Construction and characterization of a yeast artificial chromosome library for Xpter-Xq27.3: a systematic determination of cocloning rate and X-chromosome representation

Exploiting the yeast Saccharomyces cerevisiae for the study of the organization and evolution of complex genomes

Yeast artificial chromosome (YAC) cloning systems have advanced the analysis of complex genomes considerably. They permit the cloning of larger fragments than do bacterial artificial chromosome systems, and the cloned material is more easily modified. We recently developed a novel YAC cloning system called transformation-associated recombination (TAR) cloning. Using in vivo recombination in yeast, TAR cloning selectively isolates, as circular YACs, desired chromosome segments or entire genes from complex genomes. The ability to do that without constructing a representative genomic library of random clones greatly facilitates analysis of gene function and its role in disease. In this review, we summarize how recombinational cloning techniques have advanced the study of complex genome organization, gene expression, and comparative genomics.

Construction of a YAC library from barley cultivar Franka and identification of YAC-derived markers linked to the Rh2 gene conferring resistance to scald (Rhynchosporium secalis)

The Rh2 resistance gene of barley (Hordeum vulgare) confers resistance against the scald pathogen (Rhynchosporium secalis). A high-resolution genetic map of the Rh2 region on chromosome I (7H) was established by the use of molecular markers. Tightly linked markers from this region were used to screen existing and a newly constructed yeast artificial chromosome (YAC) library of barley cv. Franka composed of 45,000 clones representing approximately two genome equivalents. Corresponding YAC clones were identified for most markers, indicating that the combined YAC library has good representation of the barley genome. The contiguous sets of YAC clones with the most tightly linked molecular markers represent entry points for map-based cloning of this resistance gene.

Large-insert clone/STS contigs in Xq11-q12, spanning deletions in patients with androgen insensitivity and mental retardation

An integrated large-insert clone map of the region Xq11-q12 is presented. A physical map containing markers within a few hundred kilobases of the centromeric locus DXZ1 to DXS1125 spans nearly 5 Mb in two contigs separated by a gap estimated to be approximately 100-250 kb. The contigs combine 75 yeast artificial chromosome clones, 12 bacterial artificial chromosome clones, and 17 P1-derived artificial chromosome clones with 81 STS or EST markers. Overall marker density across this region is approximately 1 STS/60 kb. Mapped within the contigs are 12 ESTs as well as 5 known genes, moesin (MSN), hephaestin (HEPH), androgen receptor (AR), oligophrenin-1 (OPHN1), and Eph ligand-2 (EPLG2). Orientation of the contigs on the X chromosome, as well as marker order within the contigs, was unambiguously determined by reference to a number of X chromosome breakpoints. In addition, the distal contig spans deletions from chromosomes of three patients exhibiting either complete androgen insensitivity (CAI) or a contiguous gene syndrome that includes CAI, impaired vision, and mental retardation.

Integrated STS/YAC physical, genetic, and transcript map of human Xq21.3 to q23/q24 (DXS1203-DXS1059)

A map has been assembled that extends from the XY homology region in Xq21.3 to proximal Xq24, approximately 20 Mb, formatted with 200 STSs that include 25 dinucleotide repeat polymorphic markers and more than 80 expressed sequences including 30 genes. New genes HTRP5, CAPN6, STPK, 14-3-3PKR, and CALM1 and previously known genes including BTK, DDP, GLA, PLP, COL4A5, COL4A6, PAK3, and DCX are localized; candidate loci for other disorders for which genes have not yet been identified, including DFN-2, POF, megalocornea, and syndromic and nonsyndromic mental retardation, are also mapped in the region. The telomeric end of the contig overlaps a yeast artificial chromosome (YAC) contig from Xq24-q26 and with other previously published contigs provides complete sequence-tagged site (STS)/YAC-based coverage of the long arm of the X chromosome. The order of published landmark loci in genetic and radiation hybrid maps is in general agreement. Combined with high-density STS landmarks, the multiple YAC clone coverage and integrated genetic, radiation hybrid, and transcript map provide resources to further disease gene searches and sequencing.

