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.     

Deletion Mapping of Chromosome 1p and 22q in Pheochromocytoma

To identify the localization of tumor suppressor genes, 22 pheochromocytomas (9 hereditary and 13 sporadic) were examined for loss of heterozygosity (LOH) on the short arm of chromosome 1 and on the long arm of chromosome 22 by using 11 polymorphic DNA markers on each chromosome arm. LOH on 1p was observed in 12 of 22 informative cases (55%) and on 22q in 8 of 20 informative cases (40%). There was no significant difference in the frequency of LOH on 1p or 22q between hereditary and sporadic cases. We could localize the commonly deleted regions as distal to D1S73 and proximal to D1S63 on 1p and distal to D22S24 and proximal to D22S1 on 22q. In addition, the relationship between LOH on 1p and 22q was studied in 20 pheochromocytomas which were informative for probes on both chromosome arms. Of eight tumors that showed LOH on 22q, allelic loss on 1p was also detected in seven. Thus, LOH on 22q was correlated significantly with LOH on 1p ( P = 0.0249; Fisher's exact test). These results suggest that inactivation of multiple tumor suppressor genes may be required for development and progression of hereditary and non-hereditary pheochromocytoma.     

Chromosomal deletions in anaplastic meningiomas suggest multiple regions outside chromosome 22 as important in tumor progression

Meningioma is a common, usually benign, sporadic and solitary tumor of the meninges covering the central nervous system. Meningiomas can become malignant, and such anaplastic tumors are associated with a high rate of recurrence and death from the disease. We analyzed 16 sporadic, anaplastic meningiomas for loss of alleles on the majority of chromosomal arms, in order to define regions in the genome which may be important for tumor progression. Loss of genetic material was observed on all but 2 chromosomes studied. While loss of heterozygozity (LOH) from chromosome 22 was the most frequent finding, LOH from the short arm of chromosome I was the second most common lesion occurring preferentially in tumors from men, and at a frequency almost as high as for LOH on chromosome 22. This suggests the existence of a tumor-suppressor locus on Ip involved in meningioma carcinogenesis. Three tumor samples from one large, anaplastic tumor, each with distinct histopathological characteristics, were studied. All 3 samples showed deletions on 22q and Ip. However, only one tumor sample, with the most malignant histopathological phenotype, displayed, in addition to 22q and Ip, deletions on 9q and 17p. This case suggests that the latter 2 chromosomal regions may harbor genes which contribute to the progression of meningioma.     

Loss of heterozygosity studies in extracranial metastatic meningiomas

Although most meningiomas are slow-growing tumours associated with favourable prognosis, they often present local recurrence after surgical treatment; by contrast, extracranial metastatic meningiomas are rare, occurring in less than 1% of the cases. Risk factors for distal spread remain largely unknown. We report three cases with lung or bone metastases from intracranial recurrent meningiomas. Loss of heterozygosity (LOH) analysis on 1p, 9p, 10q, 14q, and 22q was conducted in available primary, recurrent and metastatic lesions, showing the same LOH pattern in the distal metastases and in the intracranial meningioma. LOH at 1p, 14q and 9p, known to be associated with increased aggressiveness, were found. The results highlight the potential clinical relevance of integrating histopathological studies with molecular genetic analysis in the follow-up of patients with different types of meningiomas.     

Allelic loss on chromosomes 1p32, 9p21, 13q14, 16q22, 17p,and 22q12 in meningiomas associated with meningioangiomatosis and pure meningioangiomatosis

