Refined radiation hybrid map of mouse Chromosome 17

We have made a radiation hybrid map of mouse Chromosome (Chr) 17 with 75 microsatellite markers, including those from McCarthy et al. (Genome Res 7, 1153–1161, 1997). Seventy-four of the markers are linked at LOD > 9, and all link at LOD > 5. A LOD 3 framework of 18 markers was used to construct a placement map. The order obtained is in good agreement with genetic maps, and distance estimates give an idea of how recombination rates vary across the chromosome. Recombination is remarkably low with respect to RH break frequency in the region from the centromere to the end of H2. This is similar in interspecific and intersubspecific crosses despite the inversion of a substantial part of this region in Mus spretus with respect to Mus musculus. Received: 10 April 1998 / Accepted: 18 June 1998     

A high-resolution radiation hybrid map of the proximal portion of mouse chromosome 5

Radiation hybrid (RH) mapping of the mouse genome provides a useful tool in the integration of existing genetic and physical maps, as well as in the ongoing effort to generate a dense map of expressed sequence tags. To facilitate functional analysis of mouse Chromosome 5, we have constructed a high-resolution RH map spanning 75 cM of the chromosome. During the course of these studies, we have developed RHBase, an RH data management program that provides data storage and an interface to several RH mapping programs and databases. We have typed 95 markers on the T31 RH panel and generated an integrated map, pooling data from several sources. The integrated RH map ranges from the most proximal marker, D5Mit331 (Chromosome Committee offset, 3 cM), to D5Mit326, 74.5 cM distal on our genetic map (Chromosome Committee offset, 80 cM), and consists of 138 markers, including 89 simple sequence length polymorphic markers, 11 sequence-tagged sites generated from BAC end sequence, and 38 gene loci, and represents average coverage of approximately one locus per 0.5 cM with some regions more densely mapped. In addition to the RH mapping of markers and genes previously localized on mouse Chromosome 5, this RH map places the alpha-4 GABA(A) receptor subunit gene (Gabra4) in the central portion of the chromosome, in the vicinity of the cluster of three other GABA(A) receptor subunit genes (Gabrg1-Gabra2-Gabrb1). Our mapping effort has also defined a new cluster of four genes in the semaphorin gene family (Sema3a, Sema3c, Sema3d, and Sema3e) and the Wolfram syndrome gene (Wfs1) in this region of the chromosome.     

Genetic maps of mouse chromosome 17 including 12 new anonymous DNA loci and 25 anchor loci.

An interspecific backcross between lab mice and Mus spretus was used to construct a multilocus map of Chromosome 17 consisting of 12 new anonymous loci and 9 anchor loci. In addition, 7 anonymous DNA loci were added to the Chr 17 map for the BXD strains. Although we were able to identify readily the most likely gene order in the interspecific backcross, we found no evidence for an unambiguous gene order using the BXD recombinant inbred strains. Comparison of the interspecific backcross map and the BXD RI strain map revealed evidence in the interspecific backcross for a longer total genetic length, enhanced recombination distal to H-2, a segment showing suppressed recombination, and strong interference.     

Mapping of PCR-based markers for mouse Chromosome 4 on a backcross penetrant for the misty (m) mutation

A genetic linkage map for mouse Chromosome (Chr) 4 (MMU 4) has been constructed with an intersubspecific backcross between the C57BL/KsJ strain homozygous for the misty (m) coat color locus and the inbred Mus musculus musculus Czech II strain. Several recently developed PCR-based simple sequence length polymorphism (SSLP) markers have been intercalated among genebased markers including six anchor loci on mouse Chr 4 to assemble this map. Marker order and genetic distances are similar to the composite genetic linkage map compiled from crosses between a variety of other inbred and feral mouse strains. Transmission ratio distortion in favor of feral alleles is apparent for a region of distal MMU 4. In addition, the misty phenotype is more fully penetrant in the present backcross than in other reported interspecific and intersubspecific crosses. Backcrosses employing inbred Mus musculus musculus strains may allow reliable phenotyping and mapping of mouse mutations displaying complex phenotypes with incomplete and/or ambigious penetrance on other feral genetic backgrounds.     

