Construction of a 2.6-Mb contig in yeast artificial chromosomes spanning the human dystrophin gene using an STS-based approach.

A sequence tagged site (STS)-based approach has been used to construct a 2.6-Mb contig in yeast artificial chromosomes (YACs) spanning the human dystrophin gene. Twenty-seven STSs were used to identify and overlap 34 YAC clones. A DNA fingerprint of each clone produced by direct Alu-PCR amplification of YAC colonies and the isolation of YAC insert ends by vectorette PCR were used to detect overlaps in intron 1 (280 kb) where no DNA sequence data were available, thereby achieving closure of the map. This study has evaluated methods for mapping large regions of the X chromosome and provides a valuable resource of the dystrophin gene in cloned form for detailed analysis of gene structure and function in the future.     

An intronic region within the human factor VIII gene is duplicated within Xq28 and is homologous to the polymorphic locus DXS115 (767)

The genomic sequences recognized by the anonymous probe 767 (DXS115) are localized to two sites within Xq28. One site lies within intron 22 of the factor VIII gene (FBC). Physical mapping suggests that the second site lies within 1.2 megabases of the F8C gene. The RFLPs detected by 767 are located within the second site. Genetic data suggest that F8C and DXS115 are tightly linked (theta max = .04; Zmax = 8.30). Recombination events in meioses informative for DXS52 (St14), DXS115, and F8C suggest that DXS115 and F8C lie distal to DXS52.     

Isolation and characterization of a yeast artificial chromosome (YAC) contig around the human steroid sulfatase gene.

The region surrounding the steroid sulfatase (STS) locus on Xp22.3 is of particular interest since it represents a deletion hot spot, shares homology with the proximal long arm of the Y chromosome (Yq11.2), and contains genes for several well-described X-linked disorders. Here we describe yeast artificial chromosomes (YACs) covering 450 kb around the STS gene. Eight YAC clones were isolated from a human YAC library. Their STS exon content was determined and the overlap of the clones characterized. Two of the YAC clones were found to contain the entire STS gene. The most proximal and the most distal ends of the YAC contig were cloned but neither of them crossed the breakpoints in any of the previously described patients with entire STS gene deletions. This is consistent with deletions larger than 500 kb in all these patients. One of the YAC clones was found to contain sequences from the STS pseudogene on Yq11.2. Two anonymous DNA sequences, GMGXY19 and GMGXY3, previously mapped in the vicinity of the STS locus, were found within the YAC contig and their assignment with respect to the STS locus was thus possible. This contig is useful for the overlap cloning of the Xp22.3 region and for reverse genetic strategies for the isolation of disease genes in the region. Furthermore, it may provide insight into the molecular mechanisms of deletion and translocation events on Xp22.3 and in the evolution of sex chromosomes.     

Physical mapping of the factor VIII gene proximal to two polymorphic DNA probes in human chromosome band Xq28: implications for factor VIII gene segregation analysis

Genomic DNA segments for the coagulation factor VIIIc gene (F8C), which exhibits only limited restriction length polymorphism, map to the proximal region of band Xq28 by somatic cell hybridization analysis and in situ hybridization. Using somatic cell hybrids, we have obtained data which place probes DX13 (used to detect locus DXS15) and St14 (used to detect DXS52) distal to F8C, within band Xq28. Previous studies have mapped the factor IX gene (F9) and probe 52A (used to detect DXS51) proximal to F8C, in Xq26----q27 and Xq27, respectively (Camerino et al., 1984; Drayna et al., 1984; Mattei et al., 1985). Thus, the relative order of genetic marker loci in the Xq27----qter region is most likely cen-F9-DXS51-F8C-(DXS15, DXS52)-Xqter. The collection of these molecular probes is thus potentially useful in three-factor crosses of factor VIII gene segregation.     

Cloning and in vivo expression of the human GART gene using yeast artificial chromosomes.

