髓母细胞瘤10号染色体的杂合性丢失分析

目的探讨髓母细胞瘤的遗传学异常及其发病机制。方法通过微卫星分析（microsatellite analysis）方法,应用7个分别位于10号染色体长臂上PTEN（10q23）和DMBT1（10q25）基因位点的特异性标记物,分析18例髓母细胞瘤的杂合性丢失（loss of heterozygosity,LOH）。结果18例髓母细胞瘤中,位于10q23上的LOH比率为24％（9／37可分析标记）;位于10q25上的LOH比率为47％（9／19可分析标记）。结论在髓母细胞瘤中,染色体10q25上高比率的杂合性丢失提示,位于该位点上DMBT1基因的遗传学改变可能在髓母细胞瘤的发病机制中起着重要的作用。     

Loss of heterozygosity on chromosome 10p14-p15 in colorectal carcinoma.

High frequencies of loss of heterozygosity (LOH) on chromosome 10p14-p15 have been reported in various tumors, including gliomas, pulmonary carcinoid tumors and cervical, hepatic, prostatic and esophageal carcinomas. However, LOH on chromosome 10p14-p15 in colorectal tumors has not been reported. Therefore, we examined LOH on chromosome 10p14-p15 in 60 colorectal carcinomas (21 superficial and 39 advanced types) by microsatellite assay. Three microsatellite loci, D10S191 (10p14), D10S558 and D10S249 (10p15) were examined by polymerase chain reaction [early colorectal carcinomas, LOH of markers D10S191 (36%), D10S558 (7%) and D10S249 (11%), and in advanced colorectal carcinomas, LOH of markers D10S191 (20%), D10S558 (13%) and D10S249 (33%)]. There were no significant associations between LOH on chromosome 10p14-p15 and clinicopathologic features, including patient age, sex, tumor location, depth of invasion, histologic type, lymph node metastasis and prognosis. These data suggest that a putative tumor suppressor gene associated with colorectal carcinogenesis may be located on chromosome 10p14-p15 and that alteration of this gene may be involved in the development but not progression of colorectal tumors.     

髓母细胞瘤8号染色体短臂的杂合性丢失

目的研究髓母细胞瘤8号染色体的遗传学异常,寻找与该肿瘤发病机制有关的杂合性丢失位点。方法通过微卫星分析（microsatellite analysis）方法,应用19个位于8号染色体短臂（8p）上的多态性标记物,检测髓母细胞瘤的杂合性丢失（loss of heterozygosity,LOH）。结果在所检测的23例髓母细胞瘤中,21例为原发肿瘤,2例为复发肿瘤。染色体8p总的LOH比率为51%（124个LOH/243个可分析位点）。我们在8p22-23.2之间发现了一个高比率的共同丢失区,其长度为18.14 cM。结论染色体8p22-23.1上很可能存在重要的抑癌基因,该基因的丢失可能与髓母细胞瘤发病有关。     

人宫颈癌组织染色体部分位点杂合性丢失

了解人宫颈癌组织中3，6，11和18号染色体部分位点杂合性丢失的分布状况，为宫颈部相关基因的定位以及临床诊断分子标志的筛选提供依据。采用宫颈癌基因组中3，6，11和18号染色体上的8个微卫星标志，对源自宫颈癌等高发区的宫颈癌活检标本，以PCR－变性电泳－银染的方法检测上述位点的杂合性丢失。其中在染色体3p14,18q21等位点存在较高频率的杂合性丢失。结果表明杂合性丢失是宫颈癌癌变过程中常见的遗传性改变，宫颈癌中存在杂合性丢失的高频区，提示相应位点存在潜在的抑癌基因。     

甲状腺肿瘤3号染色体短臂杂合性缺失的研究

目的 探讨甲状腺肿瘤中3号染色体短臂(3p)杂合性缺失(LOH)状态及其临床意义.方法 收集74例甲状腺肿瘤标本,包括20例甲状腺腺瘤(FA)、24例滤泡性甲状腺癌(FTC)和30例乳头状甲状腺癌(Prc).通过PCR扩增和银染分析其3p上11个微卫星位点的杂合性缺失状态.结果 FFC的LOH频率达到71%(17/24),PTC中30%(9/30),FA中10%(2/20).FFC的3p LOH频率显著高于FA和PTC(P<0.01).FTC中存在两个最小共同缺失区,分别位于3p26-pter和3p14.2-3p22.PTC上存在一个最小共同缺失区,位于3p 25.2-26.1.结论 FTC的3p LOH频率显著高于FA和PTC.3p的3个最小缺失区上可能存在着与FTC和PTC发生发展相关的肿瘤抑制基因.     