Integration of the feline radiation hybrid and linkage maps

The recent development of genome mapping resources for the domestic cat provides a unique opportunity to study comparative medicine in this companion animal which can inform and benefit both veterinary and human biomedical concerns. We describe here the integration and order comparison of the feline radiation hybrid (RH) map with the feline interspecies backcross (ISB) genetic linkage map, constructed by a backcross of F₁ hybrids between domestic cat (Felis catus) and the Asian leopard cat (Prionailurus bengalensis). Of 253 microsatellite loci mapped in the ISB, 176 equivalently spaced markers were ordered among a framework of 424 Type I coding markers in the RH map. The integration of the RH and ISB maps resolves the orientation of multiple linkage groups and singleton loci from the ISB genetic map. This integrated map provides the foundation for gene mapping assessments in the domestic cat and in related species of the Felidae family. Received: 10 July 2000 / Accepted: 01 February 2001     

Construction of a new porcine whole-genome framework map using a radiation hybrid panel

We have constructed a radiation hybrid (RH) map of the porcine genome using an RH panel generated by an irradiation dose of 5000-rad (Sus scrofa radiation hybrid map, SSRH map). Normal porcine aortic endothelial cells were irradiated and fused with a thymidine kinase-deficient mouse cell line, L-M (TK-). A total of 110 cell lines were selected and used for further analysis. Among 1091 microsatellite (MS) markers selected for mapping, 842 markers (77%) could be typed on the panel. The framework map comprised 342 MS markers and an additional 247 MS markers were then added to generate the whole-genome map. The average retention frequency for the data set was 30.6%. The total map length was 5596.2 centiRay (cR). Using an estimated physical length of 2718 Mbp, the average ratio between cR and physical distance over the porcine genome was estimated to be 0.49 Mb/cR.     

Construction, analysis, and application of a radiation hybrid mapping panel surrounding the mouse agouti locus.

The region surrounding the agouti coat color locus on mouse Chromosome 2 contains several genes required for peri-implantation development, limb morphogenesis, and segmentation of the nervous system. We have applied radiation hybrid mapping, a somatic cell genetic technique for constructing long-range maps of mammalian chromosomes, to eight molecular markers in this region. Using a mathematical model to estimate the frequency of radiation-induced breakage, we have constructed a map that spans approximately 20 recombination units and 475 centirays8000. The predicted order of markers, Prn-p-Pygb-Emv-13-Psp-Xmv-10-Emv-15-Src-Ada, is consistent with a previously derived multipoint meiotic map for six of the eight markers and suggests that Xmv-10 may lie relatively close to one or more of the agouti recessive lethal mutations. The resolution of our map is approximately 40-fold higher than the meiotic map, but the median retention frequency of mouse DNA in hybrid cells, 0.12, is 4-fold lower than similar experiments with human chromosomes. From one of the radiation hybrid lines that contained a minimum amount of mouse DNA, 25 independent cosmids were isolated with a mouse-specific hybridization probe. Single-copy fragments from two of these cosmids were shown to originate from mouse Chromosome 2, and the meiotic map position of one was found to be within 10 recombination units of the region of interest. Our results indicate more precise map positions for Pygb and Xmv-10, demonstrate that radiation hybrid mapping can provide high-resolution map information for the mouse genome, and establish a new method for isolating large fragments of DNA from a specific subchromosomal region.     

A radiation hybrid map of chicken Chromosome 4

The mapping resolution of the physical map for chicken Chromosome 4 (GGA4) was improved by a combination of radiation hybrid (RH) mapping and bacterial artificial chromosome (BAC) mapping. The ChickRH6 hybrid panel was used to construct an RH map of GGA4. Eleven microsatellites known to be located on GGA4 were included as anchors to the genetic linkage map for this chromosome. Based on the known conserved synteny between GGA4 and human Chromosomes 4 and X, sequences were identified for the orthologous chicken genes from these human chromosomes by BLAST analysis. These sequences were subsequently used for the development of STS markers to be typed on the RH panel. Using a logarithm of the odds (LOD) threshold of 5.0, nine linkage groups could be constructed which were aligned with the genetic linkage map of this chromosome. The resulting RH map consisted of the 11 microsatellite markers and 50 genes. To further increase the number of genes on the map and to provide additional anchor points for the physical BAC map of this chromosome, BAC clones were identified for 22 microsatellites and 99 genes. The combined RH and BAC mapping approach resulted in the mapping of 61 genes on GGA4 increasing the resolution of the chicken–human comparative map for this chromosome. This enhanced comparative mapping resolution enabled the identification of multiple rearrangements between GGA4 and human Chromosomes 4q and Xp.     

