Selective transfer of individual human chromosomes to recipient cells.

Two hypoxanthine phosphoribosyltransferase-deficient human cell lines, D98/AH-2 and HT1080-6TG, were stably transfected with pSV2 gpt, a plasmid containing the selectable marker Escherichia coli xanthine-guanine phosphoribosyl transferase (Eco gpt). Hypoxanthine-aminopterin-thymidine-resistant transformants arose with a frequency of ca. 10(-6) and contained mostly single, but occasionally multiple, copies of the plasmid sequences. These transformants actively express the Eco gpt marker. Single chromosomes from two different HT1080 gpt transformants and one D98 gpt transformant, containing the integrated plasmid sequences, were transferred via microcell-mediated chromosome transfer to hypoxanthine phosphoribosyl transferase-deficient mouse A9 cells. The transferred human chromosomes were identified as 2, 4, and 22, by using a combination of G-11 staining, G-banding, isoenzyme analysis, and in situ hybridization. This system is being used to create a library of interspecies microcell hybrid clones, each clone containing a unique single human chromosome in a mouse background. The complete library will represent the entire human karyotype.     

Number and size of human X chromosome fragments transferred to mouse cells by chromosome-mediated gene transfer.

Labeled probes of unique-sequence human X chromosomal deoxyribonucleic acid, prepared by two different procedures, were used to measure the amount of human X chromosomal deoxyribonucleic acid in 12 mouse cell lines expressing human hypoxanthine phosphoribosyltransferase after chromosome-mediated gene transfer. The amount of X chromosomal deoxyribonucleic acid detected by this procedure ranged from undetectable levels in the three stable transformants and some unstable transformants examined to about 20% of the human X chromosome in two unstable transformants. Reassociation kinetics of the X chromosomal probe with deoxyribonucleic acid from the two unstable transformants containing 15 to 20% of the human X chromosome indicate that a single copy of these sequences is present. In one of these lines, the X chromosomal sequences exist as multiple fragments which were not concordantly segregated when the cells were selected for loss of hprt.     

Molecular cloning of genomic DNA segments partially coding for human thymidylate synthase from the mouse cell transformant

Mouse cells deficient in the enzyme thymidylate synthase [TS; EC 2.1.1.45] were serially transformed with human DNA to yield primary and secondary transformants which produced human TS [Ayusawa, D., Shimizu, K., Koyama, H., Takeishi, K., & Seno, T. (1983) J. Biol. Chem. 258, 48-53]. Southern blot hybridization of their genomic DNA showed that six secondary transformants examined contained in common a 5.5 kb EcoRI fragment hybridized with a human Alu sequence. From the secondary transformant genomic library constructed with phage lambda Charon 4A, two recombinant phage clones carrying Alu sequences were isolated. Restriction endonuclease mapping revealed that the insert DNAs of the two phage clones overlapped and covered a region of 19 kb in total. Within this region at least six Alu sequences were located. A 2.0 kb DNA fragment, prepared from an EcoRI fragment subcloned in plasmid pBR322 and free of Alu sequences, hybridized to a single band on RNA blots of primary and secondary transformant poly(A)+ RNA, but not to RNA of mouse wild-type and recipient cell lines. The relative amount of the presumed human TS mRNA was linearly correlated with the relative activity of human TS in various types of mouse transformant cells. These results indicate that these two phage clones contain genomic DNA sequences encoding human TS.     

Isolation and characterization of two repetitive DNA fragments located near the centromere of the mouse X chromosome

Two repetitive DNA fragments located on the mouse X chromosome are described. The fragments were isolated from a lambda phage library enriched in X-chromosomal sequences by flow sorting. Both fragments, which are repeated 20 to 50 times in the genome, were mapped to the mouse X chromosome by Southern blot hybridization to DNA from hybrid cells retaining the mouse X chromosome, by dosage analysis, and by in situ hybridization to mouse chromosomes. In mouse strain C57BL/10BK, one fragment appeared to be located only on the X chromosome, while the other fragment had homologous sequences on chromosome 11 in addition to the X chromosome. The latter fragment showed DNA variants between mouse strains, which are potentially useful for mapping. Both fragments cross-hybridized to another mouse species: Mus caroli. In this species, each fragment appeared to be located on the X chromosome, indicating that some X-chromosome repetitive sequences are partially conserved. In addition, one fragment cross-hybridized to human DNA.     

