Transfer of the human X chromosome to human--Chinese hamster cell hybrids via isolated HeLa metaphase chromosomes.

Evidence is presented for the uptake of the human X chromosome by human-Chinese hamster cell hybrids which lack H P R T activity, following incubation with isolated human HeLa S3 chromosomes. Sixteen independent clonal cell lines were isolated in H A T medium, all of which contained a human X chromosome as determined by trypsin-Giemsa staining. The frequency of H A T-resistant clones was 32 x 10(-6) when 10(7) cells were incubated with 10(8) HeLa chromosomes. Potential reversion of the hybrid cells in H A T medium was less than 5 x 10(-7). The 16 isolated cell lines all contained activity of the human X-linked marker enzymes H P R T, P G K,alpha-Gal A, and G6PD, as determined by electrophoresis. The phenotype of G6PD was G6PD A, corresponding to G6PD A in HeLa cells. The human parental cells used in the fusion to form the hybrids had the G6PD B phenotype. The recipient cells gave no evidence of containing human X chromosomes. These results indicate that incorporation and expression of HeLa X chromosomes is accomplished in human-Chinese hamster hybrids which lack a human X chromosome.     

Expression of human hypoxanthine phosphoribosyl transferase in Chinese hamster cells treated with isolated human chromosomes.

Chinese hamster cells deficient for the enzyme hypoxanthine phosphoribosyl transferase (HPRT) were incubated with isolated human metaphase chromosomes and 21 colonies were isolated in HAT medium. Three different types of cell lines were established from these clones. First, 4 cell lines had 10-30% of normal Chinese hamster HPRT activity with the same electrophoretic mobility as human HPRT. This HPRT activity remains detectable during at least 8 weeks of growth of the cells in nonselective medium. Second, 3 cell lines also had human-like HPRT with the same activity as the first type. This HPRT persists only if the cells are grown in HAT medium and disappears during 8 weeks of growth in nonselective medium. Third, other clones survived in HAT medium as well as in medium with 8-azaguanine. These cells had no detectable HPRT activity. Using differential chromosome staining techniques no recognizable human chromosome fragments were found in any of the cell lines.     

Molecular analysis of X-ray-induced mutants at the HPRT locus in V79 Chinese hamster cells

Spontaneous and X-ray-induced mutants at the hypoxanthine phosphoribosyl transferase (HPRT) locus have been isolated from V79 Chinese hamster cells and characterized at the biochemical and cytogenetic levels. Fourteen spontaneous and 24 X-ray-induced clones were azaguanine and thioguanine resistant, did not grow in HAT medium (AZRTGRHATS) and failed to incorporate significant levels of [14C]hypoxyanthine. Cytogenetic analysis of two spontaneous and eight X-ray-induced mutants revealed no major X chromosome rearrangements. In two induced mutants, one of which was hypotetraploid (mode 35-39) with 2 X chromosomes, the short arm of the chromosome (Xp) was slightly shorter than normal. A third mutant was hyperdiploid (mode 22-23) compared with the parental clone (mode 21). When compared with wild-type clones, no other cytogenetic changes were evident in the remaining mutants. Analysis at the DNA level using a Chinese hamster HPRT cDNA probe showed major deletion of HPRT sequences in two and partial deletion in another two induced mutants. In two of the mutants with deletions of HPRT sequences there was a visible shortening of the Xp arm. In the other six mutants two spontaneous and four induced) no karyotypic changes or alterations in restriction fragment patterns were detected suggesting that they carry small deletions or point mutations at the HPRT locus.     

Transfer of the human genes coding for thymidine kinase and galactokinase to Chinese hamster cells and human-Chinese hamster cell hybrids.

Cotransfer of two linked human genes, coding for the enzymes thymidine kinase (TK) and galactokinase (Gak) was demonstrated following incubation of Chinese hamster TK-deficient cells with isolated human chromosomes. The 5 colonies which were isolated all expressed a stable TK-positive phenotype. Cotransfer of the human genes coding for TK and Gak has also been observed in experiments in which isolated human chromosomes were incubated with TK-deficient human-Chinese hamster cell hybrids. These receipient hybrids had lost all human chromosomes at the time of incubation. From these experiments, four colonies were isolated, all expressing an unstable TK-positive phenotype. Using chromosome staining techniques, the presence of human chromosomes could not be demonstrated in either of the transformed clonal lines obtained with the Chinese hamster and the hybrid recipient cells. This indicates that incorporation of only the fragment of the human chromosome 17, bearing the genes for TK and Gak, has occurred in the recipient cells.     

