Genetic mapping of nine DNA markers in the q11----q22 region of the human X chromosome

We have ordered nine polymorphic DNA markers within detailed map of the proximal part of the human X chromosome long arm, extending from band q11 to q22, by use of both physical mapping with a panel of rodent-human somatic hybrids and multipoint linkage analysis. Analysis of 44 families (including 17 families from the Centre d'Etude du Polymorphisme Humain) provided highly significant linkage data for both order and estimation of map distances between loci. We have obtained the following order: DXS1-DXS159-DXYS1-DXYS12-DXS3-(DXS94 , DXS178)-DXYS17. The most probable location of DXYS2 is between DXS159 and DXS3, close to DXYS1 and DXYS12. The high density of markers (nine loci within 30 recombination units) and the improvement in the estimation of recombination frequencies should be very useful for multipoint mapping of disease loci in this region and for diagnostic applications.     

Physical mapping studies on the human X chromosome in the region Xq27-Xqter

We have characterized three terminal deletions of the long arm of the X chromosome. Southern analysis using Xq27/q28 probes suggests that two of the deletions have breakpoints near the fragile site at Xq27.3. Flow karyotype analysis provides an estimate of 12 X 10(6) bp for the size of the deleted region. We have not detected the deletion breakpoints by pulsed-field gel electrophoresis (PFGE) using the closet DNA probes, proximal to the fragile site. The physical distance between the breakpoints and the probes may therefore be several hundred kilobases. The use of the deletion patients has allowed a preliminary physical map of Xq27/28 to be constructed. Our data suggest that the closest probes to the fragile site on the proximal side are 4D-8 (DXS98), cX55.7 (DXS105), and cX33.2 (DXS152). PFGE studies provide evidence for the physical linkage of 4D-8, cX55.7, and cX33.2. We have also found evidence for the physical linkage of F8C, G6PD, and 767 (DXS115), distal to the fragile site.     

Physical mapping of 14 new DNA markers isolated from the human distal Xp region.

We have isolated 14 new DNA markers from the human Xpter-Xp21 region distal to the Duchenne muscular dystrophy gene by targeted cloning, employing two somatic cell hybrids containing this region as their sole human material. High-resolution physical localization of these markers within this region was obtained by hybridization to two mapping panels consisting of DNA from patients carrying various translocations and deletions in distal Xp. Five markers were assigned to the pseudoautosomal region where their position on the long-range map of this region was further determined by pulsed-field gel electrophoresis. The other nine markers map to the X-specific region. Informative TaqI restriction fragment length polymorphisms were observed for four loci. One of these represents a region-specific low-copy repeated element. These 14 new markers represent useful tools for the understanding of distal Xp deletion and translocation mechanisms and for the positional cloning of disease genes in the region.     

Regional localisation of the Friedreich ataxia locus to human chromosome 9q13----q21.1

We have previously assigned the Friedreich ataxia locus (FRDA) to chromosome 9; the current maximal lod score between FRDA and MCT112 (D9S15) is greater than 50 at a recombination fraction of theta = 0. The physical assignment of the locus defined by MCT112, and hence FRDA, has not been determined, although linkage analysis of MCT112 with other chromosome 9 markers inferred a location close to the centromere. We have used in situ hybridisation with MCT112, a corresponding cosmid MJ1, and DR47 (D9S5), coupled with mapping studies on hybrid cell panels, to define more precisely the location of the disease locus. The in situ location of all three probes is 9q13----q21.1, distal to the variable heterochromatin region. Physical assignment of FRDA will allow us to identify hybrid cell lines containing the mutated gene.     

Large-scale mapping and chromosome jumping in the q27 region of the human X chromosome

We have used pulsed field gel electrophoresis for further physical mapping studies in the q27 region of the human X chromosome. We show that the DXS 102 locus and the F9 gene are separated by only 300 kb despite a genetic distance of 1.4 cM; this linkage orients our large-scale map and shows that the mcf.2 transforming sequence is telomeric to F9. A BssHII complete-digest jumping library was used to jump toward the DXS 105 locus; a 130-kb jump was achieved and the corresponding "linking clone" was obtained.     

Ordering of human chromosome 3p markers by radiation hybrid mapping.

To construct a panel of radiation hybrids (RHs) for human chromosome 3p mapping, mouse microcell hybrid cells, A9(neo3/t)-5, containing a single copy of human chromosome 3p with pSV2neo plasmid DNA integrated at 3p21-p22 were irradiated and fused to mouse A9 cells. A panel of 96 RHs that retain several sizes and portions of human chromosome 3p segments was used to map 25 DNA markers for chromosome 3p. Eight of them, H28, H29, H32, H33, H35, H38, H48, and H64, were cloned from Alu-primed PCR products using A9(neo3/t)-5 cell DNA as a template. The most likely order of the 24 markers, except for H28, based on the statistical ordering method proposed by Falk, was cen-D3S4-D3S3-D3S30-H29-D3S13-D3S2-+ ++H48-D3F15S2-D3S32-D3S23-CCK-H35-H33- D3S11-D3S12-RARB-THRB(ERBA2-pBH302)- H64-H38-RAF1-D3S18-H32-D3S22-pter. The order and location of these markers were in good agreement with those previously determined by other mapping methods, suggesting that a panel of these 96 RHs is a valuable source for a rapid mapping of human chromosome 3p markers.     

