Generation of a panel of somatic cell hybrids containing unselected fragments of human chromosome 10 by X-ray irradiation and cell fusion: application to isolating the MEN2A region in hybrid cells

Transchromosomal mouse embryonic stem cell lines and chimeric mice that contain freely segregating segments of human chromosome 21

At least 8% of all human conceptions have major chromosome abnormalities and the frequency of chromosomal syndromes in newborns is >0.5%. Despite these disorders making a large contribution to human morbidity and mortality, we have little understanding of their aetiology and little molecular data on the importance of gene dosage to mammalian cells. Trisomy 21, which results in Down syndrome (DS), is the most frequent aneuploidy in humans (1 in 600 live births, up to 1 in 150 pregnancies world-wide) and is the most common known genetic cause of mental retardation. To investigate the molecular genetics of DS, we report here the creation of mice that carry different human chromosome 21 (Hsa21) fragments as a freely segregating extra chromosome. To produce these 'transchromosomal' animals, we placed a selectable marker into Hsa21 and transferred the chromosome from a human somatic cell line into mouse embryonic stem (ES) cells using irradiation microcell-mediated chromosome transfer (XMMCT). 'Transchromosomal' ES cells containing different Hsa21 regions ranging in size from approximately 50 to approximately 0.2 Mb have been used to create chimeric mice. These mice maintain Hsa21 sequences and express Hsa21 genes in multiple tissues. This novel use of the XMMCT protocol is applicable to investigations requiring the transfer of large chromosomal regions into ES or other cells and, in particular, the modelling of DS and other human aneuploidy syndromes.

Estimating physical distances from radiation hybrid mapping data

Radiation hybrid mapping has become an established tool for building physical maps. It represents a powerful way of constructing YAC contigs and high-resolution maps for positional cloning experiments. Ideally, radiation hybrids should not only provide support for the true order of the markers, but also accurate estimates of the physical distances between them. Statistical analysis of radiation hybrids has proved difficult because of the number of parameters (representing the fragment retention probabilities) that must be estimated, and simplifying assumptions are needed to analyze large numbers of markers simultaneously. The ramifications of these assumptions for the calculation of physical distances are investigated. A simple two-locus model is presented to demonstrate that variation in marker retention can lead to distortions in the estimates of distance. Multilocus simulations show that, when marker retention is constant across the chromosome, good estimates of physical distance can be derived using simple models of retention. However, further simulations exploring variable retention schemes demonstrate that significant errors in the estimates of map distances can occur. Ways of minimizing these distortions are discussed.

Hybrid selection as a method of increasing mapping power for radiation hybrids

Radiation hybrids have become a widely used tool for physical mapping. A drawback of the technique is that large numbers of hybrids are required to construct robust, high-resolution maps. The information contained within a panel of radiation hybrids is limited by the frequency of retention of chromosomal fragments from the donor cell line. In almost all experiments to date, the retention frequency has been below the optimal level; therefore, many hybrids are needed to produce high-quality maps. Because of the labor-intensive nature of large-scale mapping projects, it is important to make panels as small as possible. One method that has been adopted is to produce initially a large number of hybrids that are all typed with a few loci. Those hybrids showing satisfactorily high retention are admitted to the final panel and the rest are discarded. In this way, a panel of radiation hybrids with higher than expected retention can be created. Methods for conducting such a selection regime are discussed. To investigate the potential advantages of selecting hybrids based on their retention frequency, simulations were run under a variety of conditions. As expected panels with high retention (40%) provided better mapping resources than panels with lower (20%) retention. Beginning with an initial panel of 200 hybrids, comparisons of a random sample of 100 hybrids and the set of those 100 hybrids showing the highest marker retention demonstrated that selection may not be always the best strategy despite the increase in mean retention it yields. The selection of hybrids containing large numbers of fragments leads to an overestimation of the frequency of radiation-induced breaks. When breaks occur with high frequency (for example, when high radiation doses are used), the selection of hybrids leads to a loss of linkage and hence an inability to order the markers. As such, the merits of screening hybrids depends on both the radiation dose and the desired map resolution.

