Loss of heterozygosity reveals non-VHL allelic loss in hemangioblastomas at 22q13

Hemangioblastomas (HBs) are low-grade (World Health Organization grade I/IV) central nervous system (CNS) tumors that frequently contain VHL (3p26) mutations. They occur sporadically and in von Hippel Lindau (VHL) disease. Encoded pVHL aids degradation of hypoxia-inducible factors (HIFs) in the presence of normal oxygen levels. HBs provide an in vivo view of HIF effects within a CNS tumor. Typically, HBs are cystic tumors containing a mural nodule formed by noninvasive, vacuolated stromal cells that are embedded in a network of capillaries. Nine HBs, consecutively resected from 8 patients at our institution during a recent 2-year time span, were evaluated for additional losses of tumor suppressor genes. Non-VHL microsatellites studied for loss of heterozygosity (LOH) are near tumor suppressor genes lost in gliomas, pituitary adenomas, several CNS tumors on 22q, neurofibromatosis 1, and colon carcinomas (13, 2, 2, 1, and 2 markers for each, respectively). LOH in the region of 3p21.3-3p26.3 occurred in 3 of 8 HBs informative for at least 1 marker (D3S1539, D3S2303, or D3S2373). By using 2 markers (D22S417 and D22S532) for 22q13.2, LOH was found in 5 of 8 informative HBs. All 3 HBs with allelic losses near VHL also showed LOH at 22q13.2. No consistent losses were found with markers for 1p34, LMYC, 5q21, 5q32, 9p21, 10q23, 17p13, and 19q13. LOH for the 22q13.2 region in HBs suggests that the loss of another tumor suppressor gene is involved in the pathogenesis of HBs in addition to VHL. Absence of LOH for glioma markers is consistent with the low-grade behavior of HBs.     

Patterns of allelic loss at the BRCA1 locus in Arabic women with breast cancer

Loss of heterozygosity (LOH) of BRCA1, a tumor suppressor gene, is one mechanism of genetic inactivation in both sporadic and familial forms of breast cancer. Studies reported in breast cancers from women of Northern European descent have shown LOH in 30-50% of sporadic tumors. Microsatellite instability (MSI) has served as evidence for involvement of DNA repair genes. This study investigates the extent of allelic imbalance at the BRCA1 region in Arabic women with breast cancer. Paired normal and tumor tissue were available for DNA analysis in 13 cases. Results using fluorescent tagged primers to microsatellite markers D17S1323, D17S1325 and D17S855 intragenic to BRCA1 were analyzed using an ABI 310 DNA sequencer. As compared to normal DNA, MSI and LOH were recognized as a gain and a loss, respectively, of one signal in one allele in the tumor DNA. Microsatellite analyses showed 12 of 13 (92%) cases with LOH or MSI or both. Three cases demonstrated LOH alone, 3 cases with MSI alone. Six cases indicated both LOH and MSI; 2 cases with either LOH or MSI in separate markers. The combined finding of LOH and MSI in the same marker was detected only with D17S1325 in 4/6 cases. The proportion of aberrant findings of the BRCA1 locus in breast cancer appears to be higher in Arabic women than in other populations studied to date.     

Detection of loss of heterozygosity on chromosome 9q22.3 in microdissected sporadic basal cell carcinoma

Identification of loss of heterozygosity (LOH) at specific genetic loci in cancer cells suggests the presence of a tumor suppressor gene within the deleted region. A basal cell carcinoma (BCC) susceptibility gene, human homolog of drosophila patched (PTC), has been recently cloned and localized on chromosome 9q22.3. Mutation and deletion of this region has been reported in BCCs using frozen tumor tissue. The objective of this study was to test whether LOH of human PTC on chromosome 9q22 could be detected in archival sporadic BCCs. We studied 20 randomly selected sporadic BCCs by microdissection and polymerase chain reaction using paraffin-embedded, formalin-fixed material on glass slides. In all cases, analysis was performed with the polymorphic markers D9S53, D9S15, D9S287, and D9S303. The LOH frequencies were 30%, 42%, 56%, and 75% with D9S15, D9S287, D9S53, and D9S303, respectively. LOH at 9q22 was identified in 12 of 20 cases (60%) with at least one marker. Seven cases showed LOH with two markers, two cases with three markers, and one case showed LOH with all four markers. The results indicate that BCC LOH can be frequently identified in paraffin-embedded BCC after routine processing.     

