Generation of RCAS vectors useful for functional genomic analyses

Avian leukosis type A virus-derived retroviral vectors have been used to introduce genes into cells expressing the corresponding avian receptor tv-a. This includes the use of Replication-Competent Avian sarcoma-leukosis virus (ASLV) long terminal repeat (LTR) with Splice acceptor (RCAS) vectors in the analysis of avian development, human and murine cell cultures, murine cell lineage studies and cancer biology. Previously, cloning of genes into this virus was difficult due to the large size of the vector and sparse cloning sites. To overcome some of the disadvantages of traditional cloning using the RCASBP-Y vector, we have modified the RCASBP-Y to incorporate "Gateway" site-specific recombination cloning of genes into the construct, either with or without HA epitope tags. We have found the repetitive "att" sequences, which are the targets for site-specific recombination, do not impair the production of infectious viral particles or the expression of the gene of interest. This is the first instance of site-specific recombination being used to generate retroviral gene constructs. These viral constructs will allow for the efficient transfer and expression of cDNAs needed for functional genomic analyses.

The use of expression profiling to study pigment cell biology and dysfunction

Regulation of gene expression is a fundamental process by which cells respond to both intracellular and extracellular signals. For a pigment cell, alterations in gene expression regulate the processes of cell migration, lineage restriction, differentiation, type of pigment produced, and progression from a normal pigment cell to that of melanoma. To date, the identification of genes involved in normal pigment cell development has been accomplished by the cloning of individual mutant alleles, a single gene at a time. Current advances in technology have now made it possible to use expression profile analysis to investigate, on a genomic scale, the process of pigment cell development and function. This review compares and contrasts the methods of subtractive suppressive polymerase chain reaction (PCR) and differential display with that of cDNA microarray analysis.

Informatic selection of a neural crest-melanocyte cDNA set for microarray analysis

With cDNA microarrays, it is now possible to compare the expression of many genes simultaneously. To maximize the likelihood of finding genes whose expression is altered under the experimental conditions, it would be advantageous to be able to select clones for tissue-appropriate cDNA sets. We have taken advantage of the extensive sequence information in the dbEST expressed sequence tag (EST) database to identify a neural crest-derived melanocyte cDNA set for microarray analysis. Analysis of characterized genes with dbEST identified one library that contained ESTs representing 21 neural crest-expressed genes (library 198). The distribution of the ESTs corresponding to these genes was biased toward being derived from library 198. This is in contrast to the EST distribution profile for a set of control genes, characterized to be more ubiquitously expressed in multiple tissues (P < 1 x 10(-9)). From library 198, a subset of 852 clustered ESTs were selected that have a library distribution profile similar to that of the 21 neural crest-expressed genes. Microarray analysis demonstrated the majority of the neural crest-selected 852 ESTs (Mel1 array) were differentially expressed in melanoma cell lines compared with a non-neural crest kidney epithelial cell line (P < 1 x 10(-8)). This was not observed with an array of 1,238 ESTs that was selected without library origin bias (P = 0.204). This study presents an approach for selecting tissue-appropriate cDNAs that can be used to examine the expression profiles of developmental processes and diseases.

Niemann-Pick C1 disease gene: homology to mediators of cholesterol homeostasis

Niemann-Pick type C (NP-C) disease, a fatal neurovisceral disorder, is characterized by lysosomal accumulation of low density lipoprotein (LDL)-derived cholesterol. By positional cloning methods, a gene (NPC1) with insertion, deletion, and missense mutations has been identified in NP-C patients. Transfection of NP-C fibroblasts with wild-type NPC1 cDNA resulted in correction of their excessive lysosomal storage of LDL cholesterol, thereby defining the critical role of NPC1 in regulation of intracellular cholesterol trafficking. The 1278-amino acid NPC1 protein has sequence similarity to the morphogen receptor PATCHED and the putative sterol-sensing regions of SREBP cleavage-activating protein (SCAP) and 3-hydroxy-3-methyl-glutaryl coenzyme A (HMG-CoA) reductase.

Murine model of Niemann-Pick C disease: mutation in a cholesterol homeostasis gene

An integrated human-mouse positional candidate approach was used to identify the gene responsible for the phenotypes observed in a mouse model of Niemann-Pick type C (NP-C) disease. The predicted murine NPC1 protein has sequence homology to the putative transmembrane domains of the Hedgehog signaling molecule Patched, to the cholesterol-sensing regions of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase and SREBP cleavage-activating protein (SCAP), and to the NPC1 orthologs identified in human, the nematode Caenorhabditis elegans, and the yeast Saccharomyces cerevisiae. The mouse model may provide an important resource for studying the role of NPC1 in cholesterol homeostasis and neurodegeneration and for assessing the efficacy of new drugs for NP-C disease.

