Construction and characterization of a partial library of yeast artificial chromosomes from human chromosome 21

We report a protocol for cloning large DNA fragments in yeast artificial chromosomes (YAC). A partial library has been constructed from a somatic hybrid containing chromosome 21 as the single source of human DNA. About 4.0 Mb of human DNA was recovered in 17 YAC clones. Three clones were analyzed by in situ hybridization and mapped on chromosome 21. One clone hybridized with the chromosome 21 centromeric region and may provide new insight both on the molecular structure of centromere and on the localization of Alzheimer disease gene.     

Construction and characterization of a yeast artificial chromosome library containing 1.5 equivalents of human chromosome 21.

A library of yeast artificial chromosomes (YACs) was constructed from a human/hamster somatic cell hybrid containing human chromosome 21 (q11-qter). Cells were embedded in agarose, and the DNA was partially digested with EcoRI, released into solution by agarase treatment of the agarose plugs, ligated into pYAC4, and transferred into yeast. Double screening of the yeast transformants with human and hamster genomic DNA allowed the selection of clones hybridizing only with human DNA. The library consists of 321 clones, amounting to 1.5 equivalents (61 Mb) of chromosome 21. The mean YAC size calculated from 178 clones is 190 +/- 100 kb. Screening of the library with eight sequence-tagged sites gave six positives. Among 21 YACs tested by in situ hybridization, 17 mapped to chromosome 21.     

The XRCC2 and XRCC3 repair genes are required for chromosome stability in mammalian cells.

The irs1 and irs1SF hamster cell lines are mutated for the XRCC2 and XRCC3 genes, respectively. Both show heightened sensitivity to ionizing radiation and particularly to the DNA cross-linking chemical mitomycin C (MMC). Frequencies of spontaneous chromosomal aberration have previously been reported to be higher in these two cell lines than in parental, wild-type cell lines. Microcell-mediated chromosome transfer was used to introduce complementing or non-complementing human chromosomes into each cell line. irs1 cells received human chromosome 7 (which contains the human XRCC2 gene) or, as a control, human chromosome 4. irs1SF cells received human chromosome 14 (which contains the XRCC3 gene) or human chromosome 7. For each set of hybrid cell lines, clones carrying the complementing human chromosome recovered MMC resistance to near-wild-type levels, while control clones carrying noncomplementing chromosomes remained sensitive to MMC. Fluorescence in situ hybridization with a human-specific probe revealed that the human chromosome in complemented clones remained intact in almost all cells even after extended passage. However, the human chromosome in noncomplemented clones frequently underwent chromosome rearrangements including breaks, deletions, and translocations. Chromosome aberrations accumulated slowly in the noncomplemented clones over subsequent passages, with some particular deletions and unbalanced translocations persistently transmitted throughout individual subclones. Our results indicate that the XRCC2 and XRCC3 genes, which are now considered members of the RAD51 gene family, play essential roles in maintaining chromosome stability during cell division. This may reflect roles in DNA repair, possibly via homologous recombination.     

Construction and characterization of a bacterial artificial chromosome library of banana (<Emphasis Type="Italic">Musa acuminata</Emphasis> Colla)

A bacterial artificial chromosome (BAC) library for banana was constructed from leaves of the wild diploid 'Calcutta 4' clone (Musa acuminata subsp. Burmannicoides 2n = 2 x = 22). 'Calcutta 4' is widely used in breeding programs for its resistance to the current major disease of banana and is being used to build a genetic reference map of banana. As banana leaves are particularly rich in polyphenols and polysaccharides a protocol was adapted to isolate intact nuclei and high-molecular-weight (HMW) DNA. A total of 55,152 clones with an average insert size of 100 kb were picked. The frequency of BAC clones carrying inserts derived from chloroplast and mitochondrial DNA was estimated to be 1.5%. The coverage of the library is equivalent to 9.0-times the haploid genome. The BAC library was screened with 13 RFLP probes belonging to the 8 linkage groups of the consensus molecular map of banana. A total of 135 clones were identified giving an average of 10.38 clones for each locus. This BAC library will be a valuable starting tool for many of the goals of the recently emerged International Musa Genomic Consortium. One of our initial objectives will be to develop a banana physical map by BAC-FISH (fluorescent in situ hybridization) viewing the characterization of translocation break points.     