Mapping of the MYCL2 processed gene to Xq22-23 and identification of an additional L MYC-related sequence in Xq27.2

We report here the identification of a human genomic sequence from the q27.2 region of the X chromosome which shows a high homology to the L-MYC proto-oncogene. This sequence is not the MYCL2 homology, previously mapped to the long arm of the X chromosome at q22-qter by Morton et al., as we located the MYCL2-processed gene in Xq22-23, using a panel containing a combination of hybrid DNA carrying different portions of the human X chromosome. Based on computer analysis, the MYC-like sequence (MYCL3) is 98.2% identical to a portion of exon 3 of the MYCL1 gene and maps to the Xq27.2 region, between the DXS312 and DXS292 loci.

22-Mb integrated physical and genetic map based on YAC/STS content spanning the interval DXS1125-DXS95 in human Xq12-q21.31

A YAC/STS map has been assembled spanning 22 Mb across Xq12-q21.31, between markers DXS1125 and DXS95. In addition to the landmark loci for the X-inactivation center XIST and the ATRX, ATP7A, phosphoglycerate kinase, POU3F4, and choroideremia genes, the candidate disease gene regions for torsion dystonia 3 and two X-linked mental retardation syndromes are included. Also, the human voltage-dependent anion channel gene (HVDAC1) has been placed near DXS986. The current map incorporates 211 YACs from five different libraries, formatted with 185 STSs that comprise 26 genetic linkage markers, 60 newly-developed YAC-end STSs, and eight ESTs. The multiple clone coverage and average resolution of one STS per 120 kb provide resources for disease gene searches and are facilitating complete sequencing of the region.

Physical mapping of the mouse genome

This review is intended to provide an overview of techniques and a source of reagents for physical mapping of the mouse genome. It focuses on those applications, methods, or resources unique to the mouse and on the generation of comparative physical maps. The reference list is not comprehensive; rather, recent reviews on each topic and selected representative examples are given.

Generation of large insert yeast artificial chromosome libraries

The development of YAC cloning technology has directly enhanced the relationship among genetic, physical, and functional mapping of genomes. Because of their large size, YACs have enabled the rapid construction of physical maps by ordered clone mapping and contig building, and they complement other molecular approaches for mapping complex genomes. Large insert libraries are constructed by size fractionating large DNA embedded in agarose and protecting DNA from degradation with polyamines.

High-resolution physical map of the X-linked retinoschisis interval in Xp22

X-linked retinoschisis (RS) is the leading cause of macular degeneration in young males and has been mapped to Xp22 between DXS418 and DXS999. To facilitate identification of the RS gene, we have constructed a yeast artificial chromosome (YAC) contig across this region comprising 28 YACs and 32 sequence-tagged sites including seven novel end clone markers. To establish the definitive marker order, a PAC contig containing 50 clones was also constructed, and all clones were fingerprinted. The marker order is: Xpter-DXS1317-(AFM205yd12-DXS7175-DXS7992) -60N8-T7-DXS1195-DXS7993-DXS7174 -60N8-SP6-DXS418-DXS7994-DXS7995-DXS7996-+ ++HYAT2-25HA10R-HYAT1-DXS7997-DXS7998- DXS257-434E8R-3542R-DXS6762-DXS7999-DXS 6763-434E8L-DXS8000-DXS6760-DXS7176- DXS8001-DXS999-3176R-PHKA2-Xcen. A long-range restriction map was constructed, and the RS region is estimated to be 1300 kb, containing three putative CpG islands. An unstable region was identified between DXS6763 and 434E8L. These data will facilitate positional cloning of RS and other disease genes in Xp22.

