Cloning and characterization of 13 novel transcripts and the human RGS8 gene from the 1q25 region encompassing the hereditary prostate cancer (HPC1) locus.

The aim of this study was to develop a saturated transcript map of the region encompassing the HPC1 locus to identify the susceptibility genes involved in hereditary prostate cancer (OMIM 176807) and hyperparathyroidism-jaw tumor syndrome (OMIM 145001). We previously reported the generation of a 6-Mb BAC/PAC contig of the candidate region and employed various strategies, such as database searching, exon-trapping, direct cDNA hybridization, and sample sequencing of BACs, to identify all potential transcripts. These efforts led to the identification and precise localization on the BAC contig of 59 transcripts representing 22 known genes and 37 potential transcripts represented by ESTs and exon traps. Here we report the detailed characterization of these ESTs into full-length transcript sequences, their expression pattern in various tissues, their genomic organization, and their homology to known genes. We have also identified an Alu insertion polymorphism in the intron of one of the transcripts. Overall, data on 13 novel transcripts and the human RGS8 gene (homologue of the rat RGS8 gene) are presented in this paper. Ten of the 13 novel transcripts are expressed in prostate tissue and represent positional candidates for HPC1.

Pkd1 unusual DNA conformations are recognized by nucleotide excision repair.

The 2.5-kilobase pair poly(purine.pyrimidine) (poly(R.Y)) tract present in intron 21 of the polycystic kidney disease 1 (PKD1) gene has been proposed to contribute to the high mutation frequency of the gene. To evaluate this hypothesis, we investigated the growth rates of 11 Escherichia coli strains, with mutations in the nucleotide excision repair, SOS, and topoisomerase I and/or gyrase genes, harboring plasmids containing the full-length tract, six 5'-truncations of the tract, and a control plasmid (pSPL3). The full-length poly(R.Y) tract induced dramatic losses of cell viability during the first few hours of growth and lengthened the doubling times of the populations in strains with an inducible SOS response. The extent of cell loss was correlated with the length of the poly(R.Y) tract and the levels of negative supercoiling as modulated by the genotype of the strains or drugs that specifically inhibited DNA gyrase or bound to DNA directly, thereby affecting conformations at specific loci. We conclude that the unusual DNA conformations formed by the PKD1 poly(R.Y) tract under the influence of negative supercoiling induced the SOS response pathway, and they were recognized as lesions by the nucleotide excision repair system and were cleaved, causing delays in cell division and loss of the plasmid. These data support a role for this sequence in the mutation of the PKD1 gene by stimulating repair and/or recombination functions.

The human RGL (RalGDS-like) gene: cloning, expression analysis and genomic organization.

Ral GDP dissociation stimulator (RalGDS) and its family members RGL, RLF and RGL2 are involved in Ras and Ral signaling pathways as downstream effector proteins. Here we report the precise localization and cloning of two forms of human RGL gene differing at the amino terminus. Transcript A, cloned from liver cDNA libraries has the same amino terminus as the mouse RGL, whereas transcript B cloned from brain has a substitution of 45 amino acids for the first nine amino acids. At the genomic level, exon 1 of transcript A is replaced by two alternative exons (1B1 and 1B2) in transcript B. Both forms share exons 2 through 18. The human RGL protein shares 94% amino acid identity with the mouse protein. Northern blot analysis shows that human RGL is expressed in a wide variety of tissues with strong expression being seen in the heart, brain, kidney, spleen and testis.

A 6-Mb high-resolution physical and transcription map encompassing the hereditary prostate cancer 1 (HPC1) region.

Several hereditary disease loci have been genetically mapped to the chromosome 1q24-q31 interval, including the hereditary prostate cancer 1 (HPC1) locus. Here, we report the construction of a 20-Mb yeast artificial chromosome contig and a high-resolution 6-Mb sequence-ready bacterial artificial chromosome (BAC)/P1-derived artificial chromosome (PAC) contig of 1q25 by sequence and computational analysis, STS content mapping, and chromosome walking. One hundred thirty-six new STSs, including 10 novel simple sequence repeat polymorphisms that are being used for genetic refinement of multiple disease loci, have been generated from this contig and are shown to map to the 1q25 interval. The integrity of the 6-Mb BAC/PAC contig has been confirmed by restriction fingerprinting, and this contig is being used as a template for human chromosome 1 genome sequencing. A transcription mapping effort has resulted in the precise localization of 18 known genes and 31 ESTs by database searching, exon trapping, direct cDNA hybridization, and sample sequencing of BACs from the 1q25 contig. An additional 11 known genes and ESTs have been placed within the larger 1q24-q31 interval. These transcription units represent candidate genes for multiple hereditary diseases, including HPC1.

