Steffi Urbschat

AKT1E17K mutations cluster with meningothelial and transitional meningiomas and can be detected by SFRP1 immunohistochemistry

The activating E17K mutation in the AKT1 gene has been detected in several tumor entities. Currently several clinical studies with specific AKT1 inhibitors are under way. To determine whether AKT1 mutations are involved in human tumors of the nervous system, we examined a series of 1,437 tumors including 391 primary intracranial brain tumors and 1,046 tumors of the coverings of the central and peripheral nervous system. AKT1E17K mutations were exclusively seen in meningiomas and occurred in 65 of 958 of these tumors. A strong preponderance was seen in the variant of meningothelial meningioma WHO grade I of basal and spinal localization. In contrast, AKT1E17K mutations were rare in WHO grade II and absent in WHO grade III meningiomas. In order to more effectively detect this mutation, we tested for immunohistochemical markers associated with this alteration. We observed strong up-regulation of SFRP1 expression in all meningiomas with AKT1E17K mutation and in HEK293 cells after transfection with mutant AKT1E17K, but not in meningiomas and HEK293 cells lacking this mutation.

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-µm 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.

First Evidence of Genetic Imbalances in Angiofibromas

Objective/Hypothesis Angiofibromas are clinically well characterized by their origin at the posterior lateral nasal wall close to the sphenopalatine foramen, their occurrence in male adolescent patients, and the histological findings of a benign fibrovascular neoplasm with irregular, endothelium‐lined vascular spaces in a fibrous stroma. However, their etiology and genetic causes remain unknown. The present study addresses genetic imbalances in angiofibromas.

A Different View on DNA Amplifications Indicates Frequent, Highly Complex, and Stable Amplicons on 12q13-21 in Glioma

To further understand the biological significance of amplifications for glioma development and recurrencies, we characterized amplicon frequency and size in low-grade glioma and amplicon stability in vivo in recurring glioblastoma. We developed a 12q13-21 amplicon–specific genomic microarray and a bioinformatics amplification prediction tool to analyze amplicon frequency, size, and maintenance in 40 glioma samples including 16 glioblastoma, 10 anaplastic astrocytoma, 7 astrocytoma WHO grade 2, and 7 pilocytic astrocytoma. Whereas previous studies reported two amplified subregions, we found a more complex situation with many amplified subregions. Analyzing 40 glioma, we found that all analyzed glioblastoma and the majority of pilocytic astrocytoma, grade 2 astrocytoma, and anaplastic astrocytoma showed at least one amplified subregion, indicating a much higher amplification frequency than previously suggested. Amplifications in low-grade glioma were smaller in size and displayed clearly different distribution patterns than amplifications in glioblastoma. One glioblastoma and its recurrencies revealed an amplified subregion of 5 Mb that was stable for 6 years. Expression analysis of the amplified region revealed 10 overexpressed genes (i.e., KUB3, CTDSP2, CDK4, OS-9, DCTN2, RAB3IP, FRS2, GAS41, MDM2, and RAP1B) that were consistently overexpressed in all cases that carried this amplification. Our data indicate that amplifications on 12q13-21 (a) are more frequent than previously thought and present in low-grade tumors and (b) are maintained as extended regions over long periods of time. (Mol Cancer Res 2008;6(4):576–84)

Correspondence of tumor localization with tumor recurrence and cytogenetic progression in meningiomas.