AFLP-based fine mapping of the Mlo gene to a 30-kb DNA segment of the barley genome

Resistance of barley (Hordeum vulgare) to the powdery mildew fungus Erysiphe graminis f.sp. hordei is conferred by several dominant genes, but also by recessive alleles of the Mlo locus mapping on the long arm of chromosome 4. In addition, this single-factor-mediated resistance is active against all known physiological races of the parasite. Thus the mechanism underlying mlo-mediated resistance should differ substantially from that mediated by the dominant genes. A positional cloning strategy to isolate the Mlo gene from the barley genome, the size of which is almost double the size of the human genome, has been designed. The AFLP technique was employed to identify markers tightly linked to the Mlo locus and to produce a local high-resolution genetic map. The use of this high-volume marker technology allowed the rapid screening of approximately 250,000 loci for linkage to Mlo. A large number of Mlo-linked AFLP markers were identified, one of which cosegregated with Mlo on the basis of more than 4000 meiotic events. A four-genome-equivalent barley YAC library (average insert size 480 kb) was constructed and screened with this cosegregating marker. Four YACs containing this marker were isolated and subsequent characterization by AFLP-based physical mapping allowed the physical delimitation of the Mlo locus to a DNA segment of 30 kb.

Evolutionary features of the 4-Mb Xq21.3 XY homology region revealed by a map at 60-kb resolution

Forty-three yeast artificial chromosomes (YACs) from the X chromosome have been overlapped across the 4-Mb Xq21.3 region, which is homologous to a segment in Yp11.1. The region is formatted to 60-kb resolution with 57 STSs and is merged at its edges with contigs specific for X. This allows a direct comparison of marker orders and distances on X and Y. In addition to some sequence variation and possible differences in marker order, two larger evolutionary divergencies between the X and Y homologs were revealed: (1) The X homolog is interrupted by a small X-specific region detected by a 3-kb plasmid probe for locus DXS214. An STS was developed from one end of the probe, but the sequence at the other end was highly homologous to an L1 repetitive element. This suggests that the interpolation of the X-specific segment may have involved an L1-mediated event. (2) A 250-kb portion containing DXYS1 is several megabases away from the rest of the homologous DNA on the Y but is contiguous with the remainder of the homologous region on X. Marker orders are consistent with the origin of the Y-specific 250-kb region in a paracentric inversion after the initial transfer of X DNA to the Y chromosome.

Mapping of 59 EST gene markers in 31 intervals spanning the human X chromosome

The positioning of Expressed Sequence Tags (ESTs) constitutes an important step towards a functional map of the human genome, including candidate genes for human genetic disorders that have been localized by linkage analysis. We localized 59 ESTs on the human X chromosome, including 44 derived from infant brain and 15 from adult muscle cDNA libraries. Localizations by a somatic cell hybrid panel were refined for five cDNAs by mapping them in yeast artificial chromosome (YAC) contigs.

Long-range map of a 3.5-Mb region in Xp11.23-22 with a sequence-ready map from a 1.1-Mb gene-rich interval

Most of the yeast artificial chromosomes (YACs) isolated from the Xp11.23-22 region have shown instability and chimerism and are not a reliable resource for determining physical distances. We therefore constructed a long-range pulsed-field gel electrophoresis map that encompasses approximately 3.5 Mb of genomic DNA between the loci TIMP and DXS146 including a CpG-rich region around the WASP and TFE-3 gene loci. A combined YAC-cosmid contig was constructed along the genomic map and was used for fine-mapping of 15 polymorphic microsatellites and 30 expressed sequence tags (ESTs) or sequence transcribed sites (STSs), revealing the following order: tel-(SYN-TIMP)-(DXS426-ELK1)-ZNF(CA) n-L1-DXS1367-ZNF81-ZNF21-DXS6616- (HB3-OATL1pseudogenes-DXS6950)-DXS6949-DXS694 1-DXS7464E(MG61)-GW1E(EBP)- DXS7927E(MG81)-RBM- DXS722-DXS7467E(MG21)-DXS1011E-WASP-DXS6940++ +-DXS7466E(MG44)-GF1- DXS226-DXS1126-DXS1240-HB1- DXS7469E-(DXS6665-DXS1470)-TFE3-DXS7468E-+ ++SYP-DXS1208-HB2E-DXS573-DXS1331- DXS6666-DXS1039-DXS 1426-DXS1416-DXS7647-DXS8222-DXS6850-DXS255++ +-CIC-5-DXS146-cen. A sequence-ready map was constructed for an 1100-kb gene-rich interval flanked by the markers HB3 and DXS1039, from which six novel ESTs/STSs were isolated, thus increasing the number of markers used in this interval to thirty. This precise ordering is a prerequisite for the construction of a transcription map of this region that contains numerous disease loci, including those for several forms of retinal degeneration and mental retardation. In addition, the map provides the base to delineate the corresponding syntenic region in the mouse, where the mutants scurfy and tattered are localized.

