Germline and somatic mutations in the tyrosine kinase domain of the MET proto-oncogene in papillary renal carcinomas.

Hereditary papillary renal carcinoma (HPRC) is a recently recognized form of inherited kidney cancer characterized by a predisposition to develop multiple, bilateral papillary renal tumours. The pattern of inheritance of HPRC is consistent with autosomal dominant transmission with reduced penetrance. HPRC is histologically and genetically distinct from two other causes of inherited renal carcinoma, von Hippel-Lindau disease (VHL) and the chromosome translocation (3;8). Malignant papillary renal carcinomas are characterized by trisomy of chromosomes 7, 16 and 17, and in men, by loss of the Y chromosome. Inherited and sporadic clear cell renal carcinomas are characterized by inactivation of both copies of the VHL gene by mutation, and/or by hypermethylation. We found that the HPRC gene was located at chromosome 7q31.1-34 in a 27-centimorgan (cM) interval between D7S496 and D7S1837. We identified missense mutations located in the tyrosine kinase domain of the MET gene in the germline of affected members of HPRC families and in a subset of sporadic papillary renal carcinomas. Three mutations in the MET gene are located in codons that are homologous to those in c-kit and RET, proto-oncogenes that are targets of naturally-occurring mutations. The results suggest that missense mutations located in the MET proto-oncogene lead to constitutive activation of the MET protein and papillary renal carcinomas.

Characterization and chromosomal localization of a cDNA encoding brain amyloid of Alzheimer's disease.

Four clones were isolated from an adult human brain complementary DNA library with an oligonucleotide probe corresponding to the first 20 amino acids of the beta peptide of brain amyloid from Alzheimer's disease. The open reading frame of the sequenced clone coded for 97 amino acids, including the known amino acid sequence of this polypeptide. The 3.5-kilobase messenger RNA was detected in mammalian brains and human thymus. The gene is highly conserved in evolution and has been mapped to human chromosome 21.

Hypoxic repression of STAT1 and its downstream genes by a pVHL/HIF-1 target DEC1/STRA13.

DEC1/STRA13 is a bHLH type transcriptional regulator involved with immune regulation, hypoxia response and carcinogenesis. We recently demonstrated that STRA13 interacts with STAT3 in the transcriptional activation of STAT-dependent promoters. Here, we pursue STRA13 involvement in the JAK/STAT pathway by studying its role in STAT1 expression. First, we showed that VHL deficiency or HIF-1 activation resulted in the repression of endogenous STAT1 mediated by STRA13. We then characterized the STAT1 proximal promoter to assess its response to STRA13 by transient coexpression in a luciferase reporter assay. Using sequential truncation and site-directed mutagenesis of the STAT1 promoter with STRA13 deletion constructs, we showed that the STRA13 C-terminal trans-activation domain, which is known to bind HDAC1, mostly determines the repressive activity. Involvement of HDAC activity in STAT1 regulation was validated by TSA inhibition and chromatin immunoprecipitation (ChIP) assay. Thus, we demonstrate that STRA13-mediated repression of STAT1 transcription utilizes an HDAC1-dependent mechanism. Furthermore, we show that targets of unphosphorylated STAT1, such as antigen presenting genes and CASP1, are also repressed by hypoxia possibly through the same STRA13-mediated mechanism. Thus, the newly discovered link between HIF-1 and STAT1 reveals a previously unknown role of STRA13 in hypoxia and carcinogenesis.

Hypermethylation of Ron proximal promoter associates with lack of full-length Ron and transcription of oncogenic short-Ron from an internal promoter.

The gene for tyrosine-kinase receptor Ron (MST1R) resides in the chromosome 3p21.3 region, frequently affected in common human malignancies. The gene generates two transcripts, 5 and 2 kb-long, full-length Ron (flRon) and short-form Ron (sfRon), respectively. Here, we show for the first time that the variegated Ron expression is associated with variations in the methylation patterns of two distinct CpG islands in Ron proximal promoter. Widespread hypermethylation associates with lack of flRon whereas hypermethylation of the distal island associates with transcription of sfRon, a constitutively active tyrosine-kinase that drives cell proliferation. sfRon inhibition with kinase-dead transgenes decreases cancer cell growth and induces cellular differentiation. sfRon could be a new drug target in cancer types in which it contributes to tumor progression.

