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.     

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.     

Circular YAC vectors containing short mammalian origin sequences are maintained under selection as HeLa episomes

pYACneo, a 15.8-kb plasmid, contains a bacterial origin, G418-resistance gene, and yeast ARS, CEN, and TEL elements. Three mammalian origins have been cloned into this circular vector: 343, a 448-bp chromosomal origin from a transcribed region of human chromosome 6q; X24, a 4.3-kb element containing the hamster DHFR origin of bidirectional replication (oribeta), and S3, a 1.1-kb human anti-cruciform purified autonomously replicating sequence. The resulting constructs have been transfected into HeLa cells, and G418-resistant subcultures were isolated. The frequency of G418-resistant transformation was 1.7-8.7 times higher with origin-containing YACneo than with vector alone. After >45 generations under G418 selection, the presence of episomal versus integrated constructs was assessed by fluctuation assay and by PCR of supercoiled, circular, and linear genomic cellular DNAs separated on ethidium bromide-cesium chloride gradients. In stable G418-resistant subcultures transfected with vector alone or with linearized constructs, as well as in some subcultures transfected with circular origin-containing constructs, resistance was conferred by integration into the host genome. However, several examples were found of G418-resistant transfectants maintaining the Y.343 and the YAC.S3 circular constructs in a strictly episomal state after long-term culture in selective medium, with 80-90% stability per cell division. The episomes were found to replicate semiconservatively in a bromodeoxyuridine pulse-labeling assay for 相似文献   

The human HPRT gene on a yeast artificial chromosome is functional when transferred to mouse cells by cell fusion

A 680-kb yeast artificial chromosome (YAC) that contains a functional copy of the human hypoxanthine phosphoribosyltransferase (HPRT) gene has been isolated. This YAC, yHPRT, and another YAC, yXY837, which contains the 3' end of the HPRT gene, have been mapped with restriction enzymes that cleave human DNA infrequently. The HPRT gene lies near the center of yHPRT. Fusion of yHPRT-containing yeast spheroplasts with mouse L A-9 cells, which are HPRT-negative, gives rise to HPRT-positive colonies. These colonies contain the human HPRT gene and express human HPRT mRNA. Fusion of yeast with mammalian cells is an efficient way of testing the integrity and functionality of human DNA contained in YACs.     

Analysis of a YAC with human telomeres and oriP from epstein-barr virus in yeast and 293 cells.

One approach to the construction and propagation of a mammalian artificial chromosome is to build it up in Saccharomyces cerevisiae, using a yeast artificial chromosome (YAC) base. We have demonstrated that circular YACs carrying the Epstein-Barr virus origin of plasmid replication ( oriP ) are maintained as stable, episomal elements in human cells. We wished to determine whether this technology could be extended, to generate linear extrachromosomal elements. Here, we describe the generation of retrofitting constructs, which permit the addition of human telomeres and the oriP domain to YACs. The constructs contain 0.8 kb of human telomere sequence separated by a unique Not I site from 0.7 kb of Tetrahymena telomere sequence. These constructs seed telomere formation with approximately 40-60% efficiency in human 293-EBNA and HT1080 cells whether or not the Tetrahymena sequence is removed by Not I digestion. A detailed analysis demonstrates that YACs carrying the human telomere cassettes on both arms show instability of the telomere sequences in S.cerevisiae at a frequency of approximately 50%. Introduction of correctly retrofitted, linear oriP YACs into human 293-EBNA cells by lipofection resulted in the generation of circular extrachromosomal elements varying in size from 8 to 300 kb. However, no apparently linear YACs could be detected, suggesting that extrachromosomal maintenance of DNA with the oriP /EBNA-1 system is not compatible with linear molecules capped by telomeres.     

Targeted integration of neomycin into yeast artificial chromosomes (YACs) for transfection into mammalian cells.

Vectors have been constructed for the introduction of the neomycin resistance gene (neo) into the left arm, right arm or human insert DNA of yeast artificial chromosomes (YACs) by homologous recombination. These vectors contain a yeast selectable marker Lys-2, i.e. the alpha-aminoadipidate reductase gene, and a mammalian selection marker, neo, which confers G418 resistance. The vectors can be used to modify YACs in the most commonly used yeast strain for YAC library construction, AB1380. Specific targeting can be carried out by transfection of restriction endonuclease treated linear plasmids, with highly specific recombinogenic ends, into the YAC containing yeast cells. Analysis of targeted YACs confirmed that all three vectors can target correctly in yeast. Introduction of one of the targeted YACs into V79 (Chinese hamster fibroblast) cells showed complete and intact transfer of the YAC.     

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.     

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.     

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.     

Modification and transfer into an embryonal carcinoma cell line of a 360-kilobase human-derived yeast artificial chromosome.

A neomycin resistance cassette was integrated into the human-derived insert of a 360-kilobase yeast artificial chromosome (YAC) by targeting homologous recombination to Alu repeat sequences. The modified YAC was transferred into an embryonal carcinoma cell line by using polyethylene glycol-mediated spheroplast fusion. A single copy of the human sequence was introduced intact and stably maintained in the absence of selection for over 40 generations. A substantial portion of the yeast genome was retained in hybrids in addition to the YAC. Hybrid cells containing the YAC retained the ability to differentiate when treated with retinoic acid. This approach provides a powerful tool for in vitro analysis because it can be used to modify any human DNA cloned as a YAC and to transfer large fragments of DNA intact into cultured mammalian cells, thereby facilitating functional studies of genes in the context of extensive flanking DNA sequences.     

