Refined human artificial chromosome vectors for gene therapy and animal transgenesis

Human artificial chromosomes (HACs) have several advantages as gene therapy vectors, including stable episomal maintenance, and the ability to carry large gene inserts. We previously developed HAC vectors from the normal human chromosomes using a chromosome engineering technique. However, endogenous genes were remained in these HACs, limiting their therapeutic applications. In this study, we refined a HAC vector without endogenous genes from human chromosome 21 in homologous recombination-proficient chicken DT40 cells. The HAC was physically characterized using a transformation-associated recombination (TAR) cloning strategy followed by sequencing of TAR-bacterial artificial chromosome clones. No endogenous genes were remained in the HAC. We demonstrated that any desired gene can be cloned into the HAC using the Cre-loxP system in Chinese hamster ovary cells, or a homologous recombination system in DT40 cells. The HAC can be efficiently transferred to other type of cells including mouse ES cells via microcell-mediated chromosome transfer. The transferred HAC was stably maintained in vitro and in vivo. Furthermore, tumor cells containing a HAC carrying the suicide gene, herpes simplex virus thymidine kinase (HSV-TK), were selectively killed by ganciclovir in vitro and in vivo. Thus, this novel HAC vector may be useful not only for gene and cell therapy, but also for animal transgenesis.

Cloning of human centromeres by transformation-associated recombination in yeast and generation of functional human artificial chromosomes

Human centromeres remain poorly characterized regions of the human genome despite their importance for the maintenance of chromosomes. In part this is due to the difficulty of cloning of highly repetitive DNA fragments and distinguishing chromosome-specific clones in a genomic library. In this work we report the highly selective isolation of human centromeric DNA using transformation-associated recombination (TAR) cloning. A TAR vector with alphoid DNA monomers as targeting sequences was used to isolate large centromeric regions of human chromosomes 2, 5, 8, 11, 15, 19, 21 and 22 from human cells as well as monochromosomal hybrid cells. The alphoid DNA array was also isolated from the 12 Mb human mini-chromosome DeltaYq74 that contained the minimum amount of alphoid DNA required for proper chromosome segregation. Preliminary results of the structural analyses of different centromeres are reported in this paper. The ability of the cloned human centromeric regions to support human artificial chromosome (HAC) formation was assessed by transfection into human HT1080 cells. Centromeric clones from DeltaYq74 did not support the formation of HACs, indicating that the requirements for the existence of a functional centromere on an endogenous chromosome and those for forming a de novo centromere may be distinct. A construct with an alphoid DNA array from chromosome 22 with no detectable CENP-B motifs formed mitotically stable HACs in the absence of drug selection without detectable acquisition of host DNAs. In summary, our results demonstrated that TAR cloning is a useful tool for investigating human centromere organization and the structural requirements for formation of HAC vectors that might have a potential for therapeutic applications.

Large-insert BAC/YAC libraries for selective re-isolation of genomic regions by homologous recombination in yeast

We constructed representative large-insert bacterial artificial chromosome (BAC) libraries of two human pathogens (Trypanosoma brucei and Giardia lamblia) using a new hybrid vector, pTARBAC1, containing a yeast artificial chromosome (YAC) cassette (a yeast selectable marker and a centromere). The cassette allows transferring of BACs into yeast for their further modification. Furthermore, the new hybrid vector provides the opportunity to re-isolate each DNA insert without construction of a new library of random clones. Digestion of a BAC DNA by an endonuclease that has no recognition site in the vector, but which deletes most of the internal insert sequence and leaves the unique flanking sequences, converts a BAC into a TAR vector, thus allowing direct gene isolation. Cotransformation of a TAR vector and genomic DNA into yeast spheroplasts, and subsequent recombination between the TAR vector's flanking ends and a specific genomic fragment, allows rescue of the fragment as a circular YAC/BAC molecule. Here we prove a new cloning strategy by re-isolation of randomly chosen genomic fragments of different size from T. brucei cloned in BACs. We conclude that genomic regions of unicellular eukaryotes can be easily re-isolated using this technique, which provides an opportunity to study evolution of these genomes and the role of genome instability in pathogenicity.

