Physical map and cosmid contig encompassing a new interstitial deletion of the X-linked lymphoproliferative syndrome region

The X-linked lymphoproliferative syndrome (XLP) is an inherited immuno-deficiency to Epstein-Barr virus infection that has been mapped to chromosome Xq25. Molecular analysis of XLP patients from ten different families identified a small interstitial constitutional deletion in 1 patient (XLP-D). This deletion, initially defined by a single marker, DF83, known to map to interval Xq24-q26.1, is nested within a previously reported and much larger deletion in another XLP patient (XLP-739). A cosmid minilibrary was constructed from a single mega-YAC and used to establish a contig encompassing the whole XLP-D deletion and a portion of the XLP-739 deletion. Based on this contig, the size of the XLP-D deletion can be estimated at 130 kb. The identification of this minimal deletion, within which at least a portion of the XLP gene is likely to reside, should greatly facilitate efforts in isolating the gene.

Fine mapping of the EDA gene: a translocation breakpoint is associated with a CpG island that is transcribed

In order to identify the gene for human X-linked anhidrotic ectodermal dysplasia (EDA), a translocation breakpoint in a female with t(X;1)(q13.1;p36.3) and EDA (patient AK) was finely mapped. The EDA region contains five groups of rare-cutter restriction sites that define CpG islands. The two more centromeric of these islands are associated with transcripts of 3.5 kb and 1.8 kb. The third CpG island maps within <1 kb of the translocation breakpoint in patient AK, as indicated by a genomic rearrangement, and approximately 100 kb centromeric from another previously mapped translocation breakpoint (patient AnLy). Northern analysis with a probe from this CpG island detected an approximately 6-kb mRNA in several fetal tissues tested. An extended YAC contig of 1,200 kb with an average of fivefold coverage was constructed. The two most telomeric CpG islands map 350 kb telomeric of the two translocations. Taken together, the results suggest that the CpG island just proximal of the AK translocation breakpoint lies at the 5' end of a candidate gene for EDA.

Construction of a YAC contig and an STS map spanning 3.6 megabase pairs in Xp22.1

We have constructed a 3.6 Mb sequence tagged sites (STS)-based yeast artificial chromosome (YAC) contig, consisting of 58 individual YAC clones, spanning the region PDHA1 and DXS451 on Xp22.1. In addition to establishing the order of PDHA1, ISPK-1, DXS2504, DXS1528 and the 13 known polymorphic loci as Xpter-PDHA1-DXS443-DXS3424-ISPK-1-DXS12 29-DXS2504-DXS1528-DXS365-DXS7101- DXS1683-DXS1052-DXS274-DXS92-DXS1226-DX S41-DXS989-DXS451-Xcen, we have also developed 35 novel STSs from YAC end clones. These results provide a high density of STS markers (approximately 1 per 70 kb). Furthermore, a detailed long-range restriction map of the contig has been constructed with rare-cutter enzymes and this has refined and verified the physical distances between markers inferred from YAC sizes and their STS content. The integration of the physical mapping data with previous genetic mapping data and the use of STSs and non-chimeric YAC clones reported here should facilitate the construction of a transcript map of this region and the positional cloning of disease genes in this portion of Xp22.1.

Multiple genetic loci within 11p15 defined by Beckwith-Wiedemann syndrome rearrangement breakpoints and subchromosomal transferable fragments