A radiation hybrid map spanning the entire human X Chromosome integrating YACs,genes, and STS markers

We present a radiation hybrid (RH) map of human Chromosome (Chr) X, using 50 markers on 72 radiation hybrids. The markers, obtained from the consensus map, form a grid spanning the entire chromosome. To check the RH map, the marker order was determined by analysis of presence or absence of retained human DNA fragments in the RHs; the comparison with the consensus showed a similar order. Any STSs, microsatellites, genes, and clones can be positioned and ordered relative to the marker grid. This approach integrates genetic, physical, and large-scale clone mapping and is used to link YAC contigs containing data from various experimental sources. Received: 14 February 1996 / Accepted: 20 May 1996     

Development of a gene-based radiation hybrid map of chicken Chromosome 7 and comparison to human and mouse

To validate the ChickRH6 whole-genome radiation hybrid (WGRH) panel, we constructed a map of chicken Chromosome 7 based on 19 microsatellite markers from the genetic map and 76 ESTs (expressed sequence tags), whose efficient targeted development was made possible by using the ICCARE software. This high-density radiation hybrid (RH) map of a chicken macrochromosome gives us indications on characteristics of ChickRH6. The potential resolution of the panel is 325 kb and the practical resolution of our framework map is 1.3 Mb. Based on these results, a complete framework map of the chicken genome would comprise 1000 markers. The marker order is in good agreement with the genetic map and comparison with the human and mouse sequence maps revealed a number of internal rearrangements.     

Evidence for abundant transcription of non-coding regions in the Saccharomyces cerevisiae genome

Background

The ChickRH6 whole chicken genome radiation hybrid (RH) panel recently produced has already been used to build radiation hybrid maps for several chromosomes, generating comparative maps with the human and mouse genomes and suggesting improvements to the chicken draft sequence assembly. Here we present the construction of a RH map of chicken chromosome 2. Markers from the genetic map were used for alignment to the existing GGA2 (Gallus gallus chromosome 2) linkage group and EST were used to provide valuable comparative mapping information. Finally, all markers from the RH map were localised on the chicken draft sequence assembly to check for eventual discordances.

Results

Eighty eight microsatellite markers, 10 genes and 219 EST were selected from the genetic map or on the basis of available comparative mapping information. Out of these 317 markers, 270 gave reliable amplifications on the radiation hybrid panel and 198 were effectively assigned to GGA2. The final RH map is 2794 cR₆₀₀₀ long and is composed of 86 framework markers distributed in 5 groups. Conservation of synteny was found between GGA2 and eight human chromosomes, with segments of conserved gene order of varying lengths.

Conclusion

We obtained a radiation hybrid map of chicken chromosome 2. Comparison to the human genome indicated that most of the 8 groups of conserved synteny studied underwent internal rearrangements. The alignment of our RH map to the first draft of the chicken genome sequence assembly revealed a good agreement between both sets of data, indicative of a low error rate.     

An interspecific linkage map of mouse chromosome 15 positioned with respect to the centromere

We have used an interspecific backcross between C57BL/6J and Mus spretus to derive a molecular genetic linkage map of chromosome 15 that includes 25 molecular markers and spans 93% of the estimated length of chromosome 15. Using a second interspecific backcross that was analyzed with a centromere-specific marker, we were also able to position our map with respect to the chromosome 15 centromere. This map provides molecular access to many discrete regions on chromosome 15, thus providing a framework for establishing relationships between cloned DNA markers and known mouse mutations and for identifying homologous genes in mice and humans that may be involved in disease.     

A human genome map of comparative anchor tagged sequences.

