Tuberous sclerosis complex (TSC) gene involvement in sporadic tumours.

In tuberous sclerosis patients, inactivation of the tuberous sclerosis complex tumour-suppressor genes TSC1 and TSC2 contributes to the development of a wide range of hamartomatous lesions. These patients do not, however, show an increased risk of the common adult solid cancers. Recent evidence that the TSC genes play a role in the phosphoinositide 3-kinase pathway, a pathway whose dysregulation is implicated in a wide range of human malignancies, raises the possibility that their inactivation could contribute to the development of some sporadic cancers. To date the only evidence for this comes from the finding of mutations of TSC1 in bladder cancer. The mutation spectrum of TSC1 in bladder cancer and functional evidence from TSC1 -gene-replacement studies in bladder tumour cells will be presented. The literature on genetic changes in several other sporadic epithelial cancers reveals relatively common deletions in the region of the TSC genes. In ovarian and gall bladder carcinoma and non-small-cell carcinoma of the lung, deletions in both 16p13 and 9q34 are found at significant frequency. Mutation analyses in such tumours are now merited.

A sequence-ready 840-kb PAC contig spanning the candidate tumor suppressor locus DBC1 on human chromosome 9q32-q33.

A putative tumor suppressor locus involved in bladder cancer has been mapped to human chromosome 9q32-q33 and designated DBC1. Our previous microsatellite-based deletion mapping study indicated that DBC1 was localized between D9S1848 and AFMA239XA9. We have constructed an 840-kb sequence-ready contig composed of bacteriophage P1-derived artificial chromosomes (PACs), which encompasses DBC1. Clones were initially identified by screening a PAC library with markers localized to the region by physical mapping, and subsequently PAC end probes were used to complete the contig. This contig contains a minimum tiling path of six PAC clones between D9S1848 and AFMA239XA9. Three expressed sequence tags (ESTs) were mapped to the DBC1 region by screening 24 ESTs mapped to the surrounding area by radiation hybrids. One represented the gene for DBCCR1, a known candidate for DBC1, and the other two were novel. This contig and preliminary expression map form the basis for the identification of the bladder cancer tumor suppressor gene in this region.

Mutation of the 9q34 gene TSC1 in sporadic bladder cancer.

Deletions involving chromosome 9 occur in more than 50% of human bladder cancers of all grades and stages. Most involve loss of the whole chromosome or of an entire chromosome arm but some small deletions are found which can be used to define critical regions which may contain tumour suppressor genes. We have localized such a critical region of deletion at 9q34 between the markers D9S149 and D9S66, an interval which contains the Tuberous Sclerosis gene TSC1. Single strand conformation polymorphism (SSCP) and sequence analysis of TSC1 in bladder tumours and cell lines with 9q34 loss of heterozygosity (LOH) has identified five mutations in retained TSC1 alleles. Our results support the hypothesis that TSC1 can act as a bladder tumour suppressor gene.

Clustered cadherin genes: a sequence-ready contig for the desmosomal cadherin locus on human chromosome 18.

We describe the assembly of a cosmid and PAC contig of approximately 700 kb on human chromosome 18q12 spanning the DSC and DSG genes coding for the desmocollins and desmogleins. These are members of the cadherin superfamily of calcium-dependent cell adhesion proteins present in the desmosome type of cell junction found especially in epithelial cells. They provide the strong cell-cell adhesion generated by this type of cell junction for which expression of both a desmocollin and a desmoglein is required. In the autoimmune skin diseases pemphigus foliaceous and pemphigus vulgaris (PV), where the autoantigens are, respectively, encoded by the DSG1 and DSG3 genes, severe areas of acantholysis (cell separation), potentially life-threatening in the case of PV, are evident. Dominant mutations in the DSG1 gene causing striate palmoplantar keratoderma result in hyperkeratosis of the skin on the parts of the body where pressure and abrasion are greatest, viz., on the palms and soles. These genes are also candidate tumor suppressor genes in squamous cell carcinomas and other epithelial cancers. We have screened two chromosome 18-specific cosmid libraries by hybridization with previously isolated YAC clones and DSC and DSG cDNAs, and a whole genome PAC library, both by hybridization with the YACs and by screening by PCR using cDNA sequences and YAC end sequence. The contigs were extended by further PCR screens using STSs generated by vectorette walking from the ends of the cosmids and PACs, together with sequence from PAC ends. Despite screening of two libraries, the cosmid contig still had four gaps. The PAC contig filled these gaps and in fact covered the whole locus. The positions of 45 STSs covering the whole of this region are presented. The desmocollin and desmoglein genes, which are about 30-35 kb in size, are quite well separated at approximately 20-30 kb apart and are arranged in two clusters, one DSC cluster and one DSG cluster, which are transcribed outward from the interlocus region. The order of the genes is correlated with the spatial order of gene expression in the developing mouse embryo, and this, and previous transgenic experiments, suggests that long-range genetic elements that coordinate expression of these genes may be present. The complete bacterial clone contig described in this paper is thus a resource not only for future sequencing but also for investigations into the control of expression of these clustered genes.