Somatic mutation of TSSC5, a novel imprinted gene from human chromosome 11p15.5.

We previously reported the isolation of a 2.5 Mb tumor-suppressing subchromosomal transferable fragment (STF) from 11p15.5 and the identification of nine known genes and four novel genes within this STF. We now report the isolation of a fifth novel cDNA, tumor-suppressing STF cDNA 5, designated TSSC5, located within the STF. TSSC5 encodes a predicted protein of 424 amino acids. Sequence analysis suggests that TSSC5 is a membrane protein with 10 transmembrane segments, and it is located between two imprinted genes, p57KIP2 and TSSC3. Northern blot hybridization revealed a 1.6-kb transcript in multiple adult tissues and in fetal liver and kidney, consistent with a potential role in embryonal tumors. We also found that TSSC5 is imprinted with preferential expression from the maternal chromosome. Reverse transcription-PCR analysis of TSSC5 revealed frequent occurrence of aberrant RNA splicing, which deleted exons 4, 5, and 6 in Wilms' tumors. Mutational analysis of TSSC5 by direct DNA sequencing of exons revealed a base substitution of G1120A in a Wilms' tumor, matched normal kidney, and the patient's mother, changed Arg at codon 309 to Gln. The G1120A substitution thus represents either a rare polymorphism or a tumor-predisposing mutation, because the mutant allele was of maternal origin and preferentially expressed in the patient's tissue. A second base substitution, C892T, was found in a lung cancer, changing Ser at codon 233 to Phe. This substitution was absent from the matched normal tissue and thus represented a somatic mutation. We also found loss of heterozygosity in the lung cancer, suggesting that TSSC5 may be a conventional tumor suppressor gene in the adult human lung and an imprinted tumor suppressor gene in the fetal kidney.

A 2.5-Mb transcript map of a tumor-suppressing subchromosomal transferable fragment from 11p15.5, and isolation and sequence analysis of three novel genes.

11p15.5 is an important tumor-suppressor gene region, showing loss of heterozygosity in Wilms tumor, rhabdomyosarcoma, adrenocortical carcinoma, and lung, ovarian, and breast cancer. We previously mapped directly by genetic complementation a subtransferable fragment (STF) harboring an embryonal tumor-suppressor gene and spanning about 2.5 Mb. We have now mapped the centromeric end of this STF between D11S988 and D11S12 and its telomeric end between D11S1318 and TH. We have isolated a complete contig of PAC, P1, BAC, and cosmid genomic clones spanning the entire 2.5-Mb region defined by this STF, as well as more than 200 exons from these genomic clones using exon trapping. We have isolated genes in this region by directly screening DNA libraries as well as by database searching for ESTs. Nine of these genes have been reported previously by us and by others. However, the initial mapping of most of those genes was based on FISH or somatic cell hybrid analysis, and here we precisely define their physical location. These genes include RRM1, GOK (D11S4896E), Nup98, CARS, hNAP2 (NAP1L4), p57KIP2 (CDKN1C), KVLQT1 (KCNA9), TAPA-1, and ASCL2. In addition, we have identified several novel genes in this region, three of which, termed TSSC1, TSSC2, and TSSC3, are reported here. TSSC1 shows homology to Rb-associated protein p48 and chromatin assembly factor CAF1, and it is located between GOK and Nup98. TSSC2 is homologous to Caenorhabditis elegans beta-mannosyl transferase, and it lies between Nup98 and CARS. TSSC3 shows homology to mouse TDAG51, which is implicated in FasL-mediated apoptosis, and it is located between hNAP2 and p57KIP2. Thus, these genes may play a role in malignancies that involve this region.

