Introduction of YACs containing a putative mammalian replication origin into mammalian cells can generate structures that replicate autonomously

Yeast artificial chromosomes (YACs) containing or lacking a biochemically defined DNA replication origin were transferred from yeast to mammalian cells in order to determine whether origin-dependent autonomous replication would occur. A specialized YAC vector was designed to enable selection for YACs in mammalian cells and for monitoring YAC abundance in individual mammalian cells. All of eight clones made with linear and circularized YACs lacking the origin and seven of nine clones made with linear and circularized YACs containing the origin region contained single copies of the transfected YAC, along with various amounts of yeast DNA, integrated into single but different chromosomal sites. By contrast, two transformants derived from circularized YACs containing the putative replication origin showed very heterogeneous YAC copy number and numerous integration sites when analyzed after many generations of in vitro propagation. Analysis of both clones at an early time after fusion revealed variously sized extrachromosomal YAC/yeast structures reminiscent of the extrachromosomal elements found in some cells harboring amplified genes. The data are consistent with the interpretation that YACs containing a biochemically defined origin of replication can initially replicate autonomously, followed by integration into multiple chromosomal locations, as has been reported to occur in many examples of gene amplification in mammalian cells.     

LCR-dependent gene expression in beta-globin YAC transgenics: detailed structural studies validate functional analysis even in the presence of fragmented YACs

Yeast artificial chromosome (YAC) transgenesis is associated with a high frequency of deletions in the integrated transgenes. To determine the impact of these rearrangements on the ability to derive structure- function relationships using YACs, transgenic mice were generated with 248 or 155 kb beta-globin locus YACs. The transgenics were examined for structural integrity of the YAC using an approach of structural analysis that unambiguously demonstrates intactness of YAC transgene copies. Globin gene expression per copy of each integrated transgene and the profiles of globin gene expression during development were determined. Diverse deletion patterns were observed in one or more integrated YACs in all the 248 and most of the 155 kb transgenic lines we analyzed. However, when the structure of the major regulatory element of the beta-globin locus, the locus control region, was preserved, the genes of the beta-globin locus functioned normally and globin transgenes of both the 248 and 155 kb beta-YACs were expressed in a position-independent, copy number-dependent manner. Furthermore, the globin genes of both beta-YACs displayed normal developmental regulation. We conclude that YACs can be used for analysis of structure- function relationships of large genes or multigene loci in spite of the tendency for rearrangements and deletions of the integrated transgenes. However, detailed structural evidence for integrity and continuity of locus sequences is required for correct interpretation of functional data.      

Functional human CFTR produced by stable Chinese hamster ovary cell lines derived using yeast artificial chromosomes

The cystic fibrosis transmembrane conductance regulator gene (CFTR) encodes a transmembrane protein (CFTR) which functions in part as a cyclic adenosine monophosphate (cAMP)-regulated chloride channel. CFTR expression is controlled temporally and cell specifically by mechanisms that are poorly understood. Insight into CFTR regulation could be facilitated by the successful introduction of the entire 230 kb human CFTR and adjacent sequences into mammalian cells. To this end, we have introduced two different CFTR-containing yeast artificial chromosomes (YACs) (320 and 620 kb) into Chinese hamster ovary-K1 (CHO) cells. Clonal cell lines containing human CFTR were identified by PCR, and the genetic and functional analyses of one clone containing each YAC are described. Integration of the human CFTR-containing YACs into the CHO genome at a unique site in each cell line was demonstrated by fluorescence in situ hybridization (FISH). Southern blot analysis suggested that on the order of one copy of human CFTR was integrated per CHO cell genome. Fiber-FISH and restriction analysis suggested that CFTR remained grossly intact. Northern analysis showed full-length, human CFTR mRNA. Immunoprecipitation followed by phosphorylation with protein kinase demonstrated mature, glycosylated CFTR. Finally, chloride secretion in response to cAMP indicated the functional nature of the human CFTR. This study provides several novel results including: (i) functional human CFTR can be expressed from these YACs; (ii) CHO cells are a permissive environment for expression of human CFTR; (iii) the level of human CFTR expression in CHO cells is unexpectedly high given the lack of endogenous CFTR production; and (iv) the suggestion by Fiber-FISH of CFTR integrity correlates with functional gene expression. These YACs and the cell lines derived from them should be useful tools for the study of CFTR expression.      