Meningioangiomatosis (MA) is a rare lesion appearing sporadically or as a part of neurofibromatosis 2. The occurrences of meningiomas arising from MA (MA-M) have raised doubts about the traditional concept of a hamartomatous origin for MA. Cytogenetic or molecular studies on MA, with or without meningiomas, are limited because of the rarity of MA. The current study was to evaluate the loss of heterozygosity (LOH) in seven cases of MA-M and two cases of pure MA. LOH on six chromosomes (1p32, 9p21, 13q14, 16q22, 17p, and 22q12) were investigated using 13 sets of microsatellite markers, including D1S193, D1S463, D22S193, D22S929, D22S282, TP53, D17S796, D16S421, D16S512, D13S118, D13S153, D9S162, and D9S104. PCR was performed using each marker and polymorphic analysis was accomplished by silver staining. Immunohistochemical stain for Ki-67 was carried out and labeling index was measured by using a semiquantitative manual counting method. The meningioma portions of MA-Ms showed LOH for loci on chromosomes 22q12, 9p21, and 1p32 in 57.1% (4/7), 28.6% (2/7), and 28.6% (2/7) of cases, respectively. The MA portions of MA-M had a LOH for loci on 22q12 in 28.6% (2/7) of cases, whereas each pure MA harbored one LOH on either chromosome 22q12 or 9p21. The proliferation indices of MA-Ms were significantly higher in the meningioma than in the MA components. Our data suggest that both the meningioma and the MA undergo the same overlapping clonal process, with the MA-M while undergoing additional genetic alterations that confer a greater proliferative potential.     

Deletion mapping of the long arm of chromosome 22 in human meningiomas

Cytogenetic and molecular genetic analyses have shown that a tumor-suppressor gene for human meningioma is located on the long arm of chromosome 22. Recently, somatic mutations of the NF2 gene have been identified in sporadic meningiomas. However, tumorigenesis of certain cases of meningioma cannot be fully explained by inactivation of the NF2 gene alone. Thus, to obtain some indication as to the existence of another tumorsuppressor gene, it seemed important to re-examine the loss of heterozygosity (LOH) on 22q in sporadic meningioma. A total of 46 sporadic meningiomas was examined for LOH at 20 loci on 22q. LOH was observed in 29 tumors (63%), of which 13 (28%) showed different patterns of a partial loss of 22q. However, the NF2 locus was retained in one tumor that lost a more distal part of 22q. Moreover, 27 of the 28 tumors which showed LOH at the NF2 locus also lost alleles at more telomeric loci. These results raise the possibility that another tumor-suppressor gene for meningioma may exist on 22q and that its localization may be distal to the D22S102 locus. © 1995 Wiley-Liss, Inc.     

Frequent Loss of 1p32 Region but no Mutation if the p18 Tumor Suppressor Gene in Meningiomas

After chromosome 22 and NF2 inactivation, the loss of chromosome 1p is one of the most frequent abnormalities encountered in meningiomas. However the putative tumor suppressor gene located on 1p inactivated in meningiomas has still to be identified. We screened 68 meningiomas for LOH on chromosome 22 and 1. We found 34 LOH on the NF2 region on chromosome 22 (50%) and 19 LOH on 1p (28%), 16 being associated with loss of chromosome 22. Partial deletions delimited a candidate region located between D1S234 and D1S2797. The p18 ^INK4C tumor suppressor gene, a member of the genes family coding for inhibitors of cyclin-dependent kinases, is located in this region. To determine whether p18 is involved in development of meningiomas, we performed a mutation analysis of the p18 gene and a search for homozygous deletion in the 19 meningiomas with 1p loss. Sequencing analysis of the p18 gene revealed one polymorphism, but no somatic mutations and no homozygous deletions were found. These results confirm that the loss of chromosome 1p32 is a frequent feature in meningiomas, however the p18 tumor suppressor gene which is located in this region, does not seem to be involved.     

Multiple meningiomas: Investigating the molecular basis of sporadic and familial forms

Meningiomas are common tumors of the coverings of the central nervous system (CNS), comprising 20% of intracranial neoplasms. The only genes known to be associated with sporadic meningiomas are NF2 on chromosome 22 and the related cytoskeleton element DAL-1 on chromosome 18. Between 1 and 8% of patients with meningiomas develop multiple meningiomas, a trait transmitted occasionally in an autosomal dominant fashion. We investigated the DAL-1 and NF2 loci in 7 unrelated multiple meningioma patients without clinical evidence of NF2 by mutational and pathological analysis. Five novel intragenic microsatellite polymorphisms were developed for specific detection of loss of heterozygosity (LOH) at the DAL-1 locus. Three of 7 patients had affected relatives and all affected individuals were female. No tumors from familial patients were of a fibroblastic subtype. Truncating NF2 mutations were detected in 3 tumor specimens, but were not present in the corresponding blood samples. Two tumors showed LOH at the NF2 locus. All tumors showing mutations at the NF2 locus originated from patients without affected relatives and were of the fibroblastic subtype. Five non-truncating alterations in the DAL-1 gene were found, however, LOH of chromosome 18 markers was not seen in any tumor. In contrast to the NF2 results, all DAL-1 alterations were found in paired blood specimens. Our findings provide further evidence that the molecular basis of sporadic and familial multiple meningiomas is fundamentally different and extend this dichotomy to pathologic subtypes. DAL-1 does not function as a true tumor suppressor in these patients.     