Pairwise analysis of radiation hybrid mapping data

Two point lod scores are widely used in pedigree analysis as they provide a fast and efficient method of establishing linkage. Groups of markers that lie in close proximity to one another can be formed by admitting any locus that is linked to at least one existing member of the group with lod score greater than some predetermined value. It seems natural to extend this technique to Radiation Hybrid Mapping both for constructing groups of tightly linked loci that may then be analysed using more powerful statistics and as a method of ordering in its own right. A general extension of two point analysis is derived and the problems associated with radiation hybrid data are discussed. In particular, the additional parameters representing the probabilities of different fragments being retained (which have no parallel in classical linkage analysis) lead to a range of estimators of the breakage probability, O, which have equal and maximal likelihood. Ways of circumventing this problem are discussed along with the potential errors they introduce. Importantly the ambiguity in estimation of theta is not carried through to the lod score as this depends only on the maximum value of the likelihood and not on the particular value of theta at which it occurs. Thus even though two point analysis fails to provide robust estimates of either breakage probabilities or the distance between loci, it represents a simple and effective method of constructing linkage groups that may be analysed with more powerful statistical methods. This is particularly important given the large number of microsatellites, ESTs and candidate genes currently being typed on radiation hybrids.

Irradiation and fusion gene transfer

Irradiation and fusion gene transfer (IFGT) is a technique that spans the gap between the limitations of molecular methods and somatic-cell genetics, allowing the separation of DNA fragments between 0.25 and 30 Mb in size. In conjunction with genetic linkage analysis and physical mapping techniques, IFGT provides a very useful addition to methods for cloning disease loci, and mapping chromosomes and entire genomes.

An extended panel of hamster-human hybrids for chromosome 2q

A hamster-human hybrid containing only the q arm of chromosome 2 has been used to construct a panel of hybrids bearing reduced regions of chromosome 2 using the technique of irradiation fusion gene transfer. The human chromosome 2 carried the Ecogpt gene and all hybrids were selected using this marker. The integrated Ecogpt gene was localized to the region 2q33-34, resulting in the selective retention of this region in the hybrids. These data were combined with another previously constructed panel of hybrids containing regions of 2q, which were enriched for the region 2q36-37. The combined hybrid panel is useful for the mapping of new markers to defined regions of chromosome 2 and for the cloning of genes located on 2q by a positional strategy.

A method for constructing radiation hybrid maps of whole genomes

In radiation hybrid mapping, chromosomes in human-rodent hybrid cells are fragmented by X-rays and fragments rescued by fusion of the donor cell to a recipient rodent cell. The co-retention frequencies of markers in 100-200 hybrids are used to map individual chromosomes, but mapping the whole genome in this way is impractical. We have reverted to the original protocols of Goss and Harris and have produced a panel of 44 hybrids using irradiated human fibroblasts as donors. This panel has been used to make a map of human chromosome 14 containing 40 ordered markers. The map integrates previously published maps and localizes nine new markers. We suggest that the construction of a high resolution map of the whole human genome is feasible with a single panel of 100-200 hybrids.

Construction of radiation-reduced hybrids and their use in mapping of microclones from chromosome 10p11.2-q11.2

Radiation-reduced hybrids for mapping of DNA markers in the pericentromeric region of chromosome 10 were developed. A Chinese hamster/human somatic cell hybrid (762-8A) carrying chromosomes 10 and Y as the only human material were exposed to 40,000 rads of irradiation and then rescued by fusion with non-irradiated recipient Chinese hamster cells (GM459). Southern hybridization analyses revealed that 10 of 128 HAT-resistant clones contained human chromosomal fragments corresponding to at least one marker locus between FNRB (10p-11.2) and RBP3 (10q11.2). These hybrids were then used to map micro-dissection clones previously isolated and roughly mapped to this chromosomal region by fluorescence in situ hybridization (FISH). Two of the six microclones studied could be mapped to the proximity of the D10-S102 locus. These radiation hybrids are useful for the construction of refined genetic maps of the pericentromeric region of chromosome 10.

