Genome mapping by arbitrary amplification of yeast artificial chromosomes

Several methods have been described for using the polymerase chain reaction (PCR) to isolate fragments of DNA for genome mapping. We have developed an approach for isolating discrete fragments by amplifying DNA with single oligonucleotides (10-mers) with arbitrarity selected sequences. The method is rapid and technically simple. We isolated fragments from a contig of three yeast artificial chromosomes (YACs) from the human Xq28 chromosomal region. We purified YACs yWXD 37, yWXD348, and yWXD705 from a preparative pulsed field gel. Amplifications of each YAC were performed with single 10-mers as the PCR primers and the products were visualized on agarose gels. These fragments have been successfully used as hybridization probes against Southern blots containing the YACs and against blots containing human genomic DNA and somatic cell hybrids containing Xq28 as their only human constituent. The results have been concordant with the known order of the YACs. We have also successfully combined 10-mers with primers derived from vector arm sequences to isolate YAC ends. We discuss several uses of this method in comparative mapping and in filling in gaps in physical and genetic maps.     

Transgenic mice carrying yeast artificial chromosomes

The generation of transgenic mice with yeast artificial chromosomes (YACs) has proven to be a valuable system to: (1) study gene structure-function relationships; (2) produce mouse models of human disease; (3) complement mouse mutants; (4) generate mice bioreactors; and (5) screen YAC libraries in vivo. Continued refinement of current techniques and development of new protocols should encourage widespread adaptation of this strategy for these and other applications. Use of whole loci as transgenes is an important improvement in murine transgenesis because it results in a more realistic pattern and level of gene expression during ontogeny. Application of this technology to develop human artificial chromosomes (HACs) might provide the next generation of gene therapy vectors that will overcome most of the problems and barriers associated with current vector systems.     

Mitotic recombination of yeast artificial chromosomes.

Large regions of human DNA can be cloned and mapped in yeast artificial chromosomes (YACs). Overlapping YAC clones can be used in order to reconstruct genomic segments in vivo by meiotic recombination. This is of importance for reconstruction of a long gene or a gene complex. In this work we have taken advantage of yeast protoplast fusion to generate isosexual diploids followed by mitotic crossing-over, and show that it can be an alternative simple strategy for recombining YACs. Integrative transformation of one of the parent strains with the construct pRAN4 (containing the ADE2 gene) is used to disrupt the URA3 gene contained within the pYAC4 vector arm, providing the markers required for forcing fusion and detecting recombination. All steps can be carried out within the commonly used AB1380 host strain without the requirement for micromanipulation. The method was applied to YAC clones from the human MHC and resulted in the reconstruction of a 650 kb long single clone containing 18 known genes from the MHC class II region.     

Double-strand breaks on artificial chromosomes in yeast

Yeast artificial chromosomes composed primarily of bacteriophage λ DNA exhibit very low levels of meiotic crossing over compared with similarly sized intervals of natural yeast DNA. When these recombinationally quiet chromosomes were augmented with a 12.5 kb insert of sequences from yeast chromosome VIII, genetic studies demonstrated that the artificial chromosomes had acquired recombination properties characteristic of this region of chromosome VIII. On authentic yeast chromosomes, most meiotic recombination events are initiated at sites where the DNA is cleaved to create a double-strand break (DSB). This report describes physical analyses that were carried out to examine the relationship between DSB sites and the recombination behavior of the artificial chromosomes. The results show that DSBs are rare on these artificial chromosomes, except for the 12.5 kb insert. Mapping of the DSB sites shows that their positions correlate with the previously determined positions of DSB sites on chromosome VIII. Deletion of two characterized chromosome VIII DSB sites from the 12.5 kb insert on the artificial chromosome resulted in the loss of the predicted DSB fragments and a reduction in crossing over between artificial chromosomes. Received: 15 May 1998; in revised form: 26 September 1999 / Accepted: 18 November 1999     

Transfer of yeast artificial chromosomes from yeast to mammalian cells.