Unusual class of Alu sequences containing a potential Z-DNA segment.

A potential Z-DNA sequence, (dA-dC)9, has been found to replace the customary A-rich region in the middle of an Alu family member in the African green monkey genome. This Alu, bounded by imperfect direct repeats, also contains an unusual 3' end and may be a member of a large subfamily of such sequences.

A transforming activity not detected by DNA transfer to NIH 3T3 cells is detected by JB6 mouse epidermal cells.

Transfection of four different mouse epidermal tumor cell DNAs into NIH 3T3 cells yielded neither morphologically altered foci nor anchorage independence. However, promotion-sensitive, but not promotion-insensitive, JB6 mouse epidermal cell lines were permissive for the expression of anchorage independence after transfection of DNA from three of these tumor cell lines. This transforming activity and the promotion-sensitive activity that confers sensitivity to promotion of transformation show differences in restriction enzyme sensitivity. In view of this difference and the differences in both recipient cells and 12-O-tetradecanoyl-phorbol-13-acetate dependence of expression, it appears that the transforming activity and the promotion-sensitive activity are specified by different genes. The JB6 promotion-sensitive cell lines may be useful for detecting and cloning transforming genes that escape detection in the NIH 3T3 cell focus assay.

STRA13 expression and subcellular localisation in normal and tumour tissues: implications for use as a diagnostic and differentiation marker.

BACKGROUND: STRA13 is a bHLH transcription factor that plays a crucial role in cell differentiation, proliferation, apoptosis, and response to hypoxia. OBJECTIVE: To assess STRA13 involvement in carcinogenesis and evaluate its diagnostic value. METHODS: A comprehensive analysis was undertaken of the endogenous protein expression in 389 normal and corresponding malignant specimens, using newly generated polyclonal antibodies. RESULTS: STRA13 was commonly expressed in epithelial cells of normal and neoplastic tissues where it was confined mostly to the nucleus. Intense cytoplasmic STRA13 immunoreactivity was characteristic of myoepithelial and differentiated squamous epithelial cells of all organ sites and their neoplastic counterparts, suggesting application of STRA13 as a myoepithelial cell marker. A distinctive apical granular cytoplasmic staining pattern observed in the pancreas and large intestine was retained in corresponding metastatic carcinomas, providing for identification of the primary sites of these disseminating tumours. In less differentiated tumours there was a tendency to lose the cytoplasmic staining or to switch to nuclear STRA13 staining. Analysis of STRA13, HIF-1alpha, and CAIX expression patterns in a large set of various tumours substantiated the association of STRA13 with HIF-1alpha expression and hypoxia in vivo. Investigation of the molecular mechanisms of STRA13 nucleo-cytoplasmic shuttling suggested that STRA13 employs nuclear import/export that utilises the NLS/NES motifs situated within the N-terminus and in the middle of the protein. CONCLUSIONS: STRA13 may serve as a marker for myoepithelial cells, for the degree of tumour differentiation, and for identification of the primary site of certain metastatic tumours. In combination with CAIX and CAXII markers, it may lead to a more accurate classification of all renal carcinomas.

Genetic changes in human adrenocortical carcinomas.

Recent studies have suggested that loss of heterozygosity at loci on the short arm of human chromosome 11 (11p) may be important in the pathogenesis of benign and malignant adrenal cortical tumors. To test this concept, adrenocortical carcinomas from nine patients and benign adrenal cortical lesions from eight patients were tested for loss of alleles at loci on human chromosomes 11, 13, and 17. All patients with adrenocortical carcinoma whose normal somatic tissues were heterozygous for a locus on chromosome 17p had lost alleles in the tumor. Four of six patients with adrenocortical carcinoma who were heterozygous for one or more alleles on chromosome 11p in normal tissues had lost 11p alleles in the tumor. Three of six patients with adrenocortical carcinoma showed loss of 13q alleles in the tumor. Loss of alleles on chromosomes 11p, 13q, and 17p was observed in primary tumors and metastases but not in adrenocortical adenomas or hyperplastic lesions of the adrenal cortex. One patient with adrenocortical carcinoma had a somatic mutation in the HRAS1 gene in the normal adrenal gland. The consistency of the genetic changes on chromosomes 11p, 13q, and 17p suggests that they are important in the pathogenesis of adrenocortical carcinoma.