An integrated YAC map of the human X chromosome

The human X chromosome is associated with a large number of disease phenotypes, principally because of its unique mode of inheritance that tends to reveal all recessive disorders in males. With the longer term goal of identifying and characterizing most of these genes, we have adopted a chromosome-wide strategy to establish a YAC contig map. We have performed > 3250 inter Alu-PCR product hybridizations to identify overlaps between YAC clones. Positional information associated with many of these YAC clones has been derived from our Reference Library Database and a variety of other public sources. We have constructed a YAC contig map of the X chromosome covering 125 Mb of DNA in 25 contigs and containing 906 YAC clones. These contigs have been verified extensively by FISH and by gel and hybridization fingerprinting techniques. This independently derived map exceeds the coverage of recently reported X chromosome maps built as part of whole-genome YAC maps.

Analysis of extrachromosomal structures containing human centromeric alphoid satellite DNA sequences in mouse cells

Yeast artificial chromosomes (YACs) spanning the centromeric region of the human Y chromosome were introduced into mouse LA-9 cells by spheroplast fusion in order to determine whether they would form mammalian artificial chromosomes. In about 50% of the cell lines generated, the YAC DNA was associated with circular extrachromosomal structures. These episomes were only present in a proportion of the cells, usually at high copy number, and were lost rapidly in the absence of selection. These observations suggest that, despite the presence of centromeric sequences, the structures were not segregating efficiently and thus were not forming artificial chromosomes. However, extrachromosomal structures containing alphoid DNA appeared cytogenetically smaller than those lacking it, as long as yeast DNA was also absent. This suggests that alphoid DNA can generate the condensed chromatin structure at the centromere.

A 450 kb transgene displays properties of the mammalian X-inactivation center

X inactivation results in inactivation of one X chromosome to compensate for gene dosage differences between mammalian females and males. It requires the X-inactivation center (Xic) and Xist in cis. We report that introducing 450 kb of murine Xic/Xist sequences onto autosomes activates female dosage compensation in male ES cells. Xist is induced upon differentiation and can be expressed from both endogenous and ectopic loci, suggesting that elements for counting and choosing Xs are present in the transgene. Differentiating transgenic ES cells undergo excessive cell death. Postnatally, Xist is expressed only from the transgene. Ectopic Xist RNA structurally associates with the autosome and may inactivate a marker gene in cis. These results argue that the Xic is contained within 450 kb and that these sequences are sufficient for chromosome counting, choosing, and initiation of X inactivation.

YAC contigs mapping the human COL4A5 and COL4A6 genes and DXS118 within Xq21.3-q22

Sequence-tagged sites (STSs) were developed for three loci of uncertain X chromosomal localization (DXS122, DXS137, and DXS174) and were used to seed YAC contigs. Two contigs now total about 3.3 Mb formatted with 34 STSs. One contains DXS122 and DXS174 within 250 kb on single YACs; it is placed in Xq21.3-q22.1 by FISH analysis, which is consistent with somatic cell hybrid panel analyses and with the inclusion of a probe that detects polymorphism at the DXS118 locus already assigned to that general region. The other contig, which contains DXS137, is in Xq22.2 by FISH, consistent with cell hybrid analyses and with the finding that it covers the human COL4A5 and COL4A6 genes known to be in that vicinity. In addition to extending the cloned coverage of this portion of the X chromosome, these materials should aid, for example, in the further analysis of Alport syndrome.

