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.

Combining serial analysis of gene expression and array technologies to identify genes differentially expressed in breast cancer.

Several methods have been used recently to determine gene expression profiles of cell populations. Here we demonstrate the strength of combining two approaches, serial analysis of gene expression (SAGE) and DNA arrays, to help elucidate pathways in breast cancer progression by finding genes consistently expressed at different levels in primary breast cancers, metastatic breast cancers, and normal mammary epithelial cells. SAGE profiles of 21PT and 21MT, two well-characterized breast tumor cell lines, were compared with SAGE profiles of normal breast epithelial cells to identify differentially expressed genes. A subset of these candidates was then placed on an array and screened with clinical breast tumor samples to find genes and expressed sequence tags that are consistently expressed at different levels in diseased and normal tissues. In addition to finding the predicted overexpression of known breast cancer markers HER-2/neu and MUC-1, the powerful coupling of SAGE and DNA arrays resulted in the identification of genes and potential pathways not implicated previously in breast cancer. Moreover, these techniques also generated information about the differences and similarities of expression profiles in primary and metastatic breast tumors. Thus, combining SAGE and custom array technology allowed for the rapid identification and validation of the clinical relevance of many genes potentially involved in breast cancer progression. These differentially expressed genes may be useful as tumor markers and prognostic indicators and may be suitable targets for various forms of therapeutic intervention.

Evidence for more than one mechanism of action of the glucocorticoid hormones.

The data presented here provide evidence for at least two major cellular responses to the glucocorticoid hormones that do not seem to involve an interaction between the activated hormone-receptor complex and chromatin. We observed that 5mM pyridoxine in L-cell culture medium both increases the intracellular content of free pyridoxal phosphate by about 30% and decreases the glucocorticoid induction of glutamine synthetase to less than 30% of that at the normal (5 microM) concentration of the vitamin. Two other responses to the hormone-a major decrease in the polysome content of the cells and a decrease in the state of phosphorylation of ribosomal protein S6-are unaffected by the 5mM dose of the vitamin. In light of the findings of DiSorbo and Litwack ((1981) Biochem. Biophys. Res. Commun. 99, 1203-1208), pyridoxal phosphate appears to modulate the enzyme-inducing activity of dexamethasone in L-cells but not the polysome and ribosome related changes. These results are consistent with the hypothesis that certain important glucocorticoid induced responses are independent of nuclear function.

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.

Transcriptional properties of chick embryonic erythroid nuclei in vitro.

Chick embryo red blood cells express the embryonic globin and the rRNA genes before 5 days of development but only the adult globin genes and no rRNA after 12 days of development. We have isolated nuclei from the red blood cells of these developmental stages and allowed them to transcribe in vitro. We have analyzed the overall transcriptional properties of these nuclei, the overall activities of RNA polymerases I and II and the sequence-specific activity of RNA polymerase II in the beta-globin domain using cloned genomic hybridization probes. Among our findings are the following. 1) Erythroid nuclei of 5-day embryos are more transcriptionally active than those at 12 days. 2) RNA polymerase I is a very active at 5 days but is off by 12 days. 3) A template-independent activity which yields labeled RNA is present in the red cell nuclei of 12-day but not 5-day embryos. 4) Between 5 and 12 days of development transcriptional modulation delineates embryonic and adult beta-globin domains. 5) These domains exceed the boundaries of the genes themselves by several kilobases. 6) All transcripts which hybridize to sequences in the beta-globin gene region, including repeat sequence transcripts, are transcribed by RNA polymerase II.

Molecular characterization and refined genomic localization of three human potassium ion channel genes.

Potassium ion (K+) channels are essential for a variety of cellular functions in both excitable and non-excitable cells and are likely to be involved in the pathogenesis of some cardiovascular and neurological disorders. To be useful in candidate gene analysis of inherited diseases it is important to identify new K+ channel genes and localize these sequences on the human physical and genetic maps. Using fluorescence in situ hybridization (FISH), we mapped two new K+ channel gene containing cosmids, c2-3a and c9-2a, to chromosomes 1 and 19, respectively. Partial DNA sequencing (c2-3a) and restriction enzyme site analysis (c9-2a) established the uniqueness of each clone. We refined the localization of c2-3a, c9-2a and a previously described K+ channel gene KCNA5, (c7-2), by performing contour length measurements of hybridized metaphase chromosomes and determining the average FLpter% value (fractional length relative to the fixed reference point pter x 100%). When compared to ideograms of banded metaphase chromosomes, these FLpter% values correspond to 12p13.31-->p13.33, 1p13.1-->p21.1 and 19q13.32-->q13.33, respectively. Using FISH, each of these clones has been finely mapped to a different human chromosome indicating a significant dispersion of K+ channel sequences in the human genome.

