Incorporation of copy-number control elements into yeast artificial chromosomes by targeted homologous recombination

We have developed a pair of vectors for exchanging yeast artificial chromosome (YAC) arms by targeted homologous recombination. These conversion vectors allow the introduction of copy-number control elements into YACs constructed with pYAC4 or related vectors. YACs modified in this way provide an enriched source of DNA for genetic or biochemical studies. A LYS2 gene on the conversion vector provides a genetic selection for the modified YACs after transformation with appropriately prepared vector. A background of Lys⁺ clones that do not contain modified YACs is also present. However, clones with converted YACs can be distinguished from this background by counter-screening for loss of the original p YAC4 TRP1 arm (Trp^- phenotype). The elimination of yeast replication origins (ARS elements) from the conversion vectors increased the frequency of Lys⁺ Trp^- clones, but resulted in weaker amplification. Several YACs have been converted with these vectors, and the fate of the transformed DNA and of the resident YAC DNA has been systematically investigated.     

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.     

Use of repetitive DNA probes as physical mapping strategy in Caenorhabditis elegans.

A method for linking genomic sequences cloned in yeast artificial chromosomes (YACs) has been tested using Caenorhabditis elegans as a model system. Yeast clones carrying YACs with repeated sequences were selected from a C. elegans genomic library, total DNA was digested with restriction enzymes, transferred to nylon membranes and probed with a variety of repetitive DNA probes. YAC clones that overlap share common bands with one or more repetitive DNA probes. In 159 YAC clones tested with one restriction enzyme and six probes 28 overlapping clones were detected. The advantages and limitations of this method for construction of YAC physical maps is discussed.     

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.     

Transfer of small YACs to E. coli as large circular plasmids

We have designed a YAC circularization vector, pCIRC3, allowing enrichment of the YAC DNA by exonuclease digestion of the linear yeast chromosomes. Due to the presence of P1 replicon sequences in this vector, the circular YACs would replicate as PACs in Escherischia coli.     

Transgenic mice generated by pronuclear injection of a yeast artificial chromosome.

Transgenic mice have become invaluable for analysing gene function and regulation in vivo. However, the size of constructs injected has been limited by the cloning capacity of conventional vectors, a constraint that could be overcome with yeast artificial chromosomes (YACs). We investigated the feasibility of making transgenic mice with YACs by pronuclear injection of a small YAC carrying a gene encoding tyrosinase. Use of a vector with a conditional centromere allowed fifteenfold amplification of the YAC in yeast and its recovery in high yield. The albino phenotype of the recipient mice was rescued demonstrating the correct expression of the tyrosine gene from the construct. Furthermore, the telomeric sequences added by the yeast integrated into the mouse genome and did not reduce efficiency of integration. Using this technique future experiments with longer YACs will allow the expression of gene complexes such as Hox and the globin gene clusters to be analysed in transgenic animals.     

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.     

A new vector for recombination-based cloning of large DNA fragments from yeast artificial chromosomes.

The functional analysis of genes frequently requires manipulation of large genomic regions embedded in yeast artificial chromosomes (YACs). We have designed a yeast-bacteria shuttle vector, pClasper, that can be used to clone specific regions of interest from YACs by homologous recombination. The important feature of pClasper is the presence of the mini-F factor replicon. This leads to a significant increase in the size of the plasmid inserts that can be maintained in bacteria after cloning by homologous recombination in yeast. The utility of this vector lies in its ability to maintain large fragments in bacteria and yeast, allowing for mutagenesis in yeast and simplified preparation of plasmid DNA in bacteria. Using PCR-generated recombinogenic fragments in pClasper we cloned a 27 kb region from a YAC containing the Hoxc cluster and a 130 kb region containing the entire Hoxb cluster. No rearrangements were seen when the recombinants in the shuttle vector were transferred to bacteria. We outline the potential uses of pClasper for functional studies of large genomic regions by transgenic and other analyses.     

Recovery and potential utility of YACs as circular YACs/BACs

A method has been established to convert pYAC4-based linear yeast artificial chromosomes (YACs) into circular chromosomes that can also be propagated in Escherichia coli cells as bacterial artificial chromosomes (BACs). The circularization is based on use of a vector that contains a yeast dominant selectable marker (G418R), a BAC cassette and short targeting sequences adjacent to the edges of the insert in the pYAC4 vector. When it is introduced into yeast, the vector recombines with the YAC target sequences to form a circular molecule, retaining the insert but discarding most of the sequences of the YAC telomeric arms. YACs up to 670 kb can be efficiently circularized using this vector. Re-isolation of megabase-size YAC inserts as a set of overlapping circular YAC/BACs, based on the use of an Alu-containing targeting vector, is also described. We have shown that circular DNA molecules up to 250 kb can be efficiently and accurately transferred into E.coli cells by electroporation. Larger circular DNAs cannot be moved into bacterial cells, but can be purified away from linear yeast chromosomes. We propose that the described system for generation of circular YAC derivatives can facilitate sequencing as well as functional analysis of genomic regions.     

