Cloning of the cDNA for a human homolog of the rat PEP-19 gene and mapping to chromosome 21q22.2–q22.3

Exon trapping was used to identify fragments of genes on human chromosome 21. One trapped sequence, hmc18h10 (GenBank no. X88329), showed homology to a sequence (GenBank no. S65225) that includes the first three codons of the rat PEP-19 gene and 5′ untranslated leader region. We have cloned the corresponding cDNA for a human homolog of the rat PEP-19 gene and mapped it to the region between markers ERG and D21S56 of chromosome 21q22.2–q22.3. Rat PEP-19 is a neuron-specific polypeptide expressed in several regions of the central nervous system. It serves as a cell-specific marker in Purkinje cells and its expression is developmentally regulated in the cerebellum, but its precise function is unknown. It is also presently unknown whether overexpression of the PEP-19 gene is involved in certain phenotypes of Down syndrome. Received: 3 May 1996 / Revised: 2 July 1996     

Localisation of a human homologue of the Drosophila mnb and rat Dyrk genes to chromosome 21q22.2

Exon trapping was used to identify portions of human chromosome 21-encoded genes. More than 600 potential exons on the chromosome have been cloned and characterised to date. A BLAST search of databases revealed that three of these trapped “exons”, hmc18a08, hmc18f10 and hmc27g09, showed strong homology to different regions of the Drosophila mnb (Genbank X70794) and rat Dyrk (Genbank X79769) genes, indicating that these three exons may be portions of a human homologue of these genes (we termed this gene MNB for minibrain). With amplification by the polymerase chain reaction and hybridisation analysis we have mapped the human MNB gene on overlapping yeast artificial chromosomes 336G11 and 806A11 of chromosome 21q22.2 between markers D21S65 and ERG. The Drosophila mnb (minibrain) gene, which encodes a member of the protein kinase family, is involved in postembryonic neurogenesis. The Dyrk gene, which encodes a dual specificity protein kinase, is a rat homologue of the Drosophila mnb gene. The kinase activity is dependent on tyrosine residues in the catalytic domain, and it has been speculated that the protein is involved in control of the cell cycle. Altered expression of the human MNB gene may be involved in the pathogenesis of certain phenotypes of Down syndrome, including mental retardation. Received: 14 June 1996 / Revised: 5 September 1996     

Cloning a new human gene from chromosome 21q22.3 encoding a glutamic acid-rich protein expressed in heart and skeletal muscle

The identification and functional characterization of genes on chromosome 21 is a necessary step to understand the pathogenesis of the various phenotypic anomalies that affect Down syndrome patients. Using direct cDNA selection we have identified a new gene, SH3BGR, that maps to 21q22.3, proximal to HMG14, and is differentially expressed in heart and skeletal muscle. SH3BGR encodes a novel protein that is characterized by the presence of a proline-rich region containing the consensus sequence for a SH3-binding domain and by an acidic carboxyl-terminal region containing a glutamic acid-rich domain predicted to assume a coiled coil. The presence of two functional domains involved in protein-protein interactions suggests that SH3BGR could be part of a multimeric complex. Its overexpression might alter specific functions of muscular tissue and therefore take part in the pathophysiology of muscular hypotonia in Down syndrome. Received: 12 August 1996 / Revised: 22 October 1996     

Cloning and characterization of human FTCD on 21q22.3, a candidate gene for glutamate formiminotransferase deficiency

We have identified a new human gene, FTCD, which maps to chromosome 21q22.3 and encodes the enzyme formiminotransferase cyclodeaminase, an intermediate metabolism enzyme that links histidine catabolism to folate metabolism. The major cDNA encodes a protein containing 541 amino acid residues and shows 84% identity with porcine FTCD. Several other cDNAs have been isolated, which may result from alternative splicing events and have the potential to code for three different protein isoforms. The gene is highly expressed in human fetal and adult liver. The two FTCD protein domains show high sequence similarity to two distinct open reading frames from eubacterial genomes, suggesting that eukaryotic FTCD appeared through a gene fusion event. Defects in the glutamate formiminotransferase pathway have been documented, and the deficiency is presumed to be inherited as an autosomal recessive trait. The sequence reported here may be helpful in identifying the primary defect in glutamate formiminotransferase deficiency and establishing a molecular diagnosis.     

Linkage of congenital recessive deafness (gene DFNB10) to chromosome 21q22.3.

Deafness is a heterogeneous trait affecting approximately 1/1,000 newborns. Genetic linkage studies have already implicated more than a dozen distinct loci causing deafness. We conducted a genome search for linkage in a large Palestinian family segregating an autosomal recessive form of nonsyndromic deafness. Our results indicate that in this family the defective gene, DFNB10, is located in a 12-cM region near the telomere of chromosome 21. This genetic distance corresponds to <2.4 Mbp. Five marker loci typed from this region gave maximum LOD scores > or = to 3. Homozygosity of marker alleles was evident for only the most telomeric marker, D21S1259, suggesting that DFNB10 is closest to this locus. To our knowledge, this is the first evidence, at this location, for a gene that is involved in the development or maintenance of hearing. As candidate genes at these and other deafness loci are isolated and characterized, their roles in hearing will be revealed and may lead to development of mechanisms to prevent deafness.     