Dynamic molecular combing: stretching the whole human genome for high-resolution studies.

DNA in amounts representative of hundreds of eukaryotic genomes was extended on silanized surfaces by dynamic molecular combing. The precise measurement of hybridized DNA probes was achieved directly without requiring normalization. This approach was validated with the high-resolution mapping of cosmid contigs on a yeast artificial chromosome (YAC) within yeast genomic DNA. It was extended to human genomic DNA for precise measurements ranging from 7 to 150 kilobases, of gaps within a contig, and of microdeletions in the tuberous sclerosis 2 gene on patients' DNA. The simplicity, reproducibility, and precision of this approach makes it a powerful tool for a variety of genomic studies.

A 1.7-megabase sequence-ready cosmid contig covering the TSC1 candidate region in 9q34.

The disease gene TSC1 has been genetically mapped to human chromosome region 9q34, in a 4-cM interval between the markers D9S149 and D9S114. Within this interval there is conflicting genetic evidence as to the finer localization of the gene. We have used finger-printing methods and hybridization to produce a 1.7-Mb overlapping clone map covering the TSC1 candidate region, with a single gap of 20 kb. We have localized 12 previously cloned genes and 17 genetic markers on this map and have confirmed the order of the genetic map. This deep set of overlapping clones is now ready to be used for candidate gene isolation, for transcription studies, or for sequencing.

Fucosyltransferase genes are dispersed in the genome: FUT7 is located on 9q34.3 distal to D9S1830.

Synthesis of A, B, H, Lewis and related histo-blood group antigens is catalyzed by different fucosyltransferases. Enzymatic acceptor specificity and tissue expression permit the definition of 2 types of alpha-2-fucosyltransferases and 5 types of alpha-3-fucosyltransferases encoded by specific genes registered as FUT1 to FUT7. We have previously assigned FUT4 to 11q21, the cluster FUT1-FUT2 to 19q13.3 and the cluster FUT6-FUT3-FUT5 to 19p13.3. The last gene cloned (FUT7) encodes an alpha-3-fucosyltransferase expressed in leukocytes which synthesizes the sialyl Le antigen, a selectin ligand. We have localized this gene by PCR assay using somatic cell hybrids, which retain rearrangements of chromosome 9 characterized in respect with the genetic microsatellite map, and then by screening a cosmid library. We assign FUT7 to chromosome band 9q34.3 telomeric to D9S1830 and close to the genes ABC2 and C8G.

Allelic loss is frequent in tuberous sclerosis kidney lesions but rare in brain lesions.

Tuberous sclerosis (TSC) is an autosomal dominant disorder characterized by seizures, mental retardation, and hamartomatous lesions. Although hamartomas can occur in almost any organ, they are most common in the brain, kidney, heart, and skin. Allelic loss or loss of heterozygosity (LOH) in TSC lesions has previously been reported on chromosomes 16p13 and 9q34, the locations of the TSC2 and TSC1 genes, respectively, suggesting that the TSC genes act as tumor-suppressor genes. In our study, 87 lesions from 47 TSC patients were analyzed for LOH in the TSC1 and TSC2 chromosomal regions. Three findings resulted from this analysis. First, we confirmed that the TSC1 critical region is distal to D9S149. Second, we found LOH more frequently on chromosome 16p13 than on 9q34. Of the 28 patients with angiomyolipomas or rhabdomyomas, 16p13 LOH was detected in lesions from 12 (57%) of 21 informative patients, while 9q34 LOH was detected in lesions from only 1 patient (4%). This could indicate that TSC2 tumors are more likely than TSC1 tumors to require surgical resection or that TSC2 is more common than TSC1 in our patient population. It is also possible that small regions of 9q34 LOH were missed. Lastly, LOH was found in 56% of renal angiomyolipomas and cardiac rhabdomyormas but in only 4% of TSC brain lesions. This suggests that brain lesions can result from different pathogenic mechanisms than kidney and heart lesions.