Defining the minimal length of sequence homology required for selective gene isolation by TAR cloning

The transformation-associated recombination (TAR) cloning technique allows selective and accurate isolation of chromosomal regions and genes from complex genomes. The technique is based on in vivo recombination between genomic DNA and a linearized vector containing homologous sequences, or hooks, to the gene of interest. The recombination occurs during transformation of yeast spheroplasts that results in the generation of a yeast artificial chromosome (YAC) containing the gene of interest. To further enhance and refine the TAR cloning technology, we determined the minimal size of a specific hook required for gene isolation utilizing the Tg.AC mouse transgene as a targeted region. For this purpose a set of vectors containing a B1 repeat hook and a Tg.AC-specific hook of variable sizes (from 20 to 800 bp) was constructed and checked for efficiency of transgene isolation by a radial TAR cloning. When vectors with a specific hook that was >/=60 bp were utilized, approximately 2% of transformants contained circular YACs with the Tg.AC transgene sequences. Efficiency of cloning dramatically decreased when the TAR vector contained a hook of 40 bp or less. Thus, the minimal length of a unique sequence required for gene isolation by TAR is approximately 60 bp. No transgene-positive YAC clones were detected when an ARS element was incorporated into a vector, demonstrating that the absence of a yeast origin of replication in a vector is a prerequisite for efficient gene isolation by TAR cloning.

Radial transformation-associated recombination cloning from the mouse genome: isolation of Tg.AC transgene with flanking DNAs

Transformation-associated recombination (TAR) cloning allows entire genes and large chromosomal regions to be specifically, accurately, and quickly isolated from total genomic DNA. We report the first example of radial TAR cloning from the mouse genome. Tg.AC mice carry a zeta-globin promoter/v-Ha-ras transgene. Fluorescence in situ hybridization localized the transgene integrant as a single site proximal to the centromere of chromosome 11. Radial TAR cloning in yeast was utilized to create orientation-specific yeast artificial chromosomes (YACs) to explore the possibility that cis-flanking regions were involved in transgene expression. YACs containing variable lengths of 5' or 3' flanking chromosome 11 DNA and the Tg.AC transgene were specifically chosen, converted to bacterial artificial chromosomes (BACs), and assayed for their ability to promote transcription of the transgene following transfection into an FVB/N carcinoma cell line. A transgene-specific reverse transcription-polymerase chain reaction assay was utilized to examine RNA transcripts from stably transfected clones. All Tg.AC BACs expressed the transgene in this in vitro system. This report describes the cloning of the v-Ha-ras transgene and suggests that transcriptional activity may not require cis elements flanking the transgene's integration site.

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.

Discovery of a novel, paternally expressed ubiquitin-specific processing protease gene through comparative analysis of an imprinted region of mouse chromosome 7 and human chromosome 19q13.4

Using mouse BAC clones spanning an imprinted interval of proximal mouse chromosome 7 and the genomic sequence of the related interval of human chromosome 19q13.4, we have identified a novel mouse gene, Usp29 (ubiquitin-specific processing protease 29), near two known imprinted genes, Peg3 and Zim1. Gene Usp29 is located directly adjacent to Peg3 in a "head-to-head" orientation, and comprises exons distributed over a genomic distance of at least 400 kb. A similar human gene is also found in the homologous location in human chromosome 19q13.4. The mouse Usp29 gene is also imprinted and is transcribed mainly from the paternal allele with highest expression levels in adult brain, especially in the cerebral cortex and hippocampus, and in the forebrain, face, and limb buds of midgestation mouse embryos. Analysis of a full-length 7.6-kb cDNA clone revealed that Usp29 encodes an 869-amino-acid protein that displays significant homology with yeast and nematode ubiquitin carboxyl-terminal hydrolases. These data suggest that, like the candidate Angelman syndrome gene Ube3a (ubiquitin ligase), Usp29 may represent another imprinted gene involved in the ubiquitination pathway. This identification of a third imprinted gene, Usp29, from the Peg3/Zim1-region confirms the presence of a conserved imprinted domain spanning at least 500 kb in the proximal portion of mouse chromosome 7 (Mmu7).

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, approximately 90kb 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.