Predominant expression of mutant EGFR (EGFRvIII) is rare in primary glioblastomas

EGFR amplification is a frequent genetic alteration in primary (de novo) glioblastomas, and is often associated with structural alterations. Most common is variant III (EGFRvIII), which results from a non-random 801 bp in-frame deletion of exons 2 to 7 of the EGFR gene. We assessed amplification and overexpression of EGFRvIII and wild-type EGFR in 30 glioblastoma biopsies. Immunohistochemically, EGFR overexpression was observed in 20 (67%) of 30 glioblastomas. Eight (27%) cases also showed immunoreactivity to an EGFRvIII antibody. In 6 of these cases, the pattern of EGFR and EGFRvIII overexpression was compared in serial sections: In 4 cases, areas with immunoreactivity to EGFRvIII largely coincided with wild-type EGFR expression. In the other 2 cases, the areas immunoreactive to EGFRvIII were significantly less extensive than EGFR-positive areas. To assess whether EGFRvIII is predominantly amplified in tumors with concurrent wild-type EGFR amplification, we carried our real-time quantitative PCR using 2 sets of primers located in exon 2 and intron 15 of the EGFR gene. A > 5-fold ratio of relative copy numbers between intron 15 (present both in wild-type EGFR and EGFRvIII) and exon 2 (present only in wild-type EGFR, but missing in EGFRvIII) suggested predominant amplification of EGFRvIII in only 3 (10%) of 30 glioblastomas. The observation that intratumoral wild-type EGFR overexpression is often more extensive and that predominant amplification of EGFRvIII is a rare event would limit the effectiveness of therapeutic approaches based on selective targeting of EGFRvIII.     

Loss of heterozygosity on chromosome arm 3p in nasopharyngeal carcinoma

We have examined 17 primary undifferentiated nasopharyngeal carcinoma biopsies for allelic loss on 3p, comparing the findings in tumors with those in normal lymphocyte DNA from the same patients. Ten polymorphic microsatellite markers were used between 3p13 and 3p26. Allelic loss was observed in 12 samples (70%). Two loci were most frequently affected: D3S1067 (3p21.1-14.3) in 60% and D3S1217 (3p14.2-14.1) in 58%. One tumor seemed to have a homozygous deletion at 3p26, detected by the D3S1297 marker. Analysis of the clinical data showed that an increased number of aberrations in 3p was correlated with more advanced tumor stages. Genes Chromosom Cancer 17:118–126 (1996). © 1996 Wiley-Liss, Inc.     

Loss of heterozygosity on the X chromosome in human breast cancer

The analysis of loss of heterozygosity (LOH) in tumours can be a powerful tool for mapping the sites of tumour suppressor genes in the human genome. A panel of breast cancer patients was assembled as pairs of tumour and lymphocyte DNA samples and LOH studies carried out by Southern hybridisation with polymorphic loci mapping to the X chromosome with appropriate controls. Deletion mapping revealed a high frequency of small regionalised deletions, defining at least three independent regions, one of which is particularly well mapped to a 500 kb stretch of DNA in the distal portion of the pseudoautosomal region of Xp. A second region has been identified within the pseudoautosomal region close to the pseudoautosomal boundary, and there is a third discrete site of loss on distal Xq. Perturbations of sequences at these regions represent independent events in a number of patients. This study represents the first detailed analysis of LOH on the X chromosome in human breast tumours, the results of which indicate that at least three regions of this chromosome are involved in the disease. © 1995 Wiley-Liss, Inc.     

Loss of heterozygosity on chromosome 11 q in breast cancer.