Is loss of heterozygosity at 9q22.3 (PTCH gene) and 19p13.3 (STK11 gene) involved in the pathogenesis of ovarian stromal tumors?

Some ovarian fibromas and rare fibrosarcomas are associated with Gorlin syndrome, which is caused by mutation in the human homologue of Drosophila patched gene (PTCH), localized on chromosome 9q22.3. The relationship between PTCH gene and sporadic ovarian tumors in the thecoma-fibroma group has not been well characterized. On the other hand, we have recently described loss of heterozygosity (LOH) at 19p13.3 in 2 sporadic fibromas with sex-cord elements. We have analyzed DNA from 8 fibromas, 6 cellular fibromas, 2 fibrothecomas, 9 luteinized thecomas, and 2 fibrosarcomas of the ovary for LOH at 9q22.3 and 19p13.3, using polymerase chain reaction amplification for 10 microsatellite markers. LOH at 9q22.3 was detected in 4 (67%) of 6 cellular fibromas, with the highest frequency at microsatellite marker D9S15, which localizes proximal to the PTCH gene. Of 9 luteinized thecomas, 2 (22%) also exhibited LOH at 9q22.3 with 3 microsatellite markers other than D9S15. Allelic losses were not detected in any fibroma, fibrothecoma, or fibrosarcoma. LOH at 19p13.3 was found in 2 (25%) of 8 fibromas, 3 (50%) of 6 cellular fibromas, and 1 (11%) of 9 luteinized thecomas. None of the 2 fibrothecomas or 2 fibrosarcomas showed LOH at 19p13.3. LOH at both 9p22.3 and 19p13.3 was observed in 3 (50%) of 6 cellular fibromas, but not in luteinized thecomas. The results indicate that (1) LOH at both PTCH gene and STK11 gene is relatively frequent in cellular fibromas; (2) approximately a quarter of luteinized thecomas exhibited LOH of the PTCH gene; in both neoplasms, cellular fibromas and luteinized thecomas, LOH may play a role in their pathogenesis; and (3) sporadic cellular fibromas may arise through similar genetic pathways as cases of Gorlin syndrome.     

Intratumoral genetic heterogeneity in Barrett adenocarcinoma

In 10 cases of Barrett adenocarcinoma, samples from 8 tumor areas (including superficial and deep from peripheral and central areas) and a regional lymph node metastasis were studied for amplification of c-myc, c-erbB-2, and EGFR. We analyzed loss of heterozygosity (LOH) at 3 loci (APC, MCC, and RB) and 2 anonymous microsatellite markers (D4S1652 and D18S474). We detected c-myc in variable fractions of tissue samples from 3 of 9 tumors; EGFR was amplified in 2 specimens from 1 tumor. One tumor demonstrated amplification of c-erbB-2 in all areas. LOH at the D4S1652, MCC, RB, APC, and D18S474 loci was found in 75% (3/4), 57% (4/7), 50% (4/8), 11% (1/9), and 0% (0/10) of informative cases, respectively. LOH generally was restricted to variable subpopulations of tumor cells within individual tumors. There was no obvious association of certain genetic alterations with topographically distinct tumor regions; however, superficial areas showed more frequent genetic alterations than areas from the deeply invading front. More aberrations were detected in the periphery than in the center. Barrett adenocarcinoma is characterized by marked intratumoral genetic heterogeneity, which must be considered when evaluating genetic alterations as indicators of response to therapy and prognosis.     

Multiple Neuroendocrine Tumors of the Pancreas in von Hippel-Lindau Disease Patients : Histopathological and Molecular Genetic Analysis