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.     

Cloning and in vivo expression of the human GART gene using yeast artificial chromosomes.

Two Yeast Artificial Chromosomes (YACs) were isolated each with a full-length copy of the human gene that encodes the trifunctional protein containing phosphoribosylglycinamide synthetase (GARS), phosphoribosylglycinamide formyltransferase (GART) and phosphoribosylaminoimidazole synthetase (AIRS). The YACs were characterized by restriction mapping and by in situ hybridization of cosmid subclones containing the YAC ends to human metaphase chromosomes. One of the YACs contains co-cloned non-contiguous DNA whereas the other appears to have a single 600 kbp insert from 21q22.1, the location of the GART gene. A restriction map of the gene was obtained from two cosmid subclones which together span the 40 kb gene. The gene is functional when YAC DNA is transferred into GARS- or GARS-and-AIRS-deficient Chinese Hamster Ovary cells. The gene transfer was carried out both by lipofection using purified yeast DNA and by fusion between yeast spheroplasts and the hamster cells. Restriction analysis of DNA from cell lines whose purine auxotrophy was complemented by the YAC showed that with either method a complete and unrearranged copy of the gene can be transferred. The majority of the fusion cell lines appear to contain at least 80% of the YAC.     

Preparation of intact yeast artificial chromosome DNA for transgenesis of mice

Transgenesis with large DNA molecules such as yeast artificial chromosomes (YACs) has an advantage over smaller constructs in that an entire locus and all its flanking cis-regulatory elements are included. The key to obtaining animals bearing full-length transgenes is to avoid physical shearing of the DNA during purification and microinjection. This protocol details how to prepare intact YAC DNA for transgenesis of mice and involves separation of YAC DNA from yeast chromosomal DNA by pulsed field gel electrophoresis, concentration to a range suitable for microinjection by second dimension electrophoresis and enzymatic digestion of matrix-embedded YAC DNA to produce a solution that can be injected. The YAC is maintained in an agarose gel matrix to avoid damage until the final steps before microinjection. Special precautions are also taken during the microinjection protocol. Transgenesis efficiency is approximately 15%; most animals carry 1-5 copies of the desired locus. This method takes 6 d for completion.     

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.     

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.     

PCR amplification and analysis of yeast artificial chromosomes

A strategy for the analysis of yeast artificial chromosome (YAC) clones that relies on polymerase chain reaction (PCR) amplification of small restriction fragments from isolated YACs following adapter ligation was developed. Using this method, termed YACadapt, we have amplified several YACs from a human Xq24-qter library and have used the PCR products for physical mapping by somatic cell hybrid deletion analysis and fluorescent in situ hybridization. One YAC, RS46, was mapped to band Xq27.3, near the fragile X mutation. The PCR product is an excellent renewable source of YAC DNA for analyses involving hybridization of YAC inserts to a variety of DNA/RNA sources.     

Polyamines eliminate an extreme size bias against transformation of large yeast artificial chromosome DNA

The recent development of vectors and methods for cloning large linear DNA as yeast artificial chromosomes (YACs) has enormous potential in facilitating genome analysis, particularly because of the large cloning capacity of the YAC cloning system. However, the construction of comprehensive libraries with very large DNA segments (400-500 kb average insert size) has been technically very difficult to achieve. We have examined the possibility that this difficulty is due, at least in part, to preferential transformation of the smaller DNA molecules in the yeast transformation mixture. Our data indicate that the transformation efficiency of a 330-kb linear YAC DNA molecule is 40-fold lower, on a molar basis, than that of a 110-kb molecule. This extreme size bias in transformation efficiency is dramatically reduced (to less than 3-fold) by treating the DNA with millimolar concentrations of polyamines prior to and during transformation into yeast spheroplasts. This effect is accounted for by a stimulation in transformation efficiency of the 330-kb YAC molecule; the transformation efficiency of the 110-kb YAC molecule is not affected by the inclusion of polyamines. Application of this finding to the cloning of large exogenous DNA as artificial chromosomes in yeast will facilitate the construction of genomic libraries with significantly increased average insert sizes. In addition, the methods described allow efficient transfer of YACs to yeast strain backgrounds suitable for subsequent manipulations of the large insert DNA.     

Detection and characterization of chimeric yeast artificial-chromosome clones.

Methods for the construction of yeast artificial-chromosome (YAC) clones have been designed to isolate single, large (100-1000 kb) segments of chromosomal DNA. It is apparent from early experience with this cloning system that the major artifact in YAC clones involves the formation of YACs that contain two or more unrelated pieces of DNA. Such "chimeric" YACs are not easily recognized, particularly in libraries constructed from the total DNA of an organism. In some libraries, they have been found to constitute a major fraction of the clones. Here we discuss some of our experiences with chimeric YACs, with particular emphasis on the approaches that we have employed to detect such aberrant clones. In addition, we describe the detailed characterization of one chimeric YAC isolated from a library prepared from total human DNA. The organization of this clone indicates that it formed by in vivo recombination, presumably in yeast, between two Alu sequences located on unrelated segments of human DNA.     

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.