Molecular cloning, characterization, and genomic localization of a human potassium channel gene.

Potassium (K+) channels are critical for a variety of cell functions, including modulation of action potentials, determination of resting membrane potential, and development of memory and learning. In addition to their role in regulating myocyte excitability, cardiac K+ channels control heart rate and coronary vascular tone and are implicated in the development of arrhythmias. We report here the cloning and sequencing of a k+ channel gene, KCNA1, derived from a human cardiac cDNA library and the chromosomal localization of the corresponding genomic clone. Oligonucleotides based on a delayed rectifier K+ channel gene were used in PCR reactions with human genomic DNA to amplify the S4-S6 regions of several different K+ channel genes. These sequences were used to isolate clones from a human cardiac cDNA library. We sequenced one of these clones, HCK1. HCK1 contains putative S2-S6 domains and shares approximately 70% sequence homology with previously isolated Shaker homologues. HCK1 was used to screen human cosmid libraries and a genomic clone was isolated. By sequencing the genomic clones, a putative S1 domain and translation initiation sequences were identified. Genomic mapping using human-rodent somatic cell panels and in situ hybridization with human metaphase chromosomes have localized KCNA1 to the distal short arm of human chromosome 12. This work is an important step in the study of human cardiac K+ channel structure and function and will be of use in the study of human inherited disease.

Hemoglobin switching in chickens. Is the switch initiated post-transcriptionally?

We have investigated the transcriptional specificity of chick embryo erythroid nuclei as a function of developmental age during progression of the hemoglobin switch. Nuclei were allowed to transcribe in vitro in the presence of high specific activity [alpha-32P]CTP and the radioactive transcripts were hybridized to a collection of plasmid clones spanning the beta-like globin gene region of the chicken genome. The results reveal locus-specific waves of transcription appearing during the interval between 5 and 12 days of incubation. The last wave, which comes in at 12 days, is highly specialized in transcription of the adult beta-globin gene locus. The most interesting wave of transcription occurs at 6-7 days. The most actively transcribed gene in the early part of this wave is the embryonic rho gene. As the wave progresses, the rho gene activity gradually gives way to beta gene transcription. Definitive red blood cells, which would be synthesizing little rho globin protein at this stage, appear to be responsible for the rho gene transcription. These results and additional data which we present indicate that during the initial stages of the hemoglobin switch the embryonic globin genes are silenced post-transcriptionally.

Isolation and characterization of human casein kinase I epsilon (CKI), a novel member of the CKI gene family.

The casein kinase I (CKI) gene family is a rapidly enlarging group whose members have been implicated in the control of cytoplasmic and nuclear processes, including DNA replication and repair. We report here the cloning and characterization of a novel isoform of CKI from a human placental cDNA library. The cDNA for this isoform, hCKI epsilon, predicts a basic polypeptide of 416 amino acids and a molecular mass of 47.3 kDa. It encodes a core kinase domain of 285 amino acids and a carboxyl-terminal tail of 123 amino acids. The kinase domain is 53-98% identical to the kinase domains of other CKI family members and is most closely related to the delta isoform. Localization of the hCKI epsilon gene to chromosome 22q12-13 and the hCKI delta gene to chromosome 17q25 confirms that these are distinct genes in the CKI family. Northern blot analysis shows that hCKI epsilon is expressed in multiple human cell lines. Recombinant hCKI epsilon is an active enzyme that phosphorylates known CKI substrates including a CKI-specific peptide substrate and is inhibited by CKI-7, a CKI-specific inhibitor. A budding yeast isoform of CKI, HRR25, has been implicated in DNA repair responses. Expression of hCKI epsilon but not hCKI alpha rescued the slow-growth phenotype of a Saccharomyces cerevisiae strain with a deletion of HRR25. Human CKI epsilon is a novel CKI isoform with properties that overlap those of previously described CKI isoforms.