Although pancreatic neuroendocrine tumors (NETs) in von Hippel-Lindau (VHL) disease have been reported, their pathological features have not been characterized. In addition, it is unknown whether alterations of the VHL gene are responsible for pancreatic NET development. To evaluate NETs in VHL patients, we performed histopathological analysis of 30 pancreatic tumors in 14 patients. In addition, DNA from NETs and normal pancreatic tissue from 6 patients with documented germ-line VHL gene mutations was studied for allelic deletions of the second copy of the VHL gene by fluorescence in situ hybridization and polymerase chain reaction-based single-strand conformational polymorphism analysis. Morphologically, the tumors were characterized by solid, trabecular, and/or glandular architecture and prominent stromal collagen bands. Sixty percent of the tumors revealed at least focally clear-cell cytology. All tumors were positive for panendocrine immunohistochemistry markers (chromogranin A and/or synaptophysin); 35% of NETs demonstrated focal positivity for pancreatic polypeptide, somatostatin, insulin, and/or glucagon; and no immunostaining for pancreatic and gastrointestinal hormones was observed in 65% of tumors. Dense core neurosecretory granules were evident by electron microscopic examination, and the clear cells additionally revealed abundant intracytoplasmic lipid. All NETs that were subjected to genetic analysis showed allelic loss of the second copy of the VHL gene. We conclude that multiple, nonfunctional pancreatic NETs occur in VHL patients. Stromal collagen bands and clear-cell morphology are important histological features of VHL-associated NETs. The presence of allelic deletions of the VHL gene in pancreatic NETs provides direct molecular evidence for a role of the gene in their tumorigenesis and establishes NET as an independent tumor type of VHL disease.     

Allelic Deletion of VHL Gene Detected in Papillary Tumors of the Broad Ligament, Epididymis, and Retroperitoneum in von Hippel-Lindau Disease Patients

Although clinically associated with von Hippel-Lindau (VHL) disease, the pathogenesis of papillary tumors of the broad ligament, epididymis, and peritoneum arising in patients with VHL disease is not clear. The "classic" VHL-associated neoplasms, including hemangioblastoma and renal ceil carcinoma, have been found to be associated with the inactivation of both VHL gene copies. It is not known whether a similar inactivation of the VHL gene is also responsible for the development of these uncommon VHL-associated lesions. The authors performed PCR (polymerase chain reaction) and PCR-based SSCP (single-strand conformation polymorphism) analysis on five predominantly papillary tumors in five VHL patients (one papillary cystadenoma of the broad ligament, one endometrioid cystadenoma of the broad ligament, two papillary cystadenomas of the epididymis, one papillary tumor of the retroperitoneum) with four polymorphic markers of VHL gene (D3S1038, D3S1110, D3S2452, 104/105). All five tumors showed allelic loss of VHL gene. The results provide the first genetic evidence for the role of VHL gene in the tumorigenesis of these rare benign neoplasms and confirm these tumors as phenotypic manifestations of VHL disease. Int J Surg Pathol 8(3):207-212, 2000     

Distinction between dysplasia-associated lesion or mass (DALM) and adenoma in patients with ulcerative colitis

Polyps with epithelial dysplasia in ulcerative colitis (UC) represent either dysplasia-associated lesions or masses (DALMs) or sporadic adenomas. DALMs are frequently associated with associated carcinoma and are an indication for colectomy. Removal of the polyp is treatment of choice for sporadic adenomas. Differentiating between these 2 lesions is not always easy. The goal of this study was to distinguish DALMs from adenomas in patients with UC on a genetic basis. We evaluated genetic alterations in DALMs and compared them with a previously published set of dysplastic polyps in patients with UC that were considered adenomas for the following reasons: (1) polyps were located outside of current active disease; (2) polyps had histological features of sporadic adenomas; and (3) patients displayed a uneventful follow-up after polypectomy (UC-adenomas). In addition, adenomas not associated with UC were studied. Genetic alterations on chromosome 3p were assessed for the markers D3S1766, D3S2409, and D3S2387. LOH with or without microsatellite instability was found in 70%, 37%, and 57% of cases of DALM, respectively. In contrast, UC-adenomas lesions exhibited genetic alterations in 8.3%, 11.7%, and 15.3% for the respective markers. Spontaneous adenomas exhibited genetic alterations in 10.5%, 7.1%, and 0% of cases, which were not significantly different from the UC-adenoma results. These results indicate that UC-adenomas are genetically and biologically similar to sporadic adenomas and that UC-adenomas may biologically represent sporadic adenomas, supporting on a genetic basis the criteria chosen to diagnose adenomas in UC. Genetic markers on chromosome 3p may be useful in the differential diagnosis between DALM and UC-adenomas.     