High-density physical mapping of a 3-Mb region in Xp22.3 and refined localization of the gene for X-linked recessive chondrodysplasia punctata (CDPX1)

The study of patients with chromosomal rearrangements has led to the mapping of the gene responsible for X-linked recessive chondrodysplasia punctata (CDPX1; MIM 302950) to the distal part of the Xp22.3 region, between the loci PABX and DXS31. To refine this mapping, a yeast artificial chromosome (YAC) contig map spanning this region has been constructed. Together with the YAC contig of the pseudo-autosomal region that we previously established, this map covers the terminal 6 Mb of Xp, with an average density of 1 probe every 100 kb. Newly isolated probes that detect segmental X-Y homologies on Yp and Yq suggest multiple complex rearrangements of the ancestral pseudoautosomal region during evolution. Compilation of the data obtained from the study of individuals carrying various Xp22.3 deletions led us to conclude that the CDPX disease displays incomplete penetrance and, consequently, to refine the localization of CDPX1 to a 600-kb interval immediately adjacent to the pseudoautosomal boundary. This interval, in which 12 probes are ordered, provides the starting point for the isolation of CDPX1.

A 6-Mb YAC contig in Xp22.1-p22.2 spanning the DXS69E, XE59, GLRA2, PIGA, GRPR, CALB3, and PHKA2 genes

We report the generation of an approximately 6-Mb contig of 70 overlapping yeast artificial chromosomes (YAC) covering the interval between DXS16 and DXS1229 in Xp22.1-p22.2. Within this region lie the genes for calbindin (CALB3), gastrin-releasing peptide receptor (GRPR), phosphatidyl-inositol glycan-class A protein (PIGA), glycine receptor alpha-2 (GLRA2), phosphorylase kinase alpha (PHKA2), XE59 (a gene escaping X chromosome inactivation), and DXS69E (71-7A). YACs were isolated initially from four libraries either by hybridization or using sequence tagged sites (STSs) for DXS16, DXS9, GLRA2, DXS207, DXS43, DXS1416, DXS1317, DXS1195, and DXS418. Additional STSs were obtained from the end fragments of the original YACs studied, thus allowing us to cover the contig with a series of 73 STSs, approximately 1 per 100 kb. YAC contig construction allowed the following locus order to be established: Xpter-DXS16-DXS69E-DXS414-XE59 - DXS9 - (GLRA2, DXS987) - (PIGA, DXS207) - DXS1053-DXS197-(GRPR,DXS43)-CALB3-DXS14 16- DXS1317 - DXS1195 - DXS418 - DXS257 - (PHKA2, DXS999)-DXS443-DXS1229-Xcen. Restriction mapping of the DXS16-DXS43 interval predicted the existence of several CpG islands, suggesting the presence of other genes in the region. This work provides a starting point for further mapping and positional cloning of several X-linked disease genes.

Techniques in mammalian genome mapping

Increasing emphasis is being given to genomic cloning using Escherichia coli vectors of intermediate insert capacity, such as bacteriophage P1, P1-derived artificial chromosomes and the F factor based bacterial artificial chromosomes. These vectors are being used in addition to yeast artifical chromosomes (YACs) in recognition of the difficulties encountered with YAC stability and with handling of YAC DNAs (problems that will not easily be overcome). Nonetheless, YACs remain the most practical cloning system for global contig building. Efforts are currently under way to produce YAC contigs that represent the human and mouse genomes, and these will increasingly exploit extensive anchoring to detailed genetic maps. Intermediate capacity clone collections based on YAC contigs will follow, enabling the compilation of mapped gene catalogues. In this way, the era of big gene hunts will draw to a close.

A human chromosome 7 yeast artificial chromosome (YAC) resource: construction, characterization, and screening

The paradigm of sequence-tagged site (STS)-content mapping involves the systematic assignment of STSs to individual cloned DNA segments. To date, yeast artificial chromosomes (YACs) represent the most commonly employed cloning system for constructing STS maps of large genomic intervals, such as whole human chromosomes. For developing a complete YAC-based STS-content map of human chromosome 7, we wished to utilize a limited set of YAC clones that were highly enriched for chromosome 7 DNA. Toward that end, we have assembled a human chromosome 7 YAC resource that consists of three major components: (1) a newly constructed library derived from a human-hamster hybrid cell line containing chromosome 7 as its only human DNA; (2) a chromosome 7-enriched sublibrary derived from the CEPH mega-YAC collection by Alu-polymerase chain reaction (Alu-PCR)-based hybridization; and (3) a set of YACs isolated from several total genomic libraries by screening for > 125 chromosome 7 STSs. In particular, the hybrid cell line-derived YACs, which comprise the majority of the clones in the resource, have a relatively low chimera frequency (10-20%) based on mapping isolated insert ends to panels of human-hamster hybrid cell lines and analyzing individual clones by fluorescence in situ hybridization. An efficient strategy for polymerase chain reaction (PCR)-based screening of this YAC resource, which totals 4190 clones, has been developed and utilized to identify corresponding YACs for > 600 STSs. The results of this initial screening effort indicate that the human chromosome 7 YAC resource provides an average of 6.9 positive clones per STS, a level of redundancy that should support the assembly of large YAC contigs and the construction of a high-resolution STS-content map of the chromosome.