Beckwith-Wiedemann syndrome (BWS) involves fetal overgrowth and predisposition to a wide variety of embryonal tumors of childhood. We have previously found that BWS is genetically linked to 11p15 and that this same band shows loss of heterozygosity in the types of tumors to which children with BWS are susceptible. However, 11p15 contains > 20 megabases, and therefore, the BWS and tumor suppressor genes could be distinct. To determine the precise physical relationship between these loci, we isolated yeast artificial chromosomes, and cosmid libraries from them, within the region of loss of heterozygosity in embryonal tumors. Five germ-line balanced chromosomal rearrangement breakpoint sites from BWS patients, as well as a balanced chromosomal translocation breakpoint from a rhabdoid tumor, were isolated within a 295- to 320-kb cluster defined by a complete cosmid contig crossing these breakpoints. This breakpoint cluster terminated approximately 100 kb centromeric to the imprinted gene IGF2 and 100 kb telomeric to p57KIP2, an inhibitor of cyclin-dependent kinases, and was located within subchromosomal transferable fragments that suppressed the growth of embryonal tumor cells in genetic complementation experiments. We have identified 11 transcribed sequences in this BWS/tumor suppressor coincident region, one of which corresponded to p57KIP2. However, three additional BWS breakpoints were > 4 megabases centromeric to the other five breakpoints and were excluded from the tumor suppressor region defined by subchromosomal transferable fragments. Thus, multiple genetic loci define BWS and tumor suppression on 11p15.

An integrated physical and genetic map of a 35 Mb region on chromosome Xp22.3-Xp21.3

We have constructed a detailed physical map of the 35 Mb region spanning human chromosome Xp22.3-Xp21.3. The backbone of the map is represented by a single oriented contiguous stretch of 585 overlapping yeast artificial chromosome (YAC) clones covering the entire region. The map is formatted with 615 map objects that include 324 YACs, 185 sequence tagged sites, 28 genes, 85 chromosomal breakpoints and 37 highly polymorphic markers. Physical mapping was both guided and confirmed using 183 bins defined by chromosomal breakpoints and by overlapping regions of YAC clones. The localization of polymorphic markers in the physical map permits the integration of physical and genetic data across the region. These data establish chromosome Xp22.3-Xp21.3 as one of the best characterized large regions in the human genome. The map should greatly facilitate finer scale mapping and sequencing as well as the identification of disease genes from this portion of the human genome.

A YAC-based contig of 1.5 Mb spanning the human multidrug resistance gene region and delineating the amplification unit in three human multidrug-resistant cell lines

A contig of 21 nonchimeric yeast artificial chromosomes (YACs) has been assembled across 1.5 Mb of the multidrug resistance (MDR) gene region located at 7q21, and formatted with four previously reported probes, six newly isolated probes, and three sequence-tagged sites (STSs) from internal and end fragments of YACs. A physical map of rare cutter restriction enzyme sites across the region was also constructed by pulsed-field gel electrophoretic (PFGE) analysis of four overlapping YAC clones. The amplification unit of this region in different cell lines was then determined by Southern blot analysis on the basis of the physical map and probes. Amplified DNA was located in extrachromosomal elements in human MDR cell lines studied here, and the size of the amplification unit was determined to be discrete in one MDR amplification but variable in others.

Functional expression of yeast artificial chromosome-human multidrug resistance genes in mouse cells

Multidrug resistance (MDR) genes, which are ATP-binding cassette family genes, encode the cell surface glycoprotein, P-glycoprotein, which functions as an energy-dependent drug efflux pump. Two relevant human genes, PGY1 and PGY3, are located on human chromosome 7, and three relevant mouse genes, mdr1a, mdr1b, and mdr2, are located on mouse chromosome 5. An LMD1 cell line was established after the transfer of a 580-kb yeast artificial chromosome (YAC) clone carrying the human MDR locus into mouse L cells; the cell line was shown to have stably integrated YAC DNA in an apparent intact form. Using LMD1 cells as the parental cell line, five vincristine-resistant sublines, designated LMD1-V50, LMD1-V100, LMD1-V200, LMD1-V500, and LMD1-V1000, were isolated by exposure to increasing concentrations of the drug. LMD1-V50, LMD1-V100, LMD1-V200, LMD1-V500, and LMD1-V1000 showed 3-, 7-, 13-, 45-, and 110-fold higher resistance to the cytotoxic effects of vincristine, respectively, than their parental counterpart, LMD1. Immunofluorescence, Western blot, and Northern blot analyses revealed that the human PGY1 gene or its product was overexpressed, accompanied by gene amplification. The human PGY3 gene was also overexpressed in the LMD1-V20, LMD1-V100, and LMD1-V1000 cell lines. Southern blot and fluorescence in situ hybridization (FISH) analyses demonstrated that although essentially the entire YAC DNA was integrated in mouse genome and amplified, the endogenous mouse mdr genes were not amplified in these drug-resistant cell lines. Similar results were obtained by the analyses of vincristine-resistant cell lines isolated from four independent subclones of LMD1 cells. Thus, in contrast to their mouse counterparts, the integrated human MDR genes retained susceptibility to both gene activation and amplification, during the selection of drug-resistant mouse cell lines. The possibility that transferred YACs may retain regulatory properties observed in the cells of origin, and may have a chromatin structure that favors augmented expression, is discussed.