Protein-free transfection of CHO host cells with an IgG-fusion protein: selection and characterization of stable high producers and comparison to conventionally transfected clones

In order to improve the current techniques of cell cultivation in the absence of serum, we have developed a protein-free transfection protocol for CHO cells, based on the Nucleofector technology. After starting with a heterogeneous pool of primary transfectants which express the fusion protein EpoFc, we isolated single clones and compared them with parallel clones generated by lipofection in serum-dependent cultivation. Our intensive characterization program was based on determination of specific productivity (q(p)) and analysis of genetic parameters. In two nucleofection experiments, transfection with 5 microg of DNA resulted in best productivities of the primary cell pools. After subcloning, the q(p) could be raised up to 27 pg x cells(-1) x day(-1). While the serum-dependent transfectants exhibited specific productivities up to 57 pg x cells(-1) x day(-1) in serum-dependent cultivation, a significant decrease that resulted in the range of q(p) of the protein-free transfectants was observed after switching to protein-free conditions. Investigation of genetic parameters revealed higher mRNA levels and gene copy numbers (GCN) for the protein-free adapted serum-dependent transfectants. Therefore, we assume that problems during protein-free adaptation (PFA) lead to a less efficient translation machinery after serum deprivation. We describe the generation of stable-producing recombinant CHO clones by protein-free transfection of a protein-free adapted host cell line, which reduces the risk of adverse clonal changes after PFA. The main advantage of this approach is the earlier predictability of clone behavior, which makes the generation of production clones by protein-free transfection, a viable and highly efficient strategy for recombinant cell line development.     

SV 40-transformed normal and DNA-repair-deficient human fibroblasts can be transfected with high frequency but retain only limited amounts of integrated DNA

The ability of simian virus 40-transformed human fibroblasts to integrate and maintain transfected genomic DNA has been investigated in two normal and six DNA-repair-deficient human cell lines. These cell lines were transfected with DNA containing two selective markers (G418 and hygromycin (Hyg) resistance) separated by random pieces of human DNA of 0-40 kb in length. The transfection frequency for the selected (G418R) marker was between 2 x 10(-4) and 2 x 10(-3) for all cell lines, comparable to many other mammalian systems. About 50% of the G418R colonies were also initially resistant to Hyg. Analysis of the DNA from individual clones expanded for a further month revealed, however, that about one to three copies of the selected marker but only about 0.1 copy per cell of the unselected marker were maintained. Our results were broadly similar for all eight cell lines. Thus the amount of integrated DNA that is stably maintained in these cells is in general very small (less than 50 kb). This may provide an explanation for the difficulties encountered in many laboratories in attempts to correct the defect in DNA-repair-deficient human cells by transfection with genomic DNA. Our results also show that none of several defects in DNA repair has any obvious effect on either the transfection frequency or the amount of stably integrated foreign DNA.     

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 ΔYq74 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 ΔYq74 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.     

Introduction of new genetic markers on human chromosomes

The purpose of this study was to use DNA transfection and microcell chromosome transfer techniques to engineer a human chromosome containing multiple biochemical markers for which selectable growth conditions exist. The starting chromosome was a t(X;3)(3pter----3p12::Xq26----Xpter) chromosome from a reciprocal translocation in the normal human fibroblast cell line GM0439. This chromosome was transferred to a HPRT (hypoxanthine phosphoribosyltransferase)-deficient mouse A9 cell line by microcell fusion and selected under growth conditions (HAT medium) for the HPRT gene on the human t(X;3) chromosome. A resultant HAT-resistant cell line (A9(GM0439)-1) contained a single human t(X;3) chromosome. In order to introduce a second selectable genetic marker to the t(X;3) chromosome, A9(GM0439)-1 cells were transfected with pcDneo plasmid DNA. Colonies resistant to both G418 and HAT medium (G418r/HATr) were selected. To obtain A9 cells that contained a t(X;3) chromosome with an integrated neo gene, the microcell transfer step was repeated and doubly resistant cells were selected. G418r/HATr colonies arose at a frequently of 0.09 to 0.23 x 10(-6) per recipient cell. Of seven primary microcell hybrid clones, four yielded G418r/HATr clones at a detectable frequency (0.09 to 3.4 x 10(-6)) after a second round of microcell transfer. Doubly resistant cells were not observed after microcell chromosome transfers from three clones, presumably because the markers were on different chromosomes. The secondary G418r/HATr microcell hybrids contained at least one copy of the human t(X;3) chromosome and in situ hybridization with one of these clones confirmed the presence of a neo-tagged t(X;3) human chromosome. These results demonstrate that microcell chromosome transfer can be used to select chromosomes containing multiple markers.     