High resolution mapping of overlapping cosmids by fluorescence in situ hybridization.

The constituents of two cosmid contigs were analyzed by high resolution mapping using two-color fluorescence in situ hybridization (FISH) to extended DNA molecules. Samples were prepared by lysing the nuclei in situ followed by histone depletion. This treatment results in elongate DNA filaments appropriate for high resolution mapping. The hybridization signals appeared as a strong of fluorescent spots separated by non-fluorescing gaps. Probe-specific features of the hybridization patterns were detected and some of the non-fluorescing gaps were found to represent regions of repetitive DNA suppressed during hybridization.

Narrowing the position of the Treacher Collins syndrome locus to a small interval between three new microsatellite markers at 5q32-33.1.

Treacher Collins syndrome (TCOF1) is an autosomal dominant disorder of craniofacial development, the features of which include conductive hearing loss and cleft palate. The TCOF1 locus has been localized to chromosome 5q32-33.2. In the present study we have used the combined techniques of genetic linkage analysis and fluorescence in situ hybridization (FISH) to more accurately define the TCOF1 critical region. Cosmids IG90 and SPARC, which map to distal 5q, encompass two and one hypervariable microsatellite markers, respectively. The heterozygosity values of these three markers range from .72 to .81. Twenty-two unrelated TCOF1 families have been analyzed for linkage to these markers. There is strong evidence demonstrating linkage to all three markers, the strongest support for positive linkage being provided by haplotyping those markers at the locus encompassed by the cosmid IG90 (Zmax = 19.65; theta = .010). FISH to metaphase chromosomes and interphase nuclei established that IG90 lies centromeric to SPARC. This information combined with the data generated by genetic linkage analysis demonstrated that the TCOF1 locus is closely flanked proximally by IG90 and distally by SPARC.

Two novel genes in the center of the 11p15 imprinted domain escape genomic imprinting.

We previously reported the isolation of a 2.5 Mb tumor-suppressing subchromosomal transferable fragment (STF) from human chromosome 11p15 and the identification of nine known genes and four novel genes within this STF. We now report the isolation of two novel cDNAs, designated here as TSSC4 and TSSC6 (tumor-suppressing STF cDNA 4 and 6), located within the STF. TSSC4 and TSSC6 encode predicted proteins of 329 and 290 amino acids, respectively, with no close similarity to previously reported proteins. TSSC4 and TSSC6 are both located in the center of a 1 Mb imprinted domain, which contains the imprinted genes TSSC3, TSSC5, p57(KIP2), KVLQT1, ASCL2, IGF2 and H19. However, we found that neither TSSC4 nor TSSC6 was significantly imprinted in any of the fetal or extra-embryonic tissues examined. Based on this result, the imprinted gene domain of 11p15 appears to contain at least two imprinted subdomains, between which TSSC4 and TSSC6 substantially escape imprinting, due either to lack of initial silencing or to an early developmental relaxation of imprinting.

Comparative genomic hybridization and its application to Wilms' tumorigenesis.

Eighty sporadic Wilms' tumor samples were analyzed by comparative genomic hybridization (CGH) to identify chromosomal regions involved in the etiology of the disease. Twenty percent of the samples showed chromosomal gains or losses. The majority of chromosomal gains and losses were similar to those identified through molecular and cytogenetic studies. Gains were observed on chromosomes 1q, 7q, 8, and 12, whereas losses were found on chromosomes 1p, 4p, 4q, 7p, 16q, 18q, 21q, and 22q. Other genetic aberrations identified in this study included deletions of chromosomes 5p and 15q, as well as gains of discrete loci on chromosomes 3p and 3q. These latter regions have not been previously implicated in Wilms' tumorigenesis and may contain novel genes relevant to the development and/or progression of this disease.

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.

Genetic and physical mapping of the Treacher Collins syndrome locus: refinement of the localization to chromosome 5q32-33.2.