Integrity of human YACs during propagation in recombination-deficient yeast strains

Several isogenic strains with defects in recombination/repair genes (RAD1, RAD50, RAD51, RAD52, RAD54, and RAD55) were examined for their ability to propagate accurately a variety of linear and circular yeast artificial chromosomes (YACs) containing human DNA inserts. To assess YAC stability, the human DNA inserts were internally marked by an ADE2-pBR-URA3 cassette. Following selection for Ura- clones on 5-fluoroorotic acid containing medium, the following types of YAC deletions were identified: (i) those caused by homologous recombination with a telomeric pBR sequence; (ii) internal deletions, presumed to occur by recombination between commonly occurring DNA repeats such as Alu and LINE sequences; and (iii) deletions leading to loss of part of a YAC arm. rad52 host strains, but not other recombination-deficient strains, decreased the rate of all types of YAC deletions 25- to 400-fold. We have also developed and tested kar1 strains with a conditional RAD52 gene that allow transfer of a YAC from any host into a recombination-deficient background. These strains provide an efficient tool for stabilization of YACs and are useful for allowing additional recombinational modification of YACs.

Construction of human chromosome 16- and 5-specific circular YAC/BAC libraries by in vivo recombination in yeast (TAR cloning)

Transformation-associated recombination (TAR) in yeast was exploited for the selective isolation of human DNAs as large circular yeast artificial chromosomes (YACs) from two rodent/human hybrid cell lines containing human chromosomes 5 and 16. TAR cloning vectors containing the F-factor origin of replication were constructed for use in these experiments. Presence of the F-factor origin in TAR vectors provides the capability of transferring the YACs generated by in vivo recombination in yeast into Escherichia coli cells and propagating them as bacterial artificial chromosomes (BACs). A high enrichment of human versus rodent YACs was observed during isolation of human DNA from the rodent/human hybrid cell lines. Although <3% of the DNA content in the hybrid cells was human, as many as 75% of the transformants contained human YACs. In contrast to the standard YAC cloning method based on in vitro ligation, no human/mouse chimeras were observed during TAR cloning. The constructed human chromosome 16 YAC library had approximately 2.6x coverage, represented by 4320 YAC clones with an average insert size of 80 kb. YAC clones generated from chromosome 16 were successfully converted into BACs by electroporation of DNA isolated from yeast transformants into E. coli. The BAC clones represent approximately 0.6x chromosomal coverage. Pilot YAC and BAC libraries of chromosome 5 have been also constructed. The chromosomal distribution of YAC/BACs from chromosome 5 and chromosome 16 was evaluated by fluorescence in situ hybridization (FISH). The distribution of FISH signals appeared random along the length of each chromosome. We conclude that TAR cloning provides an efficient means for generating representative chromosome-specific YAC/BAC libraries.

Rescue of targeted regions of mammalian chromosomes by in vivo recombination in yeast

In contrast to other animal cell lines, the chicken pre-B cell lymphoma line, DT40, exhibits a high level of homologous recombination, which can be exploited to generate site-specific alterations in defined target genes or regions. In addition, the ability to generate human/chicken monochromosomal hybrids in the DT40 cell line opens a way for specific targeting of human genes. Here we describe a new strategy for direct isolation of a human chromosomal region that is based on targeting of the chromosome with a vector containing a yeast selectable marker, centromere, and an ARS element. This procedure allows rescue of the targeted region by transfection of total genomic DNA into yeast spheroplasts. Selection for the yeast marker results in isolation of chromosome sequences in the form of large circular yeast artificial chromosomes (YACs) up to 170 kb in size containing the targeted region. These YACs are generated by homologous recombination in yeast between common repeated sequences in the targeted chromosomal fragment. Alternatively, the targeted region can be rescued as a linear YACs when a YAC fragmentation vector is included in the yeast transformation mixture. Because the entire isolation procedure of the chromosomal region, once a target insertion is obtained, can be accomplished in approximately 1 week, the new method greatly expands the utility of the homologous recombinationproficient DT40 chicken cell system.

Functional copies of a human gene can be directly isolated by transformation-associated recombination cloning with a small 3' end target sequence

Unique, small sequences (sequence tag sites) have been identified at the 3' ends of most human genes that serve as landmarks in genome mapping. We investigated whether a single copy gene could be isolated directly from total human DNA by transformation-associated recombination (TAR) cloning in yeast using a short, 3' unique target. A TAR cloning vector was constructed that, when linearized, contained a small amount (381 bp) of 3' hypoxanthine phosphoribosyltransferase (HPRT) sequence at one end and an 189-bp Alu repeat at the other end. Transformation with this vector along with human DNA led to selective isolations of the entire HPRT gene as yeast artificial chromosomes (YACs) that extended from the 3' end sequence to various Alu positions as much as 600 kb upstream. These YACs were retrofitted with a NeoR and a bacterial artificial chromosome (BAC) sequence to transfer the YACs to bacteria and subsequently the BACs to mouse cells by using a Neo selection. Most of the HPRT isolates were functional, demonstrating that TAR cloning retains the functional integrity of the isolated material. Thus, this modified version of TAR cloning, which we refer to as radial TAR cloning, can be used to isolate large segments of the human genome accurately and directly with only a small amount of sequence information.