Construction and Identification of Bacterial Artificial Chromosome Library for 0-613-2R in Upland Cotton

A bacterial artificial chromosome （BAC） library containing a large genomlc DNA insert is an important tool for genome physical mapping, map-based cloning, and genome sequencing. To Isolate genes via a map-based cloning strategy and to perform physical mapping of the cotton genome, a high-quality BAC library containing large cotton DNA Inserts Is needed. We have developed a BAC library of the restoring line 0-613-2R for Isolating the fertility restorer （Rf1） gene and genomic research in cotton （Gossypium hirsutum L.）. The BAC library contains 97 825 clones stored In 255 pieces of a 384-well mlcrotiter plate. Random samples of BACs digested with the Notl enzyme Indicated that the average Insert size Is approximately 130 kb, with a range of 80-275 kb, and 95.7% of the BAC clones in the library have an average insert size larger than 100 kb. Based on a cotton genome size of 2 250 Mb, library coverage is 5.7 × haploid genome equivalents. Four clones were selected randomly from the library to determine the stability of the BAC clones. There were no different fingerprints for 0 and 100 generations of each clone digested with Notl and Hlndiii enzymes. Thus, the atabiiity of a single BAC clone can be sustained at iesat for 100 generations. Eight simple sequence repeat （SSR） markers flanking the Rf; gene were chosen to screen the BAC library by pool using PCR method and 25 positive clones were identified with 3.1 positive clones per SSR marker.     

Construction and application of a full-coverage, high-resolution, human chromosome 8q genomic microarray for comparative genomic hybridization.

BACKGROUND: Array-based comparative genomic hybridization (aCGH) enables genome-wide quantitative delineation of genomic imbalances. A high-resolution contig array was developed specifically for chromosome 8q because this chromosome arm is frequently altered in many human cancers. METHODS: A minimal tiling path contig of 702 8q-specific bacterial artificial chromosome (BAC) clones was generated with a novel computational tool (BAC Contig Assembler). BAC clones were amplified by degenerative oligonucleotide primer (DOP) polymerase chain reaction and subsequently printed onto glass slides. For validation of the array DNA samples of gastroesophageal and prostate cancer cell lines, and chronic myeloid leukemia specimens were used, which were previously characterized by multicolor fluorescence in situ hybridization and conventional CGH. RESULTS: Single and double copy gains were confidently demonstrated with the 8q array. Single copy loss and high-level amplifications were accurately detected and confirmed by bicolor fluorescence in situ hybridization experiments. The 8q array was further tested with paraffin-embedded prostate cancer specimens. In these archival specimens, the copy number changes were confirmed. In fresh and archival samples, additional alterations were disclosed. In comparison with conventional CGH, the resolution of the detected changes was much improved, which was demonstrated by an amplicon of 0.7 Mb and a deletion of 0.6 Mb, both spanned by only six BAC clones. CONCLUSIONS: A comprehensive array is presented, which provides a high-resolution method for mapping copy number alterations on chromosome 8q.     

用人染色体14q24.3区带探针池直接分离表达顺序

本文报道了从显微切割的人染色体区带直接分离区带专一性表达序列的方法和结果。     

New strategy for mapping the human genome based on a novel procedure for construction of jumping libraries

