A region of common deletion in 22q13.3 in human glioma associated with astrocytoma progression.

Loss of heterozygosity for chromosome 22 (LOH 22) occurs in gliomas of all malignancy grades. Neurofibromatosis type 2 (NF2) patients are at increased risk of developing a glioma. However, the NF2 gene in 22q12.2 is not involved in glioma tumorigenesis. To detect additional regions on chromosome 22 that may harbor tumor suppressor genes important in glioma tumorigenesis, we determined LOH 22 profiles for 159 gliomas using 32 markers. LOH 22 was found in 46 tumors (29%). Thirteen tumors displayed partial LOH 22, from which we deduced a region of common deletion between markers D22S928 and D22S1169 in 22q13.3. LOH of at least this region was detected in 13% of the astrocytomas (As), in 20% of the anaplastic astrocytomas (AAs) and in 35% of the glioblastomas multiforme (GBMs). The significant increased frequency of LOH 22q13.3 in the highest malignancy grade (GBM vs. A and AA, p = 0.02) indicates that loss of this region is associated with astrocytoma progression.

Evidence for an ependymoma tumour suppressor gene in chromosome region 22pter-22q11.2.

Ependymomas are glial tumours of the brain and spinal cord. The most frequent genetic change in sporadic ependymoma is monosomy 22, suggesting the presence of an ependymoma tumour suppressor gene on that chromosome. Clustering of ependymomas has been reported to occur in some families. From an earlier study in a family in which four cousins developed an ependymoma, we concluded that an ependymoma-susceptibility gene, which is not the NF2 gene in 22q12, might be located on chromosome 22. To localize that gene, we performed a segregation analysis with chromosome 22 markers in this family. This analysis revealed that the susceptibility gene may be located proximal to marker D22S941 in 22pter-22q11.2. Comparative genomic hybridization showed that monosomy 22 was the sole detectable genetic aberration in the tumour of one of the patients. Loss of heterozygosity studies in that tumour revealed that, in accordance to Knudson's two-hit theory of tumorigenesis, the lost chromosome 22 originated from the parent presumed to have contributed the wild-type allele of the susceptibility gene. Thus, our segregation and tumour studies collectively indicate that an ependymoma tumour suppressor gene may be present in region 22pter-22q11.2.

Dynamics of genetic alterations associated with glioma recurrence.

We investigated the dynamics of the genetic changes that are associated with two types of glioma recurrence, that is, progression from a lower-grade to a high-grade tumor (7 cases) and development of a same high-grade recurrence (15 cases). Each pair of tumors was analyzed for TP53 mutation, EGFR amplification, and loss of heterozygosity for tumor suppressor genes (TP53, RB1, CDKN2A, PTEN, DMBT1) and tumor suppressor gene regions (1p36, 19q13, 11p15, 10p15) known to be frequently implicated in glioma tumorigenesis. By comparing the genetic changes in the primary and corresponding secondary tumors, we found that additional loss of CDKN2A and/or RB1, encoding important components of the cell cycle regulatory pathway, was the most frequent genetic change in both types of recurrence development (10 of 22 cases, 45%). Additional loss of heterozygosity for the 10p15 region, for PTEN, and/or for DMBT1 in the recurrent tumor was noted in 7 of 22 cases (32%), suggesting that additional inactivation of tumor suppressor genes on chromosome 10 is another important feature of glioma relapse. Less frequent additional losses were detected for chromosome regions 11p15 and 19q13 (3 of 22 cases, 14%, each). We conclude that glioma recurrences are characterized by an increased involvement of tumor suppressor genes, even in those cases in which the primary and secondary tumor are of the same high malignancy grade.

Genetic sub-types of human malignant astrocytoma correlate with survival.

In human malignant astrocytoma, age of the patient and histological grade of the tumor are important prognostic variables. Several genetic changes have been reported to occur in these tumors, which may be of additional and independent prognostic relevance. To determine their prognostic significance, we analyzed 75 high-grade tumors, 12 anaplastic astrocytomas and 63 glioblastomas multiforme, for the presence of genetic changes that occur frequently in high-grade astrocytoma, i.e., loss of heterozygosity (LOH) for chromosome 10, p53-gene alteration (mutation and/or LOH), and EGFR-gene amplification. We defined 4 groups of patients who showed a specific combination of genetic changes in the tumor: group 1, p53-gene alteration without complete LOH 10; group 2, complete LOH 10 only; group 3, p53-gene alteration + complete LOH 10; group 4, complete LOH 10 + EGFR-gene amplification. In univariate analysis, the log-rank test revealed significant differences in survival between patients of group 1 (median survival of 13 months) and group 3 (median survival of 5.2 months, p = 0.0058) and between patients of group 1 and group 4 (median survival of 4 months, p = 0.0033). In multivariate analysis, age and genetic sub-type proved to be important prognostic variables, whereas histological grading was less important. The age-corrected survival time for group-4 patients is significantly shorter than that for group-1 patients (relative risk = 3.79, p = 0.0075). Our data indicate that genetic sub-type is an important prognostic variable in human high-grade astrocytoma.