Heterogeneity of allelic deletions within melanoma metastases

During the initiation and progression of malignant melanoma, a series of different genetic events accumulate on several different chromosomes. The biological heterogeneity of tumour cells presents a major problem, preventing effective treatment of melanoma. To examine the degree of genetic heterogeneity, we searched for allelic losses (loss of heterozygosity; LOH) on chromosomes 9p, 9q, 1p and 17p, examining different areas within human melanoma metastases. All of the examined metastases were informative within at least one dissected area for at least one marker. Out of 29 areas in 11 melanoma metastases, 58% showed LOH with at least one marker. On chromosome 9p21-22, eight out of 26 informative loci (31%) showed LOH at D9S171 (three not informative), two out of 18 (11%) at IFNA (11 not informative) and seven out of 24 (29%) at D9S169 (five not informative). LOH on chromosome 9q22.3 was examined by the microsatellite marker D9S12; three out of 24 areas (12.5%) showed LOH, and five were not informative. Deletions on chromosome 1p were assessed using D1S450. Four out of 25 (16%) showed LOH; four were not informative. Deletions on chromosome 17p13 were examined with TP53; two out of 21 cases (9%) showed LOH, and eight were not informative. Our data demonstrate an impressive heterogeneity of allelic losses in the investigated chromosomal areas within the same metastatic lesion. This suggests that there is not one specific genetic alteration that accounts for melanoma progression to metastases. Rather there seem to be multiple genetic alterations accumulating even on the same chromosome, and progression from melanoma to metastases is paralleled by the accumulation of clones harbouring multiple genetic abnormalities.     

Loss of 22q Chromosome is Related to Glioma Progression and Loss of 10q

Summary Loss of heterozygosity (LOH) of chromosome 22q has been investigated in 160 gliomas. LOH at one or more microsatellite increased with increasing grade of the tumor (P < 0.01). LOH22q was more frequent in astrocytic tumors (37%) compared to mixed or oligodendroglial tumors (21%) (P = 0.02). LOH22q was correlated to 10q loss but not to 1p or 9p loss. Taken together, these data suggest that LOH22q is an alteration associated with malignant progression of gliomas.     

Narrowing of the regions of allelic losses of chromosome 1p36 in meningioma tissues by an improved SSCP analysis

Mapping loss of heterozygosity (LOH) regions in the genomes of tumor tissues is a practical approach for identifying genes whose loss is related to tumorigenesis. Conventional LOH analyses using microsatellite or single nucleotide polymorphism (SNP) markers require the simultaneous examination of tumor- and matched normal-DNA. Here, we improved the previously developed SNP-based LOH assay using single strand conformation polymorphism (SSCP) analysis, so that LOH in tumor samples heavily contaminated with normal DNA can now be precisely estimated, even when matched normal DNA is not available. We demonstrate the reliability of the improved SSCP-based LOH detection method, called the LOH estimation by quantitative SSCP analysis using averaged control (LOQUS-AC), by comparing the results with those of the previous "LOH estimated by quantitative SSCP assay" (LOQUS) method. Using the LOQUS-AC assay, LOH was detected at a high consistency (98.1%) with the previous LOQUS method. We then applied this new method to characterize LOH profiles in 130 meningiomas, using 68 SNPs (i.e., a mean inter-SNP interval of 441 kbp) that are evenly distributed throughout chromosome 1p36. Benign, atypical and anaplastic meningiomas exhibited 1p36 LOH at frequencies of 48.39, 84.62 and 100.00%, respectively, using LOQUS-AC. Subsequently, we detected a candidate common LOH region on 1p36.11 that might harbor tumor suppressor genes related to malignant progression of meningioma.     