Epigenetic inactivation of RASSF1A in lung and breast cancers and malignant phenotype suppression.

BACKGROUND: The recently identified RASSF1 locus is located within a 120-kilobase region of chromosome 3p21.3 that frequently undergoes allele loss in lung and breast cancers. We explored the hypothesis that RASSF1 encodes a tumor suppressor gene for lung and breast cancers. METHODS: We assessed expression of two RASSF1 gene products, RASSF1A and RASSF1C, and the methylation status of their respective promoters in 27 non-small-cell lung cancer (NSCLC) cell lines, in 107 resected NSCLCs, in 47 small-cell lung cancer (SCLC) cell lines, in 22 breast cancer cell lines, in 39 resected breast cancers, in 104 nonmalignant lung samples, and in three breast and lung epithelial cultures. We also transfected a lung cancer cell line that lacks RASSF1A expression with vectors containing RASSF1A complementary DNA to determine whether exogenous expression of RASSF1A would affect in vitro growth and in vivo tumorigenicity of this cell line. All statistical tests were two-sided. RESULTS: RASSF1A messenger RNA was expressed in nonmalignant epithelial cultures but not in 100% of the SCLC, in 65% of the NSCLC, or in 60% of the breast cancer lines. By contrast, RASSF1C was expressed in all nonmalignant cell cultures and in nearly all cancer cell lines. RASSF1A promoter hypermethylation was detected in 100% of SCLC, in 63% of NSCLC, in 64% of breast cancer lines, in 30% of primary NSCLCs, and in 49% of primary breast tumors but in none of the nonmalignant lung tissues. RASSF1A promoter hypermethylation in resected NSCLCs was associated with impaired patient survival (P =.046). Exogenous expression of RASSF1A in a cell line lacking expression decreased in vitro colony formation and in vivo tumorigenicity. CONCLUSION: RASSF1A is a potential tumor suppressor gene that undergoes epigenetic inactivation in lung and breast cancers through hypermethylation of its promoter region.

The 630-kb lung cancer homozygous deletion region on human chromosome 3p21.3: identification and evaluation of the resident candidate tumor suppressor genes. The International Lung Cancer Chromosome 3p21.3 Tumor Suppressor Gene Consortium.

We used overlapping and nested homozygous deletions, contig building, genomic sequencing, and physical and transcript mapping to further define a approximately 630-kb lung cancer homozygous deletion region harboring one or more tumor suppressor genes (TSGs) on chromosome 3p21.3. This location was identified through somatic genetic mapping in tumors, cancer cell lines, and premalignant lesions of the lung and breast, including the discovery of several homozygous deletions. The combination of molecular manual methods and computational predictions permitted us to detect, isolate, characterize, and annotate a set of 25 genes that likely constitute the complete set of protein-coding genes residing in this approximately 630-kb sequence. A subset of 19 of these genes was found within the deleted overlap region of approximately 370-kb. This region was further subdivided by a nesting 200-kb breast cancer homozygous deletion into two gene sets: 8 genes lying in the proximal approximately 120-kb segment and 11 genes lying in the distal approximately 250-kb segment. These 19 genes were analyzed extensively by computational methods and were tested by manual methods for loss of expression and mutations in lung cancers to identify candidate TSGs from within this group. Four genes showed loss-of-expression or reduced mRNA levels in non-small cell lung cancer (CACNA2D2/alpha2delta-2, SEMA3B [formerly SEMA(V), BLU, and HYAL1] or small cell lung cancer (SEMA3B, BLU, and HYAL1) cell lines. We found six of the genes to have two or more amino acid sequence-altering mutations including BLU, NPRL2/Gene21, FUS1, HYAL1, FUS2, and SEMA3B. However, none of the 19 genes tested for mutation showed a frequent (>10%) mutation rate in lung cancer samples. This led us to exclude several of the genes in the region as classical tumor suppressors for sporadic lung cancer. On the other hand, the putative lung cancer TSG in this location may either be inactivated by tumor-acquired promoter hypermethylation or belong to the novel class of haploinsufficient genes that predispose to cancer in a hemizygous (+/-) state but do not show a second mutation in the remaining wild-type allele in the tumor. We discuss the data in the context of novel and classic cancer gene models as applied to lung carcinogenesis. Further functional testing of the critical genes by gene transfer and gene disruption strategies should permit the identification of the putative lung cancer TSG(s), LUCA, Analysis of the approximately 630-kb sequence also provides an opportunity to probe and understand the genomic structure, evolution, and functional organization of this relatively gene-rich region.

