Creation of a yeast artificial chromosome fragmentation vector based on lysine-2

Generation of transgenic mice with megabase-sized human yeast artificial chromosomes by yeast spheroplast-embryonic stem cell fusion

Introducing human genes into mice offers the opportunity to analyze their in vivo function or to obtain therapeutic molecules. For proper gene regulation, or in case of multigene families, megabase (Mb)-sized DNA fragments often have to be used. Yeast artificial chromosome (YAC)-mediated transgenesis is irreplaceable for this purpose, because alternative methods such as the use of bacterial artificial chromosomes (BACs) cannot introduce DNA fragments larger than 500 kb into the mouse germ line. However, YAC libraries often contain only partial gene loci. Time-consuming reconstruction of YACs, genetic instability and the difficulty in obtaining intact YAC DNA above a certain size impede the generation of humanized mice. Here we describe how to reconstruct YACs containing Mb-sized human DNA, such as the T cell receptor-α (TRA) gene locus, thus facilitating the introduction of large DNA fragments into the mouse germ line. Fusion of YAC-containing yeast and embryonic stem (ES) cells avoids the need for YAC DNA purification. These ES cells are then used to stably introduce the functional TRA gene locus into the mouse germ line. The protocol takes ∼1 year to complete, from reconstruction of the entire TRA gene locus from YACs containing partial but overlapping TRA regions to germline transmission of the YAC.

Purification and characterization of YACs containing large inserts

This unit provides protocols for characterizing DNA segments cloned in YACs and for purifying YACs from yeast chromosomes. The first basic protocol describes Southern blotting and partial-digest restriction analysis of YACs. These methods are useful for determining the size and complexity of the cloned insert DNA, the presence and location of particular restriction sites or sequences, and even the species of origin of the insert DNA (indicated by hybridization to species-specific repetitive elements such as Alu repeats). The second basic protocol describes gel purification of YACs for use in procedures requiring pure YAC DNA, such as mammalian-cell transformation and subcloning into smaller insert vectors. The third basic protocol details characterizing and analyzing YACs: in vivo fragmentation via homologous recombination with specialized fragmentation vectors containing specific probe sequences or repetitive elements, followed by Southern blotting with YAC- and human-derived probes.

Comparison of a new pmp22 transgenic mouse line with other mouse models and human patients with CMT1A

Charcot-Marie-Tooth disease type 1A is a dominantly inherited demyelinating disorder of the peripheral nervous system. It is most frequently caused by overexpression of peripheral myelin protein 22 (PMP22), but is also caused by point mutations in the PMP22 gene. We describe a new transgenic mouse model (My41) carrying the mouse, rather than the human, pmp22 gene. The My41 strain has a severe phenotype consisting of unstable gait and weakness of the hind limbs that becomes obvious during the first 3 weeks of life. My41 mice have a shortened life span and breed poorly. Pathologically, My41 mice have a demyelinating peripheral neuropathy in which 75% of axons do not have a measurable amount of myelin. We compare the peripheral nerve pathology seen in My41 mice, which carry the mouse pmp22 gene, with previously described transgenic mice over-expressing the human PMP22 protein and Trembler-J (TrJ) mice which have a P16L substitution. We also look at the differences between CMT1A duplication patients, patients with the P16L mutation and their appropriate mouse models.

Identification of a psoriasis susceptibility candidate gene by linkage disequilibrium mapping with a localized single nucleotide polymorphism map

Psoriasis is a chronic inflammatory disease of the skin with both genetic and environmental risk factors. Here we describe the creation of a single-nucleotide polymorphism (SNP) map spanning 900-1200 kb of chromosome 3q21, which had been previously recognized as containing a psoriasis susceptibility locus, PSORS5. We genotyped 644 individuals, from 195 Swedish psoriatic families, for 19 polymorphisms. Linkage disequilibrium (LD) between marker and disease was assessed using the transmission/disequilibrium test (TDT). In the TDT analysis, alleles of three of these SNPs showed significant association with disease (P<0.05). A 160-kb interval encompassing these three SNPs was sequenced, and a coding sequence consisting of 13 exons was identified. The predicted protein shares 30-40% homology with the family of cation/chloride cotransporters. A five-marker haplotype spanning the 3' half of this gene is associated with psoriasis to a P value of 3.8<10(-5). We have called this gene SLC12A8, coding for a member of the solute carrier family 12 proteins. It belongs to a class of genes that were previously unrecognized as playing a role in psoriasis pathogenesis.