Genetic mapping of the human polymeric immunoglobulin receptor gene to chromosome region 1q31----q41

Polymeric immunoglobulin receptor (PIGR) is a transmembrane glycoprotein which is expressed by epithelial cells and is involved in the transcellular transport of polymeric immunoglobulins into secretions. We cloned the human gene for PIGR and used the clone to obtain probes to determine the chromosomal localization of PIGR. Analysis of somatic cell hybrids and in situ chromosomal hybridization localized the human PIGR gene locus to 1q31----q41.     

Physical mapping in the region of human Xq12-21.1 using pulsed field gel electrophoresis

A number of human disease genes have been localised to Xq12-21.1. A genetic map of this region has previously been constructed using family linkage studies and has been complemented by physical mapping studies using hybrid and deletion cell lines. We have constructed a preliminary long-range physical map of the region, which incorporates thirteen polymorphic and non-polymorphic probes, using pulsed field gel electrophoresis. The order of loci that can be inferred from all the genetic and physical mapping data is: cen-DXS133-[DXS153, DXS159]-DXS132-DXS135-[DXS131, DXS162]-[DXS325, DXS-347, DXS441]-PGKl-DXS447-DXS72-tel. The detection of several large non-overlapping MluI fragments by these probes implies that the minimum extent of the genomic DNA containing these loci is 16Mb. This information should be useful in the eventual identification and isolation of the genes responsible for diseases that map to this region.     

Genetic mapping of four DNA markers (DXS16, DXS43, DXS85, and DXS143) from the p22 region of the human X chromosome

Summary Linkage analysis of four polymorphic anonymous DNA markers from the Xp22 region was performed using families from the Centre d'Etude du Polymorphisme Humain. The loci DXS43 (pD2) and DXS16 (pXUT23) were found to be tightly linked ( = 0.02 at = 14.96) and proximal to both DXS85 (782) and DXS143 (dic56). Multipoint linkage analysis suggests the order:     

Isolation and mapping of 75 new DNA markers on human chromosome 3.

We have isolated and mapped 75 new DNA markers including 52 restriction fragment length polymorphism (RFLP) markers on human chromosome 3. Clones were mapped by nonisotopic in situ hybridization, in which discrete fluorescent signals can be detected on prometaphase R-banded chromosomes. Thirty-seven markers were mapped to each arm of chromosome 3, and one was localized to the centromere. Five markers defined variable number of tandem repeat (VNTR) loci. Although the 75 clones were scattered throughout the chromosome, they were concentrated in the R-positive bands. This physical map of chromosome 3 will contribute to the characterization of the chromosomal and molecular aberrations involved in renal cell carcinoma, small-cell lung cancer, and other malignancies and in single-gene disorders such as von Hippel-Lindau disease and autosomal dominant retinitis pigmentosa.     

Isolation and high-resolution mapping of new DNA markers from the pericentromeric region of chromosome 10.

The gene responsible for multiple endocrine neoplasia type 2A (MEN 2A) has been localized to the pericentromeric region of chromosome 10. Several markers that fail to recombine with MEN2A have been identified, including D10Z1, D10S94, D10S97, and D10S102. Meiotic mapping in the MEN2A region is limited by the paucity of critical crossovers identified and by the dramatically reduced rates of recombination in males. Additional approaches to mapping loci in the pericentromeric region of chromosome 10 are required. We have undertaken the generation of a detailed physical map by radiation hybrid mapping. Here we report the development of a radiation hybrid panel and its use in the mapping of new DNA markers in pericentromeric chromosome 10. The radiation-reduced hybrids used for mapping studies all retain small subchromosomal fragments that include both D10S94 and D10Z1. One hybrid was selected as the source of DNA for cloning. One hundred five human recombinant clones were isolated from a lambda library made with pp11A DNA. We have completed regional mapping of 22 of those clones using our radiation hybrid mapping panel. Seven markers have been identified and, when taken together with previously meiotically mapped markers, define eight radiation hybrid map intervals between D10S34 and RBP3. The identical order is found for a number of these using either the radiation hybrid mapping panel or the meiotic mapping panel. We believe that this combination cloning and mapping approach will facilitate the precise positioning of new markers in pericentromeric chromosome 10 and will help in refining further the localization of MEN2A.     

Assignment of human platelet GP2B (GPIIb) gene to chromosome 17, region q21.1-q21.3

Summary The platelet GPIIb-IIIa complex functions as a receptor for fibrinogen, fibronectin, and von Willebrand factor on activated platelets. This glycoprotein is a member of a broadly distributed family of structurally and immunologically related membrane receptors involved in cell-cell contact and cell-matrices interactions. GPIIb-IIIa is a heterodimer complex composed of GPIIb (the subunit), which consists of two disulfide-linked heavy and light chains, and GPIIIa (the subunit), which is a single polypeptide chain. Congenital absence of platelet GPIIb-IIIa in Glanzmann's thrombasthenia results in a severe bleeding disorder characterized by defective platelet aggregation and failure of fibrinogen to bind to platelets. The gene coding for GPIIb was located on 17q21.1-17q21.3 as determined by in situ hybridization with a 2650-pb GP2B (GPIIb) cDNA probe prepared from human megakaryocytes.     