Comparative evaluation of microsatellite marker, AP-PCR and CGH studies in primary renal cell carcinoma

Renal cancer consists of a heterogeneous tumor group which is characterized by complex cytogenetic and molecular genetic abnormalities. In this study, three different techniques were applied to screen renal cancers for genetic alterations. We studied 99 primary, sporadic renal cancers (96 renal cell carcinomas and three other renal cancers) by a comparative evaluation of different microsatellite markers, comparative genomic hybridization (CGH) and AP-PCR. The AP-PCR produces a genomic fingerprint after an AluEI DNA restriction digest of tumor DNA samples. Microsatellite alterations were investigated using nine microsatellite markers spanning well-known regions of FhiT and VHL (3p14.2, 3p26) but also of oncogenes and tumor suppressor genes like Myc-L1 and TP53Alu (1p32, 17p13.1). To receive a genomic fingerprint, AP-PCR was carried out for all patient samples. Performing AP-PCR, only one case out of 99 displayed genomic imbalance. Seven of 99 investigated primary renal cancers showed alterations in up to four microsatellite loci (TP53Alu, Myc-L1, D3S1300, D3S1560, D3S1317, D3S4260). Three markers (Bat25, Bat26, REN) did not reveal any aberrations within the tested tumor samples. Six cases with microsatellite alterations and four without were examined by CGH. Five samples yielded aberrations, four of them were positive for microsatellite alterations. Only one tumor sample displayed microsatellite alterations, shift patterns in AP-PCR and alterations analyzed by CGH. Our data suggest that genomic aberrations found by microsatellite analysis are also detectable by CGH with the restriction of a minimum of alterated DNA of >10 Mb. Based on this study of RCC and in contrast to other reports for solid tumors, we conclude that AP-PCR is far less informative in investigation of renal cancers.     

Extraneuraxial hemangioblastoma: A clinicopathologic study of 10 cases with molecular analysis of the VHL gene

Less than 250 extraneuraxial hemangioblastomas occurring in paraneuraxial or peripheral sites have been reported to date, sporadically or in the setting of von Hippel-Lindau disease. Seventeen such cases underwent molecular genetic analysis, using either the patient’s peripheral blood in 9 cases or paraffin embedded tumor tissue in the rest. VHL gene mutations were documented in 3/9 cases in which DNA from peripheral blood lymphocytes was used, all with clinically manifest von Hippel-Lindau disease; instead, no VHL gene alterations were found in all of the 8 cases with sporadic extraneuraxial hemangioblastoma in which DNA from tumor tissue was analyzed. Our aim is to investigate the molecular genetic profile of the VHL gene in extraneuraxial hemangioblastoma using paraffin embedded tumor tissues.The clinical features, histopathology, and molecular investigations of 10 extraneuraxial hemangioblastomas (7 females, 3 males; median age: 47 years) are presented herein. The histopathologic diagnosis was supported by immunohistochemistry (10/10) and electron microscopy (4/10). Molecular genetic analysis was conducted (10/10) for VHL gene mutations, LOH, and gene promoter methylation. Two of the present cases were already published with only limited or no molecular investigations.Four tumors of the present series were paraneuraxial, and 6 peripheral (2 involved soft tissues, and 4 the kidney). One tumor was von Hippel-Lindau disease-associated, 1 was classified as “hemangioblastoma-only VHLD”, 7 were sporadic, and one was unknown. All were histopathologically analogous to their counterpart located inside the central nervous system. Immunophenotypically, all tumors expressed vimentin, S-100, NSE, and alpha-inhibin (10/10). Ultrastructurally, unbound lipid droplets filled the cytoplasms of the stromal cells. Molecular analysis revealed 3 inactivating mutations (1 germline, two somatic) in the coding sequence of the VHL gene in 2 different extraneuraxial hemangioblastomas, and LOH in 4 (two as a double hit), all non-renal extraneuraxial hemangioblastomas. Methylation analysis failed to disclose promoter methylation in any case.In conclusion, we report eight new cases from the wide category of extraneuraxial hemangioblastomas (4 paraneuraxial, and 4 renal), one of which was von Hippel-Lindau disease-associated and 7 sporadic. VHL gene alterations were found not only in the von Hippel-Lindau disease-associated tumor, but ? for the first time ? also in 3 sporadic ones, two of which with novel mutations.     