AIMS--Chromosome 11q23 seems to be a site of frequent mutation in cancer. It also contains loci such as ataxia telangiectasia with possible importance in the pathogenesis of breast tumours. The short arm of chromosome 11 has been studied extensively in breast cancer, but the long arm, in particular the distal part, has been studied less frequently. Cytogenetic analysis has shown possible involvement of chromosome 11q in breast tumours. Chromosome transfer experiments have also implicated chromosome 11q in breast cancer. A high frequency of mutations might therefore be expected to occur on chromosome 11q in breast cancers. METHODS--Using restriction fragment analysis, the primary tumours of 41 patients with breast cancer were screened for mutations at five loci on chromosome 11q (D11Z1, INT2, (FGF3), DRD2, NCAM, and D11S29). RESULTS--Allelic loss occurred at a high frequency (59%) at D11S29. At NCAM, novel alleles were frequently seen on autoradiographs. Relatively low frequencies of mutation were detected at the other loci. Allelic loss at D11S29 was associated with the presence of lymph node metastases, but this may be a chance association. CONCLUSIONS--The frequency of allelic loss at the DS11S29 locus is high. The significance of novel alleles at NCAM and their relation to allelic loss at D11S29 are unclear. The results presented here do not permit fine mapping of a region of allelic loss, but suggest that the region of greatest loss lies distal to DRD2. The results provide further evidence for the importance of gene(s) near 11q23 in the pathogenesis of breast cancer, and of tumours in general.     

Loss of heterozygosity on chromosome arm 11q in lung carcinoids

Neuroendocrine lung tumors such as typical carcinoid, atypical carcinoid, small-cell lung carcinoma, and large-cell neuroendocrine carcinoma represent a variable group with different biologic characteristics and unclear genetical relationships. We investigated the pattern of allelic loss on chromosome arm 11q in 20 sporadic carcinoid tumors of the lung using 10 microsatellite markers. Loss of heterozygosity was found in 13 of 20 tumors. In 5 of 9 typical carcinoids, 3 distinct regions of allelic loss were identified: 11q13.1 (D11S1883), 11q14.3-11q21 (D11S906), and 11q25 (D11S910). Atypical carcinoids showed loss of heterozygosity at 4 different regions: the first, most proximal region at 11q13 between markers PYGM and D11S937; the second at 11q14.3-11q21 (D11S906); and the third and fourth defined by markers D11S939 (11q23.2-23.3) and D11S910 (11q25). However, the region 11q13 harboring the MEN1 gene was more frequently affected in atypical carcinoids (7 of 11) than in typical carcinoids (2 of 9). The high rate of allelic losses within chromosomal region 11q13 in atypical carcinoids emphasizes the importance of this region for tumor development. We also recognized that more aggressive atypical carcinoids defined by high mitotic counts, vascular invasion, and/or organ metastasis are combined with increased allelic losses. HUM PATHOL 32:333-338.     

Loss of heterozygosity in sporadic primary cutaneous melanoma

Difficulties in obtaining clinical samples from primary melanomas have meant that most genetic analyses of melanoma have concentrated on cell lines and metastases. Because the Breslow thickness of the primary tumour is the single best prognostic indicator, it is important to identify genetic abnormalities in primary melanomas and relate these changes to the thickness of the lesion. We have investigated 47 sporadic melanomas, of which 41 were primary lesions, for loss of heterozygosity (LOH) on several chromosomal arms, including areas where genes involved in familial melanoma and other relevant hereditary syndromes map, and where LOH has previously been reported in cell lines or metastatic lesions. LOH was identified at 66 (18%) of 358 informative loci in primary melanomas, and there was a significant relationship between the overall frequency of LOH and Breslow thickness (P < 0.0005). Loss of chromosome arm 9p was most frequent, occurring in 15 (47%) of 32 informative primary tumours, and was observed in 3 of 11 informative lesions ≦ 1.5 mm in depth. LOH on chromosome arms 3p, 6q, 10q, 11q, and 17p was also relatively frequent, with loss of 3p and 10q heterozygosity in lesions ≦ 1.5 mm in depth, while LOH on 6q, 11q, and 17p was only detected in more invasive tumours. The results suggest that loss of these chromosome regions are important in sporadic cutaneous melanoma, and are consistent with chromosome arm 9p loss occurring before loss of other chromosome arms.     

