Localization of the gene for human erythrocyte glycophorin C to chromosome 2, q14–q21

Summary A complementary cDNA clone (900 bp) representing the 3 untranslated region and almost the entire coding sequence of the human erythrocyte membrane glycophorin C has been used to determine the chromosomal location of the blood group Gerbich locus by in situ hybridization. The results indicate that this locus is assigned to the region q14–q21 of chromosome 2.     

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     

Localization of the human progesterone receptor gene to chromosome 11q22–q23

Summary The human progesterone receptor gene was mapped by in situ hybridization using two cDNA probes corresponding to the 5′ and 3′ part of the coding sequence. This gene was localized to 11q22-q23.     

Human NK-2 receptor gene maps to chromosome region 10q11–21

Summary The human NK-2 receptor gene has been mapped to chromosome 10 using the polymerase chain reaction to amplify specifically the human NK-2 receptor sequence in hamster/human hybrid DNA and also in mouse/human monochromosome hybrids. The assignment to chromosome 10 was confirmed by in situ hybridisation to human metaphase chromosomes, giving a regional localisation of 10q11–21.     

Localization of a novel locus for alopecia with mental retardation syndrome to chromosome 3q26.33–q27.3

Alopecia with mental retardation syndrome is a rare autosomal recessive disorder characterized clinically by total or partial alopecia and mental retardation. In an effort to understand the molecular bases of this form of alopecia syndrome, large Pakistani consanguineous kindred with multiple affected individuals has been ascertained from a remote region in Pakistan. Genome wide scan mapped the disease locus on chromosome 3q26.33–q27.3. A maximum two-point LOD score of 3.05 (θ=0.0) was obtained at marker D3S3583. Maximum multipoint LOD score exceeding 5.0, obtained with several markers, supported the linkage. Recombination events observed in affected individuals localized the disease locus between markers D3S1232 and D3S2436, spanning 11.49-cM region on chromosome 3q26.33–q27.3. Sequence analysis of a candidate gene ETS variant gene 5 from DNA samples of two affected individuals of the family revealed no mutation.     

Localisation of a cDNA clone for human cytokeratin 18 to chromosome 17p11–p12 by in situ hybridisation

Summary A human cytokeratin 18 cDNA sequence was localised to chromosome 17p11-p12 by in situ hybridisation.     

Regional localization of human ecto-5′nucleotidase to chromosome 6q14–q21

Summary Human and mouse hybrids that contain fragments of human chromosome 6 as translocations were analysed for expression of ecto-5nucleotidase enzymic activity measured by the conversion of AMP to adenosine and for antigenicity recognized by a monoclonal antibody specific for the human isozyme. Both methods allow a regional assignment of ecto-5nucleotidase to 6q14–q21.     

Assignment of the gene for human tenascin to the region q32–q34 of chromosome 9

Summary Tenascin (TN) is a hexameric extracellular matrix glycoprotein that is highly expressed in solid tumors but has a restricted distribution in normal adult tissues. Each TN subunit is composed of segments with high homology to the sequences of epidermal growth factor, fibronectin and fibrinogen. Furthermore, it has been suggested that TN could modulate epithelial-mesenchymal and neuronal-glial interactions. Here, using a cDNA probe to human TN, we have carried out Southern blot analysis of the genomic DNAs from a panel of human-hamster somatic cell hybrids carrying different complements of human chromosomes. The results demonstrate that the human TN gene is located on chromosome 9. Furthermore, in situ hybridization studies demonstrate that human TN is located at 9q32–q34.     

Sublocalization of the human protein C gene on chromosome 2q13–q14

Summary The localization of human protein C gene on chromosome 2 was investigated by in situ hybridization using a partial cDNA for protein C. Silver-grain analysis indicates that the protein C gene is located on 2q13-q14.     