Isolation and characterization of the faciogenital dysplasia (Aarskog-Scott syndrome) gene: a putative Rho/Rac guanine nucleotide exchange factor

Faciogenital dysplasia (FGDY), also known as Aarskog-Scott syndrome, is an X-linked developmental disorder characterized by disproportionately short stature and by facial, skeletal, and urogenital anomalies. Molecular genetic analyses mapped FGDY to chromosome Xp11.21. To clone this gene, YAC clones spanning an FGDY-specific translocation breakpoint were isolated. An isolated cDNA, FGD1, is disrupted by the breakpoint, and FGD1 mutations cosegregate with the disease. FGD1 codes for a 961 amino acid protein that has strong homology to Rho/Rac guanine nucleotide exchange factors (GEFs), contains a cysteine-rich zinc finger-like region, and, like the RasGEF mSos, contains two potential SH3-binding sites. These results provide compelling evidence that FGD1 is responsible for FGDY and suggest that FGD1 is a Rho/RacGEF involved in mammalian development.

Characterization of four human YAC libraries for clone size, chimerism and X chromosome sequence representation

Four collections of human X-specific YACs, derived from human cells containing supernumerary X chromosomes or from somatic cell hybrids containing only X human DNA were characterized. In each collection, 80-85% of YAC strains contained a single X YAC. Five thousand YACs from the various libraries were sized, and cocloning was assessed in subsets by the fraction of YAC insert-ends with non-X sequences. Cocloning was substantial, ranging up to 50% for different collections; and in agreement with previous indications, in all libraries the larger the YACs, the higher the level of cocloning. In libraries made from human-hamster hybrid cells, expected numbers of clones were recovered by STS-based screening; but unexpectedly, the two collections from cells with 4 or 5 X chromosomes yielded numbers of YACs corresponding to an apparent content of only about two X equivalents. Thus it is possible that the DNA of inactive X chromosomes is poorly cloned into YACs, speculatively perhaps because of its specialized chromatin structure.

High-throughput rapid yeast DNA extraction. Application to yeast artificial chromosomes as polymerase chain reaction templates

An automation-assisted method enables DNA extraction of over a thousand yeast colonies in a day by one person. Yeast DNA is extracted essentially quantitatively in three steps: (a) cells are converted into spheroplasts with yeast lytic enzyme, (b) cells are lysed with proteinase K, and (c) DNA is collected by ethanol precipitation. The DNA stored at 4 degrees C is active in polymerase chain reaction experiments for more than a year.

Construction and preliminary analysis of the ICRF human P1 library

P1 clone libraries have now been established as effective complements to cosmid and yeast artificial chromosome libraries in long-range mapping projects. To allow general access to P1 clones, we have constructed human and mouse P1 libraries. Clones have been picked into microtiter plates and used to prepare high-density filter grids, providing an efficient and easy screening system. Filters are being made available to other laboratories through the Reference Library System. In this work, we have developed a reliable protocol for generating P1 clones, based on the use of pulsed-field gel electrophoresis for size selection of DNA. A 1.2x genome coverage human library has been produced using this method. A preliminary analysis of this library is described.

An ordered collection of Bacillus subtilis DNA segments cloned in yeast artificial chromosomes

A collection of 772 Bacillus subtilis DNA segments was obtained by cloning in yeast artificial chromosomes. The B. subtilis inserts of 288 clones were mapped by hybridization using as probes 65 cloned genes and 188 isolated insert ends. In this way, 59 inserts were ordered in four contigs that cover > 98% of the B. subtilis chromosome. This ordered collection is now available for further genetic and physical analysis of the B. subtilis genome.