Cellular proteins that bind the von Hippel-Lindau disease gene product: mapping of binding domains and the effect of missense mutations.

The von Hippel-Lindau disease (VHL) gene is a novel tumor suppressor gene that plays a role in the pathogenesis of renal cell carcinomas and hemangioblastomas of the central nervous system. To begin an evaluation of the biological functions of the VHL gene product (pVHL), we prepared bacterial fusion protein between glutathione S-transferase and wild-type or mutant pVHLs. The fusion proteins were used to identify cellular proteins that bind to pVHL in vitro. Monkey kidney cells transfected with wild-type or mutant VHL cDNAs were used to identify cellular proteins that bind to pVHL in vivo. Wild-type pVHL consistently bound two cellular proteins with apparent molecular masses of 10 and 14 kilodaltons that were designated p10 and p14, respectively. Mapping studies with a panel of VHL deletion mutant proteins demonstrated that p10 and p14 bound to a 32-amino acid peptide located in the carboxy terminal portion of pVHL. Missense mutation located within this 32-amino acid peptide abrogated the ability of the VHL protein to bind p10 and p14. Of 67 VHL families with identified germline mutations, 42 families had mutations predicted to affect the p10/p14-binding region. Maintenance of the integrity of the p10/p14-binding region appears to be essential for cellular growth regulation by pVHL.

Molecular analysis of genetic changes in the origin and development of renal cell carcinoma.

Renal cell carcinoma has been characterized by an abnormality on the short arm of chromosome 3 which suggests the presence of a tumor suppressor gene at this location. In order to more precisely define the location of the renal cell carcinoma gene and to differentiate molecular changes occurring in early stages of renal neoplasia versus those occurring later in malignant progression, DNA from normal and tumor tissue from 60 patients with various stages of renal cell carcinoma was analyzed for loss of alleles at different chromosomal loci. In tumor tissue from 51 of 58 evaluable patients (88%) there was loss of heterozygosity at one or more of 10 loci tested on chromosome 3 independently of tumor stage. Analysis of the genotypes identified the distal portion of 3p bounded by D3S2 and D3S22 (3p21-26) as the region of the disease gene. In tumor tissue from patients with advanced renal cell carcinoma, we found loss of heterozygosity on chromosome 11p in 5 of 21 (24%), on chromosome 13 in 3 of 9 (33%), and on chromosome 17 in 2 of 19 (11%). We found no loss of heterozygosity at the loci on chromosomes 11, 13, or 17 in tumor tissue from patients with localized renal cell carcinoma (N = 5). These data suggest the existence of a tumor suppressor gene on chromosome 3p which may be essential to the genesis of sporadic renal cell carcinoma and that other tumor suppressor genes are associated with progression of this malignancy.

Molecular and cellular characterization of human renal cell carcinoma cell lines.

Recent studies have suggested that a tumor suppressor gene located in the region 3p21-26 of chromosome 3 is essential to the genesis of sporadic renal cell carcinoma (RCC) and that other tumor suppressor genes located on other chromosomes may be involved with progression of this malignancy. The cellular heterogeneity of solid tumors complicates their analysis. In order to analyze a homogeneous population of tumor cells and identify genetic changes associated with histology in renal cortical tumors, we have established and characterized 35 RCC lines derived from tumor tissue from 31 patients with renal cell carcinomas. The overall success rate in establishing these cell lines from fresh or frozen specimens was 75% (18 of 24) and 35% (17 of 48), respectively. These lines differed in their morphology, growth rates, and tumorigenicity in athymic nude mice. Molecular characterization utilizing DNA fingerprinting and restriction fragment length polymorphism deletion analysis was performed to detect somatic mutations and loss of heterozygosity on the short arm of chromosome 3. Analysis revealed loss of heterozygosity on chromosome 3p in 25 cell lines derived from 28 informative nonpapillary forms of RCC (89%). Deletion-mapping analysis showed the retention of the distal locus, D3S18, in one of the RCC cell lines, which further localized the position of the putative tumor suppressor gene to the region proximal to D3S18. Although deletions on chromosome 3 have been recently suggested to be specific to the clear cell-type phenotype, our results revealed no correlation between loss of heterozygosity and clear or granular cell types.