Human DNA can be cloned as yeast artificial chromosomes (YACs), each of which contains several hundred kilobases of human DNA. This DNA can be manipulated in the yeast host using homologous recombination and yeast selectable markers. In relatively few steps it is possible to make virtually any change in the cloned human DNA from single base pair changes to deletions and insertions. In order to study the function of the cloned DNA and the effects of the changes made in the yeast, the human DNA must be transferred back into mammalian cells. Recent experiments indicate that large genes can be transferred from the yeast host to mammalian cells in tissue culture and that the genes are transferred intact and are expressed. Using the same methods it may soon be possible to transfer YAC DNA into the mouse germ line so that the expression and function of genes cloned in YACs can be studied in developing and adult mammalian animals.     

Chromosomal in situ hybridization using yeast artificial chromosomes

Large DNA fragment cloning methods using yeast artificial chromosomes (YACs) have vastly improved the strategies for constructing physical maps of regions of complex genomes, as well as for isolating and cloning genes important for human disease. We present here a simple and rapid method for carrying out in situ hybridization to metaphase chromosomes using isolated YAC clones by labeling DNA directly in agarose gel slices. Nonisotopic labeling and chromosomal in situ hybridization can be used to determine the chromosomal localization of individual YAC clones on human metaphase chromosomes. This method can also be used to characterize YAC clones consisting of single fragments from those that contain concatamerized, and thus artifactual, inserts. This technique also offers a valuable tool to study consistent translocations in neoplastic diseases by identifying YACs that span a specific chromosomal breakpoint.     

A method for linking yeast artificial chromosomes.

A method for linking any standard yeast artificial chromosomes (YAC) is described. YACs are introduced into the same cell and joined by mitotic recombination between the vector arms and the homologous sequence in a linking vector; several YACs can be recombined sequentially. The linking vectors also contain the beta-galactosidase gene as an expression reporter in mammalian cells.     

DNase-hypersensitive sites in yeast artificial chromosomes containing human DNA

We have mapped the DNase I-hypersensitive sites (HSs) in Yeast Artificial Chromosomes (YACs) containing segments of human chromosomal DNA. One of the five HSs found in a YAC carrying the β-globin gene cluster has been localised in the region, termed HS2, that is DNase I hypersensitive in most human cells. We have also identified a class of HSs in YACs containing DNA from the q11.2 band of human chromosome 21, which are located close to, or within, segments of the chromosome that are sensitive to restriction enzymes recognizing CGCG tetranucleotides. Received: 18 June 1997 / Accepted: 10 August 1997     

Genetic selection of meiotic and mitotic recombinant yeast artificial chromosomes.

We have developed a genetic screen for the isolation of larger or smaller recombinant yeast artificial chromosomes derived from overlapping YACs. Integration plasmids were used to modify the TRP1 and URA3 auxotrophic markers present respectively on the left and right vector arms of one of the parental YACs. Diploids containing the two parental YACs were studied through meiosis and mitosis. Tetrad analysis revealed the presence of meiotic recombinant YACs at a frequency comparable with what is expected for yeast DNA (about 3 kb/cM). More direct genetic selection of diploids on -TRP-LYS synthetic media in the presence of 5-fluoro-orotic acid (5-FOA), led to the isolation of mitotic recombinant YACs at a high frequency. Analysis of these yeast cells by pulsed-field gel electrophoresis, confirmed the loss of both parental artificial chromosomes, and the specific retention of a larger or smaller recombinant YAC.     