Construction of a porcine YAC library and mapping of the cardiac muscle ryanodine receptor gene to Chromosome 14q22–q23

Large-scale physical mapping of the porcine genome has been limited because up to now no suitable genomic libraries for this purpose have been available. Therefore, we have constructed a yeast artificial chromosome (YAC) library from porcine lymphocytes. The library was cloned in the amplifiable vector pCGS966. A total of 10080 YAC clones was obtained and has been ordered into 105 96-well microtiter plates. An average insert size of 300 kb was calculated from the analysis of 78 randomly selected clones, giving a onefold coverage of the porcine genome. To analyze the complexity, we have screened the library for five different genes and isolated four different clones containing parts of three of these genes. One YAC clone harboring parts of the porcine cardiac muscle ryanodine receptor (RYR2) gene allowed us to assign this locus to Chromosome (Chr) 14q22-q23. The data were confirmed by PCR analysis of a rodent-porcine hybrid cell panel.     

The gene coding for the p68 calcium-binding protein is localised to bands q32–q34 of human chromosome 5, and to mouse chromosome 11

Summary The gene encoding a tissue inhibitor of metalloproteinases, TIMP, has previously been shown to be X-linked in both the human and mouse genomes. We have used a series of somatic cell hybrids segregating translocation and deletion X chromosomes to map the TIMP gene on the human X chromosome. In combination with previous data, the gene can be assigned to Xp11.23Xp11.4. Genetic linkage analyses demonstrate that TIMP is linked to the more distal ornithine transcarbamylase (OTC) locus at a distance of about 22 centimorgans. The data are consistent with the conclusion that TIMP maps to a conserved synteny and linkage group on the proximal short arm of the human X chromosome and on the pericentric region of the mouse X chromosome, including loci for synapsin-1, a member of the raf oncogene family, OTC, and TIMP.     

Mapping of a gene for epidermolytic palmoplantar keratoderma to the region of the acidic keratin gene cluster at 17q12–q21

Summary Epidermolytic palmoplantar keratoderma (EPPK) (Vörner-Unna-Thost) is an autosomal dominantly inherited skin disease of unknown etiology characterized by diffuse severe hyperkeratosis of the palms and soles and, histologically, by cellular degeneration. We have mapped a gene for EPPK to chromosome 17q11–q23, with linkage analysis using microsatellite DNA-polymorphisms, in a single large family of 7 generations. A maximum lod score of z=6.66 was obtained with the probe D17S579 at a recombination fraction of =0.00. This locus maps to the same region as the type I (acidic) keratin gene cluster. Keratins, members of the intermediate filament family, the major proteins of the cytoskeleton in epidermis, are differentially expressed in a tissue-specific manner. One acidic keratin, keratin 9 (KRT9), is expressed only in the terminally differentiated epidermis of palms and soles. The KRT9 gene has not yet been cloned; however, since the genes for most acidic keratins are clustered, it is highly probable that it too will map to this region. We therefore propose KRT9 as the candidate gene for EPPK.     

Regional mapping of human chromosome 10: Assignment of the gene for cytoplasmic glutamate-oxaloacetate transaminase to 10q24 » qter

Summary Segregation analysis of human-mouse somatic cell hybrids involving fibroblasts of a 10/17 translocation carrier as human partner allowed to assign the gene for human soluble GOT to 10q24»qter.Supported by the Deutsche Forschungsgemeinschaft, GR 373/6.     

Regional assignment of the human C1-inhibitor gene to 11q11–q13.1

Summary In situ hybridisation using a biotinylated 1.8kb human cDNA clone in both normal and structurally abnormal chromosomes supports regional localisation of the gene for human C1-inhibitor to chromosome 11q11-q13.11.     

A gene responsible for Ghosal hemato-diaphyseal dysplasia maps to chromosome 7q33–34

Ghosal hemato-diaphyseal dysplasia is a rare autosomal recessive disorder characterized by a progressive sclerosing diaphyseal dysplasia and refractory anemia. The pathogenesis and genetic bases of this syndrome remain hitherto unknown. We have performed a genome wide search in two inbred families originating from Algeria and Tunisia. Here, we report on the mapping of a disease gene to chromosome 7q33–34 (Z _max = 4.21 at θ = 0 at locus D7S2513) in a 3.4 Mb defined by loci D7S2560 and AC091742. Ongoing studies will hopefully lead to identification of the disease-causing gene.     

Regional mapping of human chromosome 3. Assignment of a glutathione peroxidase-1 gene to 3p13→3q12

Summary The segregation of human glutathione peroxidase-1 (GPX1, EC 1.11.1.9) was followed in a series of human-mouse somatic cell hybrids carrying various fragments of human chromosome 3. These fragments originated from translocations in the parental human fibroblasts or from spontaneous deletions which occurred during the cultivation of hybrid clones. The smallest region of overlap found for the position of GPX 1 was 3p133q12.     