Mapping the human Y chromosome by fingerprinting cosmid clones.

We have used Y-specific cosmid clones in a random fingerprinting approach to build contigs on the human Y chromosome. Clones derived from two libraries have been analyzed. The construction of one library is described here, the second was the Y chromosome-specific library LLOYNCO3 "M" (Lawrence Livermore National Laboratory). To date, we have fingerprinted 4430 cosmids: 377 contigs have been constructed containing from 2 to 39 clones. Along with the singletons, we estimate that we have covered 72.5% of the euchomatic portion of the Y chromosome with fingerprinted clones. Sequence tagged sites are being used to anchor cosmids and contigs onto the YAC framework.

The genetics of tasting in mice. VII. Glycine revisited, and the chromosomal location of Sac and Soa.

Previous work which appeared to show that some strains of mice taste glycine solutions as bitter has been found to be in error. The bitterness came from copper glycinate which formed in the brass drinking spouts. Taste testing with copper glycinate shows that the genetical data identifying the gene Glb are still valid. The close linkage of Glb and Rua has been confirmed. Most strains of mice prefer glycine solution to water, presumably because the glycine tastes sweet. The degree of preference for glycine is correlated with the degree of preference for other sweet substances such as saccharin or acesulfame. The gene dpa appears not to be involved. The sweetness tasting gene Sac has been mapped to chromosome 4 at 8.1 +/- 3.4 cM distal to Nppa (formerly Pnd). The bitterness tasting gene Soa is very closely linked to Prp on chromosome 6 (no recombinants among 67 backcross progeny). It is suggested that the sweetness and bitterness tasting genes have descended from a common ancestral tasting gene which existed before the tetraploidization of the genome which took place in early vertebrate evolution.

Regional localization of 64 cosmid contigs, including 18 genes and 14 markers, to intervals on human chromosome 9q34.

A fluorescence in situ hybridization map of distal human chromosome 9q has been produced by mapping cosmid clones to metaphase chromosomes with balanced reciprocal translocations. This is a very accurate method of mapping, as clones are localized by their position with respect to the breakpoint in addition to cytogenetic banding. By using three lymphoblastoid cell lines with translocation breakpoints within 9q34, we have localized 18 genes and 14 DNA markers to one of four intervals on the chromosome. Cosmid contigs exist around 16 of these genes and 12 of these markers. A further 43 contigs have also been mapped, but they are as yet anonymous.

Cosmid contigs spanning 9q34 including the candidate region for TSC1.

The tuberous sclerosis disease gene TSC1 has been mapped to 9q34. However, its precise localisation has proved problematic because of conflicting recombination data. Therefore, we have attempted to clone the entire target area into cosmid contigs prior to gene isolation studies. We have used Alu-PCR from irradiation hybrids to produce complex probes from the target region which have identified 1,400 cosmids from a chromosome-specific library. These, along with cosmids obtained by other methods, have been assembled into contigs by a fingerprinting technique. We estimate that we have obtained most of the region in cosmid contigs. These cosmids are a resource for the isolation of expressed genes within the TSC1 interval. In addition, the cosmid contig assembly has demonstrated a number of previously unknown physical connections between genes and markers in 9q34.

The use of irradiation and fusion gene transfer (IFGT) hybrids to isolate DNA clones from human chromosome region 9q33-q34.

We have generated somatic cell hybrids containing fragments of human chromosome arm 9q by an irradiation and fusion technique. No selection for human material was imposed, but of 23 clones analyzed most contained human DNA sequences and many contained multiple fragments of the human chromosome arm. A hybrid that appears to contain only two small fragments of human DNA from the regions of q33 and q34 has been used as a source from which to clone probes specific to those areas of the chromosome.