Active Role of a Human Genomic Insert in Replication of a Yeast Artificial Chromosome

Yeast artificial chromosomes (YACs) are a common tool for cloning eukaryotic DNA. The manner by which large pieces of foreign DNA are assimilated by yeast cells into a functional chromosome is poorly understood, as is the reason why some of them are stably maintained and some are not. We examined the replication of a stable YAC containing a 240-kb insert of DNA from the human T-cell receptor beta locus. The human insert contains multiple sites that serve as origins of replication. The activity of these origins appears to require the yeast ARS consensus sequence and, as with yeast origins, additional flanking sequences. In addition, the origins in the human insert exhibit a spacing, a range of activation efficiencies, and a variation in times of activation during S phase similar to those found for normal yeast chromosomes. We propose that an appropriate combination of replication origin density, activation times, and initiation efficiencies is necessary for the successful maintenance of YAC inserts.     

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.     

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.     

Retrofitting YACs for direct DNA transfer into plant cells

The utility of plant YAC libraries prepared in conventional YAC vectors would be dramatically increased if these YACs could be used directly for plant transformation. A pair of vectors that allow clones from YAC libraries to be modified (retrofitted) for plant transformation by direct DNA transfer methods, such as particle bombardment or electroporation, has been developed. Modification of the YAC is achieved in two sequential yeast transformation steps by taking advantage of the homologous recombination system in yeast. Using this approach, two plant-selectable marker genes and DNA sequence elements required for copy number amplification in yeast can be introduced into YACs present in yeast strain AB1380. The utility of these vectors is demonstrated by retrofitting YACs that contain inserts ranging in size from 80 to 700 kb. The 6- to 12-fold increase in copy number of these modified YACs facilitates the isolation of YAC DNA for direct DNA transformation methods. Retrofitted YACs were used for particle bombardment to examine the efficiency with which their large DNA inserts are transferred into plant cells. The availability of these retrofitting vectors should facilitate the transfer of YAC DNA inserts into plant cells and thus help bridge the gap between existing mapping techniques and plant transformation procedures.     

The role of yeast artificial chromosome clones in generating genome maps.

The cloning of large DNAs as yeast artificial chromosomes (YACs) holds the promise of greatly expanding the scope of physical genomic mapping. Recent improvements in YAC clone libraries and their screening, as well as in the analysis of YAC-cloned DNA, are beginning to fulfill the potential of this system.     

Characterization of yeast artificial chromosomes from Plasmodium falciparum: construction of a stable, representative library and cloning of telomeric DNA fragments.

Molecular genetic studies of the human malaria parasite Plasmodium falciparum have been hampered in part due to difficulties in stably cloning and propagating parasite genomic DNA in bacteria. This is thought to be a result of the unusual A+T bias (>80%) in the parasite's DNA. Pulsed-field gel electrophoretic separation of P. falciparum chromosomes has shown that large chromosomal polymorphisms, resulting from the deletion of DNA from chromosome ends, frequently occur. Understanding the biological implications of this chromosomal polymorphism will require the analysis of large regions of genomic, and in particular telomeric, DNA. To overcome the limitations of cloning parasite DNA in bacteria, we have cloned genomic DNA from the P. falciparum strain FCR3 in yeast as artificial chromosomes. A pYAC4 library with an average insert size of approximately 100 kb was established and found to have a three to fourfold redundancy for single-copy genes. Unlike bacterial hosts, yeast stably maintain and propagate large tracts of parasite DNA. Long-range restriction enzyme mapping of YAC clones demonstrates that the cloned DNA is contiguous and identical to the native parasite genomic DNA. Since the telomeric ends of chromosomes are underrepresented in YAC libraries, we have enriched for these sequences by cloning P. falciparum telomeric DNA fragments (from 40 to 130 kb) as YACs by complementation in yeast.     

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.     

Microinjection of Intact 200- to 500-kb Fragments of YAC DNA into Mammalian Cells

DNA of yeast artificial chromosomes (YACs) was prepared for microinjection by separation from most of the natural yeast chromosomes on a pulsed-field gel, treatment with agarase, and centrifugation. A salt concentration of 100 mM NaCl was necessary to protect the DNA from shear during these procedures. Injection of a 590-kb YAC, yGART2, into Chinese hamster ovary cells gave rise to cells expressing the 40-kb human GART gene carried on the YAC. Nine of 12 cell lines analyzed contained an intact stretch of at least 110 kb of YAC DNA surrounding the GART gene, and one cell line contained at least 480 kb, but not the entire 590 kb, intact. Mouse L A-9 cells were similarly injected with DNA of a 230-kb YAC containing the human β-globin gene cluster and a mammalian selectable marker. Seven of 10 of the resulting cell lines contained both YAC vector arms plus the intact 140-kb SfiI fragment spanning the β-globin gene. Three cell lines were analyzed by Rec A-assisted restriction endonuclease (RARE) cleavage and found to contain the entire intact 210-kb YAC insert. Introduction of similarly prepared DNA into mammalian cells by lipofection gave rise to cell lines with multiple YAC fragments that were generally shorter than the YAC fragments found in microinjected cell lines. The results show that microinjection of gel-purified YAC DNA into mammalian cells is an efficient method of transferring DNA fragments several hundred kilobase pairs in size into mammalian cells.     

