Jesus Vaquero

NF2 gene mutations and allelic status of 1p, 14q and 22q in sporadic meningiomas

Formation of meningiomas and their progression to malignancy may be a multi-step process, implying accumulation of genetic mutations at specific loci. To determine the relationship between early NF2 gene inactivation and the molecular mechanisms that may contribute to meningioma tumor progression, we have performed deletion mapping analysis at chromosomes 1, 14 and 22 in a series of 81 sporadic meningiomas (54 grade I (typical), 25 grade II (atypical) and two grade III (anaplastic)), which were also studied for NF2 gene mutations. Single-strand conformational polymorphism analysis was used to identify 11 mutations in five of the eight exons of the NF2 gene studied. All 11 tumors displayed loss of heterozygosity (LOH) for chromosome 22 markers; this anomaly was also detected in 33 additional tumors. Twenty-nine and 23 cases were characterized by LOH at 1p and 14q, respectively, mostly corresponding to aggressive tumors that also generally displayed LOH 22. All three alterations were detected in association in seven grade II and two grade III meningiomas, corroborating the hypothesis that the formation of aggressive meningiomas follows a multi-step tumor progression model.

High-Resolution Analysis of Chromosome Arm 1p Alterations in Meningioma

Loss of heterozygosity (LOH) for loci on chromosome arm 1p is a relatively common event in human meningioma, and this anomaly has been proposed to be associated with the development of grade II or grade III forms (atypical and anaplastic meningiomas). Nevertheless, the limited data available do not allow the establishment of the frequency and the extent of the affected 1p regions. To determine the status of chromosome 1p in meningiomas, we have performed a comprehensive analysis of LOH on 1p in 100 meningiomas using a high density of 1p-marker loci. Allelic loss was found in 35% of tumors, most corresponding to nontypical meningiomas that also displayed losses for loci on chromosome 22. Although some tumors displayed complex rearrangements leading to distinct 1p deletions, the patterns of loss indicated two main target regions: 1p36 and 1p34-p32, which represent the most frequently involved regions, whereas 1p22 and 1p21.1-1p13 regions appeared deleted in some tumors. These results suggest that there may be several putative tumor suppressor genes on 1p, the inactivation of which may be important in the pathogenesis of meningiomas, as well as in other tumor types.

Allelic status of chromosome 1 in neoplasms of the nervous system

By using five highly polymorphic markers, the allelic status of chromosome 1 was established in a series of 236 tumors of the nervous system, including all major histologic subtypes: gliomas, meningiomas, neurinomas, neuroblastomas, medulloblastomas, etc. Loss of alleles at 1p was observed at significant frequencies in neuroblastomas (26% of cases), meningiomas (32%), and malignant gliomas (37%) (primarily oligodendrogliomas [94%]). This anomaly was also detected in two of 23 neurinomas, two of three neurofibrosarcomas, one primary lymphoma, and two metastatic tumors of the brain. The analysis of tumors displaying partial 1p deletions suggests the existence of two distinct regions, 1p36 and 1p35-p32, in which loci nonrandomly involved in the development of neurogenic neoplasms might be located.

Abnormalities of chromosome 22 in human brain tumors determined by combined cytogenetic and molecular genetic approaches.

Southern blot hybridization studies were performed on a panel of 130 blood/tumor samples from brain neoplasms including all major histologic subtypes: 50 meningiomas, 18 neurinomas, 56 gliomas, and six others. To detect abnormalities involving chromosome 22, polymorphic probes were used to analyze eight loci located in this chromosome: D22S9, IGLV, D22S20, D22S32, MB, PDGF-B, D22S80, and D22S171. Loss of heterozygosity (LOH) was observed in 40 cases including monosomy, terminal, and interstitial deletions, which suggest the location of recessive tumor genes in certain chromosome 22 subregions (22q11.3-q12 in neurinomas and meningiomas, and 22q13 in malignant gliomas). Cytogenetic studies were performed in parallel on the same tumors, in most instances corroborating the presence of abnormalities for chromosome 22. Nevertheless, discrepancies between the cytogenetic and molecular findings were observed in several cases, suggesting that the use of both methodologies in combination might provide key information on the incidence and extent of the abnormalities involving chromosome 22 in human brain tumors.

Analysis of p73 gene in meningiomas with deletion at 1p

The p73 gene has been mapped to 1p36.33, a chromosome region that is frequently deleted in a wide variety of neoplasms including meningiomas. The protein encoded by p73 shows structural and functional similarities to p53 and may thus represent a candidate tumor suppressor gene. To determine whether p73 is involved in the development of meningiomas, we examined 30 meningioma samples with proven 1p deletion for mutations of p73. Sequence analysis of the entire coding region of the p73 gene revealed previously reported polymorphisms in eight cases. A tumor-specific missense mutation as a result of an A-to-G transition with an Asn204Ser change was found in one meningioma that nevertheless retained the normal allele. These results suggest that if p73 plays a role in meningioma carcinogenesis, it must be in a manner different from the Knudson two-hit model.

Molecular analysis of genomic abnormalities in human gliomas.