Localization of the human thyroxine-binding globulin gene to the long arm of the X chromosome (Xq21-22).

Thyroxine-binding globulin (TBG) is the major thyroid-hormone transport protein in the plasma of most vertebrate species. A recombinant phage (lambda cTBG8) containing a cDNA insert of human TBG recently has been described. With the cDNA insert from lambda cTBG8 used as a radiolabeled probe, DNA from a series of somatic-cell hybrids containing deletions of the X chromosome was analyzed by means of blot hybridization. The results indicated that the TBG gene is located in the midportion of the long arm of the X chromosome between bands Xq11 and Xq23. The gene then was mapped to band region Xq21-22 by means of in situ hybridization to metaphase chromosomes. Sequences on the X chromosome that are homologous to the cDNA probe are contained within a single EcoRI restriction fragment of 12.5 kb in human DNA. On the basis of the intensity of the hybridization signal on Southern blots, it was determined that the human TBG cDNA probe used in the present study shares significant homology with hamster and mouse sequences. A single EcoRI restriction fragment was recognized in both hamster (8.0-kb) and mouse (5.1-kb) DNA.     

Temperature-dependent plasmid integration into and excision from the chromosome of Bacillus stearothermophilus

A transformant of Bacillus stearothermophilus carrying a recombinant plasmid, pLP11 (9.5 MDa), on which the penicillinase gene (penP) and kanamycin resistance gene (kan) were located was subjected to mutagenesis, and a mutant plasmid (9.5 MDa; penP kan), designated pTRA117, was obtained. A transformant of B. stearothermophilus carrying pTRA117 could grow at 63 degrees C in medium containing kanamycin, whereas a transformant carrying pLP11 could not. Although pTRA117 was detected as covalently closed circular (ccc) DNA when it was extracted from transformants cultured at 48 degrees C, it was integrated into the host chromosome when the culture temperature was shifted up to 63 degrees C. If the culture temperature was lowered to 48 degrees C from 63 degrees C, a new plasmid (10.7 MDa; penP kan), designated pTRZ117, could be detected as ccc DNA; the size of this plasmid suggested that it was pTRA117 plus a 1.2 MDa DNA fragment of the host chromosome, and this was confirmed by Southern hybridization. pTRZ90 (7.9 MDa; kan) was constructed from pTRZ117 by the deletion of a 2.8 MDa DNA fragment that contained penP. Fresh transformants of B. stearothermophilus that carried either pTRZ117 or pTRZ90 could grow at 65 degrees C.     

Assignment of the human granulocyte colony-stimulating factor receptor gene (CSF3R) to chromosome 1 at region p35-p34.3.

The gene for the granulocyte colony-stimulating factor (G-CSF) receptor (CSF3R) was localized on the p35-p34.3 region of human chromosome 1 by in situ hybridization using human G-CSF receptor cDNA as the probe. Polymerase chain reaction using oligonucleotides specific for the human CSF3R produced a specifically amplified DNA fragment with DNA from mouse A9 cells that contained human chromosome 1 but not other human chromosomes. Localization of the CSF3R on chromosome 1 was further confirmed by the spot-blot hybridization of sorted human chromosomes.     

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.     

Assignment of the human granulocyte colony-stimulating factor receptor gene (CSF3R) to chromosome 1 at region p35–p34.3

The gene for the granulocyte colony-stimulating factor (G-CSF) receptor (CSF3R) was localized on the p35–p34.3 region of human chromosome 1 by in situ hybridization using human G-CSF receptor cDNA as the probe. Polymerase chain reaction using oligonucleotides specific for the human CSF3R produced a specifically amplified DNA fragment with DNA from mouse A9 cells that contained human chromosome 1 but not other human chromosomes. Localization of the CSF3R on chromosome 1 was further confirmed by the spot-blot hybridization of sorted human chromosomes.     

Transforming DNA sequences present in human prolactin-secreting pituitary tumors.