Allelic loss on chromosome 17 in human ovarian cancer

In order to identify a common region of deletion on chromosome 17 potentially containing a tumor-suppressor gene, 27 ovarian carcinomas and 3 ovarian tumors of low malignant potential (LMP) were examined for loss of heterozygosity (LOH) at 6 p arm and 10 q arm loci. Ninety percent of all tumors had deletions at one or more loci. On the p arm, there was a single near-common region of deletion on 17p 13.3 (D/7S30/ pYNZ22.1; 86% LOH), an intervening locus with a low LOH rate, and a more proximal locus on 17p11.2 (D/7S58/pEW301; 82% LOH) with a high LOH rate. In less aggressive tumors, LOH at Df 7S30 was not accompanied by LOH at p53. The q arm had a common region of deletion for high-stage carcinoma at D/7S579 (Mfd 188; 74% LOH) on q21, a locus tightly linked to the familial breast-ovarian-cancer syndrome (BRCAI) locus. D/7S579 was lost in all informative high-stage carcinomas and retained in all low-stage carcinomas and tumors of LMP. There may be at least 2 tumor-suppressor genes, an early-acting gene on the p arm and a gene on the q arm involved in tumor progression and metastasis.     

Comprehensive allelotyping of human intrahepatic cholangiocarcinoma.

We performed a genome-wide scan for loss of heterozygosity (LOH) in 22 intrahepatic cholangiocarcinoma (ICC) cases using 168 polymorphic microsatellite markers throughout all of the human chromosomes and 48 markers of which LOH is reportedly characteristic of hepatocellular carcinoma (HCC). Markers with LOH in more than 30% of informative cases were observed at 21 loci. Among these, eight markers on 6q (three loci), 4q (two loci), 9q, 16q, and 17p shared high frequencies of LOH with HCC in our previous study. As for gross appearance, mass-forming type tumors showed higher frequency of LOH (P < 0.001) compared with other types. Compared by tumor size (< or =5 cm versus >5 cm), number (multiple versus solitary), and the International Union Against Cancer TNM classification (stage IVB versus II-IVA), LOH was observed more frequently in advanced stages (P < 0.01, respectively). However, LOH frequency does not differ regardless of lymph node status (pN0 versus pN1). Frequent LOH on 1p36 including the p73 locus was noted in large tumors without lymph node metastasis. These suggest that ICC shares some common carcinogenic steps with HCC such as LOH of 4q and 6q and that inactivation of tumor suppressor genes on chromosome 1p36 contributes to progression of ICC but not to metastatic traits.     

Frequent loss of heterozygosity at the DCC locus in gastric cancer.

We examined 28 cases of surgically resected gastric cancer, excluding the diffuse type, for loss of heterozygosity (LOH) on 12 chromosomal arms using polymorphic DNA markers. LOH on chromosome 18q was detected in 61% (14 of 23) of the cases by the probes OLVIIA8, OLVIIE10, p15-65, SAM 1.1, and OS-4, and a putative common region showing LOH included the locus of the DCC tumor suppressor gene. LOH on chromosome 17p was also frequently found (8 of 19 or 42% of the cases) by the probes p10-3 and pHF12-1, and in 5 of these 6 cases the LOH on chromosome 17p was accompanied by LOH on chromosome 18q. On the other hand, the incidence of LOH was 30% or less using probes pHRnES, pHF12-65, p-c-mybE2.6, NJ3 3.2, pHF12-8, pHINS6.0, p9D11, hp2-alpha, pCMM6, and P1A5 on chromosomes 1q, 5, 6q, 7q, 9, 11p, 13q, 16q, 20, and 22q, respectively. LOH on chromosome 18q was frequent irrespective of the depth of tumor invasion, whereas the incidence of LOH on chromosome 17p was higher in the cases in which the tumor invaded beyond the muscularis propria than in those in which tumor invasion was limited to the submucosa and muscularis propria. These results suggest that LOH on chromosome 18q occurs at an earlier stage than LOH on chromosome 17p and that the inactivation of tumor suppressor genes located on chromosome 17p and 18q (e.g., the p53 and DCC genes) is critically involved in the development of the majority of gastric cancers. While alteration of the p53 gene is observed in various human cancers, that of the DCC gene is considered to occur more selectively in gastrointestinal cancers.     