Methods for finding genes. A major rate-limiting step in positional cloning

Identification of transcribed sequences from within genomic regions has been a major rate-limiting step in the pursuit of genes involved in many human genetic diseases. Early efforts focused primarily on screening of cDNA libraries, identification of evolutionarily conserved sequences, and northern blot hybridization. In recent years, several innovative techniques for gene identification have been devised. These techniques expand the size of the genomic region capable of being scanned for genes, while also allowing detection of genes regardless of their expression patterns. This article reviews several new and older techniques and discusses the advantages and limitations of each.

Genome analysis and the human X chromosome

A unified genetic, physical, and functional map of the human X chromosome is being built through a concerted, international effort. About 40 percent of the 160 million base pairs of the X chromosome DNA have been cloned in overlapping, ordered contigs derived from yeast artificial chromosomes. This rapid progress toward a physical map is accelerating the identification of inherited disease genes, 26 of which are already cloned and more than 50 others regionally localized by linkage analysis. This article summarizes the mapping strategies now used and the impact of genome research on the understanding of X chromosome inactivation and X-linked diseases.

Detection and characterization of "chimeric" yeast artificial chromosome clones by fluorescent in situ suppression hybridization

"Chimeric" yeast artificial chromosomes (YACs) are clones containing two or more noncontiguous segments of DNA and represent the most common artifact found in total genomic YAC libraries currently used for large-scale genome mapping. These YACs create spurious mapping information that complicates the construction of YAC contigs and leads to erroneous maps during chromosome walks. The presence of these artifactual clones necessitates laborious and time-consuming characterization of each isolated YAC clone, either by comparison of the physical map of the YAC with the corresponding source genomic DNA, or by demonstrating discrepant chromosomal origins for the two ends of the YAC by hybridization or polymerase chain reaction (PCR). Here, we describe a rapid and sensitive method for the assessment of YAC colinearity by fluorescence in situ suppression hybridization (FISSH) by utilizing fluorescein-12-dUTP for labeling YAC clones. We have analyzed 51 YACs and found that 43% (22 out of 51) are chimeric and significantly larger (302 kb) than colinear ones (228 kb). One of the 51 YAC clones (2%) examined contains portions of three chromosomes and 2 (4%) seem to map to a chromosome different than that of the identifying STS. FISSH analysis offers a straightforward visualization of the entire YAC insert on the chromosomes and can be used to examine many YACs simultaneously in few days.

Mapping human chromosomes by walking with sequence-tagged sites from end fragments of yeast artificial chromosome inserts

Sequence-tagged sites (STSs) derived from end fragments of chromosome-specific yeast artificial chromosomes (YACs) can facilitate the assembly of an overlapping YAC/STS map. Contigs form rapidly by iteratively screening YAC collections with end-fragment STSs from YACs that have not yet been detected by any previous STS. The map is rendered rapidly useful during its assembly by incorporating supplementary STSs from genes and genetic linkage probes with known locations. Methods for the systematic development and testing of the end-fragments STSs are given here, and a group of 100 STSs is presented for the X chromosome. The mapping strategy is shown to be successful in simulations with portions of the X chromosome already largely mapped into overlapping YACs by other means.

Chromosomal assignment of human YAC clones by fluorescence in situ hybridization: use of single-yeast-colony PCR and multiple labeling

Alu-PCR provides a convenient tool for amplification of human-specific sequences from yeast DNA containing yeast artificial chromosomes (YAC) clones. PCR products can be labeled nonisotopically and hybridized in situ, and the chromosomal origin of the clones can be determined. This avoids time-consuming gel purification of the yeast artificial chromosome and the low-efficiency procedure of labeling whole yeast DNA containing the YAC. The application of Alu-PCR to single-yeast colonies permits the mapping of YACs at a very early stage of their characterization. In situ hybridization can detect clones with noncontiguous fragments of DNA, and these can be discarded without further time-consuming characterization. To increase further the potential of the method, we show the application of multicolor hybridization techniques.