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 into Escherichia coli DH10B, 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.

Specific isolation of human rDNA genes by TAR cloning

Selective cloning of human DNA in YACs from monochromosomal human/rodent hybrid cells lines and radiation hybrids can be accomplished by transformation-associated recombination (TAR) between Alu-containing vector(s) and human DNA in yeast. We have expanded this approach to the specific isolation of repetitive genes from the human genome. Highly selective isolation of human rDNA was accomplished using total human DNA and a pair of differentially marked linear TAR cloning vectors where one contained a small fragment of a human rDNA repeat and the other had an Alu repeat as targeting sequences. About half the transformants that acquired both vectors markers had YACs with human rDNA inserts. These results suggest that TAR can be applied to the general isolation of gene families and amplified region from genomic DNAs.

Direct isolation of human BRCA2 gene by transformation-associated recombination in yeast

Mutant forms of the BRCA2 gene contribute significantly to hereditary breast cancer. Isolation of the normal and mutant forms of the BRCA2 gene with its natural promoter would greatly facilitate analysis of the gene and its contribution to breast cancer. We have accomplished the direct isolation of the 90-kb gene from total human DNA by transformation-associated recombination in yeast using a small amount of 5' and 3' BRCA2 sequence information. Because the entire isolation procedure of a single chromosomal gene could be accomplished in approximately 2 weeks, the transformation-associated recombination cloning approach is readily applicable to studies of chromosome alterations and human genetic diseases.

Highly selective isolation of human DNAs from rodent-human hybrid cells as circular yeast artificial chromosomes by transformation-associated recombination cloning

Transformation-associated recombination (TAR) can be exploited in yeast to clone human DNAs. TAR cloning was previously accomplished using one or two telomere-containing vectors with a common human repeat(s) that could recombine with human DNA during transformation to generate yeast artificial chromosomes (YACs). On basis of the proposal that broken DNA ends are more recombinogenic than internal sequences, we have investigated if TAR cloning could be applied to the generation of circular YACs by using a single centromere vector containing various human repeats at opposite ends. Transformation with these vectors along with human DNA led to the efficient isolation of circular YACs with a mean size of approximately 150 kb. The circular YACs are stable and they can be easily separated from yeast chromosomes or moved into bacterial cells if the TAR vector contains an Escherichia coli F-factor cassette. More importantly, circular TAR cloning enabled the selective isolation of human DNAs from monochromosomal human-rodent hybrid cell lines. Although < 2% of the DNA in the hybrid cells was human, as much as 80% of transformants had human DNA YACs when a TAR cloning vector contained Alu repeats. The level of enrichment of human DNA was nearly 3000-fold. A comparable level of enrichment was demonstrated with DNA isolated from a radiation hybrid cell line containing only 5 Mb of human DNA. A high selectivity of human DNA cloning was also observed for linear TAR cloning with two telomere vectors. No human-rodent chimeras were detected among YACs generated by TAR cloning. The results with a circular TAR cloning vector or two vectors differed from results with a single-telomere vector in that the latter often resulted in a series of terminal deletions in linear YACs. This could provide a means for physical mapping of cloned material.

Specific cloning of human DNA as yeast artificial chromosomes by transformation-associated recombination

DNA molecules undergoing transformation into yeast are highly recombinogenic, even when diverged. We reasoned that transformation-associated recombination (TAR) could be employed to clone large DNAs containing repeat sequences, thereby eliminating the need for in vitro enzymatic reactions such as restriction and ligation and reducing the amount of DNA handling. Gently isolated human DNA was transformed directly into yeast spheroplasts along with two genetically marked (M1 and M2) linearized vectors that contained a human Alu sequence at one end and a telomere sequence at the other end (Alu-CEN-M1-TEL and Alu-M2-TEL). Nearly all the M1-selected transformants had yeast artificial chromosomes (YACs) containing human DNA inserts that varied in size from 70 kb to > 600 kb. Approximately half of these had also acquired the unselected M2 marker. The mitotic segregational stability of YACs generated from one (M1) or two (M1 and M2) vector(s) was comparable, suggesting de novo generation of telomeric ends. Since no YACs were isolated when rodent DNAs or a vector lacking an Alu sequence was used, the YACs were most likely the consequence of TAR between the repeat elements on the vector(s) and the human DNA. Using the BLUR13 Alu-containing vector, we demonstrated that human DNA could be efficiently cloned from mouse cells that contained a single human chromosome 16. The distribution of cloned DNAs on chromosome 16 was determined by fluorescence in situ hybridization. We propose that TAR cloning can provide an efficient means for generating YACs from specific chromosomes and subchromosome fragments and that TAR cloning may be useful for isolating families of genes and specific genes from total genome DNA.