Transfer of the human HPRT and GART genes from yeast to mammalian cells by microinjection of YAC DNA

DNA of two yeast artificial chromosomes (YACs) containing selectable human genes was transferred by microinjection to rodent cells in tissue culture. The human hypoxanthine phosphoribosyltransferase (HPRT) gene, spanning 45 kb, is contained on the 660-kb YAC yHPRT as described elsewhere. The human phosphoribosylglycinamide formyltransferase (GART) gene, spanning approximately 40 kb, is contained on the 590-kb YAC yGART2 as described previously. YAC DNA was isolated from pulsed-field gels and microinjected into mammalian cells in which the human HPRT and GART genes can be selected. The cell lines that were selected contain the entire human genes. Some of the cell lines contain multiple copies of the genes integrated at the same chromosomal position. The YAC yGART2 could not be purified away from natural yeast chromosomes of similar size, and the cell lines into which the human GART gene was introduced contain variable amounts of yeast DNA in addition to the human DNA.     

Viral integration and fragile sites in human papillomavirus-immortalized human keratinocyte cell lines.

Human papillomavirus (HPV) types 16 and 18 integration sites were mapped in six HPV-immortalized human keratinocyte cell lines by fluorescence in situ hybridization (FISH). Mapping of HPV sequences in these cell lines revealed that HPV integration varied in copy number and location but that integration sites were stable over extended passages in culture. Integration occurred at different sites throughout the genome and did not correspond to the location of specific cellular genes. However, integration sites were consistent with integration near or within known fragile sites in five of the six cell lines. Induction of aphidicolin-sensitive fragile sites in one cell line prior to in situ hybridization revealed that integrated HPV DNA was disrupted by fragile-site expression, suggesting that integration occurred within a fragile site.     

De novo formation of several features of a centromere following introduction of a Y alphoid YAC into mammalian cells

The DNA sequence requirements for mammalian centromere functionhave been Investigated by re-Introducing human YAC clones containingeither centromeric or non-centromeric sequences Into hamsterand human cells. All YACs integrated into the host chromosomes.In most cell lines produced by spheroplast fusion into hamstercells, intact copies of the YAC and a large amount of yeastDNA were found. Cell lines produced by lipofection Into humancells usually contained simple structures without yeast DNA.YACs containing Y alphoid DNA reformed several of the propertiesof a centromere, Including a cytogenetlcally visible constriction,CREST antiserum binding and disruption of anaphase chromosomemovement. In contrast, YACs containing non-centromeric sequencesproduced none of these results. This work suggests that a fewhundred kb of alphoid DNA is sufficient to reconstitute severalImportant features of a centromere.     

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 ~1 week, the new method greatly expands the utility of the homologous recombinationproficient DT40 chicken cell system.     

Integration of physical, breakpoint and genetic maps of chromosome 22. Localization of 587 yeast artificial chromosomes with 238 mapped markers

Detailed physical maps of the human genome are important resourcesfor the Identification and isolation of disease genes and forstudying the structure and function of the genome. We used datafrom STS content mapping of YACs and natural and induced chromosomalbreakpoints to anchor contigs of overlapping yeast artificialchromosome (YAC) clones spanning extensive regions of humanchromosome 22. The STSs were assigned to specific regions (bins)on the chromosome using cell lines from a somatic hybrid mappingpanel defining a maximum of 25 intervals. YAC libraries werescreened by PCR amplification of hierarchical pools of yeastDNA with 238 markers, and a total of 587 YAC clones were identified.These YACs were assembled into contigs based upon their sharedSTS content using a simulated annealing algorithm. Fifteen contigs,containing between 2 and 74 STSs were assembled, and orderedalong the chromosome based upon the cytogenetic breakpoint,meiotic and PFG maps. Additional singleton YACs were assignedto unique chromosomal bins. These ordered YAC contigs will beuseful for identifying disease genes and chromosomal breakpointsby positional cloning and will provide the foundation for higherresolution physical maps for large scale sequencing of the chromosome.     