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.     

Introduction of YACs into intact yeast cells by a procedure which shows low levels of recombinagenicity and co-transformation.

Yeast artificial chromosomes (YACs) enable the cloning and analysis of large segments of genomic DNA and permit the isolation of sequences which are impossible to maintain in Escherichia coli. However, the construction of genome libraries in YAC vectors is beset by a number of technical problems, not least of which is the creation of cloned fragments which are not true representatives of the donor genome. These artefactual clones arise mainly due to intra-fragment rearrangements or inter-fragment chimaera formation, both phenomena resulting from the activity of the host yeast's mitotic recombination system. We demonstrate that this system is significantly stimulated by the spheroplasting step of the standard YAC transformation system. In contrast, the transformation of intact yeast cells by either the lithium method or a new lithium-free protocol is much less recombinagenic. It is not possible to introduce high molecular weight YACs into yeast using the lithium protocol, but we find that such molecules may be introduced into pde2-mutants using the lithium-free approach. Since intact cells are transformed by this method, automation of post-transformation steps in the construction of YAC libraries is facilitated. Moreover, the frequency of cotransformation (and, therefore, chimera formation) is significantly reduced. However, these advantages do incur a penalty. Yields of YAC transformants by this simplified intact cell approach are reduced some 25- to 30-fold compared to those obtained by the spheroplast transformation route. Nevertheless, the considerable advantages of the new system recommend it for a number of applications.     

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 constructted by size fractionating large DNA embedded in agarose and protecting DNA from degradation with polyamines.     

YAC cloning of DNA embedded in an agarose matrix

Yeast artificial chromosome (YAC) cloning of DNA in agarose is an alternative method to cloning from aqueous solutions. It minimizes any shearing that may result from handling of high molecular weight DNA and can be done with nanogram to microgram amounts of material, which facilitates construction of YACs from sources of DNA other than genomic DNA isolated from cells. The average size of the YACs recovered (200-1000 kb) and efficiency of transformation of ligation products (200-1000 cfu/micrograms) are similar to those reported using aqueous protocols. This method has been used to construct chromosome specific YACs, and it should be possible to apply the technique to the construction of chromosome specific libraries using flow sorted chromosomes as source material, and the cloning of restriction fragments isolated by preparative pulsed field gel electrophoresis.     

The construction and analysis of M13 libraries prepared from YAC DNA.

Yeast artificial chromosomes (YACs) provide a powerful way to isolate and map large regions of genomic DNA and their use in genome analysis is now extensive. We modified a series of procedures to produce high quality shotgun libraries from small amounts of YAC DNA. Clones from several different libraries have been sequenced and analyzed for distribution, sequence integrity and degree of contamination from yeast DNA. We describe these procedures and analyses and show that sequencing at about 1-fold coverage, followed by database comparison (survey sequencing) offers a relatively quick method to determine the nature of previously uncharacterized cosmid or YAC clones.     

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.     

Biolistic transfer of large DNA fragments to tobacco cells using YACs retrofitted for plant transformation

To determine whether large DNA molecules could be transferred and integrated intact into the genome of plant cells, we bombarded tobacco suspension cells with yeast DNA containing artificial chromosomes (YACs) having sizes of 80, 150, 210, or 550 kilobases (kb). Plant selectable markers were retrofitted on both YAC arms so that recovery of each arm in transgenic calli could be monitored. Stably transformed calli resistant to kanamycin (300 mg/L) were recovered for each size of YAC tested. Two of 12 kanamycin-resistant transformants for the 80 kb YAC and 8 of 29 kanamycin-resistant transformants for the 150 kb YAC also contained a functional hygromycin gene derived from the opposite YAC arm. Southern analyses using probes that spanned the entire 55 kb insert region of the 80 kb YAC confirmed that one of the two double-resistant lines had integrated a fully intact single copy of the YAC DNA while the other contained a major portion of the insert. Transgenic lines that contained only one selectable marker gene from the 80 kb YAC incorporated relatively small portions of the YAC insert DNA distal to the selectable marker. Our data suggest genomic DNA cloned in artificial chromosomes up to 150 kb in size have a reasonable likelihood of being transferred by biolistic methods and integrated intact into the genome of plant cells. Biolistic transfer of YAC DNA may accelerate the isolation of agronomically useful plant genes using map-based cloning strategies.     