Direct Cloning of Human 10q25 Neocentromere DNA Using Transformation-Associated Recombination (TAR) in Yeast

The transformation-associated recombination (TAR) procedure allows rapid, site-directed cloning of specific human chromosomal regions as yeast artificial chromosomes (YACs). The procedure requires knowledge of only a single, relatively small genomic sequence that resides adjacent to the chromosomal region of interest. We applied this approach to the cloning of the neocentromere DNA of a marker chromosome that we have previously shown to have originated through the activation of a latent centromere at human chromosome 10q25. Using a unique 1.4-kb DNA fragment as a “hook” in TAR experiments, we achieved single-step isolation of the critical neocentromere DNA region as two stable, 110- and 80-kb circular YACs. For obtaining large quantities of highly purified DNA, these YACs were retrofitted with the yeast–bacteria–mammalian-cells shuttle vector BRV1, electroporated intoEscherichia coliDH10B, and isolated as bacterial artificial chromosomes (BACs). Extensive characterization of these YACs and BACs by PCR and restriction analyses revealed that they are identical to the corresponding regions of the normal chromosome 10 and provided further support for the formation of the neocentromere within the marker chromosome through epigenetic activation.     

Recovery and potential utility of YACs as circular YACs/BACs

A method has been established to convert pYAC4-based linear yeast artificial chromosomes (YACs) into circular chromosomes that can also be propagated in Escherichia coli cells as bacterial artificial chromosomes (BACs). The circularization is based on use of a vector that contains a yeast dominant selectable marker (G418R), a BAC cassette and short targeting sequences adjacent to the edges of the insert in the pYAC4 vector. When it is introduced into yeast, the vector recombines with the YAC target sequences to form a circular molecule, retaining the insert but discarding most of the sequences of the YAC telomeric arms. YACs up to 670 kb can be efficiently circularized using this vector. Re-isolation of megabase-size YAC inserts as a set of overlapping circular YAC/BACs, based on the use of an Alu-containing targeting vector, is also described. We have shown that circular DNA molecules up to 250 kb can be efficiently and accurately transferred into E.coli cells by electroporation. Larger circular DNAs cannot be moved into bacterial cells, but can be purified away from linear yeast chromosomes. We propose that the described system for generation of circular YAC derivatives can facilitate sequencing as well as functional analysis of genomic regions.     

A physical map of the human APP gene in YACs

Several point mutations within exons 16 and 17 of the amyloid precursor protein (APP) gene have been reported that are associated with Alzheimer's disease in a small number of familial cases. To determine the size of the APP gene and the organization of the exons within human genomic DNA, we have characterized 11 Yeast Artificial Chromosome (YAC), recombinants containing human APP gene sequences. The smallest YAC insert was 125 kb, and the largest was 1.4 Mb. The YACs were screened by polymerase chain reaction amplification of APP exons to determine which of the 18 exons coding for APP770 were present. Four of the YACs (D110G1, D110G6, D110E9, and B142F9) contain all 18 exons and at least part of the promoter. Construction of an overlapping map of the gene with all of the YACs demonstrated that 3 of the 11 YACs were chimeric. The orientation and position of the coding sequence on the map was determined by probing digests of the YAC DNA with exon PCR products and the vector arms. The coding region of the APP gene spans approximately 400 kb of genomic DNA.     

Isolation of a functional copy of the human BRCA1 gene by transformation-associated recombination in yeast

The BRCA1 gene, mutations of which contribute significantly to hereditary breast cancer, was not identified in the existing YAC and BAC libraries. The gene is now available only as a set of overlapping fragments that form a contig. In this work we describe direct isolation of a genomic copy of BRCA1 from human DNA by transformation-associated recombination (TAR) cloning. Despite the presence of multiple repeats, most of the primary BRCA1 YAC isolates did not contain detectable deletions and could be stably propagated in a host strain with conditional RAD52. Similar to other circular YACs, 90 kb BRCA1 YACs were efficiently and accurately retrofitted into bacterial artificial chromosomes (BACs) with the Neo^R mammalian selectable marker and transferred as circular BAC/YACs in E. coli cells. The BRCA1 BAC/YAC DNAs were isolated from bacterial cells and were used to transfect mouse cells using the Neo^R gene as selectable marker. Western blot analysis of transfectants showed that BRCA1 YACs isolated by a TAR cloning contained a functional gene. The advantage of this expression vector is that the expression of BRCA1 is generated from its own regulatory elements and does not require additional promoter elements that may result in overexpression of the protein. In contrast to the results with cDNA expression vectors, the level of BRCA1 expression from this TAR vector is stable, does not induce cell death, maintains serum regulation, and approximates the level of endogenously expressed BRCA1 in human cells. The entire isolation procedure of BRCA1 described in this paper can be accomplished in approximately 10 days and can be applied to isolation of gene from clinical material. We propose that the opportunity to directly isolate normal and mutant forms of BRCA1 will greatly facilitate analysis of the gene and its contribution to breast cancer.     