Molecular characterization of the breakpoint region associated with a constitutional t(2;15)(q34;q26) in a patient with multiple myeloma

The molecular cloning of the translocation breakpoints from constitutional chromosome rearrangements in patients with a variety of human diseases has consistently led to the isolation of genes important in the development of the phenotype. We used fluorescence in situ hybridization (FISH) to analyze the breakpoint region of a constitutional chromosome translocation involving regions 2q34 and 15q26 observed in a patient with multiple myeloma (MM), a malignant disorder of plasma cells secreting monoclonal immunoglobulin. FISH analysis of this rearrangement showed that the chromosome 2-specific yeast artificial chromosome (YAC) 914E7 and the chromosome 15-specific YAC 757H6 span the translocation breakpoints, respectively. In order to characterize the location of the breakpoints further, somatic cell hybrids were constructed between mouse NIH3T3 cells and t(2;15)-bearing lymphoblastoid cells. Using these somatic cell hybrids, we have shown that the breakpoint on chromosome 2 lies between D2S3007 and D2S3004 and the chromosome 15 breakpoint lies between D15S107 and WI5967 (D15S836). YAC fragmentation has been used to define a 350 kb region containing the 15q26 breakpoint.

Identification of a coordinate regulator of interleukins 4, 13, and 5 by cross-species sequence comparisons

Long-range regulatory elements are difficult to discover experimentally; however, they tend to be conserved among mammals, suggesting that cross-species sequence comparisons should identify them. To search for regulatory sequences, we examined about 1 megabase of orthologous human and mouse sequences for conserved noncoding elements with greater than or equal to 70% identity over at least 100 base pairs. Ninety noncoding sequences meeting these criteria were discovered, and the analysis of 15 of these elements found that about 70% were conserved across mammals. Characterization of the largest element in yeast artificial chromosome transgenic mice revealed it to be a coordinate regulator of three genes, interleukin-4, interleukin-13, and interleukin-5, spread over 120 kilobases.

CFTR intron 1 increases luciferase expression driven by CFTR 5'-flanking DNA in a yeast artificial chromosome

The DNA elements that account for the highly regulated expression of the cystic fibrosis transmembrane conductance regulator gene (CFTR) are poorly understood. The goal of this study was to assess the feasibility of using a yeast artificial chromosome (YAC)-based reporter gene construct to define these elements further. An approximately 350-kb YAC (y5'luc) was constructed by replacing CFTR with a luciferase reporter gene (luc). A second YAC (y5'lucI) was similarly constructed but included a putative positive regulatory element from CFTR intron 1. Stable Chinese hamster ovary (CHO-K1) cell clones were derived using each YAC to assess the role that luc copy number and the presence of intron 1 played in luc expression. The CHO-K1 clonal cell lines demonstrated a wide range of luciferase activity. On average, this activity was significantly higher in clones derived from y5'lucI. After correcting for luc copy number, the presence of intron 1 was still associated with an increase in luciferase activity (P < 0.05), despite the fact that luciferase activity did not correlate with luc copy number in y5'luc-derived clones (r = -0.12). In contrast, the luciferase activity correlated well with luc copy number in the clones derived from y5'luc (r = 0. 75). These data are consistent with a positive role for intron 1 in regulating CFTR expression, but suggest that copy number is not the only factor that determines expression levels, particularly when this element is present. This YAC-based reporter system will provide a unique strategy for further assessment of the cis-acting elements that control CFTR expression.