Substantial narrowing of the Niemann-Pick C candidate interval by yeast artificial chromosome complementation

Niemann-Pick disease type C (NP-C) is an autosomal recessive lipidosis linked to chromosome 18q11-12, characterized by lysosomal accumulation of unesterified cholesterol and delayed induction of cholesterol-mediated homeostatic responses. This cellular phenotype is identifiable cytologically by filipin staining and biochemically by measurement of low-density lipoprotein-derived cholesterol esterification. The mutant Chinese hamster ovary cell line (CT60), which displays the NP-C cellular phenotype, was used as the recipient for a complementation assay after somatic cell fusions with normal and NP-C murine cells suggested that this Chinese hamster ovary cell line carries an alteration(s) in the hamster homolog(s) of NP-C. To narrow rapidly the candidate interval for NP-C, three overlapping yeast artificial chromosomes (YACs) spanning the 1 centimorgan human NP-C interval were introduced stably into CT60 cells and analyzed for correction of the cellular phenotype. Only YAC 911D5 complemented the NP-C phenotype, as evidenced by cytological and biochemical analyses, whereas no complementation was obtained from the other two YACs within the interval or from a YAC derived from chromosome 7. Fluorescent in situ hybridization indicated that YAC 911D5 was integrated at a single site per CT60 genome. These data substantially narrow the NP-C critical interval and should greatly simplify the identification of the gene responsible in mouse and man. This is the first demonstration of YAC complementation as a valuable adjunct strategy for positional cloning of a human gene.

Treacher Collins syndrome may result from insertions, deletions or splicing mutations, which introduce a termination codon into the gene

Treacher Collins syndrome is an autosomal dominant disorder of craniofacial development the features of which include conductive hearing loss and cleft palate. Recently, the Treacher Collins syndrome gene (TCOF1) has been positionally cloned and a series of five mutations within the coding sequence of the gene identified. In the current investigation, seven exons of TCOF1 have been identified which has permitted the identification of additional mutations in the gene. The mutations that have been identified are three distinct deletions and an insertion, which cause a frameshift, and a missense mutation which inactivates a donor splice site with extension of transcription into the intron. To date, all 10 of the mutations which have been reported result in a premature termination codon and are unique to a given family. As these mutations are spread throughout the gene, these observations provide further support for the hypothesis that Treacher Collins syndrome results from haploinsufficiency, although a dominant negative effect cannot, at this stage, be excluded.

Genomic organization of the human heparan sulfate-N-deacetylase/N-sulfotransferase gene: exclusion from a causative role in the pathogenesis of Treacher Collins syndrome

Heparan sulfate-N-deacetylase/N-sulfotransferase (HSST) catalyzes both the N-deacetylation and the N-sulfation of heparan sulfate. Previous studies have resulted in the isolation of the human HSST gene from within the Treacher Collins syndrome locus (TCOF1) critical region on 5q. In the present study, the genomic organization of the HSST gene has been elucidated, and the 14 exons identified have been tested for TCOF1-specific mutations. As a result of these studies, mutations within the coding sequence and adjacent splice junctions of HSST can be excluded from a causative role in the pathogenesis of Treacher Collins syndrome.

Transcriptional map of the Treacher Collins candidate gene region

Treacher Collins syndrome (TCOF1) is a dominant disorder of craniofacial development that has been linked previosuly to a region of chromosome 5q31.3-32. Identification of recombination events in affected individuals has reduced the candidate gene region to a 0.5-Mb area between the loci RPS14 (proximal) and ANX6 [distal]. A transcriptional map of this candidate gene region, generated by analysis of exon amplification clones, has identified the genomic location of four genes, heparan sulfate-N-sulfotransferase-N-deacetylase, glutathione peroxidase, as well as two novel, previously uncharacterized genes. Each of these genes, based on their location, must be considered candidates for TCOF1 locus.