Two tumor suppressive loci on chromosome 10 involved in human glioblastomas

A number of cytogenetic and molecular analyses have revealed very frequent and extensive losses of regions of chromosome 10 in human glioblastomas. Our recent studies have demonstrated that the transfer of a chromosome 10 into human glioblastoma cells resulted in suppression of their transformed and tumorigenic phenotype. To localize the suppressive region further, we isolated and characterized certain hybrid cells that had undergone chromosomal rearrangements to yield hybrid cells retaining only various regions of the inserted chromosome 10. One series of subclones showed the loss of the majority of the long arm of chromosome 10 (10q21-10qter) and regained the ability to grow under anchorage-independent conditions, but the cells still failed to exhibit significant tumorigenicity in nude mice. Another set of subclones exhibited major deletions of large segments of the long arm of chromosome 10 (10q21-q23; 10q26-qter), yet retained certain distal alleles associated with 10q24 to 10q26. These subclones were identical in their biological characteristics to the hybrids containing an intact chromosome 10, exhibiting no growth in soft agarose or in nude mice. These results implicate the presence of two independent phenotypically suppressive regions on chromosome 10 (10pter-q11 and 10q24-q26) that are involved in glioma progression.     

Loss of heterozygosity of chromosome 13 in Merkel cell carcinoma

We have examined a series of 24 Merkel cell carcinoma (MCC) DNAs for loss of heterozygosity (LOH) at eight loci on chromosome 13. All patients were heterozygous for at least one locus. Overall, 18 of 24 (75%) patients showed LOH, among whom 10 patients demonstrated LOH at all informative loci. A single common region of loss was identified in all cases and included the marker D13S233 (13q14.3), which maps close to the retinoblastoma susceptibility gene RB1. The RB1 protein was not detected by Western blot analysis in any of nine MCC cell lines tested. These data indicate that 13q losses are the most common chromosomal losses observed to date in MCC and the likely target of these deletions is the RB1 locus. Genes Chromosom. Cancer 20:93–97, 1997. © 1997 Wiley-Liss, Inc.     

Molecular cytogenetic analysis of a de novo interstitial chromosome 10q22 deletion

Interstitial deletions of 10q are rare, and only one patient with a deletion confined to chromosome band 10q22 has been reported so far. We report on a 2 6/12-year-old girl with a constitutional interstitial deletion of one homologue of 10q [karyotype: 46,XX,del(10)(q22.2q22.3)de novo]. Our patient had muscular hypotonia, developmental delay, growth retardation, mild facial dysmorphism, and hypoplastic labia minora. The precise location and extent (3.6 Mb) of the deletion was determined by fluorescence in situ hybridization (FISH) using 16 YAC and BAC clones. The clinical features in our patient are remarkably similar to the previously reported patient with a 10q22.2 deletion.     

Loss of heterozygosity on chromosome arm 16q in breast cancer metastases

One of the main genetic abnormalities associated with breast carcinogenesis is the loss of genetic material from chromosome arm 16q. Different groups have identified two regions (16q22.1 and 16q24-ter) that are frequently deleted in primary tumors, suggesting the presence of tumor suppressor genes in these regions. Little is known about the late stages of tumor progression in this respect, and we, therefore, analyzed biopsy specimens of breast cancer metastases for deletions in these critical regions of 16q. We examined fine needle cytopunctures from 24 metastases, each with lymphocyte DNA, for allelic imbalance on 16q by means of polymerase chain reaction (PCR) with 15 highly polymorphic markers. All the metastatic samples showed deletion of at least one informative locus on 16q. The loss of heterozygosity (LOH) pattern often indicated the loss of a complete long arm of chromosome 16 (13 cases); nevertheless, in the remaining 11 samples, partial LOH patterns were observed. A small region of overlap (SRO2) in 16q22.1 was frequently involved, whereas another (SRO1) in 16q24-ter was affected in only two cases. A third region of LOH in 16q22.2-q23.2 was found in 6/11 samples. These results suggest that at least three different regions are involved in allelic imbalance on chromosome arm 16q in breast cancer. Loss of material from the third region could be a major event in the genesis of metastases. Genes Chromosom. Cancer 19:185–191, 1997. © 1997 Wiley-Liss Inc.     