Polycystin: in vitro synthesis, in vivo tissue expression, and subcellular localization identifies a large membrane-associated protein.

The primary structure of polycystin predicts a large integral membrane protein with multiple cell recognition motifs, but its function remains unknown. Insight into polycystin's normal function and its role in the development of autosomal dominant polycystic kidney disease (PKD1) requires the assembly of an extensive collection of molecular reagents to examine its expression and create model systems for functional studies. Development of these crucial reagents has been complicated due to the presence of transcriptionally active homologous loci. We have assembled the authentic full-length PKD1 cDNA and demonstrated expression of polycystin in vitro. Polyclonal antibodies directed against distinct extra- and intracellular domains specifically immunoprecipitated in vitro translated polycystin. The panel of antibodies was used to determine localization of polycystin in renal epithelial and endothelial cell lines and tissues of fetal, adult, and cystic origins. In normal adult kidney and maturing fetal nephrons, polycystin expression was confined to epithelial cells of the distal nephron and vascular endothelial cells. Expression in the proximal nephron was only observed after injury-induced cell proliferation. Polycystin expression was confined to ductal epithelium in liver, pancreas, and breast, and restricted to astrocytes in normal brain. We report clear evidence for the membrane localization of polycystin by both tissue sections and by confocal microscopy in cultured renal and endothelial cells. Interestingly, when cultured cells made cell-cell contact, polycystin was localized to the lateral membranes of cells in contact. These data suggest that polycystin is likely to have a widespread role in epithelial cell differentiation and maturation and in cell-cell interactions.

The NTN2L gene encoding a novel human netrin maps to the autosomal dominant polycystic kidney disease region on chromosome 16p13.3.

The netrins define a family of chemotropic factors that have been shown to play a central role in axon guidance. We identified two exon traps encoding netrin-like sequences during the assembly of a transcriptional map for the genomic interval surrounding the polycystic kidney disease type 1 and tuberous sclerosis type 2 genes. We describe the characterization of a novel human netrin-2-like gene, designated NTN2L, and its transcript. The genomic interval containing the NTN2L gene was sequenced, and the coding region was predicted based on computer analysis. The structure of the NTN2L gene has been confirmed utilizing nested RT-PCR. The NTN2L gene is predicted to encode a 580-amino-acid protein having homology to the chicken and Drosophila netrins and to Caenorhabditis elegans UNC-6. The NTN2L gene has a restricted pattern of expression; its transcript is undetectable by Northern analysis in all tissues examined, but can be recovered from spinal cord RNA by RT-PCR. This report represents the first description and characterization of a human netrin.

The cloning of a human ABC gene (ABC3) mapping to chromosome 16p13.3.

The ATP binding cassette (ABC) transporters, or traffic ATPases, constitute a large family of proteins responsible for the transport of a wide variety of substrates across cell membranes in both prokaryotic and eukaryotic cells. We describe a human ABC protein with regions of strong homology to the recently described murine ABC1 and ABC2 transporters. The gene for this novel protein, human ABC3, maps near the polycystic kidney disease type 1 (PKD1) gene on chromosome 16p13.3. The ABC3 gene is expressed at highest levels in lung compared to other tissues.

A novel ribosomal protein L3-like gene (RPL3L) maps to the autosomal dominant polycystic kidney disease gene region.

A full-length cDNA encoding a novel ribosomal protein L3 gene was isolated and sequenced. The deduced protein sequence is 407 amino acids long and shows 77% identity to other known mammalian ribosomal protein L3 genes, which are themselves highly conserved. Southern blot analysis of human genomic DNA suggests that this novel gene is single copy. While the previously identified human ribosomal protein L3 gene has ubiquitous expression in all tissues surveyed, the novel gene described herein is strongly expressed in skeletal muscle and heart tissue, with low levels of expression in the pancreas. This novel gene, RPL3L, is located in a gene-rich region near the PKD1 and TSC2 genes on chromosome 16p13.3.

The region surrounding the PKD1 gene: a 700-kb P1 contig from a YAC-deficient interval.