Radiation hybrids: irradiation and fusion gene transfer

Irradiation and fusion gene transfer can be used to construct detailed genetic maps of complex genomes. This technique is complementary to mapping methods based on both physical distance and genetic recombination.

Rearrangements between irradiated chromosomes in three-species radiation hybrid cell lines revealed by two-color in situ hybridization

A human-hamster hybrid cell line containing only the human X chromosome (GM06318B) was exposed to 6,000-7,000 rad of X-rays and fused with a mouse cell line (CL1D,TK-). Three radiation hybrids, LXKC40, LXKC50, and LXKC56, were selected among 39 independent clones containing human material. Two-color in situ hybridization with total genomic DNA probes (cot1 human DNA and hamster total genomic DNA) was used to analyse the irradiated chromosome rearrangements. With this three-species model system (human-hamster-mouse) and the chromosome painting process it was possible to determine the origin of each chromosomal fragment in metaphase and interphase. The results obtained indicate preferential rearrangement between irradiated human and hamster chromosomes. Whole, apparently intact hamster chromosomes were observed in all the mitoses. We suggest that these chromosomes could be neoformated from random fragments after irradiation. Hamster and human "minichromosomes" were also detected. While the integration of human material into the mouse genome was exceptional, the integration of hamster material into mouse chromosomes was more frequent. During interphase the irradiated chromosome domains were often at the periphery of the nucleus. Irradiated material protruded at the periphery of the nuclei. Micronuclei containing hamster material were detected in the vicinity of these protrusions.

A hamster-human subchromosomal hybrid cell panel for chromosome 2

We have constructed hamster-human hybrid cell lines containing fragments of human chromosome 2 as their only source of human DNA. Microcell-mediated chromosome transfer was used to transfer human chromosome 2 from a monochromosomal mouse-human hybrid line to a radiation-sensitive hamster mutant (XR-V15B) defective in double-strand break rejoining. The human chromosome 2 carried the Ecogpt gene and hybrids were selected using this marker. The transferred human chromosome was frequently broken, and the resulting microcell hybrids contained different sized segments of the q arm of chromosome 2. Two microcell hybrids were irradiated and fused to XR-V15B to generate additional hybrids bearing reduced amounts of human DNA. All hybrids were analyzed by PCR using primers specific for 27 human genes located on chromosome 2. From these data we have localized the integrated gpt gene on the human chromosome 2 to the region q36-37 and present a gene order for chromosome 2 markers.

Telomere-associated chromosome fragmentation: applications in genome manipulation and analysis

Telomere-associated chromosome fragmentation (TACF) is a new approach for chromosome mapping based on the non-targeted introduction of cloned telomeres into mammalian cells. TACF has been used to generate a panel of somatic cell hybrids with nested terminal deletions of the long arm of the human X chromosome, extending from Xq26 to the centromere. This panel has been characterized using a series of X chromosome loci. Recovery of the end clones by plasmid rescue produces a telomeric marker for each cell line and partial sequencing will allow the generation of sequence tagged sites (STSs). TACF provides a powerful and widely applicable method for genome analysis, a general way of manipulating mammalian chromosomes and a first step towards constructing artificial mammalian chromosomes.

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.

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.

Radiation hybrids for mapping and cloning DNA sequences of distal 16p

Three hundred fifteen radiation hybrids (RH) were isolated using a monochromosomal cell hybrid containing chromosome 16 only. A panel of 18 RH, which showed breakpoints among four markers (3.15, 26.6, 3'HVR, and 5'HVR) mapping in the distal portion of 16p, were selected and characterized for the retention of nine additional DNA sequences already localized in this region, and for one centromeric sequence. One or more breakpoints were identified in nine of the 12 intervals defined by the 13 single-copy sequences used. This panel of RH represents a tool for the construction of a detailed physical map of the distal part of 16p and for cloning sequences located in the proximity of disease genes. Three inter-Alu DNA sequences, amplified from one of these RH containing the autosomal dominant polycystic kidney disease (PKD1) gene, were cloned and mapped in the panel. Sequencing of the ends of one of three clones showed a (CAAA)n repeat, which revealed a two-allele polymorphism.