Five human PRL-secreting pituitary tumors were tested for the presence of DNA-transforming sequences. After calcium phosphate transfection to NIH-3T3 mouse fibroblast cells, DNA samples derived from two prolactinomas induced foci of morphologically transformed cells which subsequently grew in soft agar. After retransfection of transformant DNA, resulting secondary transformants elicited rapidly growing solid tumors in nude mice. Southern analysis of transformant DNA revealed the integration of Alu-positive human DNA sequences into the mouse fibroblast NIH-3T3 cells, as judged by hybridization to a Blur-8 probe. The Alu signal became increasingly more difficult to detect with the multiple passaging (greater than 20) of transformant cells in culture. Alu polymerase chain reaction (PCR) was, therefore, used to selectively amplify human DNA sequences from the NIH-3T3 rodent background. PCR using a human Alu-specific primer resulted in amplification of an Alu-containing DNA region within these transformants. The transformant DNA did not hybridize to human genomic probes for genes known to evoke focus formation in this assay, including H-ras, K-ras, N-ras, trk, ret, ros, or met. Further identification of the Alu-containing region revealed that it contained sequences from the human hst gene, a member of the fibroblast growth factor family. The presence of human hst was demonstrated by strong hybridization to a 40-mer oligonucleotide probe to the second exon of hst, by amplification of this region with human hst-nested amplimers within the first and second introns, and finally by direct sequencing.(ABSTRACT TRUNCATED AT 250 WORDS)     

A Transforming Marker That Produces Merodiploids with High Efficiency and Stable Transformants with Low Efficiency in Streptococcus

A mutation (ery-r8) conferring a high level of resistance to erythromycin in the Challis strain of Streptoccus sanguis can be transferred to wild-type erythromycin-sensitive recipients via single molecules of donor DNA. The transformants thus produced are of two types: (1) cells slightly more resistant to erythromycin than wild-type and capable of segregating (at a frequency of 2 X 10(-4)/bacterium/generation) either wild-type or highly-resistant cells like the original donor type; (2) cells phenotypically and genotypically identical to the original donor type. The unstable diploids (ery-r8/+) occur with a frequency equivalent to that obtained with high-efficiency (HE) markers, whereas the stable donor-type (ery-r8) transformants occur with about five hundred times lower frequency. Penetration of the wild-type recipient by more than one molecule of DNA bearing the ery-r8 marker increases by as much as seven times the incidence of stable transformants. UV-irradiation of molecules bearing the ery-r8 marker diminishes their ability to cooperate in producing a stable transformant, although the UV sensitivity of stable transformant production by a single DNA molecule is not different from that of diploid production. Hence, stable transformants do not appear to be produced by a process typical of low efficiency (LE) markers, which are generally highly sensitive to ultraviolet irradiation. Moreover, stable ery-r8 transformants are produced with equally low frequencies in strains of S. pneumoniae that discriminate (hex+) and fail to discriminate (hex--) between HE and LE markers. We postulate that all transformations by the ery-r8 marker result in ery-r8/+ diploids, and that segregation results in the infrequent stable transformants of the original donor type. This hypothesis is supported by the observations that rifampin treatment of ery-r8/+ populations increases the frequency of segregation and similar treatment of wild-type recipients under-going transformation by the ery-r8 marker increases the frequency of stable transformants.--In producing the ery-r8/+ transformant the r8 allele is integrated close to the site of its wild-type homolog, since single molecules of DNA from this transformant can be shown to carry both alleles. Segregation of either the ery-r8 or + allele is not detectably enhanced by acridine orange or thymidine deprivation.--The ery-r8 marker occurs close to a site of mutation (ery-r2) which confers erythromycin resistance upon ribosomes. When the r2 and r8 markers are jointly transferred, ery-r2-r8/+ genomes are produced in which the r2 marker is stably integrated but the r8 marker is unstably adjoined to its wild-type homolog. Thus, the duplicated region can be quite short. When the ery-r8 marker is stably integrated, the region of the marker is refractory to subsequent transformation. Markers with properties like ery-r8 are not particularly rare, being found with a frequency of about 4% among spontaneous mutations to erythromycin resistance.     