Fine mapping of a region of common deletion on chromosome arm 10p in human glioma.

Allelic loss on chromosome 10 is a frequent event in high grade gliomas. Earlier studies have shown that in most cases a complete copy of chromosome 10 is lost in the tumor. To define more accurately and specifically the region of common deletion on chromosome arm 10p, we have screened a large series of gliomas for allelic losses that exclusively affect this part of the chromosome. Allelic loss profiles were determined for 127 gliomas, including 118 astrocytomas of various malignancy grades. Seventeen tumors displayed loss of part of chromosome 10. In three of these, only chromosome arm 10p sequences were lost. The interval between loci D10S559 and D10S435 in 10p15, with a length of approximately 800 kilobase pairs, was commonly deleted in the latter tumors, suggesting that this region may harbor a tumor suppressor gene important in glioma tumorigenesis. Comparison of the allelic loss profiles in the low and high grade astrocytomas revealed that astrocytoma progression is associated with increased loss of chromosome 10 sequences.

Malignant astrocytoma-derived region of common amplification in chromosomal band 17p12 is frequently amplified in high-grade osteosarcomas.

Recently, we reported a new amplification event that involves marker D17S67 in 17p12 in three malignant astrocytomas of patients with a very short survival. The amplified region may contain an oncogene implicated in astrocytoma tumorigenesis. To determine the extent of the amplified regions, we constructed a yeast artificial chromosome contig spanning the D17S67 region and tested the amplification status of markers that map to the contig. We determined a commonly amplified region between markers D17S1311 and D17S1875 with a maximal length of 1,630 kb. By using marker 745R, from within the commonly amplified region, we screened 60 high-grade astrocytomas but could not detect additional tumors with the amplification event. This suggests that the incidence of the amplification event in high-grade astrocytoma is low (5%). It has recently been shown by comparative genomic hybridization that amplification of 17p11-p12 is a frequent event in high-grade osteosarcomas, occurring in 20-30% of cases. Since the commonly amplified region is within 17p12, we tested 745R in 20 osteosarcomas, including 6 lung metastases, and detected amplification in 9 cases (45%). Marker 745R was found to be amplified in 4 of the 6 lung metastases (66%). From this frequent involvement and the association with clinically aggressive astrocytomas we conclude that for both tumor types presence of the amplification event seems to correlate with aggressive clinical behaviour.

Identification and characterization of NF1-related loci on human chromosomes 22, 14 and 2.

Neurofibromatosis type 1 (NF1) is a frequent hereditary disorder. The disease is characterized by a very high mutation rate (up to 1/10000 gametes per generation). NF1-related loci in the human genome have been implicated in the high mutation rate by hypothesizing that these carry disease-causing mutations, which can be transferred to the functional NF1 gene on chromosome arm 17q by interchromosomal gene conversion. To test this hypothesis, we want to identify and characterize the NF1-related loci in the human genome. In this study, we have localized an NF1-related locus in the most centromeric region of the long arm of chromosome 22. We demonstrate that this locus contains sequences homologous to cDNAs that include the GAP-related domain of the functional NF1 gene. However, the GAP-related domain itself is not represented in this locus. In addition, cosmids specific to this locus reveal, by in situ hybridization, NF1-related loci in the pericentromeric region of chromosome arm 14q and in chromosomal band 2q21. These cosmids will enable us to determine whether identified disease-causing mutations are present at the chromosome 22-associated NF1-related locus.

Molecular analysis of genetic changes in ependymomas.

Ependymomas are glial cell-derived tumors. They are, in contrast to other gliomas (astrocytomas, oligodendrogliomas, and oligoastrocytomas), ill-defined with respect to the genes and chromosomal segments important in their tumorigenesis. In this study, we extensively screened 17 ependymomas for genetic changes characteristic of other gliomas. Allelic loss was detected on chromosome arm 22q in three tumors; on chromosome 10 in two tumors; on chromosome arm 17p in two tumors; and on chromosome arms 6q, 9p, 13q, and 19q, each in one tumor. No allelic losses were found on chromosome arms 1p and 16q. None of the tumors had EGFR gene amplification. In each case, the chromosomal segment affected by the deletion included the region known to harbor a tumor suppressor gene important in glioma tumorigenesis. We conclude that ependymomas resemble the other glial neoplasms with respect to type and location of the chromosomal changes involved. Given the relatively infrequent occurrence of these genetic changes, ependymomas should be considered genetically as low-grade gliomas.