Isolation, characterization, and precise physical localization of human CDX1, a caudal-type homeobox gene

The human CDX1 gene has been isolated from a small intestine cDNA library using a murine Cdx1 cDNA probe. The nucleotide sequence of CDX1 is 81% identical to murine Cdx1 and predicts a 265-amino-acid protein with 85% identity to the mouse protein (98% identity, including conservative amino acid changes). The CDX1 locus has been mapped to a cosmid contig from chromosome 5q31-q33, placing CDX1 approximately 100 kb distal to CSFIR. Expression of CDX1 in adults appears to be limited to the intestine and colon by Northern analysis, suggesting a possible role in the terminal differentiation of the intestine. Further analysis of CDX1 should elucidate the function of caudal-type homeobox genes in human development.

Cloning of the human heparan sulfate-N-deacetylase/N-sulfotransferase gene from the Treacher Collins syndrome candidate region at 5q32-q33.1

Treacher Collins syndrome is an autosomal dominant disorder of craniofacial development, the features of which include conductive hearing loss and cleft palate. Previous studies have shown that the Treacher Collins syndrome locus is flanked by D5S519 and SPARC, and a yeast artificial chromosome contig encompassing this "critical region" has been completed. In the current investigation a cosmid containing D5S519 has been used to screen a human placental cDNA library. This has resulted in the cloning of the human heparan sulfate-N-deacetylase/N-sulfotransferase gene. Two different mRNA species that have identical protein coding sequences but that differ in the size and sequence of the 3' untranslated regions (3' UTR) have been identified. The smaller species has a 3' UTR of 1035 bp, whereas that of the larger is 4878 bp.

A YAC contig encompassing the Treacher Collins syndrome critical region at 5q31.3-32

Treacher Collins syndrome (TCOF1) is an autosomal dominant disorder of craniofacial development the features of which include conductive hearing loss and cleft palate. Previous studies have localized the TCOF1 locus between D5S519 (proximal) and SPARC (distal), a region of 22 centirays as estimated by radiation hybrid mapping. In the current investigation we have created a contig across the TCOF1 critical region, using YAC clones. Isolation of a novel short tandem repeat polymorphism corresponding to the end of one of the YACs has allowed us to reduce the size of the critical region to approximately 840 kb, which has been covered with three nonchimeric YACs. Restriction mapping has revealed that the region contains a high density of clustered rare-cutter restriction sites, suggesting that it may contain a number of different genes. The results of the present investigation have further allowed us to confirm that the RPS14 locus lies proximal to the critical region and can thereby be excluded from a role in the pathogenesis of TCOF1, while ANX6 lies within the TCOF1 critical region and remains a potential candidate for the mutated gene.

Genes encoding adrenergic receptors are not clustered on the long arm of human chromosome 5

The distal portion of the long arm of chromosome 5 (5q) contains a large number of genes encoding membrane receptors belonging to various gene families, including G protein-coupled adrenergic receptors. Previous reports indicated that the genes for two of the adrenergic receptors, ADRB2 and ADRA1B, were within 300 kb of one another on 5q. In an effort to determine if a third adrenergic receptor assigned to 5q, ADRA1A, was physically close to the genes encoding the other adrenergic receptors, we attempted to place all three loci on a radiation hybrid map of 5q. The results conflicted with previous mapping results in two ways. First, ADRA1B is on 5q but is several million bases, rather than a few hundred thousand bases, from ADRB2. Second, ADRA1A is not on chromosome 5, but rather on chromosome 20. Thus, even though 5q contains an extraordinary number of genes encoding receptors for various hormones, growth factors, and neurotransmitters, there is no particular clustering of genes encoding adrenergic receptors in this region.

A combined genetic and radiation hybrid map surrounding the Treacher Collins syndrome locus on chromosome 5q

The distal region of chromosome 5q contains a large number of genes, including those implicated in a variety of Mendelian disorders. One of these, Treacher Collins syndrome (TCOF1), is an autosomal dominant disorder of craniofacial development the features of which include conductive hearing loss and cleft palate. Previous studies have localized the TCOF1 locus between D5S519 (proximal) and SPARC (distal). To more accurately define the genetic distance between these markers, and to extend a high resolution genetic map of 5q31-33 to include additional highly informative markers, 15 loci (including polymorphisms for 4 known genes) were mapped through the Centre d'Etude du Polymorphisme Humain reference pedigrees. The resulting genetic map encompasses 29 cM on the sex-averaged map. To help integrate this linkage map with a physical map of the region, 13 loci from 5q31--33, including 6 genes, were used to construct a radiation hybrid map. As eight of the loci are common to both maps this has allowed us to combine the maps. The most likely location for the TCOF1 locus within this marker framework is in the D5S519-SPARC interval; a region estimated to be approximately 880 kb.