CHL12, a gene essential for the fidelity of chromosome transmission in the yeast Saccharomyces cerevisiae

We have analyzed the CHL12 gene, earlier identified in a screen for yeast mutants with increased rates of mitotic loss of chromosome III and circular centromeric plasmids. A genomic clone of CHL12 was isolated and used to map its physical position on the right arm of chromosome XIII near the ADH3 locus. Nucleotide sequence analysis of CHL12 revealed a 2.2-kb open reading frame with a 84-kD predicted protein sequence. Analysis of the sequence upstream of the CHL12 open reading frame revealed the presence of two imperfect copies of MluI motif, ACGCGT, a sequence associated with many DNA metabolism genes in yeast. Analysis of the amino acid sequence revealed that the protein contains a NTP-binding domain and shares a low degree of homology with subunits of replication factor C (RF-C). A strain containing a null allele of CHL12 was viable under standard growth conditions, and as well as original mutants exhibited an increase in the level of spontaneous mitotic recombination, slow growth and cold-sensitive phenotypes. Most of cells carrying the null chl12 mutation arrested as large budded cells with the nucleus in the neck at nonpermissive temperature that typical for cell division cycle (cdc) mutants that arrest in the cell cycle at a point either immediately preceding M phase or during S phase. Cell cycle arrest of the chl12 mutant requires the RAD9 gene. We conclude that the CHL12 gene product has critical role in DNA metabolism.

The role of recombination and RAD52 in mutation of chromosomal DNA transformed into yeast

While transformation is a prominent tool for genetic analysis and genome manipulation in many organisms, transforming DNA has often been found to be unstable relative to established molecules. We determined the potential for transformation-associated mutations in a 360 kb yeast chromosome III composed primarily of unique DNA. Wild-type and rad52 Saccharomyces cerevisiae strains were transformed with either a homologous chromosome III or a diverged chromosome III from S. carlsbergensis. The host strain chromosome III had a conditional centromere allowing it to be lost on galactose medium so that recessive mutations in the transformed chromosome could be identified. Following transformation of a RAD+ strain with the homologous chromosome, there were frequent changes in the incoming chromosome, including large deletions and mutations that do not lead to detectable changes in chromosome size. Based on results with the diverged chromosome, interchromosomal recombinational interactions were the source of many of the changes. Even though rad52 exhibits elevated mitotic mutation rates, the percentage of transformed diverged chromosomes incapable of substituting for the resident chromosome was not increased in rad52 compared to the wild-type strain, indicating that the mutator phenotype does not extend to transforming chromosomal DNA. Based on these results and our previous observation that the incidence of large mutations is reduced during the cloning of mammalian DNA into a rad52 as compared to a RAD+ strain, a rad52 host is well-suited for cloning DNA segments in which gene function must be maintained.

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.

A model system to assess the integrity of mammalian YACs during transformation and propagation in yeast