Integration of physical, genetic and cytogenetic maps of human chromosome 7: isolation and analysis of yeast artificial chromosome clones for 117 mapped genetic markers

An Important goal of the human genome project is to assemblefully integrated physical, genetic and cytogenetic maps foreach human chromosome. Towards that end, we have isolated yeastartificial chromosome (YAC) clones containing 117 of the 119genetic markers that constitute a recently constructed, detailedgenetic map of human chromosome 7. Analysis of these clonesreveals numerous examples where adjacent genetic markers havebeen physically connected, either In Individual YACs or in multi-YACcontigs. At present, the 117 genetic markers are contained Infewer than 80 YAC contigs, with most of these contigs uniquelyordered relative to one another based on the genetic map positionsof the corresponding markers. These YAC and YAC contigs areestimated to contain {small tilde}60–85% of the DNA fromhuman chromosome 7. YACs representing 36 genetic markers weremapped by fluorescence In situ hybridization (FISH) to metaphasechromosomes, allowing assignment of these genetic markers tocytogenetic bands along chromosome 7 and placement of the centromerewithin the genetic map. Together, these studies provide geneticallyand cytogenetically anchored YAC clones covering the majorityof chromosome 7 that will be useful both for the positionalcloning of genes and as a framework for assembling a completeYAC-based physical map of the chromosome.     

Epstein-Barr virus is integrated between REL and BCL-11A in American Burkitt lymphoma cell line (NAB-2)

Epstein-Barr virus (EBV) initially isolated from the cultured Burkitt lymphoma (BL) cells, is one of the well-known oncogenic virus. The NAB-2 line, which was established from a North American Burkitt's tumor, was indicated to contain one copy of EBV DNA as the integrated form into chromosome 2p13 of the host genome. To demonstrate the integration site of EBV directly, and to clarify the relation between the integration sites and the oncogenes, fragments containing the nucleotide sequence of NAB-2 integration sites were cloned. EBV was integrated via the terminal repeats (TR), and integration sites located in the clone RP11-440P5 on chromosome 2, between two oncogenes, REL and BCL11A, which is apart from approximately 350 kbp from each other. Expression level of REL in NAB-2 was increased. The flanking region of chromosome 2 at the bilateral junction sites showed no homology to the junction sites of EBV. The integration site 2p13 overlaps with common fragile site, FRA2E. NAB-2 cells expressed almost all latent genes but LMP-2A that flanks the TR, indicating the type III of latent infection of EBV. Integration event in NAB-2 might alter the regulation of the oncogenes and provide advantage for continuous cell proliferation.     

Frequent genomic structural alterations at HPV insertion sites in cervical carcinoma

To investigate whether integration of HPV DNA in cervical carcinoma is responsible for structural alterations of the host genome at the insertion site, a series of 34 primary cervical carcinomas and eight cervical cancer‐derived cell lines were analysed. DNA copy number profiles were assessed using the Affymetrix GeneChip Human Mapping 250K Sty array. HPV 16, 18 or 45 integration sites were determined using the DIPS‐PCR technique. The genome status at integration sites was classified as follows: no change, amplification, transition normal/gain, normal/loss or gain/LOH. A single HPV integration site was found in 34 cases; two sites were found in seven cases; and three sites in one case (51 sites). Comparison between integration sites and DNA copy number profiles showed that the genome status was altered at 17/51 (33%) integration sites, corresponding to 16/42 cases (38%). Alterations detected were amplification in nine cases, transition normal/loss in four cases, normal/gain in three cases, and gain/LOH in one case. A highly significant association was found between genomic rearrangement and integration of HPV DNA (p < 10^?10). Activation of the replication origin located in viral integrated sequences in a cell line derived from one of the primary cervical carcinomas induced an increase of the amplification level of both viral and cellular DNA sequences flanking the integration locus. This mechanism may be implicated in the triggering of genome amplification at the HPV integration site in cervical carcinoma. Structural alterations of the host genome are frequently observed at the integration site of HPV DNA in cervical cancer and may act in oncogenesis. Copyright © 2010 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