Physical and cDNA mapping in the DBH region of human chromosome 9q34

Chromosome 9q34 has been extensively studied and mapped due to the presence of known disease genes, principally tuberous sclerosis 1 (TSC1), in this region. During the course of our mapping of this region we constructed a 555-kb contig beginning approximately 50 kb proximal to the dopamine-beta-hydroxylase (DBH) gene and extending, with one small deletion, distal to the D9S114 marker. The contig consists of 11 P1 clones, four PAC clones, one BAC clone and six cosmid clones and contains 27 new nonpolymorphic STSs. We have found the region to be unstable in P1, PAC and BAC cloning vehicles and have identified several deleted genomic clones. In addition, we have isolated and mapped the 3' portions of three putative genes located within or immediately distal to the DBH gene, including one large gene that runs on the opposite strand to DBH and utilizes portions of two DBH exons. The genomic clones of the contig, cDNAs and new STSs will be useful reagents for the further study and mapping of this region.     

Gene-dosage mapping of 30 DNA markers on chromosome 21.

Using a slot-blot method for the dosage of single-copy sequences, the copy numbers of 30 chromosome 21 markers were assessed in the blood DNA of 11 patients with partial trisomy or monosomy 21 and in the DNA of a patient-derived human-hamster hybrid cell line carrying a microduplication of chromosome 21. The physical order of these markers on chromosome 21 was thereby determined.     

Assignment of the human myeloperoxidase gene (MPO) to bands q21.3----q23 of chromosome 17

Using a human myeloperoxidase cDNA, we have mapped the human myeloperoxidase gene to chromosome 17 at q21.3----q23 by in situ hybridization to metaphase chromosomes from human lymphocyte preparations.     

Genetic mapping of the mouse X chromosome in the region homologous to human Xq27-Xq28.

The four loci Gabra3, DXPas8, CamL1, and Bpa, located near the murine X-linked visual pigment gene (Rsvp), have been ordered using 248 backcross progeny from an interspecific mating of (B6CBA-Aw-J/A-Bpa) and Mus spretus. One hundred twenty backcross progeny have been analyzed at seven anchor loci spanning the X chromosome and form a regional mapping panel. An additional 128 progeny have been screened for recombination events between Cf-9 and Dmd. Eighteen recombinants between these loci have been detected in the 248 animals; all of the recombinants were screened at the other anchor loci to identify any double crossovers. Pedigree analysis using these recombinants strongly favors a gene order of (Cf-9)-Gabra3-(DXPas8, Bpa)-CamL1-(Rsvp, P3, Cf-8)-Dmd for the loci studied. Synteny with human Xq27-Xq28 is retained, although the relative order of some loci may differ between the two species.     

Physical and radiation hybrid mapping of canine chromosome 12, in a region corresponding to human chromosome 6p12-q12

The positional cloning of the hypocretin receptor 2, the gene for autosomal recessive canine narcolepsy, has led to the development of a physical map spanning a large portion of canine chromosome 12 (CFA12), in a region corresponding to human chromosome 6p12-q13. More than 40 expressed sequence tags (ESTs) were used in homology search experiments, together with chromosome walking, to build both physical and radiation hybrid maps of the CFA12 13-21 region. The resulting map of bacterial artificial chromosome ends, ESTs, and microsatellite markers represents the longest continuous high-density map of the dog genome reported to date. These data further establish the dog as a system for studying disease genes of interest to human populations and highlight feasible approaches for positional cloning of disease genes in organisms where genomic resources are limited.     

Physical mapping of the holoprosencephaly critical region in 18p11.3.

Holoprosencephaly (HPE) is a common developmental defect that results in a spectrum of craniofacial malformations. HPE is genetically heterogeneous, some cases being associated with deletions of the short arm of chromosome 18. In order to map the putative HPE gene located on 18p (HPE4) more precisely, six patients with various cytogenetic 18p deletions and clinical features of HPE have been characterized by using a combination of somatic cell hybrid analysis and FISH. By using a set of 27 chromosome 18p-specific markers, the deletion in each patient was characterized. The HPE minimal critical region on 18p was defined on a molecular level, localizing the HPE4 gene to 18p11.3.     

Human metallothionein-II processed gene is located in region p11----q21 of chromosome 4

Metallothionein (MT) genes comprise a multigene family encoding low-molecular-weight, heavy-metal-binding proteins. We have mapped a human MT-II processed gene to chromosome 4, using Southern blotting in combination with a human X mouse hybrid clone panel containing defined subsets of human chromosomes. We have further localized this gene to region p11----q21, using in situ hybridization.