Loss of heterozygosity for loci on the long arm of chromosome 6 in human malignant melanoma.

Malignant melanoma has been documented to display recurring abnormalities of chromosome 6, particularly the long arm (6q). Restriction fragment length polymorphism analysis was used as a molecular genetic approach to examine loci on chromosome 6q for loss of constitutional heterozygosity (LOH). Five DNA markers that recognize restriction fragment length polymorphisms along 6q and one polymorphic DNA marker for 6p were used to screen 20 autologous pairs of tumor DNA and normal DNA to determine the tumor and constitutional genotypes of each patient. LOH on chromosome 6q was identified at 21 of 53 informative loci (40%). Five patients with more than one informative locus had allele losses consistent with the loss of the entire long arm (or of an entire copy) of chromosome 6, while four other patients demonstrated terminal deletions of 6q. The chromosomal region bearing the highest frequency of 6q allelic loss (60%) is defined by the marker loci c-MYB and ESR (6q22-23 and 6q24-27). In contrast to the frequency of 6q loss, LOH was observed at loci on four other chromosomes (1, 11, 16, 17) in only 5% of cases. These results have led us to conclude that the loss of sequences from the long arm of chromosome 6 is a nonrandom and possibly biologically relevant event in human malignant melanoma.     

Allelotype of human breast carcinoma: a second major site for loss of heterozygosity is on chromosome 6q.

Loss of heterozygosity (LOH), which is detected with polymorphic DNA markers by comparing constitutional and tumor genotypes, has been observed at a number of different chromosome arms in primary breast tumors. These include 1p, 1q, 3p, 11p, 13q, 17p and 18q. We present here the results of a screening of all non-acrocentric chromosome arms, including those of the X chromosome, with at least one polymorphic marker per arm, in a total of 86 breast carcinomas. This dataset, termed an allelotype, indicates that in addition to the chromosome regions listed above, allelic loss may be observed in more than 30% of informative cases on 6q, 8q, 9q, 15q, and 16q. Multiple LOH involving at least two different chromosomes in a single tumor was observed in approximately 75% of the investigated tumors, and revealed complex chromosome involvement. Six different combinations of concurrent LOH at two different chromosome arms were found to be significantly correlated (r greater than 0.45; P less than 0.01). Tumors showing LOH at 3p or 17p were preferentially aneuploid, while LOH at 6q and 17q was inversely correlated with the number of positive lymph nodes and age respectively.     

Allelotype analysis of hepatocellular carcinoma

To elucidate the genetic events which may play important roles in hepatocarcinogenesis, we examined every non-acrocentric chromosome arm of 22 hepatocellular carcinomas (HCCs) for loss of heterozygosity (LOH) using 68 highly polymorphic microsatellite markers. Thirty-six (92%) of 39 chromosome arms showed LOH in at least one patient, however 3 chromosome arms, 2p, 2q, and 20q, did not show any LOH. High to moderate frequency of LOH (>30% of informative cases) was observed at chromosomes 1q (68.1%), 4q (72.7%), 8p (63.6%), 8q (77.3%), 10q (33.3%), 13q (40%), 14q (46.1%), 16q (59.1%), and 17p (46.2%). Among these, LOH on chromosomes 1q and 8q have not been previously identified in HCC. Our results suggest that novel tumor suppressor genes may be involved in the development and progression of HCC. Int. J. Cancer 75:29–33, 1998.© 1998 Wiley-Liss, Inc.     