Generation of region- and species-specific expressed gene probes from somatic cell hybrids

Human genes expressed in interspecific somatic cell hybrids can be cloned specifically by subtractive cDNA hybridization. This approach is based on the observation that cDNA fragments from noncoding segments of mature human transcripts do not form stable heteroduplexes with their rodent homologues under high-stringency hybridization conditions. Thus, small, oligo-dT primed cDNAs from a rat/human hybrid retaining a fragment of human chromosome 17 were enriched for human sequences by hybridization with RNA from a sister clone containing a smaller human chromosome fragment. The enriched probe was used to screen a human cDNA library, and nine expressed genes from within the non-overlap region were obtained. This method should be useful for cloning active human genes from defined chromosome segments.

Human repeat element-mediated PCR: Cloning and mapping of chromosome 10 DNA markers

Repeat element-mediated PCR can facilitate rapid cloning and mapping of human chromosomal region-specific DNA markers from somatic cell hybrid DNA. PCR primers directed to human repeat elements result in human-specific DNA synthesis; template DNA derived from a somatic cell hybrid containing the human chromosomal region of interest provides region specificity. We have generated a series of repeat element-mediated PCR clones from a reduced complexity somatic cell hybrid containing a portion of human chromosome 10. The cloning source retains the centromere and tightly linked flanking markers, plus additional chromosome 10 sequences. Twelve new inter-Alu, two inter-L1, and four inter-Alu/L1 repeat element-mediated PCR clones were mapped by hybridization to Southern blots of repeat element-mediated PCR products amplified from somatic cell hybrid DNA templates. Two inter-Alu clones mapped to the pericentromeric region. We propose that a scarcity of Alu elements in the pericentromeric region of chromosome 10 contributed to the low number of clones obtained from this region. One inter-Alu clone, pC11/A1S-6-c23, defines the D10S94 locus, which is tightly linked to MEN2A and D10Z1.

Radiation-reduced hybrids for the myotonic dystrophy locus

The myotonic dystrophy (DM) gene maps to the long arm of human chromosome 19 and is flanked by markers ERCC1 and D19S51. Also mapping to this region is the polio virus receptor gene (PVS). To produce more markers for this interval, we have constructed radiation-reduced hybrids by selecting for the retention of ERCC1 and for the loss of PVS. One of the cell lines produced has been characterized extensively and contains about 2 Mb of human DNA derived exclusively from chromosome 19, and includes ERCC1 and D19S51. Phage libraries constructed from DNA of this cell line have been screened and several new markers identified, including two for which cDNAs have been isolated. These represent candidate genes for DM. The new markers have also been used to extend the long-range restriction map of this region.

Isolation and characterization of radiation-reduced hybrids containing portions of the proximal long arm of the human X chromosome: identification of hybrids containing the Menkes' disease locus

The proximal long arm of the human X chromosome (Xcen----Xq13) encompasses an estimated 23 megabases of DNA and contains numerous identified genetic loci. In order to generate a highly enriched source of DNA from this region, radiation-reduced human-hamster hybrids were constructed and screened to identify those that contained at least part of proximal Xq. Eight such hybrids were identified and characterized by Southern blot and fluorescence in situ hybridization analyses to determine more precisely the human DNA complement in each. One hybrid contains the entire proximal long arm and will be useful for mapping Xcen----Xq13 in its entirety and for localizing genes within this region. Another hybrid contains a smaller portion of the proximal long arm that includes the region reported to contain the gene for Menkes' disease.