Patterns of meiotic double-strand breakage on native and artificial yeast chromosomes

The preferred positions for meiotic double-strand breakage were mapped on Saccharomyces cerevisiae chromosomes I and VI, and on a number of yeast artificial chromosomes carrying human DNA inserts. Each chromosome had strong and weak double-strand break (DSB) sites. On average one DSB-prone region was detected by pulsed-field gel electrophoresis per 25 kb of DNA, but each chromosome had a unique distribution of DSB sites. There were no preferred meiotic DSB sites near the telomeres. DSB-prone regions were associated with all of the known ”hot spots” for meiotic recombination on chromosomes I, III and VI. Received: 19 March 1996; in revised form: 26 July 1996 / Accepted: 18 August 1996     

PCR amplification of chromosome-specific DNA isolated from flow cytometry-sorted chromosomes.

We have established a method for amplifying and obtaining large quantities of chromosome-specific DNA by linker/adaptor ligation and polymerase chain reaction (PCR). Small quantities of DNA isolated from flow cytometry-sorted chromosomes 17 and 21 were digested with MboI, ligated to a linker/adaptor, and then subjected to 35 cycles of PCR. Using this procedure, 20 micrograms of chromosome-specific DNA can be obtained. Southern blot analysis using several DNA probes previously localized to chromosomes 17 and 21 indicated that these gene sequences were present in the amplified chromosome-specific DNA. A small quantity of the chromosome-specific DNA obtained from the first round of PCR amplification was used to amplify DNA for a second, third, and fourth round of PCR (30 cycles), and specific DNA sequences were still detectable. Fluorescence in situ hybridization using these chromosome-specific DNA probes clearly indicated the hybridization signals to the designated chromosomes. We showed that PCR-amplified chromosome 17-specific DNA can be used to detect nonrandom chromosomal translocation of t(15;17) in acute promyelocytic leukemia by fluorescence in situ hybridization.     

Identification of region-specific yeast artificial chromosomes using pools of Alu element-mediated polymerase chain reaction probes labeled via linear amplification.

The ability to identify large numbers of yeast artificial chromosomes (YACs) specific to any given genomic region rapidly and efficiently enhances both the construction of clone maps and the isolation of region-specific landmarks (e.g., polymorphic markers). We describe a method of preparing region-specific single-stranded hybridization probes from Alu element-mediated polymerase chain reaction (Alu-PCR) products of somatic cell hybrids for YAC library screening. Pools of up to 50 cloned Alu-PCR products from an irradiation-reduced hybrid containing 22q11.2-q13.1 were labeled to high specific activity by linear amplification using a single vector primer. The resulting single-stranded probes were extensively competed to remove repetitive sequences, while retaining the full complexity of the probe. Extensive coverage of the region by YACs using multiple probe pools was demonstrated as many YACs were detected more than once. In situ analysis using chosen YACs confirmed that the clones were specific for the region. Thus, this pooled probe approach constitutes a rapid method to identify large numbers of YACs relevant to a large chromosomal region.     

Rescue of end fragments of yeast artificial chromosomes by homologous recombination in yeast.

Yeast artificial chromosomes (YACs) provide a powerful tool for the isolation and mapping of large regions of mammalian chromosomes. We developed a rapid and efficient method for the isolation of DNA fragments representing the extreme ends of YAC clones by the insertion of a rescue plasmid into the YAC vector by homologous recombination. Two rescue vectors were constructed containing a yeast LYS2 selectable gene, a bacterial origin of replication, an antibiotic resistance gene, a polylinker containing multiple restriction sites, and a fragment homologous to one arm of the pYAC4 vector. The 'end-cloning' procedure involves transformation of the rescue vector into yeast cells carrying a YAC clone, followed by preparation of yeast DNA and transformation into bacterial cells. The resulting plasmids carry end-specific DNA fragments up to 20 kb in length, which are suitable for use as hybridization probes, as templates for direct DNA sequencing, and as probes for mapping by fluorescence in situ hybridization. These vectors are suitable for the rescue of end-clones from any YAC constructed using a pYAC-derived vector. We demonstrate the utility of these plasmids by rescuing YAC-end fragments from a human YAC library.     