Genetic linkage between Von Hippel--Lindau disease and three microsatellite polymorphisms refines the localisation of the VHL locus

Von Hippel—Lindau (VHL) disease is a dominantly inheritedfamilial cancer syndrome characterised by the development ofretinal and central nervous system haemangioblastomas, renalcell carcinoma and phaeochromocytoma. The gene for VHL diseasehas been mapped to chromosome 3p25–p26 and presymtomaticdiagnosis using linked DNA markers is available. We have previouslymapped the VHL disease gene to a 4 cM interval between D3S1250and D3S18. To increase access to presymptomatic diagnosis andto accelerate progress towards isolating the VHL disease genewe attempted to identify microsatellite DNA markers linked tothe disease gene by genetic linkage analysis in 29 families.We found significant linkage between the VHL disease gene anddinucleotide (CA) repeat polymorphisms at D3S1038 (Zmax = 22.24at     

Chromosome 1 alterations in breast cancer: allelic loss on 1p and 1q is related to lymphogenic metastases and poor prognosis.

The development of human breast cancer is characterized by a variety of genetic alterations, and cytogenetic analyses have documented the consistent involvement of both arms of chromosome 1. In the present study, molecular markers detecting restriction fragment length polymorphisms were used in pairwise screening of normal and tumor DNA to determine the frequency of allelic imbalance in breast tumors. Loss of heterozygosity (LOH) in the polymorphic epithelial mucin (PEM or MUCI) gene at 1q21 was found in 16% of 89 informative (constitutionally heterozygous) cases, whereas gain in intensity of one allelic band was more frequent (37%), a total of 47% of cases manifesting either allelic loss or gain. Three additional tumors manifested a structural alteration. Allelic loss or gain in the PEM gene was not associated with other prognostic factors, e.g., tumor size, lymph node status, steroid receptors. DNA ploidy, S phase fraction, protooncogene amplification, histological type, or patient age. However, LOH in the PEM gene was significantly correlated with early disease recurrence (P = 0.006). LOH on 1p was found in 27% of 117 informative cases, using probes for either D1S57 or D1Z2 located at 1p33-p35 and 1p36, respectively. Somatic allelic imbalance on 1p and 1q seemed to be independent events and not the effect of loss of a whole chromosome 1. LOH on 1p was significantly correlated to the presence of lymph node metastasis, to larger tumor size, and to DNA nondiploidy, but not correlation was found to disease outcome at this limited duration of follow-up (median 29 months).     

Deletion mapping of endocrine tumors localizes a second tumor suppressor gene on chromosome band 11q13

Multiple endocrine neoplasia type 1 syndrome (MEN1, MIM 131100), an autosomal dominant disease, is characterized by parathyroid hyperplasia, pancreatic endocrine tumors, and pituitary adenomas. These tumors also occur sporadically. Both the familial (MEN1) and the sporadic tumors reveal loss of heterozygosity (LOH) for chromosome band 11q13 sequences. Based on prior linkage and LOH analyses, the MEN1 gene was localized between PYGM and D11S460. Recently, the MEN1 gene (menin) has been cloned from sequences 30-kb distal to PYGM. We performed deletion mapping on 25 endocrine tumors (5 MEN1 and 20 sporadic) by using 21 polymorphic markers on chromosome band 11q13. Of these, two (137C7A, 137C7B) were derived from PYGM-containing BAC (bacterial artificial chromosome-137C7) sequences, one from INT2-containing cosmid sequences and the marker D11S4748, a (CA)₂₀ repeat marker that was developed by us. The LOH analysis shows that the markers close to the MEN1 (menin) gene were not deleted in three of the tumors. These tumors, however, showed LOH for distal markers. Thus, the data suggest the existence of a second tumor suppressor gene on chromosome band 11q13. Genes Chromosomes Cancer 22:130–137, 1998. © 1998 Wiley-Liss, Inc.     

