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.     

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.     

Chromosomal localization of the type-I 15-PGDH gene to 4q34–q35

The gene encoding the human NAD⁺-dependent 15-hydroxyprostaglandin dehydrogenase, designated type-I 15-PGDH, was mapped to chromosome 4 by analyzing its segregation in a panel of human-hamster somatic cell hybrids. This gene was further localized to bands 4q34–q35 by in situ hybridization on human chromosomes. Received: 7 October 1996     

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.     

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.     

Comparative analysis of vertebrate EIF2AK2 (PKR) genes and assignment of the equine gene to ECA15q24–q25 and the bovine gene to BTA11q12–q15

The structures of the canine, rabbit, bovine and equine EIF2AK2 genes were determined. Each of these genes has a 5'' non-coding exon as well as 15 coding exons. All of the canine, bovine and equine EIF2AK2 introns have consensus donor and acceptor splice sites. In the equine EIF2AK2 gene, a unique single nucleotide polymorphism that encoded a Tyr329Cys substitution was detected. Regulatory elements predicted in the promoter region were conserved in ungulates, primates, rodents, Afrotheria (elephant) and Insectifora (shrew). Western clawed frog and fugu EIF2AK2 gene sequences were detected in the USCS Genome Browser and compared to those of other vertebrate EIF2AK2 genes. A comparison of EIF2AK2 protein domains in vertebrates indicates that the kinase catalytic domains were evolutionarily more conserved than the nucleic acid-binding motifs. Nucleotide substitution rates were uniform among the vertebrate sequences with the exception of the zebrafish and goldfish EIF2AK2 genes, which showed substitution rates about 20% higher than those of other vertebrates. FISH was used to physically assign the horse and cattle genes to chromosome locations, ECA15q24–q25 and BTA11q12–15, respectively. Comparative mapping data confirmed conservation of synteny between ungulates, humans and rodents.     

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.     

Regional assignment of the gene coding for a human Graves' disease autoantigen to 10q21.3–q22.1

A cDNA coding for a human Graves' disease autoantigen (hGT) has been isolated from a thyroid expression library. Using this cDNA as a probe, the gene for hGT, previously assigned to chromosome 10, has been further localized to 10q21.3–q22.1 by non-isotopic in situ hybridization.     

Assignment of the human aggrecan gene AGC1 to 15q25→q26.2 by in situ hybridization

The human aggrecan gene (AGC1) has been localized to 15q25q26.2 by in situ hybridization. Although no genetic diseases of connective tissue map to this location, the malignant melanoma-associated surface antigen mel-CSPG is located here; mel-CSPG is a chondroitin sulfate proteoglycan. This raises the possibility that AGC1 and mel-CSPG may be the same gene.     

Regional assignment of the human uroporphyrinogen III synthase (UROS) gene to chromosome 10q25.2→q26.3

Summary Uroporphyrinogen III synthase [UROS; hydroxymethylbilane hydro-lyase (cyclizing), EC 4.2.1.75] is the fourth enzyme in the human heme biosynthetic pathway. The recent isolation of the cDNA encoding human UROS facilitated its chromosomal localization. Human UROS sequences were specifically amplified by the polymerase chain reaction (PCR) from genomic DNA of two independent panels of human-rodent somatic cell hybrids. There was 100% concordance for the presence of the human UROS PCR product and human chromosome 10. For each of the other chromosomes, there was 19%–53% discordance with human UROS. The chromosomal assignment was confirmed by Southern hybridization analysis of DNA from somatic cell hybrids with the full-length UROS cDNA. Using human-rodent hybrids containing different portions of human chromosome 10, we assigned the UROS gene to the region 10q25.2 q26.3.     

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.     