Molecular evidence for independent origin of multifocal neuroendocrine tumors of the enteropancreatic axis

Neuroendocrine tumors of the enteropancreatic axis are often multifocal. We have investigated whether multifocal intestinal carcinoid tumors and multifocal pancreatic endocrine tumors arise independently or whether they originate from a single clone with subsequent intramural or intrapancreatic spread. Twenty-four cases, including 16 multifocal intestinal carcinoid tumors and eight multifocal pancreatic endocrine tumors, were studied. Genomic DNA samples were prepared from 72 distinct tumor nodules using laser capture microdissection. Loss of heterozygosity (LOH) assays were done using markers for putative tumor suppressor genes located on chromosomes 9p21 (p16), 11q13 (MEN1), 11q23 (SDHD), 16q21, 18q21, and 18q22-23. In addition, X chromosome inactivation analysis was done on the tumors from eight female patients. Twenty-two of 24 (92%) cases showed allelic loss in at least one tumor focus, including 15 of 16 (94%) cases of multifocal carcinoid tumors and 7 of 8 (88%) cases of multifocal pancreatic endocrine tumors. Eleven of 24 (46%) cases exhibited a different LOH pattern for each tumor. Additionally, 9 of 24 (38%) cases showed different LOH patterns among some of the coexisting tumors, whereas other coexisting tumors displayed the same allelic loss pattern. Two of 24 (8%) cases showed the same LOH pattern in every individual tumor. X chromosome inactivation analysis showed a discordant pattern of nonrandom X chromosome inactivation in two of six informative cases and concordant pattern of nonrandom X chromosome inactivation in the four remaining informative cases. Our data suggest that some multifocal neuroendocrine tumors of the enteropancreatic axis arise independently, whereas others originate as a single clone with subsequent local and discontinuous metastasis.     

Early loss of heterozygosity on 17q in ovarian cancer. The Abe Ovarian Cancer Genetics Group.

We have studied 146 ovarian tumours (94 carcinomas, 22 tumours of low malignant potential and 30 benign tumours) for evidence of allele loss on chromosome 17p and 17q sufficient to imply the proximity of a tumour-suppressor gene. We have examined two polymorphic loci (YNZ22.2 and BHP53) on 17p13 and one on chromosome 17q (17q23-qter). Loss of heterozygosity (LOH) was detected in 34/63 (54%) informative malignant tumours at YNZ22.2 and 22/47 (47%) at BHP53; on 17q, 45/64 (70%) had LOH. Allele loss was detected in a small number of benign and borderline tumours. There was a statistically significant difference between the patterns of allele loss in serous and endometrioid groups of tumours, and allele loss occurred with significantly greater frequency on 17q than on 17p. Comparison of all malignant tumours presenting with either localized (FIGO stage I/II) or widespread (FIGO stage III/IV) disease showed that, particularly on 17q, allele loss increases in the more advanced stages. The p53 tumour-suppressor gene is implicated in ovarian carcinogenesis, and our findings suggest that an important tumour-suppressor gene may be located in the region 17q23-qter. Loss of function in this gene may be responsible for the frequently observed rapid progression of serous-type adenocarcinomas to an advanced stage.     

胶质母细胞瘤3号染色体杂合性丢失的研究

目的　寻找胶质母细胞瘤 (GBM) 3号染色体上可能存在肿瘤抑制基因的杂合性丢失 (LOH)区域 ,为发现和定位肿瘤抑制基因 (TSG)提供线索和依据。方法　采用荧光标记的引物和 377型DNA序列自动分析仪 ,分析了 2 0例GBM 3号染色体上 2 3个微卫星多态性标记的LOH。结果　在 50 % (1 0 / 2 0例 )GBM的 3号染色体上观察到LOH ,在 2 5 .6 % (88/ 344)可提供信息位点存在LOH。其中 3q的LOH率明显高于 3p ,3q和 3p的LOH率分别为 50 % (1 0 / 2 0 )、35 % (7/ 2 0 )。在 3q上的下列位点检测到较高的LOH率 :3q2 2 2 3上的微卫星位点D3s1 569(35 .3 % )、3q2 4 2 7上的D3s1 61 4 (42 .9% ) D3s1 565(35 .3 % ) ;在3p1 4 .1 1 4 .3上D3s1 2 89的LOH率也较高 (33 .3 % )。 结论　 3号染色体可能在GBM的分子发病机制中发挥着重要作用 ,3p1 4 .1 1 4 .3上的D3s1 2 89和 3q2 2 2 3上的D3s1 569位点、3q2 4 2 7上的D3s1 61 4 D3s1 565位点间区域可能存在与GBM相关的肿瘤抑制基因