As part of an effort to identify the gene responsible for the predominant form of polycystic kidney disease (PKD1), we used a gridded human P1 library for contig assembly. The interval of interest, a 700-kb segment on chromosome 16p13.3, can be physically delineated by the genetic markers D16S125 and D16S84 and chromosomally characterized as a GC-rich isochore enriched for CpG islands, genes, and Alu-like repeats. Our attempts to recover CEPH YACs that encode this region of chromosome 16 were unsuccessful. However, we screened an arrayed P1 library using 15 distinct probes from the D16S125-D16S84 interval and identified 56 independent P1 clones. Only one probe from the interval was unsuccessful in identifying a P1 clone. Forty-four P1 clones were determined to be unique based on restriction enzyme analysis, and 42 of these were found to originate from chromosome 16p13.3, based on FISH to metaphase chromosomes. The 700-kb interval could be defined by a single sequence-ready contig comprised of 12 P1 clones and 1 cosmid clone. Our studies support the use of multiple libraries to generate the requisite physical reagents for positional cloning and encourage the use of Escherichia coli-based large-insert cloning systems to recover clones from YAC-deficient chromosomal intervals.

Generation of a transcriptional map for a 700-kb region surrounding the polycystic kidney disease type 1 (PKD1) and tuberous sclerosis type 2 (TSC2) disease genes on human chromosome 16p3.3.

A 700-kb region of DNA in human chromosome 16p13.3 has been shown to contain the polycystic kidney disease 1 (PKD1) and the tuberous sclerosis type 2 (TSC2) disease genes. An estimated 20 genes are present in this region of chromosome 16. We have initiated studies to identify transcribed sequences in this region using a bacteriophage P1 contig containing 700 kb of DNA surrounding the PKD1 and TSC2 genes. We have isolated 96 unique exon traps from this interval, with 23 of the trapped exons containing sequences from five genes known to be in the region. Thirty exon traps have been mapped to additional transcription units based on data base homologies, Northern analysis, or their presence in cDNA or reverse transcriptase (RT)-PCR products. We have mapped the human RNPS gene to the cloned interval. We have obtained cDNAs or RT-PCR products from eight novel genes, with sequences from seven of these genes having homology to sequences in the data bases. Two of the newly identified genes represent human homologs for rat and murine genes identified previously. We have isolated three exon traps with homology to sequences in the data bases but have been unable to confirm the presence of these exon traps in expressed sequences. In addition, we have isolated 43 exon traps that do not map to our existing cDNAs or PCR products and have no homology to sequences in the data bases. In this report we present a transcriptional map for the 700 kb of DNA surrounding the PKD1 and TSC2 genes.

Positional cloning of a novel potassium channel gene: KVLQT1 mutations cause cardiac arrhythmias.

Genetic factors contribute to the risk of sudden death from cardiac arrhythmias. Here, positional cloning methods establish KVLQT1 as the chromosome 11-linked LQT1 gene responsible for the most common inherited cardiac arrhythmia. KVLQT1 is strongly expressed in the heart and encodes a protein with structural features of a voltage-gated potassium channel. KVLQT1 mutations are present in affected members of 16 arrhythmia families, including one intragenic deletion and ten different missense mutations. These data define KVLQT1 as a novel cardiac potassium channel gene and show that mutations in this gene cause susceptibility to ventricular tachyarrhythmias and sudden death.

A 2.5 kb polypyrimidine tract in the PKD1 gene contains at least 23 H-DNA-forming sequences.

A pyrimidine-rich element (PyRE), present in the 21st intron of the PKD1 gene, posed a significant obstacle in determining the primary structure of the gene. Only cycle sequencing of nested, single-stranded phage templates of the CT-rich strand enabled complete and accurate sequence data. Similar attempts on the GA-rich strand were unsuccessful. The resulting primary structure showed the 3 kb 21st intron to contain a 2.5 kb PyRE, whose sense-strand is 97% C + T. The PKD1 PyRE does not appear to be polymorphic based on RFLP analysis of DNA from 6 unrelated individuals digested with 9 different restriction enzymes. This is the largest pyrimidine tract sequenced to date, being over twice as large as those previously identified and shows little homology to other polypyrimidine tracts. Additional analysis of this PyRE revealed the presence of 23 mirror repeats with stem lengths of at least 10 nucleotides. The 23 H-DNA-forming sequences in the PKD1 PyRE exceed the cumulative total of 22 found in 157 human genes that have been completely sequenced. The mirror repeats confer this region of the PKD1 gene with a strong probability of forming H-DNA or triplex structures under appropriate conditions. Based on studies with PyRE found in other eukaryotic genes, the PKD1 PyRE may play a role in regulating PKD1 expression, and its potential for forming an extended triplex structure may explain some of the observed instability in the PKD1 locus.