Yeast artificial chromosomes (YACs) containing mammalian DNA potentially can undergo deletions during transformation and propagation, possibly due to interactions between repeat DNAs. To study factors involved in such rearrangements, we developed a genetic system that can signal physical changes. An Alu-HIS3-Alu cassette has been targeted to a mitotically stable YAC containing a 360-kb DNA insert of human chromosome 2. Five YACs with the cassette integrated at different positions were examined for loss of the internal HIS3 marker during transformation into yeast and subsequent growth. The average frequency of the internal marker loss in mitotically growing cells was approximately 1.0 x 10(-4). Physical analysis of His- YACs retaining both telomeric markers demonstrated that loss of the marker was due to deletions (20-90 kb). These results contrast with those obtained with YACs following transformation. Nearly 33% of the retransformed YACs lacked the internal HIS3 marker. The transformation-associated loss was also due to deletions varying from 80 to 260 kb. Similar results were obtained following retransformation with the parent human YAC and another mitotically stable YAC containing a 390-kb insert of mouse DNA. The high level of transformation-associated deletions in the human YACs was reduced over 10-fold when the host was a recombination-deficient strain deleted for the RAD52 gene. The level of internal human YAC instability during mitotic growth was also significantly decreased in the rad52 mutant strain compared to that in the isogenic Rad+ strain. However, retransformation of the rad52 mutant with a YAC-containing mouse DNA yielded comparable levels of alterations to those observed for the wildtype strain. Thus, there must be additional genetic factors involved in transformation-associated deletions in YACs. We propose that these YACs and strains can be useful tools for investigating YAC integrity. During the course of these studies a unique category of deletions was identified in mitotically propagated YACs that result from recombination between identical sequences in the telomeric region and the HIS3 cassette. In addition to the known YAC "fragmentation" method, this may provide a means for generating internal deletions as well as an alternative method for mapping.

Transformation-associated recombination between diverged and homologous DNA repeats is induced by strand breaks

Rearrangements within plasmid DNA are commonly observed during transformation of eukaryotic cells. One possible cause of rearrangements may be recombination between repeated sequences induced by some lesions in the plasmid. We have examined the mechanisms of transformation-associated recombination in the yeast Saccharomyces cerevisiae using a plasmid system which allowed the effects of physical state and/or extent of homology on recombination to be studied. The plasmids contain homologous or diverged (19%) repeats of the URA3 genes (from S. cerevisiae or S. carlsbergensis) separated by the genetically detectable ADE2 colour marker. Recombination during transformation for covalently closed circular plasmids was over 100-fold more frequent than during mitotic growth. The frequency of recombination is partly dependent on the method of transformation in that procedures involving lithium acetate or spheroplasting yield higher frequencies than electroporation. When present in the repeats, unique single-strand breaks that are ligatable, as well as double-strand breaks, lead to high levels of recombination between diverged and identical repeats. The transformation-associated recombination between repeat DNAs is under the influence of the RAD52 and RAD1 genes.

Identification and cloning of the CHL4 gene controlling chromosome segregation in yeast

A collection of chl mutants characterized by decreased fidelity of chromosome transmission and by minichromosome nondisjunction in mitosis was examined for the ability to maintain nonessential dicentric plasmids. In one of the seven mutants analyzed, chl4, dicentric plasmids did not depress cell division. Moreover, nonessential dicentric plasmids were maintained stably without any rearrangements during many generations in the chl4 mutant. The rate of mitotic heteroallelic recombination in the chl4 mutant was not increased compared to that in an isogenic wild-type strain. Analysis of the segregation of a marked chromosome indicated that sister chromatid nondisjunction and sister chromatid loss contributed equally to chromosome malsegregation in the chl4 mutant. A genomic clone of CHL4 was isolated by complementation of the chl4-1 mutation and was physically mapped to the right arm of chromosome IV near the SUP2 gene. Nucleotide sequence analysis of CHL4 clone revealed a 1.4-kb open reading frame coding for a 53-kD predicted protein which does not have homology to published proteins. A strain containing a null allele of CHL4 is viable under standard growth conditions but has a temperature-sensitive phenotype (conditional lethality at 36 degrees). We suggest that the CHL4 gene is required for kinetochore function in the yeast Saccharomyces cerevisiae.

Identification and genetic mapping of CHL genes controlling mitotic chromosome transmission in yeast

Eight independent chl (chromosome loss) mutants were isolated using yeast haploid strain disomic for chromosome III. In these mutants, chromosome III is lost during mitosis 50-fold more frequently than in the wild-type strains. chl mutants are also incapable of stable maintenance of circular and linear artificial chromosomes. Seven of the eight mutations are recessive, and one is semidominant. Complementation tests placed these mutants into six complementation groups (chl11 through chl16). Based on tetrad analysis, chl12, chl14 and chl15 correspond to mutations in single nuclear genes. Tetrad analysis of the other mutants was not possible due to poor spore viability. Complementation analysis was also carried out between collection of chl mutants and ctf mutants (chromosome transmission fidelity) (Spencer et al., 1990). The chl3, chl4, chl8, chl12 and chl15 mutants were unable to complement ctf3, ctf17, ctf12, ctf18 and ctf4, respectively. Three CHL genes were mapped by tetrad analysis. The CHL3 gene is placed on the right arm of chromosome XII, between the ILV5 (33.3 cM) and URA4 (21.8 cM) loci. The CHL10 gene is located on the left arm of chromosome VI, 12.5 cM from the centromere. The CHL15 gene is tightly linked to the KAR3 marker of the right arm of chromosome XVI (8.8 cM). The mapping data indicate that these three genes differ from other genes known to affect chromosome stability in mitosis. Therefore, the total number of the CHL genes identified (including those described by us earlier) is 13 (CHL1-CHL10, CHL12, CHL14 and CHL15).