Drosophila genome project: One-hit coverage in yeast artificial chromosomes

We present a strategy for assembling a physical map of the genome of Drosophila melanogaster based on yeast artificial chromosomes (YACs). In this paper we report 500 YACs containing inserts of Drosophila DNA averaging 200 kb that have been assigned positions on the physical map by means of in situ hybridization with salivary gland chromosomes. The cloned DNA fragments have randomly sheared ends (DY clones) or ends generated by partial digestion with either NotI (N clones) or EcoRI (E clones). Relative to the euchromatic portion of the genome, the size distribution and genomic positions of the clones reveal no significant bias in the completeness or randomness of genome coverage. The 500 mapped euchromatic clones contain an aggregate of approximately 100 million base pairs of DNA, which is approximately one genome equivalent of Drosophila euchromatin.by W. Hennig     

Stable episomal maintenance of yeast artificial chromosomes in human cells.

Plasmids carrying the Epstein-Barr virus origin of plasmid replication (oriP) have been shown to replicate autonomously in latently infected human cells (J. Yates, N. Warren, D. Reisman, and B. Sugden, Proc. Natl. Acad. Sci. USA 81:3806-3810, 1984). We demonstrate that addition of this domain is sufficient for stable episomal maintenance of yeast artificial chromosomes (YACs), up to at least 660 kb, in human cells expressing the viral protein EBNA-1. To better approximate the latent viral genome, YACs were circularized before addition of the oriP domain by homologous recombination in yeast cells. The resulting OriPYACs were maintained as extrachromosomal molecules over long periods in selection; a 90-kb OriPYAC was unrearranged in all cell lines analyzed, whereas the intact form of a 660-kb molecule was present in two of three cell lines. The molecules were also relatively stable in the absence of selection. This finding indicates that the oriP-EBNA-1 interaction is sufficient to stabilize episomal molecules of at least 660 kb and that such elements do not undergo rearrangements over time. Fluorescence in situ hybridization analysis demonstrated a close association of OriPYACs, some of which were visible as pairs, with host cell chromosomes, suggesting that the episomes replicate once per cell cycle and that stability is achieved by attachment to host chromosomes, as suggested for the viral genome. The wide availability of YAC libraries, the ease of manipulation of cloned sequences in yeast cells, and the episomal stability make OriPYACs ideal for studying gene function and control of gene expression.     

Mapping the whole human genome by fingerprinting yeast artificial chromosomes.

Physical mapping of the human genome has until now been envisioned through single chromosome strategies. We demonstrate that by using large insert yeast artificial chromosomes (YACs) a whole genome approach becomes feasible. YACs (22,000) of 810 kb mean size (5 genome equivalents) have been fingerprinted to obtain individual patterns of restriction fragments detected by a LINE-1 (L1) probe. More than 1000 contigs were assembled. Ten randomly chosen contigs were validated by metaphase chromosome fluorescence in situ hybridization, as well as by analyzing the inter-Alu PCR patterns of their constituent YACs. We estimate that 15% to 20% of the human genome, mainly the L1-rich regions, is already covered with contigs larger than 3 Mb.     

Targeted alterations in yeast artificial chromosomes for inter-species gene transfer.

In order to facilitate alterations of large DNA molecules for their introduction into mammalian cells we have characterised the mechanism of site-specific modifications in yeast artificial chromosomes (YACs). Newly developed yeast integration vectors with dominant selectable marker genes allow targeted integration into left (centromeric) and right (non-centromeric) YAC arms as well as alterations to the human derived insert DNA. In transformation experiments, integration proceeds exclusively by homologous recombination although yeast prefers linear ends of homology for predefined insertions. Targeted regions can be rescued which expedite the cloning of internal human sequences and the identification of 5' and 3' YAC/insert borders. Integration of the neomycin resistance gene into various parts of the YAC allowed the transfer and stable integration of large DNA molecules into a variety of mammalian cells including embryonic stem cells.