散发性肾癌中VHL基因的两个单核苷酸多态位点分析和杂合性缺失检测

目的检测79例散发性肾癌中抑癌基因VHL内部的两个单核苷酶多态(single nucleotide polymorphism，SNP)位点并分析杂合性缺失(loss of heterozygosity，LOH)发生情况，探讨VHL基因LOH与肾癌临床病理特征的关系。方法从肿瘤和正常肾组织中提取DNA，应用聚合酶链反应-限制性片段长度多态性方法检测VHL基因5′端SNP位点rs779805和3′端SNP位点rs1642742的基因型。在两个位点的杂合子中进行LOH检测，并分析VHL基因LOH与临床病理特征的关系。结果我们计算了两个位点的基因型、基因频率、杂合度、多态信息含量等遗传学参数。综合两个位点发现杂合子29例．其中12例(41．4％)存在LOH。VHL基因LOH与肾癌发生年龄、性别、临床分期、病理分级无显著相关性。结论在散发性肾癌中，VHL基因LOH是肿瘤发生的重要机理，其发生率达41．4％，VHL基因LOH与肾癌分期、分级无关。     

Loss of heterozygosity of the BRCA1 and FHIT genes in patients with sporadic breast cancer from Southern Brazil

Aim: The evaluation of allelic losses at the FHIT and the BRCA1 genes and at three other loci at the 17q region in a series of 34 sporadic breast cancer cases from Southern Brazil. METHODS: The samples were evaluated for loss of heterozygosity (LOH) at the FHIT and the BRCA1 genes and at three other microsatellite markers at 17q, and the findings were correlated with clinicopathological parameters. RESULTS: The BRCA1 intragenic marker, D17S855, had the highest frequency of LOH, detected in 10 of 24 informative cases, followed by the D17S579 (six of 23 informative cases), D17S806 (five of 21 informative cases), and D17S785 markers (five of 21 informative cases). LOH at the FHIT intragenic marker, D3S1300, was found in six of 25 informative cases. In four of the six cases with LOH of the FHIT gene, there was concomitant loss of the BRCA1 intragenic marker. CONCLUSIONS: The frequency of allelic losses in the FHIT and BRCA1 loci in the Southern Brazilian population is similar to that described in the general population. No correlations were found when the total LOH frequency was compared with tumour size, grade, or presence of axillary lymph node metastasis. Further studies using larger sporadic breast cancer samples and additional markers would be useful to confirm these findings, in addition to establishing more specific associations with clinicopathological parameters in this specific population.     

Analysis of loss of heterozygosity in Korean patients with keratoacanthoma

Loss of heterozygosity (LOH) has been established as an important genetic mechanism giving rise to malignant neoplasia. The mechanism of LOH has been shown to cause basal cell carcinoma and malignant melanoma as well as other types of skin cancer. A few studies on LOH in sporadic keratoacanthomas have been reported. The purpose of this study was to investigate the significance of LOH in the pathogenesis of sporadic keratoacanthomas developed in 10 Korean patients. The presents of LOH at 7 microsatellite markers (D2S286, D3S1317, D5S346, D9S160, D9S171, D10S185, and D17S261) were evaluated in sporadic keratoacanthomas. LOH was found in only 1 of 10 cases at D10S185. The low frequency of LOH detected in this study suggests that LOH may not be significant in the induction of sporadic keratoacanthomas.     

Loss of heterozygosity in 11q13-14 regions in gastric neuroendocrine tumors not associated with multiple endocrine neoplasia type 1 syndrome.

Loss of heterozygosity (LOH) at the MEN1 gene locus at 11q13 is commonly found in type II gastric carcinoid tumors, which are associated with multiple endocrine neoplasia type 1 (MEN-1). In contrast, information is scanty or absent for other types of gastric neuroendocrine tumors, represented by type I carcinoids (associated with chronic atrophic gastritis), type III (sporadic) carcinoids, and neuroendocrine carcinomas. Moreover, LOH analysis of the allelic region distal to the MEN1 gene, which is postulated to contain an additional tumor suppressor gene effective in MEN-1-associated and sporadic endocrine tumors, has never been performed. To clarify these issues, DNA extracted from archival tissue from 25 type I carcinoids, 4 type III carcinoids, and 2 neuroendocrine carcinomas was amplified by PCR, using primers for six polymorphic markers located on chromosome 11q13 (PYGM, D11S4946, and D11S913) and 11q14 (D11S916, D11S901, and D11S1365), for analysis of LOH. Allelic losses in the 11q13-14 region with at least two polymorphic markers were found in 12 of 25 (48%) type I carcinoids. When LOH was found in the 11q13 region, it was large and continuous and extended to the most telomeric marker investigated. In one tumor, retention of heterozygosity for markers in the MEN1 region and LOH for distal markers were observed. No LOH was found in three of four type III carcinoids. Large deletions in both the 11q13 and 11q14 regions were observed in both neuroendocrine carcinomas investigated. In conclusion, LOH in the 11q13-14 regions is frequently found in type I carcinoids and neuroendocrine carcinomas of the stomach, suggesting the involvement of the MEN1 gene and/or a more telomeric tumor suppressor gene in the pathogenesis of these non-MEN-1-associated neuroendocrine tumors. The low rate of LOH at 11q13-14 suggests the predominance of different genetic mechanisms in type III carcinoids, which also differ from other types of gastric carcinoids in the lack of a promoter role for gastrin.     