Two Yeast Artificial Chromosomes (YACs) were isolated each with a full-length copy of the human gene that encodes the trifunctional protein containing phosphoribosylglycinamide synthetase (GARS), phosphoribosylglycinamide formyltransferase (GART) and phosphoribosylaminoimidazole synthetase (AIRS). The YACs were characterized by restriction mapping and by in situ hybridization of cosmid subclones containing the YAC ends to human metaphase chromosomes. One of the YACs contains co-cloned non-contiguous DNA whereas the other appears to have a single 600 kbp insert from 21q22.1, the location of the GART gene. A restriction map of the gene was obtained from two cosmid subclones which together span the 40 kb gene. The gene is functional when YAC DNA is transferred into GARS- or GARS-and-AIRS-deficient Chinese Hamster Ovary cells. The gene transfer was carried out both by lipofection using purified yeast DNA and by fusion between yeast spheroplasts and the hamster cells. Restriction analysis of DNA from cell lines whose purine auxotrophy was complemented by the YAC showed that with either method a complete and unrearranged copy of the gene can be transferred. The majority of the fusion cell lines appear to contain at least 80% of the YAC.     

Construction of a 1.2-Mb contig including the citrus tristeza virus resistance gene locus using a bacterial artificial chromosome library of Poncirus trifoliata (L.) Raf.

The citrus tristeza virus resistance gene (Ctv) is a single dominant gene in Poncirus trifoliata, a sexually compatible relative of citrus. To clone this gene, a bacterial artificial chromosome (BAC) library has been constructed from an individual plant that was homozygous for Ctv. This library contains 45,696 clones with an average insert size of 80 kb, corresponding to 9.6 genome equivalents. Screening of the BAC library with five chloroplast DNA probes indicated that 0.58% of the BAC clones contained chloroplast-derived inserts. The chromosome walk across the Ctv locus was initiated using three closely linked genetic markers: C19, AD8, and Z16. The walk has been completed and a contig of ca. 1.2 Mb was constructed. Based on new data, the genetic map in the Ctv region was revised, with Ctv being located between AD8-Z16 and C19 at distances of 1.2 and 0.6 cM, respectively. Utilizing DNA fragments isolated from the contig as RFLP markers, the Ctv locus was further mapped to a region of ca. 300 kb. This contig contains several putative disease-resistance genes similar to the rice Xa21 gene, the tomato Cf-2 gene, and the Arabidopsis thaliana RPS2 gene. This library will therefore allow cloning of Ctv and other putative disease-resistance genes.     

Characterization and expression of the human leukocyte-common antigen (CD45) gene contained in yeast artificial chromosomes.

The leukocyte-common antigen (CD45) is a transmembrane protein tyrosine phosphatase expressed uniquely by cells of hematopoietic origin. There are multiple isoforms of CD45 that are generated by the variable use of three exons (exons 4-6). The use of the variable exons results in changes near the amino-terminus of the mature glycoprotein. The gene is located on chromosome 1 for both human and mouse in a region that is homologous between these two species. This conserved linkage group contains a number of genes of immunological interest, such as the genes for complement regulatory proteins and the FCG2 receptor. Yeast artificial chromosomes provide a vector system in which large fragments of foreign DNA can be isolated and are suited to long-range physical mapping. To this end, three yeast artificial chromosomes containing the human CD45 gene have been isolated and characterized. They overlap to span 475 kb, establishing the largest physical map for DNA within the conserved linkage group. The CD45 gene is entirely encoded within one yeast artificial chromosome clone as determined by mapping with cDNA probes. A mouse B cell line transfected with this YAC clone expressed the low-molecular-weight isoform of the protein into the cell surface. The size of the human CD45 gene was determined to be approximately 120 +/- 10 kb.     

Systematic generation of sequence-tagged sites for physical mapping of human chromosomes: application to the mapping of human chromosome 7 using yeast artificial chromosomes.

Basic to the development of long-range physical maps of DNA are the detection and localization of landmarks within recombinant clones. Sequence-tagged sites (STSs), which are short stretches of DNA that can be specifically detected by the polymerase chain reaction (PCR), can be used as such landmarks. Our interest is to construct physical maps of whole human chromosomes by localizing STSs within yeast artificial chromosome (YAC) clones. Here we describe a generalized strategy for the systematic generation of large numbers of STSs specific for human chromosome 7. These STSs can be detected by PCR assays developed following the sequencing of anonymous pieces of chromosome 7 DNA, which was derived from flow-sorted chromosomes or from lambda clones made from DNA of a human-hamster hybrid cell line. Our approach for STS generation is tailored for the development of PCR assays capable of screening a large YAC library. In this study, we report the generation of 100 new STSs specific to human chromosome 7.     