A novel procedure for construction of jumping libraries is described. The essential features of this procedure are as follows: (1) two diphasmid vectors (lambda SK17 and lambda SK22) are simultaneously used in the library construction to improve representativity, (2) a partial filling-in reaction is used to eliminate cloning of artifactual jumping clones and to obviate the need for a selectable marker. The procedure has been used to construct a representative human NotI jumping library (220,000 independent recombinant clones) from the lymphoblastoid cell line CBMI-Ral-STO, which features a low level of methylation of its resident EBV genomes. A human chromosome 3-specific NotI jumping library (500,000 independent recombinant clones) from the human chromosome 3 x mouse hybrid cell line MCH 903.1 has also been constructed. Of these recombinant clones 50-80% represent jumps to the neighboring cleavable NotI site. With our previously published method for construction of linking libraries this procedure makes a new genome mapping strategy feasible. This strategy includes the determination of tagging sequences adjacent to NotI sites in random linking and jumping clones. Special features of the lambda SK17 and lambda SK22 vectors facilitate such sequencing. The STS (sequence tagged site) information obtained can be assembled by computer into a map representing the linear order of the NotI sites for a chromosome or for the entire genome. The computerized mapping data can be used to retrieve clones near a region of interest. The corresponding clones can be obtained from the panel of original clones, or necessary probes can be made from genomic DNA by PCR.     

Systematic generation of sequence-tagged sites for physical mapping of human chromosomes: application to the mapping of human chromosome 7 using yeast artificial chromosomes.

Basic to the development of long-range physical maps of DNA are the detection and localization of landmarks within recombinant clones. Sequence-tagged sites (STSs), which are short stretches of DNA that can be specifically detected by the polymerase chain reaction (PCR), can be used as such landmarks. Our interest is to construct physical maps of whole human chromosomes by localizing STSs within yeast artificial chromosome (YAC) clones. Here we describe a generalized strategy for the systematic generation of large numbers of STSs specific for human chromosome 7. These STSs can be detected by PCR assays developed following the sequencing of anonymous pieces of chromosome 7 DNA, which was derived from flow-sorted chromosomes or from lambda clones made from DNA of a human-hamster hybrid cell line. Our approach for STS generation is tailored for the development of PCR assays capable of screening a large YAC library. In this study, we report the generation of 100 new STSs specific to human chromosome 7.     

A panel of irradiation-reduced hybrids selectively retaining human chromosome 11p13: their structure and use to purify the WAGR gene complex

The irradiation-fusion technique offers a means to isolate intact subchromosomal fragments of one mammalian species in the genetic background of another. Irradiation-reduced somatic cell hybrids can be used to construct detailed genetic and physical maps of individual chromosome bands and to systematically clone genes responsible for hereditary diseases on the basis of their chromosomal position. To assess this strategy, we constructed a panel of hybrids that selectively retain the portion of human chromosome band 11p13 that includes genes responsible for Wilms tumor, aniridia, genitourinary anomalies, and mental retardation (constituting the WAGR syndrome). A hamster-human hybrid containing the short arm of chromosome 11 as its only human DNA (J1-11) was gamma-irradiated and fused to a Chinese hamster cell line (CHO-K1). We selected secondary hybrid clones that express MIC1 but not MER2, cell-surface antigens encoded by bands 11p13 and 11p15, respectively. These clones were characterized cytogenetically by in situ hybridization with human repetitive DNA and were tested for their retention of 56 DNA, isozyme, and antigen markers whose order on chromosome 11p is known. These cell lines appear to carry single, coherent segments of 11p spanning MIC1, which range in size from 3000 kb to more than 50,000 kb and which are generally stable in the absence of selection. In addition to the selected region of 11p13, two cell lines carry extra fragments of the human centromere and two harbor small, unstable segments of 11p15. As a first step to determine the size and molecular organization of the WAGR gene complex, we analyzed a subset of reduced hybrids by pulsed-field gel electrophoresis. A small group of NotI restriction fragments comprising the WAGR complex was detected in Southern blots with a cloned Alu repetitive probe. One of the cell lines (GH3A) was found to carry a stable approximately 3000-kb segment of 11p13 as its only human DNA. The segment encompasses MIC1, a recurrent translocation breakpoint in acute T-cell leukemia (TCL2), and most or all of the WAGR gene complex, but does not include the close flanking markers D11S16 and delta J. This hybrid forms an ideal source of molecular clones for the developmentally fascinating genes underlying the WAGR syndrome.     