Treacher Collins syndrome (TCOF1) is an autosomal dominant disorder of craniofacial development, the locus for which has been chromosomally localized to 5q31-34. We have isolated four hypervariable microsatellite markers (heterozygosity values range from 0.70 to 0.89) which have been mapped to distal 5q. Fifteen unrelated TCOF1 families have been analyzed for linkage to these markers. There is strong evidence demonstrating linkage to all of these markers; the strongest support for positive linkage being provided by the marker IG52, with a maximum pairwise lod score of 9.77 at a recombination fraction of 0.055. Analysis of recombinant individuals, physical mapping by fluorescence in situ hybridization and genetic linkage analysis demonstrated that the TCOF1 locus was flanked proximally by the loci 2C7 and 2D10, and distally by the loci IG26 and IG52 with a maximum lod score of 14.4, as assessed by multipoint linkage analysis. The refinement of the localization of the TCOF1 locus to 5q32-33.2, with flanking markers, represents an important step towards the identification of the mutated gene itself.

Strong homophilic interactions of the Ig-like domains of polycystin-1, the protein product of an autosomal dominant polycystic kidney disease gene, PKD1.

The 14 kb mRNA of the polycystic kidney disease gene PKD1 encodes a novel large (approximately 460 kDa) protein, polycystin-1, of unknown function that is responsible for autosomal dominant polycystic kidney disease (ADPKD). The unique organization of multiple adhesive domains of polycystin-1, including 16 Ig-like domains (or PKD domains) suggests that it may play an important role in cell-cell/cell-matrix interactions. Here we demonstrate the localization of polycystin-1 to epithelial cell-cell contacts in culture. These results along with structural predictions prompted us to propose that polycystin-1 is involved in cell-cell adhesion through its cluster of Ig-like repeats. We show that Ig-like domains II-XVI are involved in strong calcium-independent homophilic interactions in vitro. Domains XI-XVI form interactions with high affinity (K(d) = 60 nM) and domains II-V exhibit the lowest binding affinity (K(d) = 730 nM) in these studies. Most importantly, we show that antibodies raised against Ig-like domains of polycystin-1 disrupt cell-cell interactions in MDCK cell monolayers, thus indicating that polycystin-1 is directly involved in the cell-cell adhesion process. Collectively, these data suggest that interactions of the Ig-like repeats of polycystin-1 play an important role in mediating intercellular adhesion. We suggest that the loss of these interactions due to mutations in polycystin-1 may be an important step in cystogenesis.

A modified two-step phage display selection for isolation of polycystin-1 ligands.

The identification of proteins that interact with polycystin-1, the product of the autosomal dominant polycystic kidney disease gene, is an important step towards understanding the molecular pathogenesis of the disease. We have developed a two-step approach for the efficient identification of potential polycystin-1 ligands using the T7 phage display system. The first enrichment step of 4-5 rounds of biopanning is followed by a second step of reverse protein overlay assay. Thus, the sequencing efforts are minimized to the analysis of only positive rather than randomly chosen clones from the enriched population as in the standard phage display approach. Most importantly, the modified approach immediately provides the confirmation of the specificity of interaction and discriminates between strong and weak interactions. Here we present several potential interactors with distinct regions of polycystin-1, representing high-affinity binding partners.

A PCR-based linkage map of human chromosome 1.

A genetic linkage map of human chromosome 1 based entirely on PCR-typable markers has been developed using 38 simple sequence repeat (SSR) polymorphisms. These SSRs include 36 dinucleotide repeats and 2 tetranucleotide repeats. The average heterozygosity at these markers was 0.73 and ranged from 0.52 to 0.95. Multipoint linkage analysis was used to develop a map of these 38 markers in which the relative placement of each locus is supported by likelihood odds > 1000:1. This PCR-based map was anchored at the centromere by the D1Z5 alpha-satellite polymorphism, and the ends of the map were defined by D1Z2 and D1S68, which are the most distal loci in the CEPH consortium map of chromosome 1. The sex-averaged, male, and female maps extend for 328, 273, and 409 cM, respectively. The average distance between markers on the sex-averaged map is 8 cM, and the largest interval is 32 cM. This map of highly informative PCR-based markers will provide a rapid means of screening human chromosome 1 for the presence of disease genes.

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.