HRAS1-selected, chromosome mediated gene transfer; in situ hybridization with combined biotin and tritium label localizes the oncogene and reveals duplications of the human transgenome

Chromosomes isolated from a human bladder carcinoma cell line which contains the actively transforming oncogene HRAS1 on chromosome 11 can be used to transform mouse cells. We have analyzed these chromosome mediated gene transformants by in situ hybridization techniques using biotinylated human DNA and a double antibody detection system to visualize the whole of the transgenome in a number of cell lines. In some transformants, where the amount of the transgenome was below the level of detection by the simple biotin system, we used a gold-silver enhancement technique. We have developed a combined in situ hybridization procedure using biotinylated human DNA plus antibodies and 3H-labeled HRAS1 DNA plus autoradiography to locate the actively transforming oncogene within the human transgenome in a selection of these transformants. In each of these there were complex insertions of the transgenome, either at multiple sites or with duplicated inserts at a single site. Each insertion contained a copy of HRAS1. The double in situ hybridization analysis helps define the types of arrangement and rearrangement which can accompany the chromosome mediated gene transfer process and, consequently, the potentials and limitations of the technique as a somatic cell and molecular genetic tool. Our analysis also suggests that multiple copies of the HRAS1 gene may be needed for stable transformation.     

DNA-mediated gene transfer without carrier DNA

DNA-mediated gene transfer is a procedure which uses purified DNA to introduce new genetic elements into cells in culture. The standard DNA-mediated gene transfer procedure involves the use of whole cell DNA as carrier DNA for the transfer. We have modified the standard DNA-mediated gene transfer procedure to transfer the Herpes simplex virus type 1 thymidine kinase gene (TK) into TK- murine recipient cells in the absence of whole cell carrier DNA. The majority (8/10) of carrier-free transformant lines expressed the TK+ phenotype stably, in sharp contrast to our results with carrier-containing DNA-mediated gene transfer. There was a wide range in donor DNA content among independent transformants. Further analysis on one transformant line using DNA restriction digests and in situ hybridization provided evidence that, in the absence of whole cell carrier DNA, multiple donor DNA sequences became integrated at a single chromosomal site.     

Molecular cytogenetic analysis of the highly repetitive DNA in the genome of Apodemus argenteus, with comments on the phylogenetic relationships in the genus Apodemus.

The DNA of Apodemus argenteus was digested with DraI, and the resultant DraI fragment of highly repetitive DNA was isolated and analyzed by DNA filter hybridization, cloning, sequencing, and fluorescence in situ hybridization (FISH). Southern blot hybridization and nucleotide sequencing revealed that most of the DraI fragment consisted of a 230-bp repeating unit and contained no sex-chromosome-specific nucleotide sequences. The DraI fragment included the CENP-B box-like sequence, with a strong homology to the human CENP-B box sequence. FISH revealed that the DraI fragment was specific to all pericentromeric C-band-positive regions, as well as to the C-block of the X chromosome. No hybridization signals were obtained from A. speciosus, A. peninsulae peninsulae, A.p. giliacus, A. agrarius, A. sylvaticus, A. semotus, or Mus musculus when the DraI fragment was used as probe. Peptide nucleic acid (PNA)-FISH using the CENP-B box-like sequence in the DraI fragments as probe suggested that this nucleotide sequence was also specific to all pericentromeric C-heterochromatic regions of A. argenteus chromosomes. Zoo-blot hybridization using DraI-digested genomic DNA from three species of Apodemus (namely, A. argenteus, A. speciosus, and A. peninsulae) and from Mus musculus strongly suggested that the consensus DraI fragment contained nucleotide sequences that were species-specific for A. argenteus. These results also suggest that A. argenteus is phylogenetically distant from other Apodemus species examined, as well as the possibility that the DraI fragment might be related directly to the delayed quinacrine mustard fluorescence of many pericentromeric C-heterochromatic regions of the chromosomes in A. argenteus.     

Unstable transformation of mouse 3T3 cells by transfection with DNA from normal human lymphocytes.

DNA fragments (0.5-4.5 kb) of normal human lymphocytes induced pre-neoplastic mouse NIH/3T3 cells after transfection to grow in soft agar medium at low efficiency (0.0007 colonies/micrograms DNA/10(6) cells). In secondary transfections high mol. wt. DNA (greater than 20 kb) of cells transformed by DNA fragments induced neoplastic transformation with high efficiency (0.16-1.1 soft agar colonies/micrograms DNA/10(6) cells). These results confirm previous data obtained by others with chicken and mouse donor DNA. We describe here that independent secondary transformants harbored human Alu repetitive DNA sequences on similar restriction fragments and formed progressively growing tumors in BALB/c mice or nude mice. The corresponding primary transformants were not tumorigenic, however, and the ability to proliferate in semi-solid agar medium was gradually lost when the cells were grown as non-confluent monolayers. Furthermore, in contrast to secondary transformants, DNA from primary transformants showed only relatively weak hybridization to a human Alu repetitive DNA probe. We conclude that in primary transformants the transformed phenotype is expressed in an unstable fashion whereas secondary transformants appear to be stably transformed.     