Assignment of the gene for carboxypeptidase A to human chromosome 7q22→qter and to mouse chromosome 6

Summary A rat cDNA probe for preprocarboxypeptidase A was used to follow the segregation of the human gene for carboxypeptidase A (CPA) in 49 human x mouse somatic cell hybrids using Southern filter hybridization techniques. CPA was assigned to human chromosome 7q22qter. Similarly, the probe was used to follow the segregation of the mouse gene for carboxypeptidase A (Cpa) in 19 mouse x Chinese hamster somatic cell hybrids. Cpa was assigned to mouse chromosome 6. The gene for carboxypeptidase A forms part of a syntenic group that is conserved in man and mouse.Preliminary chromosomal assignments of carboxypeptidase A in man and mouse have been made in abstract (Honey et al. 1983a, b)     

Progressive familial intrahepatic cholestasis (PFIC): evidence for genetic heterogeneity by exclusion of linkage to chromosome 18q21–q22

Progressive familial intrahepatic cholestasis (PFIC) is the second most common form of familial intrahepatic cholestasis. The genes for PFIC and for a milder form of the disease, benign recurrent intrahepatic cholestasis (BRIC), were recently mapped to a 19-cM region on chromosome 18q21–q22. The results suggest that PFIC and BRIC are allelic diseases. We have studied 11 Swedish patients from eight families with clinical and biochemical features consistent with PFIC. The families were genotyped for markers D18S69, D18S64, D18S55 and D18S68, spanning the PFIC candidate region. Unexpectedly, the segregation of haplotypes excluded the entire region in three families, and no indications for shared haplotypes were found in the patients of the six remaining families. A four-point linkage analysis of all families excluded linkage from D18S69 to D18S55 (Z_max < –5). Thus, our data strongly suggest the presence of a second, yet unknown, locus for PFIC. The results indicate that great care should be taken when using 18q markers for prenatal diagnosis and genetic counseling for the disease. Received: 12 February 1997 / Accepted: 11 April 1997     

Mapping of the ribophorin II (RPN II) gene to human chromosome 20q12–q13.1 by in-situ hybridization

Summary Ribophorin I and II (RPN I and RPN II), two specific glycoproteins, span the rough regions of the endoplasmic reticulum (RER) and are thought to play an important role either in translocation or in the maintenance of RER. Studies with human-mouse somatic cell hybrids have localized the gene for RPN I on human chromosome 3q, while RPN II is on chromosome 20. Using a radioactive labelled cDNA probe, we have regionally mapped the RPN II gene to human chromosome 20q12-q13.1 by in situ hybridization. This assignment predicts a location of the murine homologue, Rpn-2, to the syntenic segment on mouse chromosome 2 in close proximity to Ada, Src and Gnas.     

Characterisation of interstitial duplications and triplications of chromosome 15q11–q13

Chromosome 15 is frequently involved in the formation of structural rearrangements. We report the molecular characterisation of 16 independent interstitial duplications, including those of one individual who carried a duplication on both of her chromosomes 15, and three interstitial triplications of the Prader-Willi/Angelman syndrome critical region (PWACR). In all probands except one, the rearrangement was maternal in origin. In one family, the duplication was paternal in origin, yet appeared to segregate in a sibship of three with an abnormal phenotype that included developmental delay and a behavioural disorder. Ten duplications were familial, five de novo and one unknown. All 16 duplications, including two not visible by routine G-banding, were of an almost uniform size and shared the common deletion breakpoints of Prader-Willi syndrome and Angelman syndrome. Like deletions, the formation of duplications can occur in both male and female meiosis and involve both inter- and intrachromosomal events. This implies that at least some deletions and duplications are the reciprocal products of each other. We observed no instances of meiotic instability in the transmission of a duplication, although recombination within the PWACR occurred in two members of the same family between the normal and the duplicated chromosome 15 homologues. All three triplications arose de novo and included alleles from both maternal chromosomes 15. Triplication breakpoints were more variable and extended distally beyond the PWACR. The molecular characteristics of duplications and triplications suggest that they are formed by different mechanisms.