YAC fragmentation with repetitive and single-copy sequences: detailed physical mapping of the presenilin 1 gene on chromosome 14

We constructed new LYS2 fragmentation vectors that allow direct acentric and centric fragmentation of yeast artificial chromosomes (YACs) and selection of fragmented YACs in yeast strain AB1380. The fragmentation vectors were used efficiently with repetitive (e.g., Alu), low-copy (e.g., CA-repeats) and single-copy (e.g., exons) sequences. High recombination efficiencies were obtained in fragmenting two different CEPH YACs with the Alu consensus sequence as target sequences for homologous recombination. Analysis of the acentric Alu fragmentation panel of 788H12, containing the presenilin 1 (PSEN1) gene for familial Alzheimer's disease (AD), indicated that high-resolution YAC fragmentation panels covering the entire parent YAC are obtained. Also, marker content analysis of the fragmentation panel indicated that fragmented YACs were propagated stably without rearrangements. The same fragmentation vectors were used efficiently for fragmentation of 788H12 with unique sequences, i.e., exons 3 and 12 of PSEN1 and D14S77, a polymorphic CA repeat, as target sequences. Together, our YAC fragmentation data of 788H12 provided a size estimate for the coding region of PSEN1 of 60kb and a more precise localization of D14S77 at 25kb upstream of PSEN1.

Localization of tumor suppressor activity important in nonsmall cell lung carcinoma on chromosome 11q

Loss of heterozygosity on chromosome 11q23 is observed at high frequency in human nonsmall cell lung carcinomas (NSCLCs), suggesting the presence of a tumor suppressor gene. Previous analysis of DNA from 79 patients identified a commonly deleted segment of 5 centimorgans. Complementation analysis was used to further localize a putative tumor suppressor gene. Three yeast artificial chromosome (YAC) clones spanning the minimal loss of heterozygosity region were modified, and spheroplast fusion was used to transfer them into human A549 NSCLC or murine Lewis lung carcinoma (LLC) cell lines. The resulting yeast x human hybrid cell lines containing an intact copy of a 1.6-Mb YAC, 939b12, showed reduced growth in vitro. Injection of parental A549 cells into athymic (nu/nu) mice resulted in tumor formation at 27 of 28 injection sites. In contrast, two independent 939b12-containing cell lines formed tumors at only 3 of 20 injection sites. 939b12 also suppressed tumor formation by LLC NSCLC cells in nude mice, but YACs 785e12 and 911f2, which flank 939b12, had no suppressor activity. Further localization of tumor suppression activity on 939b12 was accomplished by introduction of defined fragmentation derivatives into A549 cells and by analysis of YACs that were broken on transfer into LLC cells. This complementation approach localized tumor suppression activity to the central 700 kb of 939b12 and provides a functional assay for positional cloning of this tumor suppressor gene.

Physical map of human 6p21.2-6p21.3: region flanking the centromeric end of the major histocompatibility complex

We have physically mapped and cloned a 2.5-Mb chromosomal segment flanking the centromeric end of the major histocompatibility complex (MHC). We characterized in detail 27 YACs, 144 cosmids, 51 PACs, and 5 BACs, which will facilitate the complete genomic sequencing of this region of chromosome 6. The contig contains the genes encoding CSBP, p21, HSU09564 serine kinase, ZNF76, TCP-11, RPS10, HMGI(Y), BAK, and the human homolog of Tctex-7 (HSET). The GLO1 gene was mapped further centromeric in the 6p21.2-6p21.1 region toward TCTE-1. The gene order of the GLO1-HMGI(Y) segment in respect to the centromere is similar to the gene order in the mouse t-chromosome distal inversion, indicating that there is conservation in gene content but not gene order between humans and mice in this region. The close linkage of the BAK and CSBP genes to the MHC is of interest because of their possible involvement in autoimmune disease.

High-resolution YAC fragmentation map of 1q21

Chromosomal band 1q21 contains a number of genes, constituting the Epidermal differentiation complex (EDC), most of which are involved in the process of terminal differentiation of the human epidermis and implicated in several disorders of keratinization and cancer. The physical map of 1q21 has been refined by generating 400 YAC derivatives. These products have allowed us to localize EDC genes and additional ESTs precisely. The transcriptional map of the region has been extended by positioning 20 ESTs reported to map between D1S442 and D1S305. Eight of the ESTs are localized in two distinct clusters, confirmed by isolating PACs and chromosome 1-specific cosmids. Two of the ESTs correspond to the genes for YL1 and selenium-binding protein, both of which have potential tumor suppressor activity. Through the use of fragmented YACs and bacterial clones, the order of markers and ESTs in the region has been established as follows: cen-A002O32-Bda44g03-Cda10d12-Bdab5d06, H60056, A005K39-D1S442-WI5663-WI7969-Cx40-Cda0g e12-Cda0kh05-A002D26- A008S07-Cda0ff08-D1S498-S100A10-WI7815( THH)-WI7217(FLG)-D1S1664-INV-SPRR2A- LOR-A001X21-D1S305-tel.