Identification of a CA repeat at the TCRA locus using yeast artificial chromosomes: a general method for generating highly polymorphic markers at chosen loci.

The creation of a comprehensive genetic map in human has been limited by the lack of highly polymorphic markers spaced evenly throughout the human genome. We have utilized yeast artificial chromosomes (YAC) containing large human DNA inserts to help identify highly polymorphic (CA)n repeats at a chosen locus. The DNA of a YAC containing the locus was subcloned in M13 vectors, and the recombinants were screened at high stringency to detect preferentially long (CA)n repeats (n greater than 20). These repeats, which are the most likely to be highly polymorphic, were then studied to confirm both the level of polymorphism and their precise genetic location. This strategy has permitted the identification of a new, highly polymorphic CA repeat (77% heterozygosity) at the T cell receptor alpha chain (TCRA) locus on chromosome 14q. It provides a powerful marker for assessing the role of this locus in the susceptibility to autoimmune and infectious diseases. This approach should permit the development of highly polymorphic markers at any targeted locus and rapidly improve the current human genetic map.     

Recombination between two 14-bp homologous sequences as the mechanism for gene deletion in factor IX Seattle 1.

Factor IXSeattle 1 is a 10-kb intragenic deletion identified in a family that has hemophilia B. By sequencing across the site of the deletion, we discovered at the deletion junction a 13-bp sequence (5' . . . TAGAA-GTTCACTT . . . 3') that was homologous to two 14-bp sequences 10 kb apart in introns D and F of the normal factor IX gene. The presence of these homologous sequences in two different regions of the normal gene allows us to propose that genetic recombination has occurred between the sequences, resulting in the gene deletion. The precise recombination site was able to be localized to one of 5 bp (5' . . . AGTTC . . . 3') in the middle of the homologous sequences. The exact length of the deletion is 10,000 bp.     

Genome mapping of the silver fox. I. Determination of the chromosomal location of 8 fox genes and the search for homologous regions on fox and human chromosomes

Twenty-three silver fox-Chinese hamster somatic cell hybrids were analysed for the expression of fox enzyme loci and the segregation of fox chromosomes. This analysis made it possible to assign the gene PGD to chromosome 2, MDH2 to chromosome 3. NP to chromosome 10. APRT, ENO1, PGM1 to chromosome 12, MDH1 and IDH1 to chromosome 16. Possible use of the above-mentioned clone panel for fox gene mapping is analysed. An attempt to reveal homologous regions on fox and human chromosomes was made by comparative analysis of prometaphase fox and human chromosomes containing the homologous genes. The means and perspectives of verification of the hypothesis proposed are discussed.     

Existence of common homologous elements in the transcriptional regulatory regions of human nuclear genes and mitochondrial gene for the oxidative phosphorylation system.

Our previous study indicated that nuclear protein factors of HeLa cells specifically bind to three nuclear Mt elements, Mt1, Mt3, and Mt4, located in the 5'-flanking regions of the human nuclear genes for cytochrome c1 and for ubiquinone-binding protein, both of which are subunits of mitochondrial cytochrome bc1 complex (Suzuki, H., Hosokawa, Y., Toda, H., Nishikimi, M., and Ozawa, T. (1990) J. Biol. Chem. 265, 8159-8163). In this study, we examined whether the same nuclear factors could recognize a set of the Mt3 and Mt4 elements that were found in the displacement loop and the promoter region of mammalian mitochondrial genomes. Gel retardation experiments disclosed that the same nuclear protein factors specifically bind to those Mt elements in the human mitochondrial genome as well as to the nuclear Mt3 and Mt4 elements of the two genes, and that the coexistence of both the elements is required for the efficient binding. The nuclear protein factors which recognize the Mt elements located in the regulatory regions of the nuclear and mitochondrial genes may play an important role in coordinate expression of the two physically separated genes during mitochondrial biogenesis.     

Distinct regions of the human granulocyte-colony-stimulating factor receptor cytoplasmic domain are required for proliferation and gene induction.