Parental origin of de novo chromosome 9 deletions in del(9p) syndrome

Parental origin of de novo deletions in the short arm of chromosome 9 in patients with a clinical diagnosis of del(9p) syndrome was assessed in 13 patients using polymerase chain reaction (PCR) analysis of highly polymorphic dinucleotide repeat micro-satellite markers located in the putative deleted region. The deletion was found to be of paternal origin in 9 cases and of maternal origin in the remaining 4 cases, suggesting that the molecular event resulting in the deletion occurs in both male and female gametogenesis and that genomic imprinting does not appear to play a role in the patho-genesis of del(9p) syndrome. © 1995 Wiley-Liss, Inc.     

A de novo interstitial deletion of chromosome 6 (q22.2q23.1)

A unique interstitial deletion of the long arm of chromosome 6 involving bands q22.2 and q23.1 was observed in a patient referred for craniostenosis and developmental delay. The associated phenotypic anomalies are compared with other reported cases of deletion 6q involving adjacent regions.     

Loss of heterozygosity on chromosome 22q in gastrointestinal stromal tumors (GISTs): a study on 50 cases

Mutational activation of KIT or PDGFRA is considered an early step in pathogenesis of gastrointestinal stromal tumors (GISTs); however, other nonrandom genetic changes have also been identified. At least three common regions of deletions on chromosome 22q, which may harbor putative tumor suppressor genes, have been defined. However, mapping of these regions has been inconsistent. It has also been speculated that GI autonomous nerve tumors (GANTs), GISTs with ultrastructural features suggestive of autonomic nerve differentiation, are characterized by a specific deletion involving 22q13 cytogenetic region. This study was undertaken to evaluate loss of heterozygosity (LOH) on chromosome 22q in 50 GISTs, including 10 GANTs. Four tumors were incidental minimal lesions 相似文献   

Loss of heterozygosity at chromosome 9p21 is a frequent finding in enteropathy-type T-cell lymphoma

Enteropathy-type T-cell lymphoma (ETL) and ulcerative jejunitis (UJ) are rare disorders often occurring in patients with coeliac disease. The genetic events associated with the accumulation of intraepithelial lymphocytes in coeliac disease and tumour development are largely unknown. Deletions at chromosome 9p21, which harbours the tumour suppressor genes p14/ARF, p15/INK4b, and p16/INK4a, and 17p13, where p53 is located, are associated with the development and progression of lymphomas. To examine whether deletions at 9p21 and 17p13 play a role in ETL, 22 cases of ETL and seven cases of UJ were screened for loss of heterozygosity (LOH) by tissue microdissection and polymerase chain reaction (PCR) analysis for microsatellite markers. Furthermore, p53 and p16 protein expression was examined by immunohistochemistry. In addition, polymerase chain reaction-single strand conformational polymorphism (PCR-SSCP) analysis for detection of mutations in exons 5-8 of the p53 gene was performed in five cases of ETL and three cases of UJ. LOH was found in at least one microsatellite marker at the 9p21 locus in 8 of 22 (36%) ETLs, but not in UJ. Five of nine (56%) tumours composed of large cells showed LOH at 9p21, as opposed to two of eight (25%) tumours with small- or medium-sized cell morphology. The region spanning the p14/p15/p16 gene locus was most frequently affected (five cases); LOH at these markers coincided with loss of p16 protein expression in all of these cases. p53 overexpression was demonstrated in all ETLs examined and in four of seven cases of UJ. However, no alterations of the p53 gene were detected by LOH or PCR-SSCP analysis. The results of this study show that LOH at chromosome 9p21 is frequent in ETL, especially in tumours with large cell morphology; this finding suggests that gene loss at this locus may play a role in the development of ETL.