Intraspecies transfer via total cellular DNA of the gene for hypoxanthine phosphoribosyltransferase into cultured mouse cells

Summary Under selective growth conditions a revertant of mouse cells, defective in hypoxanthine phosphoribosyltransferase activity (HPRT, EC-No. 2.4.2.8), was isolated, which contained an electrophoretically abnormal form of HPRT activity. The specific HPRT activity in crude extracts of the revertant cells is about 30% of the level determined in normal wild type cells. The variant HPRT reacts with antiserum against normal mouse HPRT but the rate of heat inactivation of the variant activity is different from the wild type form. By isozyme and karyotype analyses of somatic cell hybrids between the revertant mouse cells and Chinese hamster cells we found that the abnormal HPRT activity is coded for by the mouse X-chromosome as expected for a mutation in the structural HPRT gene.DNA has been purified from the abnormal HPRT revertant cells and incubated with mouse A9 cells (HPRT^-). After growth in selective medium one clone was isolated which expressed the electrophoretically abnormal form of HPRT. Six clones showed the normal form of HPRT due to reversion of the defective HRRT locus in A9 cells. This result indicates DNA-mediated transfer of the mouse HPRT gene at a frequency of about 0.5×10^-7. A similar frequency has been found for transfer of the variant HPRT locus via isolated metaphase chromosomes to A9 recipient cells. When placed in non-selective media the DNA-mediated transferent cells gradually lost their ability to express the HPRT transgenome at a rate of about 6% per average cell generation.     

Spontaneous cell hybridization of somatic cells present in sperm suspensions

Electron microscopic evidence suggests that sperm can be spontaneously incorporated by cultured cells but cytogenetic and biochemical evidence indicate that sperm do not introduce new genes into such cells with detectable frequency. Sperm suspensions from mouse or Chinese hamster epididymis or human semen were added to cultures of RAG, a mouse cell line which dies in HAT medium because of HPRT deficiency. In EMs, sperm appeared to be readily phagocytized and degraded by the cells. When sperm-treated cultures were transferred to HAT medium resistant clones arose at a frequency of about 10⁻⁶, or at least 25× the reversion rate of RAG. Most HAT-resistant clones had HPRT activity which migrated electrophoretically like HPRT of the sperm donor species, though one was apparently a spontaneous RAG revertant. Most HAT-resistant clones had some chromosomes of the sperm donor species. In human sperm× RAG clones, the array of human chromosomes suggested that the human parent had been diploid rather than haploid; some cells contained both homologues of a polymorphic pair and some contained both X and Y. Furthermore, some sperm suspensions plated alone into flasks generated colonies, thus revealing the presence of low numbers of viable somatic cells. Presence of contaminating somatic cells in a sperm suspension was correlated with ability to induce HAT-resistant colonies when the suspension was added to RAG cells. Taken together, the data suggest that correction of the HPRT deficiency of RAG by sperm suspensions occurs at very low frequency and is probably due to efficient spontaneous fusion of low numbers of contaminating somatic cells with RAG cells.     

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.     

Subchromosomal localization and order of GLA, PGK1, HPRT, and G6PD loci on the X chromosome of the American mink (Mustela vison)

Segregation of the X-linked mink markers alpha-galactosidase (GLA), phosphoglycerate kinase-1 (PGK1), hypoxanthine phosphoribosyltransferase (HPRT), and glucose-6-phosphate dehydrogenase (G6PD) was analyzed in hybrids of gamma-irradiated mink fibroblasts and Chinese hamster cells and in hybrids of nonirradiated mink fibroblasts and mouse hepatoma cells. Based on this analysis, the order of the four genes is GLA-PGK1-HPRT-G6PD on the mink X chromosome. Cytogenetic analysis of five mink x Chinese hamster hybrid clones containing mink GLA, PGK1, and HPRT, but lacking G6PD, tentatively localized mink G6PD to Xq15.22----qter and also confirmed the gene order as GLA-PGK1-HPRT-G6PD-qter. Comparison of this order with its counterpart in man and the mouse, as well as an analysis of the G-band patterns of their X chromosomes, demonstrated putative similarities between mink and man and differences in the mouse. These differences may be due to a different rate of X-chromosomal rearrangement in mammalian evolution.     