Rapid mapping of markers applying vectorette technology to YAC fragmentation allows easy assembly of a high-density STS bacterial clone contig spanning the markers D6S1260-D6S1918

We have generated a detailed physical map of the 6p21.3/p22.1 boundary, using a combination of yeast artificial chromosome (YAC) fragmentation and high-resolution sequence tagged site (STS) content mapping. YACs from the CEPH, St. Louis, and ICRF libraries have been used to construct a 4.5-Mb contig spanning the markers D6S306 to D6S1571. YAC insert sizes were determined by pulsed field gel electrophoresis (PFGE). Chimerism of YACs was determined by fluorescent in situ hybridization (FISH), and their integrity was determined by fingerprinting with Alu-PCR. We have identified 10 new CA repeat loci in this region as well as over 50 novel STSs, several tRNA genes, a new histone H2B gene and the phospholipase D gene. Using these new markers, we have rapidly generated a bacterial clone contig of over 250 kb, spanning the markers D6S1260 to D6S1918 (WI-3111) with STSs spaced on average every 6 kb.

Exploring gene function: use of yeast artificial chromosome transgenesis

Transgenesis is a very powerful tool in functional analysis of proteins and control of gene expression. One of the main drawbacks has been the low levels of expression, lack of tissue specificity, and inappropriate expression frequently observed for transgenes made with small plasmid-based constructs. The use of much larger DNA fragments cloned in yeast artificial clones (YACs), bacterial artificial clones, or P1-based artificial clones has been found to give much better levels of expression, generally very close to that of an endogenous gene, and tissue-specific expression matching that of the endogenous gene. In addition, the large DNA can easily be subtly modified by homologous recombination. This article describes the background and methods of YAC transgenesis.

Imprinted expression of the Igf2r gene depends on an intronic CpG island

Gametic imprinting is a developmental process that induces parental-specific expression or repression of autosomal and X-chromosome-linked genes. The mouse Igf2r gene (encoding the receptor for insulin- like growth factor type-2) is imprinted and is expressed from the maternal allele after embryonic implantation. We previously proposed that methylation of region 2, a region rich in cytosine-guanine doublets (a 'CpG island') in the second intron of Igf2r, is the imprinting signal that maintains expression of the maternal allele. Here we use mouse transgenes to test the role of region 2 and the influence of chromosome location on Igf2r imprinting. Yeast artificial chromosome transgenes successfully reproduced the imprinted methylation and expression pattern of the endogenous Igf2r gene; deletion of region 2 from these transgenes caused a loss of imprinting and restored biallelic Igf2r expression. These results define a primary role for region 2 and a negligible role for chromosomal location in Igf2r imprinting; they also show that methylation imprints can maintain allelic expression. Short transgenes containing only region 2 and yeast artificial chromosome transgenes with an inactive Igf2r promoter do not attract parental-specific methylation. All transgenes showing paternal-specific repression of Igf2r produced an antisense RNA whose transcription was dependent on region 2. The production of an antisense RNA by the repressed parental allele is reminiscent of the imprinting of the Igf2/H19 gene pair and may indicate that expression competition could play a general role in imprinting.

Direct isolation of human transcribed sequences from yeast artificial chromosomes through the application of RNA fingerprinting

The identification of cDNA clones from genomic regions known to contain human genes is usually the rate-limiting factor in positional cloning strategies. We demonstrate here that human genes present on yeast artificial chromosomes (YACs) are transcribed in yeast host cells. We have used the arbitrarily primed RNA (RAP) fingerprinting method to identify human-specific, transcribed sequences from YACs located in the 13q12 chromosome region. By comparing the RAP fingerprints generated using defined, arbitrary primers from various fragmented YACs, megaYACs, and host yeast, we were able to identify and map 20 products transcribed from the human YAC inserts. This method, therefore, permits the simultaneous isolation and mapping of novel expressed sequences directly from whole YACs.