利用表型筛选法测定整合子对耐药性基因盒的整合频率

目的 建立一种利用表型筛选的方法来测定整合子对耐药性基因盒的整合频率. 方法 将整合子和aadA2耐药性基因盒克隆到同一质粒pACYCl84的不同位点,该重组质粒和高表达整合酶的重组质粒分别转化大肠杆菌BL21(DE3),挑选阳性克隆过夜培养后,取适量菌液涂布含有链霉素的LB琼脂平板,同时取适量菌液涂布不含链霉素的LB琼脂平板,过夜培养后计数菌落个数,用以计算整合频率.同时以链霉素平板上的阳性克隆为模板,进行PCR扩增.对扩增产物切胶回收纯化,然后进行测序,以确定aadA2耐药性基因盒整合位点. 结果 在大肠杆菌BL21(DE3)宿主中,整合子对aadA2耐药性基因盒的整合频率为1.1×103,主要的整合位点为attI. 结论 该系统可以用于整合子对基因盒捕获频率的测定.     

Cloning of the Huntington disease region in yeast artificial chromosomes.

The gene responsible for Huntington disease has been localized to a 2.5 million base pair (Mb) region between the loci D4S10 and D4S168 on the short arm of chromosome 4. As part of a strategy to clone the HD gene on the basis of its chromosomal location, we isolated genomic DNA from the HD region as a set of overlapping yeast artificial chromosome (YAC) clones. Twenty-eight YAC clones were identified by screening human YAC libraries with twelve PCR-based sequence-tagged sites (STSs) from the region. We assembled the YAC clones into overlapping sets by hybridizing them to a large number of DNA probes from the HD region, including the STSs. In addition, we isolated the ends of the human DNA inserts of most of the YAC clones to assist in the construction of the contig. Although almost half of the YACs appear to contain chimeric inserts and several contain internal deletions or other rearrangements, we were able to obtain over 2.2 Mb of the HD region in YACs, including one continuous segment of 2.0 Mb covering the region that most likely contains the HD gene. Ten of the twenty eight YAC clones comprise a minimal set spanning the 2.2 Mb. These clones provide reagents for the complete characterization of this region of the genome and for the eventual isolation of the HD gene.     

Reconstruction of the 2.4 Mb human DMD-gene by homologous YAC recombination.

The human dystrophin gene, mutations of which cause Duchenne and Becker muscular dystrophy, measures 2.4 Mb. This size seriously limits its cloning as a single DNA fragment and subsequent in-vitro expression studies. We have used stepwise in-vivo recombination between overlapping yeast artificial chromosomes (YACs) to reconstruct the dystrophin gene. The recombinant YACs are mitotically stable upon propagation in haploid yeast cells. In contrast, specific combinations of YACs display a remarkable mitotic and meiotic instability in diploid cells. Non-disjunction is rare for overlapping YACs, but increases upon sporulation of diploid cells containing non-overlapping molecules. We have exploited this feature in a three-point recombination to bridge a 280 kb gap between two non-overlapping YACs for which no YAC of proper polarity existed. Our largest recombinant YAC measures 2.3 Mb and contains the entire muscle specific DMD-gene with the exception of a 100 kb region containing the in-frame exon 60. The latter segment has a high tendency to undergo deletions in multi-molecular interactions, probably due to the presence of as yet unidentified instability-enhancing sequences. Fluorescent in situ hybridizations confirmed that the 2.3 Mb DMD YAC contained Xp21-sequences only and indicated a compact tertiary structure of the DMD-gene in interphase lymphocyte nuclei. We conclude that the yeast system is a flexible, efficient and generally applicable tool to reconstruct or build genomic regions from overlapping YAC constituents. Its application to the human dystrophin gene has provided many possibilities for future studies.     