Deletion of two separate regions on chromosome 3p in breast cancers.

We have characterized the copy number of various loci on chromosome 3p in a series of breast cancers. To determine the precise region(s) involved, restriction fragment length polymorphism (RFLP) analysis for loss of heterozygosity (LOH) was performed using a panel of RFLP probes at 3p13-14, 3p21-22, and 3p24-26. The incidence of LOH at the three loci was 41, 32, and 45%, respectively. To validate the LOH data and to gain insights into the mechanisms resulting in LOH, chromosome 3 pericentromeric and 3p region-specific DNA probes were used to determine the DNA copy number by fluorescence in situ hybridization (FISH). Among 22 cases examined, 15 showed loss by both LOH and FISH, indicating that the dominant mechanism of LOH at 3p in breast cancer is a physical deletion. Two of the 22 cases showed loss by RFLP analysis but not by FISH, suggesting either mitotic recombination or loss and endoreduplication. In three cases, RFLP analysis indicated allelic imbalance, which was incorrectly interpreted as LOH, since a gain of one allele was suggested by FISH. By constructing a deletion map, we found that 2 separate regions, 3p13-14 and 3p24-26, were independently deleted in some breast cancers. Additionally, four cases had break points within the 3p24-26 region and one case had a homozygous deletion at 3p13, further supporting the hypothesis that there are tumor suppressor genes at both 3p13-14 and 3p24-26. Although high frequency of LOH was observed at the 3p21-22 region, there was no direct evidence supporting the existence of a breast cancer tumor suppressor gene there as opposed to codeletion with either the proximal or distal region.

The limiting effect of transfer RNA's on the rate of protein synthesis in cell extracts of rapidly growing tumors.

Using crude cell extracts from rapidly growing animal and human tumors, we found that (a) the addition of homologous transfer RNA (tRNA) to these extracts stimulated polypeptide synthesis two-to threefold, while addition of heterologous tRNA did not have a similar effect; (b) addition of homologous as well as heterologous ribosomal RNA was also stimulatory; and (c) both stimulatory effects were additive. The possibility that the effect of homologous tRNA could be mediated by contaminating material (such as the "translational control" RNA) seems to be rulted out by experiments with highly purified tRNA preparations, which did not contain even traces of 18 S, 7 S, 5 S, and smaller than 4S RNA's. Control experiments showed that no loss of tRNA occurred either during preparation of the cell extracts or under the conditions of in vitro protein synthesis. The results obtained suggest possible occurrence of a deficiency in specific isoaccepting tRNA's in rapidly growing solid tumors.

Carbonic anhydrase 9 as an endogenous marker for hypoxic cells in cervical cancer.

The presence of radiation-resistant hypoxic cells in some solid tumors is known to predict for relapse after radiotherapy. Use of an endogenous marker of hypoxia would be a convenient alternative to current methods that measure tumor oxygenation, provided the marker could be shown to reliably identify viable, radiation-resistant, hypoxic cells. Carbonic anhydrase 9 (CA9) is a transmembrane protein overexpressed in a wide variety of tumor types and induced by hypoxia. Using a monoclonal antibody and cell sorting, CA9-positive cells in SiHa cervical carcinoma xenografts growing in immunodeficient mice were found to be clonogenic, resistant to killing by ionizing radiation, and preferentially able to bind the hypoxia marker pimonidazole. CA9 and pimonidazole immunostaining were compared in formalin-fixed sections from tumors of 18 patients undergoing treatment for cancer of the cervix. Excellent colocalization was observed, although the area of the tumor section that bound anti-CA9 antibodies represented double the number of cells that bound anti-pimonidazole antibodies. Occasional regions staining with pimonidazole but not CA9 could be indicative of transient changes in tumor perfusion. Results support the hypothesis that CA9 is a useful endogenous marker of tumor hypoxia.