Effective comparative mapping inference utilizing developing gene maps of animal species requires the inclusion of anchored reference loci that are homologous to genes mapped in the more "gene-dense" mouse and human maps. Nominated anchor loci, termed comparative anchor tagged sequences (CATS), have been ordered in the mouse linkage map, but due to the dearth of common polymorphisms among human coding genes have not been well represented in human linkage maps. We present here an ordered framework map of 314 comparative anchor markers in humans based on mapping analysis in the Genebridge 4 panel of radiation hybrid cell lines, plus empirically optimized CATS PCR primers which detect these markers. The ordering of these homologous gene markers in human and mouse maps provides a framework for comparative gene mapping of representative mammalian species.     

A Whole-Genome Radiation Hybrid Map of the Dog Genome

A whole genome radiation hybrid (RH) map of the canine genome was constructed by typing 400 markers, including 218 genes and 182 microsatellites, on a panel of 126 radiation hybrid cell lines. Fifty-seven RH groups have been determined with lod scores greater than 6, and 180 framework landmarks were ordered with odds greater than 1000:1. Average spacing between adjacent markers is 23 cR₅₀₀₀, an estimated physical distance of 3.8 Mb. Fourteen groups have been assigned to 9 of the canine chromosomes, and a comparison of RH and genetic groups allowed the successful bridging of both types of data on one map composed of 31 RH and 13 syntenic RH groups. Comparison of canine, human, mouse, and pig maps underlined regions of conserved synteny. This integrated map, covering an estimated 80% of the dog genome, should prove a powerful tool for localizing and identifiying genes implicated in pathological and phenotypical traits.     

A radiation hybrid map of chicken chromosome 15

We have constructed a radiation hybrid (RH) map of chicken chromosome (GGA) 15. This map can be used as a resource to efficiently map genes to this chromosome. The map has been developed using a 6000 rad chicken-hamster whole-genome radiation hybrid panel (ChickRH6). In total, six microsatellite loci, 18 sequence tagged sites (STSs) from BAC end sequences and 11 genes were typed on the panel. The initial framework map comprised eight markers, and an additional 23 markers were then added to generate the final map. The total map length was 334 centiRay6000 (cR6000). The estimated retention frequency for the data set was 18%. Using an estimated physical length of 21 Mb, the ratio between cR6000 and physical distance over GGA15 was estimated to be 0.063 Mb/cR6000. The present map increases the marker density and the marker resolution on GGA15 and enables fast mapping of new chicken genes homologous to genes from human chromosomes 12 and 22.     

Conservation of gene order between horse and human X chromosomes as evidenced through radiation hybrid mapping

A radiation hybrid (RH) map of the equine X chromosome (ECAX) was obtained using the recently produced 5000(rad) horse x hamster hybrid panel. The map comprises 34 markers (16 genes and 18 microsatellites) and spans a total of 676 cR(5000), covering almost the entire length of ECAX. Cytogenetic alignment of the RH map was improved by fluorescent in situ hybridization mapping of six of the markers. The map integrates and refines the currently available genetic linkage, syntenic, and cytogenetic maps, and adds new loci. Comparison of the physical location of the 16 genes mapped in this study with the human genome reveals similarity in the order of the genes along the entire length of the two X chromosomes. This degree of gene order conservation across evolutionarily distantly related species has up to now been reported only between human and cat. The ECAX RH map provides a framework for the generation of a high-density map for this chromosome. The map will serve as an important tool for positional cloning of X-linked diseases/conditions in the horse.     

A high-resolution radiation hybrid map of the proximal region of rat Chromosome 4

Radiation hybrid (RH) mapping has been used to produce genome maps in the human and mouse, but as yet the technique has been applied little to other species. We describe the use of RH mapping in the rat, using a newly available rat/hamster RH panel, to construct an RH map of the proximal part of rat Chromosome (Chr) 4. This region is of interest because quantitative trait loci (QTLs) for defective insulin and catecholamine action, hypertension, and dyslipidemia map to this region. The RH map includes 23 rat genes or microsatellites previously mapped to this part of Chr 4, one rat gene not previously mapped in the rat, and markers for four new genes, homologs of which map to the syntenic region of the mouse genome. The RH map integrates genetic markers previously mapped on several rat crosses, increases the resolution of existing maps, and may provide a suitable basis for physical map construction and gene identification in this chromosomal region. Our results demonstrate the utility of RH mapping in the rat genome and show that RH mapping can be used to localize, in the rat genome, the homologs of genes from other species such as the mouse. This will facilitate identification of candidate genes underlying QTLs on this chromosomal segment. Received: 4 December 1998 / Accepted: 19 January 1999     