A BAC-based STS-content map spanning a 35-Mb region of human chromosome 1p35-p36

We have devised a mapping method for rapid assembly and ordering of bacterial artificial chromosome (BAC) clones on a radiation hybrid (RH) panel, using sequence-tagged sites (STSs) and PCR. The protocol consists of two rounds of two-dimensional screening from a limited number of BACs to correspond each to an STS. In the first round, STSs are assembled in the RH bins and ordered according to PCR signals derived from 384-well microtiter plates (MTPs) in which BAC clones have been arrayed. In the second round, individual BAC clones are isolated from the MTPs to build a contig. We applied this method to a 35-Mb region spanning human chromosome 1p35-p36 and assembled 1366 BACs in 11 contigs, the longest being about 20 Mb. The working draft sequences of the human genome have been integrated into the contigs to validate the accuracy.     

Construction of a garlic BAC library and chromosomal assignment of BAC clones using the FISH technique.

For molecular and cytogenetic studies, two partial bacterial artificial chromosome (BAC) libraries of the garlic cultivar Allium sativum L. 'Danyang' were constructed using high molecular weight (HMW) garlic DNA, the pBAC1-SACB1 vector, and the pIndigoBAC536 vector. The average insert size of the BAC library was about 90 kb. The sequence compositions of the BAC clones were characterized by Southern hybridization with garlic genomic DNA and a repetitive sequence clone of garlic. Two BAC clones with weak signals (thus implying mostly unique sequences), GBC2-5e and GBC2-4d, were selected for FISH analysis. FISH analysis localized the GBC2-5e (approximately 100 kb) BAC clone on the long arm of garlic chromosome 7. The other BAC clone, GBC2-4d (approximately 110 kb), gave rise to discrete FISH signals on a mid-size early metaphase chromosome. The FISH screening with BAC clones proved to be a useful resource for molecular cytogenetic studies of garlic, and will be useful for further mapping and sequencing studies of important genes of this plant.     

A mathematical model of homologous recombination in cultured cells.

This work presents a model describing the rate of recombination between homologous segments of DNA stably integrated into the genome of cultured cells. The model has been applied to rat cell lines carrying the polyomavirus middle T oncogene and a functional origin of viral DNA replication. Introduction of the gene coding for the polyoma large T antigen or the SV40 large T antigen into cells by DNA transfection promotes homologous recombination in the resident viral inserts with rates varying between 0.1 x 10(-3) and 3.7 x 10(-1) per cell generation.     

An integrated map of human 6q22.3-q24 including a 3-Mb high-resolution BAC/PAC contig encompassing a QTL for fetal hemoglobin

Genetic studies have previously assigned a quantitative trait locus (QTL) for hemoglobin F and F cells to a region of approximately 4 Mb between the markers D6S408 and D6S292 on chromosome 6q23. An initial yeast artificial chromosome contig of 13 clones spanning this region was generated. Further linkage analysis of an extended kindred refined the candidate interval to 1-2 cM, and key recombination events now place the QTL within a region of <800 kb. We describe a high-resolution bacterial clone contig spanning 3 Mb covering this critical region. The map consists of 223 bacterial artificial chromosome (BAC) and 100 P1 artificial chromosome (PAC) clones ordered by sequence-tagged site (STS) content and restriction fragment fingerprinting with a minimum tiling path of 22 BACs and 1 PAC. A total of 194 STSs map to this interval of 3 Mb, giving an average marker resolution of approximately one per 15 kb. About half of the markers were novel and were isolated in the present study, including three CA repeats and 13 single nucleotide polymorphisms. Altogether 24 expressed sequence tags, 6 of which are unique genes, have been mapped to the contig.     

AAV-mediated gene targeting methods for human cells

Gene targeting with adeno-associated virus (AAV) vectors has been demonstrated in multiple human cell types, with targeting frequencies ranging from 10(-5) to 10(-2) per infected cell. These targeting frequencies are 1-4 logs higher than those obtained by conventional transfection or electroporation approaches. A wide variety of different types of mutations can be introduced into chromosomal loci with high fidelity and without genotoxicity. Here we provide a detailed protocol for gene targeting in human cells with AAV vectors. We describe methods for vector design, stock preparation and titration. Optimized transduction protocols are provided for human pluripotent stem cells, mesenchymal stem cells, fibroblasts and transformed cell lines, as well as a method for identifying targeted clones by Southern blots. This protocol (from vector design through a single round of targeting and screening) can be completed in ～10 weeks; each subsequent round of targeting and screening should take an additional 7 weeks.