Increased exon-trapping efficiency through modifications to the pSPL3 splicing vector.

Exon trapping allows for the rapid identification and cloning of coding regions from cloned eukaryotic DNA. In preliminary experiments, we observed two phenomena which limited the exon-trapping efficiency of pSPL3-based systems. The first factor that affected performance was revealed when we found that up to 50% of the putative trapped exons contained sequences derived from the intron of the pSPL3 trapping vector. Removal of the DNA sequences responsible for the cryptic splice event from the original splicing vector resulted in a new vector, pSPL3B. We demonstrate that pSPL3B virtually eliminates pSPL3-only spliced products while maximizing the proportion of exon traps containing genomic DNA (> 98%). The other step which impacted performance was our observation that a majority of the ampicillin-resistant (APR) clones produced after shotgun subcloning from ApR cosmids into pSPL3 were untrappable, pSPL3-deficient, recircularized cosmid vector fragments. Replacement of the pSPL3 ApR gene with the CmR cassette encoding chloramphenicol (Cm) acetyltransferase enabled selection for only pSPL3-containing CmR clones. We show a 30-40-fold increase in the initial subcloning efficiency of cosmid-derived fragments with pSPL3-CAM, when compared to pSPL3. The collective vector alterations described improve the overall exon-trapping efficiency of the pSPL3-based trapping system.

Analysis of the genomic sequence for the autosomal dominant polycystic kidney disease (PKD1) gene predicts the presence of a leucine-rich repeat. The American PKD1 Consortium (APKD1 Consortium).

The complete genomic sequence of the gene responsible for the predominant form of polycystic kidney disease, PKD1, was determined to provide a framework for understanding the biology and evolution of the gene, and to aid in the development of molecular diagnostics. The DNA sequence of a 54 kb interval immediately upstream of the poly(A) addition signal sequence of the PKD1 transcript was determined, and then analyzed using computer methods. A leucine-rich repeat (LRR) motif was identified within the resulting predicted protein sequence of the PKD1 gene. By analogy with other LRR-containing proteins, this may explain some of the disease-related renal alterations such as mislocalization of membrane protein constituents and changes in the extracellular matrix organization. Finally, comparison of the genomic sequence and the published partial cDNA sequence showed several differences between the two sequences. The most significant difference detected predicts a novel carboxy-terminus for the PKD1 gene product.

Site-specific mutagenesis by O6-alkylguanines located in the chromosomes of mammalian cells: influence of the mammalian O6-alkylguanine-DNA alkyltransferase.

A plasmid was constructed in which a single guanine residue was replaced with either O6-methylguanine or O6-ethylguanine, two of the DNA adducts formed by carcinogenic alkylating agents. The vectors were introduced in parallel into a pair of Chinese hamster ovary cells, in which one member of the pair was deficient in the repair enzyme O6-alkylguanine-DNA alkyltransferase (mex-) and the other was proficient in this activity (mex+). The vectors integrated into and replicated within the respective host genomes. After intrachromosomal replication, the DNA sequence in the vicinity of the originally adducted site of each integrated vector was amplified from the host genome by using the polymerase chain reaction and was analyzed for mutations. High levels of mutation were observed from the O6-methylguanine- and O6-ethylguanine-containing vectors replicated in mex- cells (approximately 19% for O6-methylguanine and approximately 11% for O6-ethylguanine). DNA sequencing revealed the induced mutations to be almost exclusively G----A transitions. By contrast, little or no mutagenesis was detected when the adducted vectors were introduced into mex+ cells, indicating the significant role of the O6-alkylguanine-DNA alkyltransferase in the repair of O6-methylguanine and O6-ethylguanine in these mammalian cells.