A series of 57 malignant gliomas, including 27 astrocytomas grade III-IV (glioblastoma multiforme), 15 astrocytomas grade I-II, and 15 tumors with major oligodendroglial component, was examined to detect molecular abnormalities of loci at specific chromosome regions. At the cytogenetic level, these regions have been shown to be nonrandomly involved in neoplastic development of these histologic subtypes of tumor. We used a panel of 24 polymorphic DNA probes to analyze loss of heterozygosity (LOH) at loci on chromosomes 7, 9, 10, 13, 17p, and 22q. In addition, the retinoblastoma (RB1) oncosuppressor gene, the platelet-derived growth factor A (PDGFA) gene, and the epidermal growth factor receptor (EGFR) gene were analyzed directly. Loss of genetic information on the short arm of chromosome 17 was observed in both low- and high-grade astrocytomas, whereas no oligodendroglial tumor was characterized by this type of aberration. LOH for chromosome 10, mainly compatible with loss of the entire chromosome, was primarily evidenced in the more malignant forms and in isolated cases diagnosed as low-grade astrocytomas. Again, no oligodendroglial tumor displayed losses of chromosome 10. In contrast, four tumors with major oligodendroglial component showed losses involving 9p markers, primarily interferon A and B (IFNA, IFNB); this feature was also observed in two low-grade astrocytomas and in 11 high-grade tumors. Isolated cases displayed LOH for markers on chromosomes 13 and 22, whereas EGFR amplification was almost exclusively evidenced in the more malignant forms which, in most instances, also presented LOH for chromosome 10. In general, the samples with lower malignancy stage displayed a lesser grade of abnormalities, mainly restricted to losses at 17p and chromosome 10 in astrocytomas grade I-II and at 9p in oligodendrogliomas. In contrast, about 50% of the high-grade tumor samples analyzed included abnormalities at two or more loci, with a recurrent association of EGFR amplification and LOH for chromosome 10; this association was evident in 26% of the high-grade astrocytomas.

Search for mutations of the hRAD54 gene in sporadic meningiomas with deletion at 1p32.

The hRAD54 gene is related to a family of genes involved in DNA recombination and repair and encodes a protein with DNA helicase activity. hRAD54 has been mapped to 1p32, a region frequently involved in deletions in a variety of tumor types, including atypical and anaplastic meningiomas. To determine whether alterations of hRAD54 are a common event in meningeal tumors, by means of polymerase chain reaction–single‐stranded conformation analysis we examined 29 tumor samples characterized by 1p deletions for hRAD54 mutations. Although 18 tumors displayed allelic loss at the gene region (1p32) as determined by microsatellite marker analysis, the sole coding‐sequence alteration detected corresponded to a T → C transition, with no amino‐acid change. The genotype distribution was 10.34% TT, 44.8% TC, and 44.8% CC, whereas in the normal controls it was 3.77% TT, 13.2% TC, and 83.01% CC, and most meningiomas with 1p32 deletion retained allele C. Another polymorphism due to a T → C change was evidenced at nt 3008, in the 3′ untranslated region. This change was evidenced in all cases we sequenced. These results appear to exclude the involvement of the hRAD54 gene in the pathogenesis of the nontypical meningiomas, although a detrimental effect of the hRAD54 polymorphisms cannot be ruled out. Mol. Carcinog. 24:300–304, 1999.

Chromosomal abnormalities in pituitary adenomas.

Cytogenetic studies were conducted on 30 pituitary adenomas, using both direct and/or short-term in vitro culture methods. An apparently normal chromosome complement was found in 14 tumors; 5 adenomas were characterized by hyperdiploid or near-triploid modal chromosome numbers. Recurrent numerical deviations were identified in 12 samples, which primarily involved gains of chromosomes 4, 7, 8, 9, 12, and 20 by gains, and losses of chromosomes 10, 14, 19, and 22. Four adenomas were shown to have structural chromosome rearrangements with no apparent recurrent pattern of involvement.

Ascertainment of chromosome 7 gains in malignant gliomas by cytogenetic and RFLP analyses

The incidence of gains involving chromosome 7 was determined independently using cytogenetic and molecular genetic analyses in a series of 57 malignant gliomas. Coincidental results were observed in the group of tumors in which trisomy 7 was identified on the same cells that also displayed other clonal abnormalities (i.e., losses of chromosome 10, and structural rearrangements of 1p, 9p, etc., and the presence of dmin). On the other hand, molecular detection of gain of material from this chromosome was obtained in only one of nine cases in which trisomy 7 had been identified as a solitary anomaly at the cytogenetic level. Thus, although trisomy 7 has been identified as a clonal abnormality in about 60% of gliomas analyzed cytogenetically so far, our findings suggest that the anomaly may be representative of tumor parenchyma in half of them, while in the remaining cases (mainly those in which trisomy 7 is observed at the cytogenetic level as the sole chromosomal deviation) our data agree with those suggesting that the anomaly is the result of an in vitro non-disjunction, or represent in vivo mosaicism of the non-tumoral cells.

Chromosome 22 heterozygosity is retained in most hyperdiploid and pseudodiploid meningiomas.

Hyperdiploid or pseudodiploid modal chromosome numbers were found characterizing six human meningiomas, and all six tumors were disomic for chromosome 22. The scarce previous reports on the subject suggest that, in these cytogenetic subgroups of meningiomas, duplication of the retained chromosome 22 occurs after the loss of the other member of the pair, thus correlating well with the main characteristic of meningiomas, that is, losses of 22. To verify this question, molecular genetic analyses were performed on DNA pairs from blood and tumoral samples of all six cases, using polymorphic markers for chromosome 22. Restriction fragment length polymorphism studies failed to show any loss of heterozygosity for markers located on this chromosome in all six cases, suggesting that a different mechanism to that previously proposed might take place in the hyperdiploid or pseudodiploid meningiomas; perhaps a submicroscopic involvement (microdeletions or inactivating mutations) of the meningioma locus (both alleles) may result in an effect similar to that produced by monosomy 22 (which probably unmasks recessive mutations on the retained allele), enhancing the development of meningiomas.