Detailed genetic mapping of the von Hippel-Lindau disease tumour suppressor gene.

Von Hippel-Lindau (VHL) disease is an autosomal dominant inherited familial cancer syndrome characterised by a predisposition to the development of retinal, cerebellar, and spinal haemangioblastomas, renal cell carcinoma, and phaeochromocytoma. The gene for VHL disease has been mapped to chromosome 3p25-p26 and flanking markers identified. We report the detailed genetic mapping of the VHL disease locus in 38 families. Significant linkage was detected between VHL disease and D3S601 (Zmax = 18.86 at theta = 0.0, CI 0.0-0.025), D3S18 (Zmax = 11.42 at theta = 0.03, CI 0.005-0.08), RAF1 (Zmax = 11.02 at theta = 0.04, CI 0.007-0.01), and D3S1250 (Zmax = 4.73 at theta = 0.05, CI 0.005-0.15). Multipoint linkage analysis mapped the VHL disease locus between D3S1250 and D3S18 close to D3S601. There was no evidence of locus heterogeneity. This study has (1) confirmed the tight linkage between VHL disease and D3S601, (2) identified D3S1250 as the first marker telomeric to RAF1 which maps centromeric to the VHL disease gene, and (3) narrowed the target region for isolation of the VHL disease gene by positional cloning techniques to a 4 cM interval between D3S1250 and D3S18. These findings will improve the clinical management of families with VHL disease by improving the accuracy of presymptomatic diagnosis using linked DNA markers, and will enhance progress towards isolating the VHL disease gene.     

Somatic mosaicism in von Hippel-Lindau Disease

von Hippel-Lindau (VHL) disease is an autosomal dominant familial cancer syndrome predisposing to the development of retinal and central nervous system haemangioblastomas, pheochromocytomas, renal and pancreatic cancer. In the course of a molecular analysis conducted to detect germline mutations of this gene in von Hippel-Lindau patients and individuals affected by sporadic tumors, we have identified a case of somatic mosaicism in the asymptomatic mother of a VHL patient who was subsequently diagnosed with pheochromocytoma. This is the first report providing molecular evidence of somatic mosaicism in von Hippel-Lindau disease. Mosaicism could provide some genetic explanation for the clinical heterogeneity and variable severity of the VHL phenotype, and should be considered, as a possible event when evaluating sporadic cases of VHL or patients with isolated VHL-related tumors. Hum Mutat 15:114, 2000.     

Molecular characterization of pancreatic serous microcystic adenomas: evidence for a tumor suppressor gene on chromosome 10q

Pancreatic serous microcystic adenomas (SCAs) are rare, benign tumors with a striking female preference. Virtually no information is available about chromosomal or genetic anomalies in this disease. We performed extensive molecular characterization of 21 cases of formalin-fixed, paraffin-embedded sporadic SCAs consisting in genome-wide allelic loss analysis with 79 microsatellite markers covering all 22 autosomes, assessment of microsatellite instability, and mutational analysis of the VHL, K-ras, and p53 genes in nine cases for which frozen tissue was available. Although no case showed microsatellite instability of the type seen in mismatch repair-deficient tumors, a relatively low fractional allelic loss of 0.08 was found. Losses on chromosome 10q were the most frequent event in SCAs (50% of cases), followed by allelic losses on chromosome 3p (40% of cases). Moderately frequent losses (>25% of cases) were found on chromosomes 1q, 2q, and 7q. The VHL gene, located on chromosome 3p, had somatic inactivating mutations in two of nine cases (22%), whereas no mutations were found in either K-ras or p53, in agreement with the finding that all 21 cases stained negative for p53 by immunohistochemistry. Our study indicates that the involvement of chromosomal arms 10q and 3p is characteristic of SCAs and that the VHL gene is involved in a subset of sporadic cases.