Cloning and characterization of a human cDNA ACAD10 mapped to chromosome 12q24.1

Mitochondrial fatty acid -oxidation is an important energy resource for many mammal tissues. Acyl-CoA dehydrogenases (ACADs) are a family of flavoproteins that are involved in the -oxidation of the fatty acyl-CoA derivatives. Deficiency of these ACADs can cause metabolic disorders including muscle fatigue, hypoglycaemia, hepatic lipidosis and so on. By large scale sequencing, we identified a cDNA sequence of 3960 base pairs with a typical acyl-CoA dehydrogenase function domain. RT-PCR result shows that it is widely expressed in human tissues, especially high in liver, kidney, pancreas and spleen. It is hypothesized that this is a novel member of ACADs family. Abbreviations: ACADs – acyl-CoA dehydrogenases, FAD – flavinadenine dinucleotide, SCAD – short-chain acyl-CoA dehydrogenase,MCAD – medium-chain acyl-CoA dehydrogenase, LCAD – long-chain acyl-CoAdehydrogenase, VLCAD – very long- chain acyl-CoA dehydrogenase, IVD –isocalery-CoA dehydrogenase, SBCAD – short/branched chain acyl-CoAdehydrogenase, GCD – glutaryl- CoA dehydrogenase, ETF – electron transferflavoprotein, ACAD8 – acyl-CoA dehydrogenase 8, ACAD9 – acyl-CoAdehydrogenase 9, ACAD10 – acyl-CoA dehydrogenase 10.     

Cloning and expression of human cDNA encoding human homologue of pituitary tumor transforming gene.

Recently, a potent transforming gene which was exclusively expressed in rat pituitary tumor but not in normal pituitary had been isolated and named as pituitary tumor transforming gene (PTTG). A cDNA clone encoding human homologue of rat PTTG was isolated from human fetal liver cDNA library. It contained an open reading frame of 603 base pairs predicting a protein composed of 201 amino acids with a calculated molecular weight of 26 kDa. The deduced protein showed about 85% homology (78% identity, 7% favored substitution) with the rat PTTG. Northern blot analysis showed that the cDNA hybridized to 1.0 kb mRNA species which was expressed in fetal liver and several cancer cell lines. These results suggest that the presence of the human homologue of rat PTTG gene may not be restricted to pituitary tumor.     

Localisation of a gene for Papillon-Lefèvre syndrome to chromosome 11q14–q21 by homozygosity mapping

Papillon-Lefèvre syndrome is an autosomal recessively inherited palmoplantar keratoderma of unknown aetiology associated with severe periodontitis leading to premature loss of dentition. Three consanguineous families, two of Turkish and one of German origin, and three multiplex families, one of Ethiopian and two of German origin, with 11 affected and 6 unaffected siblings in all were studied. A targeted genome search was initially attempted to several candidate gene regions but failed to demonstrate linkage. Therefore a genome-wide linkage scan using a combination of homozygosity mapping and traditional linkage analysis was undertaken. Linkage was obtained with marker D11S937 with a maximum two-point lod score of Z _max = 6.1 at recombination fraction θ = 0.00 on chromosome 11q14–q21 near the metalloproteinase gene cluster. Multipoint likelihood calculations gave a maximum lod score of 7.35 between D11S901 and D11S1358. A 9.2-cM region homozygous by descent in the affected members of the three consanguineous families lies between markers D11S1989 and D11S4176 harbouring the as yet unknown Papillon-Lefèvre syndrome gene. Haplotype analyses in all the families studied support this localisation. This study has identified a further locus harbouring a gene for palmoplantar keratoderma and one possibly involved in periodontitis. Received: 19 July 1997 / Accepted: 22 August 1997     

Assignment of the human homologue of the mouse t-complex gene TCTE3 to human chromosome 6q27.

The gene TCTE3 from the mouse t-complex region is expressed specifically in testicular germ cells. It maps in the central subregion of the t-complex on mouse chromosome 17 containing loci involved in transmission ratio distortion and male sterility. In this study, somatic cell hybrid lines have been used to map the human homologue, TCTE3, to the long arm of chromosome 6. CISS hybridization with the human lambda clone h117 refined this chromosome assignment to the very distal position of chromosome 6q27, thus providing further evidence that loci from the t-complex of mouse chromosome 17 can map to opposite arms of human chromosome 6.     

Cloning of the human homolog of conductin (AXIN2), a gene mapping to chromosome 17q23-q24

Conductin or Axil, an Axin homolog, plays an important role in the regulation of beta-catenin stability in the Wnt signaling pathway. To facilitate the molecular analysis of the human gene, we isolated the human homolog, AXIN2. The cDNA contains a 2529-bp open reading frame and encodes a putative protein of 843 amino acids. Compared with rat and mouse homologs, AXIN2 shows an overall 89% amino acid identity. Several functional domains in this protein are highly conserved including the GRS (95.9%), GSK-3beta (96.3%), Dsh (98%), and beta-catenin (89.9%) domains. Radiation hybrid mapping localized the AXIN2 gene to human chromosome 17q23-q24, a region that shows frequent loss of heterozygosity in breast cancer, neuroblastoma, and other tumors. Human AXIN2 is thus a very strong candidate involved in multiple tumor types.