High resolution chromosome 3p allelotyping of human lung cancer and preneoplastic/preinvasive bronchial epithelium reveals multiple, discontinuous sites of 3p allele loss and three regions of frequent breakpoints.

Allele loss involving chromosome arm 3p is one of the most frequent and earliest known genetic events in lung cancer pathogenesis and may affect several potential tumor suppressor gene regions. To further study the role of chromosome 3p allele loss in the pathogenesis of lung cancer, we performed high resolution loss of heterozygosity (LOH) studies on 97 lung cancer and 54 preneoplastic/preinvasive microdissected respiratory epithelial samples using a panel of 28 3p markers. Allelic losses of 3p were detected in 96% of the lung cancers and in 78% of the preneoplastic/preinvasive lesions. The allele losses were often multiple and discontinuous, with areas of LOH interspersed with areas of retention of heterozygosity. Most small cell lung carcinomas (91%) and squamous cell carcinomas (95%) demonstrated larger 3p segments of allele loss, whereas most (71%) of the adenocarcinomas and preneoplastic/preinvasive lesions had smaller chromosome areas of 3p allele loss. There was a progressive increase in the frequency and size of 3p allele loss regions with increasing severity of histopathological preneoplastic/preinvasive changes. In analyses of the specific parental allele lost comparing 42 preneoplastic/preinvasive foci with those lost in the lung cancer in the same patient (n = 10), the same parental allele was lost in 88% of 244 comparisons for 28 3p markers (P = 1.2 x 10(-36) for this occurring by chance). This indicates the occurrence of allele-specific loss in these foci similar to that seen in the tumor by a currently unknown mechanism. Analysis of all of the data indicated multiple regions of localized 3p allele loss including telomere-D3S1597, D3S1111-D3S2432, D3S2432-D3S1537, D3S1537, D3S1537-D3S1612, D3S4604/Luca19.1-D3S4622/Luca4.1, D3S4624/Luca2.1, D3S4624/Luca2.1-D3S1582, D3S1766, D3S1234-D3S1300 (FHIT/FRA3B region centered on D3S1300), D3S1284-D3S1577 (U2020/DUTT1 region centered on D3S1274), and D3S1511-centromere. A panel of six markers in the 600-kb 3p21.3 deletion region showed loss in 77% of the lung cancers, 70% of normal or preneoplastic/preinvasive lesions associated with lung cancer, and 49% of 47 normal, mildly abnormal, or preneoplastic/preinvasive lesions found in smokers without lung cancer; however, loss was seen in 0% of 18 epithelial samples from seven never smokers. The 600-kb 3p21.3 region and the 3p14.2 (FHIT/FRA3B) and 3p12 (U2020/DUTT1) regions were common, independent sites of breakpoints (retention of heterozygosity by some markers and LOH by other markers in the immediate region). We conclude that 3p allele loss is nearly universal in lung cancer pathogenesis; involves multiple, discrete, 3p LOH sites that often show a "discontinuous LOH" pattern in individual tumors; occurs in preneoplastic/preinvasive lesions in smokers with and without lung cancer (multiple lesions often lose the same parental allele); frequently involves breakpoints in at least three very small defined genomic regions; and appears to have allele loss and breakpoints first occurring in the 600-kb 3p21.3 region. These findings are consistent with previously reported LOH studies in a variety of tumors showing allele loss occurring by mitotic recombination and induced by oxidative damage.

Construction of a 600-kilobase cosmid clone contig and generation of a transcriptional map surrounding the lung cancer tumor suppressor gene (TSG) locus on human chromosome 3p21.3: progress toward the isolation of a lung cancer TSG.