A yeast artificial chromosome contig spanning the Charcot-Marie-Tooth disease type 1A duplication region.

A contiguous set of 43 overlapping yeast artificial chromosome (YAC) clones has been developed for the Charcot-Marie-Tooth disease type 1A (CMT1A) duplication region of chromosome 17p11.2. The contig spans approximately 2.0 Mb and can be represented in a minimum of five overlapping YACs. The YAC clones were isolated from two total human genomic YAC libraries and from YAC libraries made from rodent-human hybrid cell lines. YAC clones were isolated from the libraries by polymerase chain reaction (PCR) technique. Localization to chromosome 17p11.2 was confirmed by fluorescence in situ hybridization. Overlap between the YAC clones was detected by inter-Alu PCR amplification of the YACs and by cross hybridization of the YACs with YAC insert ends obtained by Vectorette PCR. This YAC contig is a useful resource for analyzing and mapping all the genes contained within the CMT1A duplication.     

Localization of the synovial sarcoma t(X;18)(p11.2;q11.2) breakpoint by fluorescence in situ hybridization.

A high proportion of synovial sarcomas contain a chromosome translocation t(X;18)(p11.2;q11.2). We have previously used somatic cell hybrids derived from an established cell line, SS255, to map the X chromosome breakpoint to the interval flanked by the markers DXS14 and DXS146. In this study we have examined these hybrids with thirteen additional markers located at Xp11.3-Xcen, by Southern hybridization. Based on these results we have delimited the breakpoint as follows Xpter-DXS228-(UBE1-OATL1-TIMP-DXS226 )-(DXS255-TFE3-ELK1-DXS146)-OATL2- X;18-(DXS14-DXS422-DXS423-DXS674-DXS679)-+ ++Xcen. Confirmation of the breakpoint location has been obtained by analysis of two synovial sarcoma cell lines, SS255 and HA2243, using fluorescence in situ hybridization. A 350kb YAC probe spanning the DXS423 locus hybridized only to the derivative X chromosome, showing that it maps proximal to the breakpoint. Two YAC probes of 300kb and 450kb, containing the OATL2 locus, hybridized to both derivative chromosomes, indicating that these YACs span the translocation breakpoint. Similar results were obtained with both cell lines. The identification of YACs that span the t(X;18) breakpoint now facilitates a strategy for cloning candidate genes from this precisely defined region.     

A novel expression system for genomic DNA loci using a human artificial chromosome vector with transformation-associated recombination cloning

Following the recent completion of the human genome sequence, genomics research has shifted its focus to understanding gene complexity, expression, and regulation. However, in order to investigate such issues, there is a need to develop a practical system for genomic DNA expression. Transformation-associated recombination (TAR) cloning has proven to be a convenient tool for selective isolation of a genetic locus from a complex genome as a circular YAC using recombination in yeast. The human artificial chromosome (HAC) vector containing an acceptor loxP site has served as a platform for the reproducible expression of transgenes. In this study, we describe a system that efficiently expresses a genetic locus in mammalian cells by retrofitting a TAR-YAC with the donor loxP site and loading it onto the HAC vector by the Cre/loxP system. In order to demonstrate functional expression of genomic loci, the entire human hypoxanthine phosphoribosyl transferase (HPRT) locus contained in a 100 kb YAC was loaded onto the HAC vector and was shown to complement the genetic defect in Hprt-deficient CHO cells. Thus, the combination of TAR cloning and the HAC vector may serve as a powerful tool for functional genomic studies.