Isolation of circular yeast artificial chromosomes for synthetic biology and functional genomics studies

Circular yeast artificial chromosomes (YACs) provide significant advantages for cloning and manipulating large segments of genomic DNA in Saccharomyces cerevisiae. However, it has been difficult to exploit these advantages, because circular YACs are difficult to isolate and purify. Here we describe a method for purification of large circular YACs that is more reliable compared with previously described protocols. This method has been used to purify YACs up to 600 kb in size. The purified YAC DNA is suitable for restriction enzyme digestion, DNA sequencing and functional studies. For example, YACs carrying full-size genes can be purified from yeast and used for transfection into mammalian cells or for the construction of a synthetic genome that can be used to produce a synthetic cell. This method for isolating high-quality YAC DNA in microgram quantities should be valuable for functional and synthetic genomic studies. The entire protocol takes ～3 d to complete.     

Human Xq24-Xq28: approaches to mapping with yeast artificial chromosomes.

One hundred twenty-seven yeast strains with artificial chromosomes containing Xq24-Xqter human DNA were obtained starting from a human/hamster somatic cell hybrid. The clones were characterized with respect to their insert size, stability, and representation of a set of Xq24-Xqter DNA probes. The inserts of the clones add up to 19.3 megabase (Mb) content, or about 0.4 genomic equivalents of that portion of the X chromosome, with a range of 40-650 kb in individual YACs. Eleven clones contained more than one YAC, the additional ones usually having hamster DNA inserts; the individual YACs could be separated by extracting the total DNA from such strains and using it to retransform yeast cells. One of the YACs, containing the probe for the DXS49 locus, was grossly unstable, throwing off smaller versions of an initial 300-kb YAC during subculture; the other YACs appeared to breed true on subculture. Of 52 probes tested, 12 found cognate YACs; the YACs included one with the glucose-6-phosphate dehydrogense gene and another containing four anonymous probe sequences (DX13, St14, cpx67, and cpx6). Xq location of YACs is being verified by in situ hybridization to metaphase chromosomes, and fingerprinting and hybridization methods are being used to detect YACs that overlap.     

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.     

Construction and characterization of a rice YAC library for physical mapping

Genomic libraries of rice,Oryza sativa L. cv. Nipponbare, in yeast artificial chromosomes were prepared for construction of a rice physical map. High-molecular-weight genomic DNA was extracted from cultured suspension cells embedded in agarose plugs. After size fractionation of theEco RI- andNot I-digested DNA fragments, they were ligated with pYAC4 and pYAC55, respectively, and used to transformSaccharomyces cerevisiae AB1380. A total of 6932 clones were obtained containing on average ca. 350 kb DNA. The YAC library was estimated to contain six haploid genome equivalents. The YACs were examined for their chimerism by mapping both ends on an RFLP linkage map. Most YACs withEco RI fragments below 400 kb were intact colinear clones. About 40% of clones were chimeric. Genetic mapping of end clones from large size YACs revealed that the physical distance corresponding to 1 cM genetic distance varies from 120 to 1000 kb, depending on the chromosome region. To select and order YAC clones for making contig maps, high-density colony hybridization using ECL was applied. With several probes, at least one and at most ten YAC clones could be selected in this library. The library size and clone insert size indicate that this YAC library is suitable for physical map construction and map-based cloning.     

Yeast artificial chromosomes containing human Xq24-Xq28 DNA: library construction and representation of probe sequences

A library of yeast artificial chromosomes (YACs) with human DNA inserts has been assembled from a human/hamster somatic cell hybrid containing Xq24-Xqter human DNA. Screening of the agar-embedded transformants for human DNA used a manifold of 3000 stainless-steel pins to transfer colonies onto the surface of media. This facilitated the recovery of the 1 in 300 clones that contained a human DNA insert (the remainder had hamster DNA and were discarded). The library described here consists of about two genomic equivalents (102 Mb) of human DNA in 467 clones: 167 were generated by EcoRI partial digestion and contain 25.5 Mb of human DNA; 252 used partial digestion with TaqI and cover 64.2 Mb; and 48 were from sheared DNA inserts and cover 11.7 Mb. Clones were screened by hybridization with 70 probes previously assigned to Xq24-Xq28. Eleven probes did not hybridize to any YACs in the library, and 16 probes hybridized to one YAC each, 23 to two, 13 to three, and 7 to four. Also, individual YACs large enough to detect features like the clustering of polymorphic sequences in subregions of Xq24-Xqter have been obtained. For example, XY58 contained five probe sequences previously independently isolated. The overall yield of YACs containing probe sequences was indistinguishable from Poisson statistical expectations for random cloning (P = 0.9). Thus, YAC libraries such as the one described here can include most, if not all, of the sequences in the source DNA from which the library is derived. These results support the possibility that YACs may provide a reliable bridge between linkage studies and conventional recombinant DNA analyses in mapping of the human genome.