OBJECTIVEMeningiomas are mostly benign tumors that originate from the coverings of the brain and spinal cord. Cytogenetically, they reveal a normal karyotype or, typically, monosomy of chromosome 22. Progression of meningiomas is associated with a non-random pattern of secondary losses of other autosomes. Deletion of the short arm of one chromosome 1 is a decisive step to anaplastic growth in meningiomas. METHODSStatistical analyses were performed for the karyotypes of 661 meningiomas with respect to localization, progression, and recurrence of the tumor. A mathematical mixture model estimates typical pathogenetic routes in terms of the accumulation of somatic chromosome changes in tumor cells. The model generates a genetic progression score (GPS) that estimates the prognosis as related to the cytogenetic properties of a given tumor. RESULTSIn 53 patients, one or several recurrences were documented over the period of observation. This corresponds to a total rate of recurrence of 8.0% after macroscopically complete tumor extirpation. Higher GPS values were shown to be strongly correlated with tumor recurrence (P = 2.9 × 10−7). High-risk tumors, both in terms of histology and cytogenetics, are localized much more frequently at the brain surface than at the cranial base (P = 1.2 × 10−5 for World Health Organization grade and P = 3.3 × 10−12 for GPS categorization). CONCLUSIONThe tendency of cranial base meningiomas to recur seems to depend on surgical rather than biological reasons. As a quantitative measure, the GPS allows for a more precise assessment of the prognosis of meningiomas than the established categorical cytogenetic markers.

Molecular biological determinations of meningioma progression and recurrence.

Meningiomas are tumors that arise from the coverings of the brain or spinal cord. 5% of the cases turn into malignant forms with aggressive clinical behavior and increased risk of tumor recurrence. One hundred and five patients with meningiomas were operated by open surgery. To investigate predictors of meningioma recurrence in total 124 samples of 105 patients were investigated by iFISH. Dual-probe hybridization was performed to access chromosomal alterations of chromosomes 1p-, 9p- and 22q. Additionally, methylation of TIMP3 and p16 was analyzed with MS-PCR. Of the 105 investigated tumors 59.1% (62/105) were WHO grade I, 33.3% (35/105) were WHO grade II and 7.7% (8/105) were anaplastic meningiomas (grade III), respectively. The histopathological data correlates with the recurrence rate of the investigated meningiomas. Hypermethylation of TIMP3 was detected in 13.3% of all meningiomas: 10.9% in WHO grade I meningiomas, 25.0% in grade II and 14.3% in grade III meningiomas, respectively. No correlation of TIMP3 hypermethylation with tumor recurrence or WHO grade (p = 0.2) was observed. Interestingly, deletion of 1p36 emerged as a significant predictor of shorter overall survival (log rank test, p<0.001), whereas TIMP3 promoter methylation had no significant effect on overall survival (log rank test, p = 0.799). The results of the current study support the finding that the deletion of chromosome 1p is an independent marker of meningioma recurrence and progression (p = 0.0097). Therefore the measurement of genetic aberrations in meningiomas allows in a combined histological approach a more precise assessment of the prognosis of meningiomas than histopathology alone.

Application of oncogenetic trees mixtures as a biostatistical model of the clonal cytogenetic evolution of meningiomas

Meningiomas are mostly benign tumors that originate from the coverings of brain and spinal cord. Typically, they reveal a normal karyotype or monosomy for chromosome 22. Rare clinical progression of meningiomas is associated with a nonrandom pattern of secondary losses of other autosomes. Deletion of the short arm of one chromosome 1 appears to be a decisive step for anaplastic growth in meningiomas. We calculated an oncogenetic tree model that estimates the most likely cytogenetic pathways of 661 meningioma patients in terms of accumulation of somatic chromosome changes in tumor cells. The genetic progression score (GPS) estimates the genetic status of a tumor as progression in the corresponding tumor cells along this model. Large GPS values are highly correlated with early recurrence of meningiomas [p < 10−4]. This correlation holds even if patients are stratified by WHO grade. We show that tumor location also has an impact on genetic progression. Clinical relevance of the GPS is thus demonstrated with respect to origin, WHO grade and recurrence of the tumor. As a quantitative measure the GPS allows a more precise assessment of the prognosis of meningiomas than categorical cytogenetic markers based on single chromosomal aberrations.

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.

Comprehensive genomic analysis identifies MDM2 and AURKA as novel amplified genes in juvenile angiofibromas

Frequent β‐catenin mutations have been detected in juvenile angiofibromas, but the tumor pathogenesis remains unknown.