The critical region on human chromosome 3p21.3 harboring a putative lung cancer tumor suppressor gene (TSG) was previously defined by allelotyping and recently refined by overlapping homozygous deletions. We report the construction of a 700-kb (cosmid and one P1 phage) clone contig covering the deletion overlap and its flanks. The minimal set of 23 cosmids comprises 600 kb and is extended by one P1 phage to 700 kb to cover the distal breakpoint of the overlap. The clone contig was extensively characterized by restriction and expression mapping to produce high resolution physical and transcription maps of the cloned region. Potential transcribed fragments were detected by hybridization with PCR-amplified cDNA libraries, direct cDNA selection "zoo" blotting, cDNA screening, and identification of 24 CpG islands. Thus far, 15 new genes represented by partial or full-length cDNAs were isolated, characterized, and precisely positioned on the contig. Two previously cloned genes, namely GNAI-2 and GNAT-1, were also positioned. In addition, the telomeric breakpoint of the NCI H740 deletion and centromeric breakpoint of the overlapping GLC20 deletion were discovered and mapped to define precisely the candidate TSG region. This large cosmid clone contig and high resolution maps will prove crucial in the identification of the lung cancer TSG(s).

Constitutional von Hippel-Lindau (VHL) gene deletions detected in VHL families by fluorescence in situ hybridization.

von Hippel-Lindau (VHL) disease is an autosomal dominantly inherited cancer syndrome predisposing to a variety of tumor types that include retinal hemangioblastomas, hemangioblastomas of the central nervous system, renal cell carcinomas, pancreatic cysts and tumors, pheochromocytomas, endolymphatic sac tumors, and epididymal cystadenomas [W. M. Linehan et al., J. Am. Med. Assoc., 273: 564-570, 1995; E. A. Maher and W. G. Kaelin, Jr., Medicine (Baltimore), 76: 381-391, 1997; W. M. Linehan and R. D. Klausner, In: B. Vogelstein and K. Kinzler (eds.), The Genetic Basis of Human Cancer, pp. 455-473, McGraw-Hill, 1998]. The VHL gene was localized to chromosome 3p25-26 and cloned [F. Latif et al., Science (Washington DC), 260: 1317-1320, 1993]. Germline mutations in the VHL gene have been detected in the majority of VHL kindreds. The reported frequency of detection of VHL germline mutations has varied from 39 to 80% (J. M. Whaley et al., Am. J. Hum. Genet., 55: 1092-1102, 1994; Clinical Research Group for Japan, Hum. Mol. Genet., 4: 2233-2237, 1995; F. Chen et al., Hum. Mutat., 5: 66-75, 1995; E. R. Maher et al., J. Med. Genet., 33: 328-332, 1996; B. Zbar, Cancer Surv., 25: 219-232, 1995). Recently a quantitative Southern blotting procedure was found to improve this frequency (C. Stolle et al., Hum. Mutat., 12: 417-423, 1998). In the present study, we report the use of fluorescence in situ hybridization (FISH) as a method to detect and characterize VHL germline deletions. We reexamined a group of VHL patients shown previously by single-strand conformation and sequencing analysis not to harbor point mutations in the VHL locus. We found constitutional deletions in 29 of 30 VHL patients in this group using cosmid and P1 probes that cover the VHL locus. We then tested six phenotypically normal offspring from four of these VHL families: two were found to carry the deletion and the other four were deletion-free. In addition, germline mosaicism of the VHL gene was identified in one family. In sum, FISH was found to be a simple and reliable method to detect VHL germline deletions and practically useful in cases where other methods of screening have failed to detect a VHL gene abnormality.

Gene structure of the human MET proto-oncogene.

By direct sequencing of cosmids using primers designed from the known cDNA sequence, we identified 19 exons in the human MET proto-oncogene, and sequenced the corresponding 5' and 3' exon-intron junctions. By homology search in the database of the Washington University Genome Sequence Center (GSC), we identified one additional exon. These 20 exons, together with a previously reported exon, bring the total exon number of MET to 21. Oligonucleotide primers were designed to amplify each exon and adjacent intronic sequences to permit examination of each exon for mutations. By restriction mapping, we assembled a 110 kb genomic contig that covered almost the entire MET proto-oncogene. This information is relevant for the screening of recently reported mutations of the MET gene which cause hereditary papillary renal carcinomas and for the search for additional mutations of the same gene which may play a role in the pathogenesis of common human carcinomas including carcinomas of the breast, ovary and pancreas.