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.

Three genes that escape X chromosome inactivation are clustered within a 6 Mb YAC contig and STS map in Xp11.21-p11.22

In order to study the distribution of genes that escape X chromosome inactivation, a high density yeast artificial chromosome (YAC) contig and STS map spanning approximately 6 Mb has been constructed in Xp11.21-p11.22. The contig contains 113 YACs mapped with 53 markers, including 10 genes. Four genes have been assayed for their expression status on both the active and inactive human X chromosomes, and these data have been combined with previous results on two other genes in the contig. Three of these genes escape X inactivation and have been localized to a single YAC clone of approximately 1075 kb. The other three genes are subject to inactivation, with two of them lying among the genes that escape inactivation. These results suggest that there are both regional control signals as well as gene-specific elements that determine the X inactivation status of genes on the proximal short arm of the human X chromosome.

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.

Sequence and gene content in 52 kb including and centromeric to the G6PD gene in Xq28

A cosmid containing 36.4 kb of high GC human DNA centromeric to the G6PD gene has been analyzed. The sequence was 99.9% precise, based on the comparison of 4.3 kb that overlaps an earlier analysis of 20.1 kb containing G6PD. Properties of the entire 52 kb region that may be characteristic of high GC portions of the genome include a very high density of sixty-two half or full Alu sequences, or 1.2/kb, and an absence of L1 sequences. Other highly repetitive sequences include 11 MER sequences, one of them interrupted at two positions by groups of 3 Alu elements. In segments of unique sequence, computer-aided analysis predicted three possible genes, one of which has thus far been confirmed by the recovery of a corresponding cDNA, both by a direct hybridization method and by a PCR-based method based on a primer pair inferred from the genomic sequence. The cDNA has been sequenced, and is completely concordant with counterpart genomic sequence; it has no resemblance to any previously described gene.

PCR-based immortalization and screening of hierarchical pools of cDNAs

Starting from sequences of at least 60 bp, PCR-based screening has been developed to recover cDNAs from libraries without the necessity for hybridization or extensive DNA extraction steps. The method maintains the indefinite availability of even scarce cDNA libraries and provides an estimate of the relative abundance of the mRNA species. Isolation of a cDNA clone can be done in less than a week. cDNAs were isolated that were cognate for fragments of expressed sequences and for an exon predicted from genomic sequence.

Increased retention of small chromosomes in a novel yeast mutant

MSC201 and MSC202 are novel yeast mutant strains in which a 10-kb linear yeast artificial chromosome (YAC) was stably maintained in unselective medium during mitotic cell division. After culturing for 35 cycles of cell division, about 50% of MSC cells retain YAC3 DNA, compared to 0.001% of the wild-type AB1380 strain. Southern blot hybridization analysis with pBR322 DNA as the probe showed that in the MSC transformants, YAC DNA remained in a linear form free of cellular chromosomal DNA. The msc201 mutation was shown to be recessive by the rapid loss of the YAC in a diploid strain made by mating with AB1375, which has a genetic background similar to that of the MSC strain. Linear YAC DNA with a centromere was stabilized in MSC201 better than a linear construct lacking a centromere sequence.