人基因组YAC分子克隆库的构建及DMD基因YAC克隆的筛选

以pYAC4为载体,以正常人白细胞和含4条X染色体的细胞株GM1414为DNA源构建成人基因组YAC(Yeast Artificial Chromosome,酵母人工染色体)分子克隆库,已得到原始克隆近2万个,插入DNA片段长度在400—1000kb,从其中选出一组YAC克隆,它们含有DMD基因全部DNA顺序。     

Isolation of single-copy-sequence clones from a yeast artificial chromosome library of randomly-sheared Arabidopsis thaliana DNA

We describe the construction of a yeast artificial chromosome (YAC) library from the Arabidopsis thaliana genome. Randomly sheared high molecular weight source DNA was extracted from frozen, ground leaf tissue and blunt-end-ligated to the vector pYAC3. By size-fractionating the ligation products, we achieved an average clone size of 150 kb. Approximately 6% of the YACs contained inserts from the chloroplast genome. We screened clones equivalent to greater than four A. thaliana haploid nuclear genomes and isolated YACs homologous to five single-copy-sequence probes. The library should be useful chromosome walking and genome mapping experiments. In addition, the approach used for its construction should be applicable to other higher plant species.     

Recombination during transformation as a source of chimeric mammalian artificial chromosomes in yeast (YACs).

Mammalian DNAs cloned as artificial chromosomes in yeast (YACs) frequently are chimeras formed between noncontiguous DNAs. Using pairs of human and mouse YACs we examined the contribution of recombination during transformation or subsequent mitotic growth to chimeric YAC formation. The DNA from pairs of yeast strains containing homologous or heterologous YACs was transformed into a third strain under conditions typical for the development of YAC libraries. One YAC was selected and the presence of the second was then determined. Co-penetration of large molecules, as deduced from co-transformation of markers identifying the different YACs, was > 50%. In approximately half the cells receiving two homologous YACs, the YACs had undergone recombination. Co-transformation depends on recombination since it was reduced nearly 10-fold when the YACs were heterologous. While mitotic recombination between homologous YACs is nearly 100-fold higher than for yeast chromosomes, the level is still much lower than observed during transformation. To investigate the role of commonly occurring Alu repeats in chimera formation, spheroplasts were transformed with various human YACs and an unselected DNA fragment containing an Alu at one end and a telomere at the other. When unbroken YACs were used, between 1 and 6% of the selected YACs could incorporate the fragment as compared to 49% when the YACs were broken. We propose that Alu's or other commonly occurring repeats could be an important source of chimeric YACs. Since the frequency of chimeras formed between YACs or a YAC and an Alu-containing fragment was reduced when a rad52 mutant was the recipient and since intra-YAC deletions are reduced, rad52 and possibly other recombination-deficient mutants are expected to be useful for YAC library development.     

Construction of a swine YAC library allowing an efficient recovery of unique and centromeric repeated sequences

A swine DNA genomic library was constructed in yeast artificial chromosome (YAC) using the pYAC4 vector and the AB1380 strain. The DNA prepared from two Large White males was partially digested with EcoRI and size selected after both digestion and ligation. The YAC library contained 33792 arrayed clones with an average size of 280 kb as estimated by analysis of 2% of the clones, thus representing a threefold coverage of the swine haploid genome. The library was organized in pools to facilitate the PCR screening. The complexity of the library was tested both for unique and centromeric repeated sequences. In all, 20 out of 22 primer sets allowed the characterization of one to six clones containing specific unique sequences. These sequences are known to be on Chromosomes (Chrs) 1, 2, 5, 6, 7, 8, 13, 14, 15, 17, and X. Eight additional clones carrying centromeric repeat units were also isolated with a single primer set. The sequencing of 37 distinct repeat units of about 340 bp subcloned from these eight YACs revealed high sequence diversity indicating the existence of numerous centromeric repeat unit subfamilies in swine. Furthermore, the analysis of the restriction patterns with selected enzymes suggested a higher order organization of the repeat units. According to preliminary FISH experiments on a small number of randomly chosen YACs and YACs carrying specific sequences, the chimerism appeared to be low. In addition, primed in situ labeling experiments favored the idea that the YACs with centromeric repeat sequences were derived from a subset of metacentric and submetacentric chromosomes. Received: 14 July 1996 / Accepted: 24 October 1996     

A procedure for cloning restriction fragments of DNA as single inserts in yeast artificial chromosomes

A novel procedure is described for the cloning of partial EcoRI fragments of bovine DNA: it reduces the chance of sequence rearrangements due to multiple insertions (co-cloning) of restriction fragments in the resulting YAC. The DNA to be inserted has been dephosphorylated, whereas the matching ends of the vector, pYAC4, have not. The ligation was essentially complete, the transformation efficiency was close to 19 transformants per ng of vector and the frequency of clones carrying YAC, 60-100 kb in size, was close to 70%. The YACs show segregative and replicative stability.