Using two different cell systems, we show that the cytoplasmic domain of the granulocyte-colony-stimulating factor receptor (G-CSFR) may be composed of at least two functional regions. The first, within the membrane-proximal 57 amino acids, is absolutely required to deliver a proliferative signal. This region contains two sequence motifs conserved between members of the hematopoietin receptor family. The second functional region resides between amino acids 57 and 96. This region is required for the induction of acute-phase plasma protein gene expression when the G-CSFR is transfected into human hepatoma cell lines. The G-CSFR-transfected hepatoma cells respond to G-CSF by increasing the production of the same set of plasma proteins as stimulated by interleukin-6, suggesting that the two cytokines share a common signal transduction pathway.     

Construction of cDNA coding for human von Willebrand factor using antibody probes for colony-screening and mapping of the chromosomal gene.

Von Willebrand Factor (vWF) mRNA was identified in fractionated polyA+ RNA preparations isolated from cultured human endothelial cells. Micro-injection of specific polyA+ RNA fractions in Xenopus laevis oocytes provoked the synthesis of a vWF-like product which could be detected with an immunoradiometric assay relying on Sepharose-linked monoclonal anti-vWF IgG and different radiolabeled monoclonal anti-vWF IgGs. A vWF-mRNA-containing polyA+ RNA preparation served as substrate for a size-selected cDNA-expression library of 60 000 colonies which was screened for the synthesis of antigens related to vWF, using polyclonal anti-vWF IgG and a second antibody conjugated with peroxidase. Eight positive colonies were detected of which two reacted strongly in the enzyme-linked assay. Immunoblotting of bacterial extracts of "expression clones" with a monoclonal anti-vWF IgG revealed polypeptides which size fits within the length of the cDNA insertions. Northern blotting of human endothelial RNA, employing fragments of vWF cDNA as probes, showed specific hybridization with a mRNA of about 9000 nucleotides. DNA-sequence analysis of a vWF-cDNA insertion revealed an open reading frame followed by a translation stopcodon. It is argued that the cDNA insertions encode the carboxy-terminal part of the vWF protein. vWF-cDNA probes were employed to map the von Willebrand factor gene on chromosome 12 using a panel of 35 human-rodent somatic cell hybrids.     

Construction of yeast artificial chromosome (YAC) clone banks covering three genome equivalents and isolation of YACs containing the human gene encoding tumor necrosis factor receptor β

Yeast artificial chromosome (YAC) banks covering in total about three haploid genome equivalents were constructed using a human Epstein-Barr-virus-transformed B lymphocytic cell line. Two clone banks were made: 20 000 clones with average inserts of 350 kb in the pYAC4 vector and 9850 clones with average inserts of 180 kb using vectors pJS89 and pJS91. Direct comparison of pYAC4 with pJS89 and pJS91 showed pYAC4 to be the most suitable cloning vector. Two partial banks with average insert sizes of 220 kb for human endothelial cell DNA and epithelial HEp2 cell DNA were also constructed, each covering 10% of the haploid genome. A rapid, three-step PCR screening procedure for isolation of individual YAC clones was developed and used to identify two clones encoding TNF-Rβ. These clones cover about 200 kb and have 170 kb in common. TNF-Rβ is 9.3 kb long and contains two introns within the protein-coding sequence.     

Analysis of the BglI restriction fragment length polymorphism in the human factor VIII gene using “virtual PCR”– a novel approach employing the polymerase chain reaction in the absence of sequence information for the locus

The BglI restriction fragment length polymorphism (RFLP) of the human factor VIII (FVIII) gene is potentially useful in linkage studies in haemophilia A. The sequence at the RFLP locus is not known, therefore it is not amenable to analysis by the polymerase chain reaction (PCR) and Southern blotting is required. We present a novel approach for analysis of the BglI RFLP using the PCR targeted to known sequence downstream in exon 26 of the FVIII gene. Briefly, the size of the genomic restriction fragment carrying the PCR target depends upon whether the RFLP site is present or absent. If fragments of the required size are isolated from a genomic digest and used as substrates in the exon 26 PCR, the generation of a product in one or other fraction indicates the upstream RFLP status. We have called this approach “virtual PCR”, since PCR is used to obtain information about the RFLP without amplifying the locus itself. Received: 23 January 1996 / Revised: 18 March 1996