Second-generation integrated genetic linkage/radiation hybrid maps of the domestic cat (Felis catus)

We report construction of second-generation integrated genetic linkage and radiation hybrid (RH) maps in the domestic cat (Felis catus) that exhibit a high level of marker concordance and provide near-full genome coverage. A total of 864 markers, including 585 coding loci (type I markers) and 279 polymorphic microsatellite loci (type II markers), are now mapped in the cat genome. We generated the genetic linkage map utilizing a multigeneration interspecies backcross pedigree between the domestic cat and the Asian leopard cat (Prionailurus bengalensis). Eighty-one type I markers were integrated with 247 type II markers from a first-generation map to generate a map of 328 loci (320 autosomal and 8 X-linked) distributed in 47 linkage groups, with an average intermarker spacing of 8 cM. Genome coverage spans approximately 2,650 cM, allowing an estimate for the genetic length of the sex-averaged map as 3,300 cM. The 834-locus second-generation domestic cat RH map was generated from the incorporation of 579 type I and 255 type II loci. Type I markers were added using targeted selection to cover either genomic regions underrepresented in the first-generation map or to refine breakpoints in human/feline synteny. The integrated linkage and RH maps reveal approximately 110 conserved segments ordered between the human and feline genomes, and provide extensive anchored reference marker homologues that connect to the more gene dense human and mouse sequence maps, suitable for positional cloning applications.     

A Radiation Hybrid Map of BTA23: Identification of a Chromosomal Rearrangement Leading to Separation of the Cattle MHC Class II Subregions

Bovine chromosome 23 (BTA23) contains the bovine major histocompatibility complex (MHC) and is thus of particular interest because of the role of MHC genes in immunity. Previous studies have shown cattle MHC class II genes to be subdivided into two distinct subregions separated by a variable genetic distance of 15–30 cM. To elucidate the genetic events that resulted in the present organization of the class II and other MHC genes, a framework radiation hybrid (RH) map of BTA23 was developed by testing DNA samples from a 5000 rad whole genome RH panel. Twenty-six markers were screened with an average retention frequency of 0.27, ranging from 0.14 to 0.42. Total length of the chromosome was 220 cR₅₀₀₀, with 4.1 cR₅₀₀₀/cM when compared to linkage data. Gene orders for the markers common to both the RH framework map and the consensus framework linkage map are identical. Large centiray intervals,D23S23–D23S7, DYA–D23S24andCYP21–D23S31,were observed compared to linkage distances. These data may indicate a much larger physical distance or suppression of recombination in the interval separating the class II subregions and also within the class I region than previously estimated. Comparison of 13 Type I genes conserved between BTA23 and the human homolog HSA6p suggests the occurrence of an inversion encompassing the centromeric half of the bovine chromosome, thus explaining the large distance between the bovine class IIa and IIb clusters. These results exemplify the power of RH mapping in solving problems in comparative genomics and evolution. Furthermore, noncongruence of the genetic and physical RH map distances indicates that caution must be observed in using either resource alone in searching for candidate genes controlling traits of economic importance.     

A radiation hybrid map of bovine chromosome 24 and comparative mapping with human chromosome 18

We present herein a bovine chromosome 24 (BTA24) radiation hybrid (RH) map using 40 markers scored on a panel of 90 RHs. Of these markers, 29 loci were ordered with odds of at least 1000:1 in a framework map. An average retention frequency of 17.4% was observed, with relatively higher frequencies near the centromere. The length of the comprehensive map was 640 centiray5000 (cR5000) with an average marker interval of approximately 17.3 cR5000. The observed locus order is generally consistent with currently published bovine linkage and physical maps. Nineteen markers were either Type I loci or closely associated with expressed sequences and thus could be used to compare the BTA24 RH map with human mapping information. All genes located on BTA24 were located on human chromosome 18, and previously reported regions of conserved synteny were extended. The comparative data revealed the presence of at least six conserved regions between these chromosomes.