Characterization of radiation/fusion hybrids containing parts of human chromosome 10 and their use in mapping chromosome 10-specific probes

We have characterized a panel of somatic cell hybrid cell lines which contain different portions of human chromosome 10. Genomic DNA from the somatic cell hybrids was tested for hybridization with each of an ordered set of probes used previously to construct a genetic map of chromosome 10, as well as several additional probes, previously localized by in situ hybridization. Hybridization of an unmapped probe to the cell line DNAs can be used to determine its most likely position on the chromosome relative to the mapped set of probes. Genomic DNA from two of the cell lines has been used to construct region-specific cosmid and bacteriophage libraries, and clones derived from these libraries were localized by hybridization to the panel of hybrid cell lines. Several of these probes reveal restriction fragment length polymorphisms which have been genetically mapped. Three of the probes map near the locus for multiple endocrine neoplasia type 2A, and one of these probes, BG-JC353 (D10S167), maps between RBP3 and TB14.34 (D10S34). Another probe, CRI-J282 (D10S104), is close to the FNRB locus. The panel of hybrid cell lines is thus useful for rapidly localizing unmapped probes and as a source of DNA for the construction of recombinant libraries derived from specific regions of the chromosome.

Double-minute chromosomes as megabase cloning vehicles

Radiation-reduced chromosomes provide valuable reagents for cloning and mapping genes, but they require multiple rounds of x-ray deletion mutagenesis to excise unwanted chromosomal DNA while maintaining physical attachment of the desired DNA to functional host centromere and telomere sequences. This requirement for chromosomal rearrangements can result in undesirable x-ray induced chromosome chimeras where multiple non-contiguous chromosomal fragments are fused. We have developed a cloning system for maintaining large donor subchromosomal fragments of mammalian DNA in the megabase size range as acentric chromosome fragments (double-minutes) in cultured mouse cells. This strategy relies on randomly inserted selectable markers for donor fragment maintenance. As a test case, we have cloned random segments of Chinese hamster ovary (CHO) chromosomal DNA in mouse EMT-6 cells. This was done by cotransfecting plasmids pZIPNeo and pSV2dhfr into DHFR-CHO cells followed by isolation of a Neo + DHFR + CHO donor colony and radiation-fusion-hybridization (RFH) to EMT-6 cells. We then selected for initial resistance to G418 and then to increasing levels of methotrexate (MTX). Southern analysis of pulsed-field gel electrophoresis of rare-cutting restriction endonuclease digestions of DNA from five RFH isolates indicated that all five contain at least 600 kb of unrearranged CHO DNA. In situ hybridization with the plasmids pZIPNeo and pSV2dhfr to metaphase chromosomes of MTX-resistant hybrid EMT-6 lines indicated that these markers reside on double-minute chromosomes.

Generation of a panel of somatic cell hybrids containing fragments of human chromosome 12P by X-ray irradiation and cell fusion

We have employed an irradiation and fusion procedure to generate somatic cell hybrids containing various fragments of the short arm of human chromosome 12 using a 12p-only hybrid (M28) as starting material. For the initial identification of hybrids retaining human DNA, nonradioactive in situ hybridization was performed. Seventeen cell lines appeared to contain detectable amounts of human material. Detailed characterization of these hybrids by Southern blot analysis and chromosomal in situ suppression hybridization (chromosome painting), using hybrid DNAs as probes after Alu element-mediated PCR, resulted in a hybrid panel encompassing the entire chromosome 12p arm. This panel will provide a valuable resource for the rapid isolation of region-specific DNA markers. In addition, this panel may be useful for the characterization of chromosome 12 aberrations in, e.g., human germ cell tumors.

Construction of a map of chromosome 16 by using radiation hybrids

A human-hamster cell hybrid carrying a single copy of chromosome 16 as the only human genetic material was irradiated with a single dose of gamma-rays (7000 rads; 1 rad = 0.01 Gy) and then fused with a thymidine kinase-deficient hamster cell line (RJKM) to generate radiation hybrids retaining unselected fragments of this human chromosome. In two experiments, 223 hybrids were isolated in hypoxanthine/aminopterine/thymidine (HAT) medium and screened with 38 DNA probes, corresponding to anonymous DNA or gene sequences localized on chromosome 16. The most likely order and location of the 38 DNA sequences were established by multiple pairwise analysis and scaled to estimate physical distance in megabases. The order and the distances thus obtained are mostly consistent with available data on genetic and physical mapping of these markers, illustrating the usefulness of radiation hybrids for mapping.