Molecular cloning, primary structure and expression of the human X linked A1S9 gene cDNA which complements the ts A1S9 mouse L cell defect in DNA replication.

The temperature-sensitive ts A1S9 mutation of mouse L cells was previously shown to affect nuclear DNA replication and to be complemented by active and inactive human X chromosomes in human-ts A1S9 somatic cell hybrids. We report the isolation of cDNA clones which correct the ts A1S9 lesion, using as a probe a genomic fragment derived from the human A1S9 locus. The nucleotide sequence of the A1S9 cDNA encompasses a single open reading frame of 2409 bp which could encode a heretofore unreported protein of 90 393 daltons. Southern blot hybridization of the A1S9 cDNA probe with DNA from various species revealed homologous sequences in vertebrates but not in yeast. Northern blot analysis of serum-starved, synchronized cells demonstrated that the A1S9 gene was expressed at a relatively low level in quiescent cells and at a higher and constant level throughout the cell cycle. Human cell lines harbouring increasing numbers of inactive X chromosomes (47, XXX, 49, XXXXX) were found to express the A1S9 gene at the same level as control cells (45, X), suggesting that the gene does not escape X chromosome inactivation.     

The use of cell surface antigens to characterize and select for fragments of human chromosomes retained by interspecies hybrids

We have used a mouse cell transformant generated by human chromosome-mediated gene transfer (CMGT) to explore the use of cell surface antigens in the identification of fragments of human chromosomes retained by somatic cell hybrids. The transformed line, 21-30b, contained an intact rear-ranged human chromosome, and could be shown by isozyme analysis to contain genetic material from chromosomes 9 and X. By using the transformant as an immunogen in mice, it was also possible to produce antiserum to human-specific surface antigens. Using genetically characterized human X rodent hybrid lines, the genes controlling expression of these antigens could be localized to 11per----11p13, segregating concordantly with surface antigen S3. These conclusions were possible despite the fact that the presence of chromosome 11 in the transformant was not detectable by the presence of chromosome specific isozyme LDH-A or surface antigens W6/34 and 4F2. Finally, the fluorescence-activated cell sorter (FACS) was used to fractionate the transformant cells into antigen positive and negative subpopulations. This resulted in the isolation and characterization of four additional chromosome rearrangements involving interspecies chromosome translocations. This work demonstrates the value of chromosome-specific surface antigens and the FACS in the evaluation of human chromosome fragments retained by interspecies hybrids.     

Assignment of the human collagen alpha 1 (XIII) chain gene (COL13A1) to the q22 region of chromosome 10

Type XIII collagen is a recently described collagen that resembles in structure the short-chain collagens of types IX, X, and XII. Unlike any other collagen, the type XIII is found in several different forms generated through alternative splicing. A 2.0-kb genomic fragment from the human alpha 1 (XIII) collagen gene was isolated and shown by DNA sequencing to contain exon 12 as counted from the 3' end. This fragment was used as a probe to localize the gene. The gene (COL13A1) was assigned to chromosome 10 by hybridization of the probe to DNA isolated from a panel of human-mouse somatic cell hybrids containing different human chromosomes. Furthermore, the gene was mapped to the q22 region by in situ hybridization to metaphase chromosomes.     

High-resolution chromosomal localization of the beta-gene of the human beta-globin gene complex by in situ hybridization

A 4.4-kb PstI fragment containing the entire beta-gene of the human beta-globin gene cluster plus both 5'- and 3'-flanking sequences was used as a probe to study the chromosomal localization of the beta-gene by in situ hybridization. Using random oligonucleotides as primers, the beta-gene DNA was 3H-labeled with the large fragment of DNA polymerase I (Klenow fragment) to a specific activity of 1.2 X 10(8) cpm/micrograms. Almost 80% of hybridization grains observed were located on the distal short arm of chromosome 11. High-resolution chromosome analysis suggests a more precise location of the beta-gene to region 11p15.4----p15.5.