HPRT yeast artificial chromosome transfer into human cells by four methods and an involvement of homologous recombination

The transfer of a yeast artificial chromosome (YAC) into mouse and human cell lines was effected by four methods, and the efficiency and integrity of the incorporated YAC DNA were compared. A 500 kb YAC containing the human hypoxanthine-guanine phosphoribosyl transferase (HPRT) gene was transferred more efficiently by polyethylene glycol-mediated fusion than by lipofection, electrofusion, or electroporation. Southern blot analysis demonstrated that PEG fusion lines yielded fragments of the size of the original YAC clone, whereas lipofection and electroporation did not. Two of 53 fusion lines showed 6-thioguanine resistance and confirmatory disruption of the HPRT gene in the YAC DNA, suggesting that the YAC DNA was integrated by homologous recombination with the endogenous HPRT gene region.

Chimeric YACs were generated at unreduced rates in conditions that suppress coligation

Chimerism is a major limitation of current YAC libraries. A method based on partially filled-in ends of restriction fragments was designed to avoid coligation as a possible source of chimeras. Model experiments using plasmid DNA as an insert showed that coligation was clearly avoided by this method. Pilot collections of YACs with an average insert size of 650kb were then constructed with and without the partial fill-in treatment. Starting from a mixture of a equal amounts of human and mouse DNA, none of 108 clones was positive by hybridization with both Alu and B2 probes, again suggesting that coligation was effectively blocked. However, 4 out of 10 clones still hybridized to 2 or more locations by FISH on chromosomes in human metaphase spreads, level similar to that in the clones made without the partial fill-in step. These results strongly suggest that chimeric clones generally arise by a mechanism independent of coligation, presumptively based on recombination.

BLOCK-based PCR markers to find gene family members in human and comparative genome analysis

Degenerate primer pairs that include consensus sequences of evolutionary conserved portions of protein families (BLOCKs or ancient conserved regions) can be used to screen by polymerase chain reaction (PCR) for cognate cDNAs and YACs through much of phylogeny. Nine such primer pairs were developed, and five with sites on human chromosomes 7 or X were shown to identify YACs from chromosome-specific locations, including a candidate for a new zinc finger gene in Xq28. When linked to contig-based genomic maps, such BLOCK-based PCR assays may provide a route to recover the members and study the development of families containing up to 40% of genes, in genomes as diverse as humans, nematodes, and yeast.

Structure of the human CCG1 gene: relationship between the exons/introns and functional domain/modules of the protein

The human CCG1 gene, encoding CCG1/TAFII250/p250, was isolated by complementing tsBN462, a mutant BHK21 cell line that shows cell-cycle arrest at high temperature. Using the cDNA as a probe, the locations of exon-intron junctions were determined in the genomic DNA. Thirty-eight exons ranging from 68 to 219 bp in size were found. All the exon-intron junctions followed the GT-AG rule. Using a newly developed method, we performed a module analysis of the CCG1 protein. The functional domain previously predicted in CCG1 was further confirmed to be encoded in a single predicted module that is the minimal functional unit in the protein. The boundaries of the predicted modules show a close correlation to the intron/exon junction of CCG1. The entire gene, at least 110 kb long, has been recovered in a YAC, which provides a route to the further study of module function.

Stability of YACs containing ribosomal or RCP/GCP locus DNA in wild-type S. cerevisiae and RAD mutant strains

About 2% of human YAC clones, including tandemly repeated segments color vision pigment DNA, ribosomal DNA and alphoid DNA have been reported to be inherently unstable in yeast hosts, producing more stable deletion products. YACs containing color vision red pigment gene DNA or 1.5 rDNA tandem repeat units were transformed into hosts bearing lesions at the RAD1, RAD6, RAD51, or RAD52 loci. YACs susceptible to deletion during outgrowth of wild-type cells (or in preliminary experiments, in RAD6 transformants) were stable for up to 100 generations or more in the other strains. Thus both the RAD1 and RAD51/RAD52 epistatic pathways are apparently involved in the instability of YACs containing tandem repeat loci, presumably during recombination-based deletion formation; and a yeast host disarmed in these pathways will likely maintain YACs intact that are otherwise unstable.