Contribution of gene conversion in the evolution of the human β-like globin gene family

Gene conversion is referred to as one of two types of mechanisms known to act on gene families, mainly to maintain their sequence homogeneity or, in certain cases, to produce sequence diversity. The concept of gene conversion was established 20 years ago by researchers working with fungi. A few years later, gene conversion was also observed in the human genome, i.e. the γ-globin locus. The aim of this article is to emphasize the role of genetic recombination, particularly of gene conversion, in the evolution of the human β-like globin genes and further to summarize its contribution to the convergent evolution of the fetal globin genes. Finally, this article attempts to re-examine the origin and spread of specific mutations of the β-globin cluster, such as the sickle cell or β-thalassemia mutations, on the basis of repeated gene conversion events. Received: 13 February 1997 / Accepted: 15 May 1998     

Juvenile open angle glaucoma: fine mapping of the TIGR gene to 1q24.3–q25.2 and mutation analysis

Autosomal dominant juvenile open angle glaucoma (JOAG) is an early-onset form of primary open angle glaucoma (POAG), which has been linked to chromosome 1q21–q31. Recently, mutations in the trabecular meshwork inducible glucocorticoid response gene (TIGR), one of the candidate genes mapped in this region, were identified in glaucoma patients of several families. We screened for mutations of the TIGR gene in two German families with JOAG and in 100 unselected sporadic cases of POAG. In the first family we identified a Pro370Leu mutation and in the second family a Gly367Arg mutation cosegregating with the glaucoma phenotype. No pathogenic mutation was found in 100 sporadic cases but a Tyr347Tyr polymorphism was found in two patients. Furthermore, fluorescence in situ hybridization (FISH) analysis was used to map a TIGR-specific yeast artificial chromosome to 1q24.3–q25.2. Received: 19 June 1997 / Accepted: 12 August 1997     

Chromosomal assignment of the human 2,3-bisphosphoglycerate mutase gene (BPGM) to region 7q34→7q22

Summary A 1.1-kb cDNA clone for human 2,3-bisphospho-glycerate mutase (BPGM) (EC2.7.5.4) was used to map the structural gene to metaphase chromosomes. In situ hybridization experiments localized the human BPGM gene to chromosome 7 and, more precisely, to region 7q34→7q22.     

Mapping of the gene for X-chromosomal split-hand/split-foot anomaly to Xq26–q26.1

A large inbred kindred from Pakistan in which an isolated type of split-hand/split-foot anomaly is transmitted as an X-chromosomal trait has previously been described. An X/autosomal translocation and an X-chromosomal rearrangement have been excluded by cytogenetic studies. In order to map the gene responsible for this disorder, linkage analysis has been performed by using 14 highly polymorphic DNA markers distributed over the whole X chromosome. Two-point linkage analysis between the disease locus and X-chromosomal marker loci gives maximal lod scores at = 0.00 with the loci DXS294 (Z _max= 5.13) and HPRT (Z _max= 4.43), respectively, suggesting that the gene for the X-chromosomal split-hand/split-foot anomaly is localized at Xq26–q26.1.     

The identification of a DNA polymorphism of the α fibrinogen gene,and the regional assignment of the human fibrinogen genes to 4q26-qter

Summary We have identified a common restriction fragment length polymorphism of the fibrinogen gene with the enzyme TaqI. This polymorphism is probably due to a single base change that creates or destroys a TaqI recognition site about 1000 basepairs from the 3 end of the fibrinogen géne. The frequency of the rare allele in 83 unrelated healthy individuals is 0.33. We have used in situ hybridisation of the fibrinogen cDNA to localise the gene on chromosome 4q29–31. We have confirmed this regional localisation by restriction fragment detection in a human x Chinese hamster somatic cell hybrid which contains a translocated human chromosome 4 with a breakpoint at 4q26. The , , and fibrinogen genes are all present on human chromosome 4q26-qter.     

Localization of the human c-kit protooncogene on the q11–q12 region of chromosome 4

Summary Using a 166-nucleotide-long DNA synthetic probe corresponding to the v-kit sequence (1458-1623), we have mapped the human c-kit gene to chromosome 4 at the q11–q12 band by in situ hybridization on chromosomes from human lymphocyte preparations.