Radiation fusion hybrids for human chromosomes 3 and X generated at various irradiation doses

We have used a gamma-irradiation (2.5-25 krads) cell fusion procedure to generate human-hamster somatic cell hybrids (IHB, irradiated human fragments in B14-150 cells), retaining small fragments derived from human chromosomes 3 and X. By using Alu-element mediated PCR amplification and dot-blot hybridization with human alphoid or total human DNA as probes, 86 positive hybrids were identified and selected for further analysis. Nonisotopic fluorescence in situ hybridization (FISH) with human DNA in a set of eight hybrids demonstrated the presence of from one to eight human fragments per cell independent of irradiation dose. In contrast, a significant dose-dependent variation of fragment sizes was shown in the analysis of the 86 hybrids with markers previously mapped to 3p (seven markers) and to Xq (21 markers). Using the Xq27-28 region as a model, 40% of the hybrids generated at 5 krads or less were found to have retained fragments in the range of 3-30 Mb, 10% retained the whole chromosome arm, and the remaining 50% retained fragments of less than 2-3 Mb. The proportion of fragments of 3 Mb or larger decreased rapidly at higher irradiation doses and was very low (less than 6%) in hybrids generated at 25 krads. Upon further characterization, the 86 hybrids analyzed here will provide a mapping panel for the entire chromosomes 3 and X with an estimated resolution in the range of 1-2 Mb on average, a size range amenable to PFGE and YAC contig mapping.

Characterization of the central region containing the X-inactivation center and terminal region of the mouse X chromosome using irradiation and fusion gene transfer hybrids

The irradiation and fusion gene transfer (IFGT) procedure provides a means of isolating subchromosomal fragments for use in the mapping of loci and for cloning probes from a particular area of a chromosome. Using this procedure, two large panels of somatic cell hybrids that contain mouse X Chromosome (Chr) fragments have been generated. These hybrid panels were generated by irradiating the monochromosomal mouse-hamster hybrid HYBX, which retains the mouse X Chr, with either 10 K or 50 K rads of X-irradiation followed by fusion with a recipient Chinese hamster cell line. IFGT hybrids retaining mouse material were generated at high frequency. These hybrids were used to orient loci in the X-inactivation center region that had not been resolvable in our interspecies backcross panel and also to map, within the terminal region of the X Chr, repeat elements detected by the probe p15-4. These hybrids not only complement existing interspecies meiotic mapping panels for the detailed analysis of specific regions of particular chromosomes, but also provide a potential source of material for chromosome-specific probe isolation.

Radiation hybrid mapping: a somatic cell genetic method for constructing high-resolution maps of mammalian chromosomes

Radiation hybrid (RH) mapping, a somatic cell genetic technique, was developed as a general approach for constructing long-range maps of mammalian chromosomes. This statistical method depends on x-ray breakage of chromosomes to determine the distances between DNA markers, as well as their order on the chromosome. In addition, the method allows the relative likelihoods of alternative marker orders to be determined. The RH procedure was used to map 14 DNA probes from a region of human chromosome 21 spanning 20 megabase pairs. The map was confirmed by pulsed-field gel electrophoretic analysis. The results demonstrate the effectiveness of RH mapping for constructing high-resolution, contiguous maps of mammalian chromosomes.

Rapid cloning and characterization of new chromosome 10 DNA markers by Alu element-mediated PCR

Alu element-mediated polymerase chain reaction is a strategy for rapidly cloning and mapping human DNA markers from mixed DNA sources. A novel primer homologous to the 3' end of the human Alu repeat element provides the basis for preferential synthesis of human DNA fragments from human/rodent somatic cell hybrid DNA template. This approach has been used to isolate a series of new markers from chromosome 10. The Alu element-mediated PCR probes were regionally assigned on chromosome 10 by hybridization to Southern blots of Alu PCR-synthesized DNA derived from somatic cell hybrid template DNA. Alu element-mediated PCR is generally applicable and makes possible the analysis of complex genomes with a speed and sensitivity that has not been previously possible.