Physical mapping of potassium channel gene clusters on mouse chromosomes three and six

Mammalian voltage-gated K channel genes have been divided into four subfamilies (Shaker, Shab, Shal, and Shaw) based on their sequence identity and similarity to related genes in Drosophila. Genetic mapping of the voltage-gated K channel genes has shown that similar multigene clusters exist on mouse Chr 3 and 6 and suggests that the clusters may have arisen through chromosomal duplication. In this report, YAC-based physical maps of the clustered mouse Shaker-like K channel genes have been constructed using restriction endonuclease and yeast chromosome fragmentation approaches. These data define the physical spacing as 5'-Kcna3-(60 kb)-Kcna2-(90 kb)-Kcna8-3' on Chr 3, and as 5'-Kcna6-(80 kb)-Kcna1-(110 kb)-Kcna5-3' on Chr 6, with all genes oriented in a head-to-tail manner within their respective clusters. These detailed physical maps of both K channel gene clusters provide additional support for the idea of an ancient genome tetraploidization event.

Centromeric and noncentromeric ADE2-selectable fragmentation vectors for yeast artificial chromosomes in AB1380

We have constructed a set of fragmentation vectors for the truncation of either the centromeric or the noncentromeric end of YACs containing a human DNA insert. These vectors carry ADE2 or HIS5 as the selectable marker, enabling direct use in AB1380, the host strain of most publicly available YAC libraries. Centromeric fragmentation vectors for AB1380 have not been reported previously; the noncentromeric vectors show high frequencies of fragmentation.

Genomic organization of the murine Miller-Dieker/lissencephaly region: conservation of linkage with the human region

Several human syndromes are associated with haploinsufficiency of chromosomal regions secondary to microdeletions. Isolated lissencephaly sequence (ILS), a human developmental disease characterized by a smooth cerebral surface (classical lissencephaly) and microscopic evidence of incomplete neuronal migration, is often associated with small deletions or translocations at chromosome 17p13.3. Miller-Dieker syndrome (MDS) is associated with larger deletions of 17p13.3 and consists of classical lissencephaly with additional phenotypes including facial abnormalities. We have isolated the murine homologs of three genes located inside and outside the MDS region: Lis1, Mnt/Rox, and 14-3-3 epsilon. These genes are all located on mouse chromosome 11B2, as determined by metaphase FISH, and the relative order and approximate gene distance was determined by interphase FISH analysis. The transcriptional orientation and intergenic distance of Lis1 and Mnt/Rox were ascertained by fragmentation analysis of a mouse yeast artificial chromosome containing both genes. To determine the distance and orientation of 14-3-3 epsilon with respect to Lis1 and Mnt/Rox, we introduced a super-rare cutter site (VDE) that is unique in the mouse genome into 14-3-3 epsilon by gene targeting. Using the introduced VDE site, the orientation of this gene was determined by pulsed field gel electrophoresis and Southern blot analysis. Our results demonstrate that the MDS region is conserved between human and mouse. This conservation of linkage suggests that the mouse can be used to model microdeletions that occur in ILS and MDS.

Computational and biological analysis of 680 kb of DNA sequence from the human 5q31 cytokine gene cluster region

With the human genome project advancing into what will be a 7- to 10-year DNA sequencing phase, we are presented with the challenge of developing strategies to convert genomic sequence data, as they become available, into biologically meaningful information. We have analyzed 680 kb of noncontiguous DNA sequence from a 1-Mb region of human chromosome 5q31, coupling computational analysis with gene expression studies of tissues isolated from humans as well as from mice containing human YAC transgenes. This genomic interval has been noted previously for containing the cytokine gene cluster and a quantitative trait locus associated with inflammatory diseases. Our analysis identified and verified expression of 16 new genes, as well as 7 previously known genes. Of the total of 23 genes in this region, 78% had similarity matches to sequences in protein databases and 83% had exact expressed sequence tag (EST) database matches. Comparative mapping studies of eight of the new human genes discovered in the 5q31 region revealed that all are located in the syntenic region of mouse chromosome 11q. Our analysis demonstrates an approach for examining human sequence as it is made available from large sequencing programs and has resulted in the discovery of several biomedically important genes, including a cyclin, a transcription factor that is homologous to an oncogene, a protein involved in DNA repair, and several new members of a family of transporter proteins.