CTF4 (CHL15) mutants exhibit defective DNA metabolism in the yeast Saccharomyces cerevisiae

We have analyzed the CTF4 (CHL15) gene, earlier identified in two screens for yeast mutants with increased rates of mitotic loss of chromosome III and artificial circular and linear chromosomes. Analysis of the segregation properties of circular minichromosomes and chromosome fragments indicated that sister chromatid loss (1:0 segregation) is the predominant mode of chromosome destabilization in ctf4 mutants, though nondisjunction events (2:0 segregation) also occur at an increased rate. Both inter- and intrachromosomal mitotic recombination levels are elevated in ctf4 mutants, whereas spontaneous mutation to canavanine resistance was not elevated. A genomic clone of CTF4 was isolated and used to map its physical and genetic positions on chromosome XVI. Nucleotide sequence analysis of CTF4 revealed a 2.8-kb open reading frame with a 105-kDa predicted protein sequence. The CTF4 DNA sequence is identical to that of POB1, characterized as a gene encoding a protein that associates in vitro with DNA polymerase alpha. At the N-terminal region of the protein sequence, zinc finger motifs which define potential DNA-binding domains were found. The C-terminal region of the predicted protein displayed similarity to sequences of regulatory proteins known as the helix-loop-helix proteins. Data on the effects of a frameshift mutation suggest that the helix-loop-helix domain is essential for CTF4 function. Analysis of sequences upstream of the CTF4 open reading frame revealed the presence of a hexamer element, ACGCGT, a sequence associated with many DNA metabolism genes in budding yeasts. Disruption of the coding sequence of CTF4 did not result in inviability, indicating that the CTF4 gene is nonessential for mitotic cell division. However, ctf4 mutants exhibit an accumulation of large budded cells with the nucleus in the neck. ctf4 rad52 double mutants grew very slowly and produced extremely high levels (50%) of inviable cell division products compared with either single mutant alone, which is consistent with a role for CTF4 in DNA metabolism.

Stability of recombinant plasmids containing the ars sequence of yeast extrachromosomal rDNA in several strains of Saccharomyces cerevisiae

The mitotic stabilities of hybrid plasmid Rcp21/11, which contains the replicator of yeast rDNA, have been compared for four yeast host strains of different origins. In two related strains, Saccharomyces cerevisiae. A62-1G-P188 and 1A-P3812 from the Peterhof genetic stocks, the plasmid was much more stable than in strains DC5 and GRF18 from the USA stocks. The enhanced mitotic stability of Rcp21/11 in these two yeast strains is obviously attributable to a higher rate of integration of the plasmid into the chromosomal rDNA repeats of the hosts. The centromeric locus CEN3 was inserted into Rcp21/11 because it provides high mitotic and meiotic stability of plasmids with yeast replicators, due to an ordered distribution of plasmids throughout cell division. Using the new centromeric plasmid RcpCEN3, transformation of the four above-described yeast strains was carried out. It was found that, similarly to centromeric plasmids with other chromosomal replicators, RcpCEN3 remains in the cell as a single copy. In strains DC5, GRF18 and A62-1G-P188 the mitotic stability of RcpCEN3 was 20-50%, i.e., less than half that of plasmids containing locus CEN3 and other yeast replicators, ars1, ars2 and the 2mu DNA replicator. The mitotic stability of RcpCEN3 in strains 1A-P3812 (from the Peterhof genetic stocks) for individual clones reached 85%, i.e. close to that of the other plasmids. Genetic analysis showed that the capacity of strain 1A-P3812 to stably retain RcpCEN3 has a recessive polygenic character. We suggest that the observed differences in mitotic stability of centromeric plasmid RcpCEN3 between various yeast strains reflects the differences in activity of rDNA replicator in these strains.(ABSTRACT TRUNCATED AT 250 WORDS)