR) and the deletion mutant form of the receptor (EGFRvIII). Immunostaining was correlated with CGH data of chromosome 7, because chromosome 7 is the most frequently aberrant chromosome in GBM (here four of 10 tumors), and this aberration often indicates an abnormality of EGFR. Nine of nine areas that showed gain in or amplification (2 areas) of chromosome 7 with CGH contained EGFR-immunoreactive cells. Only three of 14 areas without abnormality of chromosome 7 in CGH contained EGFR-immunoreactive cells; eleven of 14 areas were immunonegative. Our findings demonstrate a strong correlation between immunohistochemistry of EGFR and the copy numbers of chromosome 7, as revealed by CGH after microdissection in glioblastoma multiforme.

Comparative genomic hybridization reveals recurrent enhancements on chromosome 20 and in one case combined amplification sites on 15q24q26 and 20p11p12 in glioblastomas.

We examined homogenized tissue samples of biopsies from 19 astrocytomas of different grades for genetic imbalances using comparative genomic hybridization (CGH): three astrocytomas grade II, and 16 astrocytomas grade IV (glioblastoma multiforme), one of the glioblastomas representing the recurrence of a benign oligoastrocytoma. In two of three cases of astrocytoma grade II, a gain of chromosome 7 was found. The alterations in the glioblastomas were complex, and most frequently showed the characteristic gain of chromosome 7 and loss of chromosome 10. The single analyzed case of recurrence of an oligoastrocytoma was characterized by a unique CGH pattern. This tumor showed two distinct alterations: apart from an amplification on 15q24q26, we found a distinct amplification of a small region on 20p11.2p12, which has not been previously described in brain tumors. Partial or complete gains of chromosome 20 arose in six other tumors; we conclude that chromosome 20 in particular 20p11. 2p12, may harbor relevant genes for glioma progression.

Evidence of focal genetic microheterogeneity in glioblastoma multiforme by area-specific CGH on microdissected tumor cells.

The term "multiforme" in glioblastoma multiforme (GBM) indicates the highly variable histomorphology that cannot be addressed by studies on homogenized tissue probes. In order to relate genetic findings with histomorphologically distinct areas we used microdissection to procure defined cell populations from microscopic tissue sections under direct visualization. Formalin-fixed and paraffin-embedded tissue sections of 10 GBM were evaluated for intratumoral genetic heterogeneity by microdissection of multiple areas of 20-50 tumor cells and DOP-PCR of DNA isolated from the dissected cell groups, followed by comparative genomic hybridization (CGH). Microdissected cells from histomorphologically normal extratumoral blood vessels from the same slides served as controls. The individual tumors showed variable combinations of primary chromosomal gains and losses common to all studied areas of a given case along with secondary, area-specific additional aberrations. CGH displayed a wider variety of chromosomal aberrations than metaphase cytogenetics of cell cultures from the same tumors. The most frequent aberrations observed were previously unperceived gains on chromosomes 4q (8/10) and 5q (5/10). Other nonrandom aberrations were gains on 12q (6/10), 13q (6/10), and 7 (5/10), and losses of 22 (5/10). Amplifications on 7p were intratumorally heterogeneous and only found in single areas of 2 tumors. In contrast to normal extratumoral vessels, vascular proliferates in most cases demonstrated chromosomal aberrations (CGH) which were partially different from the aberrations observed in the tumor itself. The described method gives evidence of considerable intratumoral genetic heterogeneity in GBM and provides a sensitive tool for the detection of quantitative chromosomal changes that are present only regionally within a given tumor.

[Genetic factors in the pathogenesis of brain tumors]. / Genetische Grundlagen der Entstehung von Hirntumoren.

The biological properties of tumor cells are determined by, mostly acquired, alterations of proliferation-relevant genes that can provide valuable diagnostic and prognostic parameters. Meningiomas and gliomas are among the genetically best characterized solid tumors. Here, specific patterns of primary and secondary genetic aberrations have been identified and shown to be correlated with clinical parameters such as recurrency of meningiomas or malignant progression of astrocytomas. Focal progression leading to intratumoral heterogeneity, which is most strikingly seen in gliomas, results from complex mechanisms of mutation and selection of tumor cells that are also iatrogenically influenced through radiotherapy and chemotherapy.