The XRCC2 DNA repair gene: identification of a positional candidate

The human XRCC2 gene, complementing a hamster cell line (irs1) hypersensitive to DNA-damaging agents, was previously mapped to chromosome 7q36.1. Following radiation reduction of human/hamster hybrids, the gene was found to be associated with the marker D7S483. Yeast artificial chromosomes (YACs) carrying D7S483 were fused to the irs1 cell line to identify a YAC that complemented the sensitivity defect. Transcribed sequences were isolated by direct cDNA selection using the complementing YAC, and these were mapped back to the YAC and hybrids to define a 400-kb region carrying XRCC2. Sequencing of cDNAs led to the identification of both known and novel gene sequences, including a candidate for XRCC2 with homology to the yeast RAD51 gene involved in the recombinational repair of DNA damage. Strong support for the candidacy of this gene was obtained from its refined map position and by the full complementation of irs1 sensitivity with a 40-kb cosmid carrying the gene.

A shuttle system for transfer of YACs between yeast and mammalian cells

The development of a system for shuttling DNA cloned as yeast artificial chromosomes (YACs) between yeast and mammalian cells requires that the DNA is maintained as extrachromosomal elements in both cell types. We have recently shown that circular YACs carrying the Epstein-Barr virus origin of plasmid replication (oriP) are maintained as stable, episomal elements in a human kidney cell line constitutively expressing the viral transactivator protein EBNA-1. Here, we demonstrate that a 90-kb episomal YAC can be isolated intact from human cells by a simple alkaline lysis procedure and shuttled back into Saccharomyces cerevisiae by spheroplast transformation. In addition, we demonstrate that the 90-kb YAC can be isolated intact from yeast cells. The ability to shuttle large, intact fragments of DNA between yeast and human cells should provide a powerful tool in the manipulation and analysis of functional regions of mammalian DNA.

Arrayed preparation of YAC DNA for pulsed field gel analysis

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The relationship between genetic and physical distances in the cloned a1-sh2 interval of the Zea mays L. genome

A 470-kb segment from the long arm of chromosome 3 of Zea mays (inbred LH82), encompassing the a1-sh2 interval, was cloned as a yeast artificial chromosome. Comparison of the sizes of the restriction fragments generated from the cloned DNA fragment and from the DNA isolated from the maize inbred line LH82 established the colinearity of the a1-sh2 interval in these DNAs. By utilizing a chromosome fragmentation technique, a yeast artificial chromosome encompassing the a1-sh2 interval was separately fragmented at the a1 and sh2 loci. Comparison of the sizes of these fragmentation products established the physical distance between the a1 and sh2 loci to be 140 kb. Furthermore, these fragmentation experiments established the physical orientation of the a1 and sh2 genes relative to the maize centromere. The molecular cloning of the contiguous region between the a1 and sh2 loci made it possible to define the relationship between physical and genetic distances over a relatively large segment of the maize genome. In this interval, the relationship between physical and genetic distances is 1560 kb/centimorgan, which compares with 1460 kb/centimorgan for the entire maize genome, and 217 kb/centimorgan for a 1-kb segment within the a1 locus. Therefore, these findings are consistent with the hypothesis that genes per se are preferred sites for meiotic recombination rather than the hypothesis that genes reside in large recombinationally active segments of the genome.

Yeast artificial chromosome fragmentation vectors that utilize URA3 selection

Two fragmentation vectors, pSE1 and pSE2, were developed for targeting yeast artificial chromosomes (YACs) containing human genomic DNA. Ura- yeast cells containing YACs were selected with 5-fluoro-orotic acid. Fragmented YACs were subsequently generated by transformation to a Ura+ phenotype. Over 80% of the transformants contained YACs of reduced molecular size. These fragmented YACs will prove to be useful in mapping the region of human chromosomes covered by the parental YAC. Fragmentation utilizing URA3 transformation provides a method for producing YAC deletion sets from YACs contained in AB1380 and other ura3- yeast stains. Linkage of a neomycin resistance gene to the URA3 gene facilitates functional analysis of these YACs in eukaryotic cells.