The distribution of 4 genes (alpha GAL, PGK-1, HPRT and G6PD) on the X chromosome of the American mink (Mustela vison)

The segregation of X-linked markers (alpha GAL, PGK-1, HPRT and G6PD) was analysed in hybrids between gamma ray-irradiated mink fibroblasts and Chinese hamster cells, or between mink cells and mouse hepatoma cells. Based on the segregation data and the data of cytogenetics analysis of a few hybrids, the order of the mink genes was deduced as alpha GAL--PGK-1--HPRT--G6PD--qter. This order differs from that reported for human and murine genes, in spite of the very obvious similarity between G-banding of the mink and human X chromosomes. Therefore, at least one reversion is responsible for the differences observed for the human and mink X chromosomes.     

Spontaneous reactivation of the inactive X chromosome in mouse embryonal carcinoma cells

The mouse embryonal carcinoma cell line MC12 carries two X chromosomes, one of which replicates late in S phase and shares properties with the normal inactive X chromosome and, therefore, is considered to be inactivated. Since the hypoxanthine phosphoribosyl transferase (HPRT) gene on the active X chromosome is mutated (HPRT(NDASH;)), MC12 cells lack HPRT activity. After subjecting MC12 cells to selection in HAT medium, however, a number of HAT-resistant clones (HAT(R)) appeared. The high frequency of HAT resistance (3.18 x 10(-4)) suggested reactivation of HPRT(PLUS;) on the inactive X chromosome rather than reversion of HPRT(NDASH;). Consistent with this view, cytological analyses showed that the reactivation occurred over the length of the inactive X chromosome in 11 of 20 HAT(R) clones isolated. The remaining nine clones retained a normal heterochromatic inactive X chromosome. The spontaneous reactivation rate of the HPRT(PLUS;) on the inactive X chromosome was relatively high (1.34 x 10(-6)) and comparable to that observed for XIST-deleted somatic cells (Csankovszki et al., 2001), suggesting that the inactivated state is poorly maintained in MC12 cells.     

Reexpression of HPRT activity following cell fusion with polyethylene glycol

Polyethylene glycol-1000 (PEG-1000) induced fusion of HPRT (E.C. 2.4.2.8) deficient Chinese hamster cells with -galactosidase A (E.C. 2.3.1.22) deficient cells from a patient with Fabry's disease yielded hybrids which contained both human and hamster HPRT, G6PD (E.C. 1.1.1.49), and APRT (E.C. 2.4.2.7) and Chinese hamster -galactosidase B. Thus PEG-1000 mediated somatic cell fusion led to reexpression of Chinese hamster HPRT. It did not restore the expression of human -galactosidase. Since PEG-1000 treatment of HPRT^– Chinese hamster cells in the absence of human cells yielded no HPRT⁺ cells, it is concluded that the element responsible for the restoration of rodent HPRT was contributed by the human cells and not by the agent employed to promote fusion.This work was supported by research grants from the United States Public Health Services GM 17702, from the National Science Foundation BMS 74-21424, and from the National Foundation March of Dimes 1-377.     

Construction of a defective retrovirus containing the human hypoxanthine phosphoribosyltransferase cDNA and its expression in cultured cells and mouse bone marrow.

Defective ecotropic and amphotropic retroviral vectors containing the cDNA for human hypoxanthine phosphoribosyltransferase (HPRT) were developed for efficient gene transfer and high-level cellular expression of HPRT. Helper cell clones which produced a high viral titer were generated by a simplified method which minimizes cell culture. We used the pZIP-NeoSV(X) vector containing a human hprt cDNA. Viral titers (1 X 10(3) to 5 X 10(4)/ml) of defective SVX HPRT B, a vector containing both the hprt and neo genes, were increased 3- to 10-fold by cocultivation of the ecotropic psi 2 and amphotropic PA-12 helper cells. Higher viral titers (8 X 10(5) to 7.5 X 10(6] were obtained when nonproducer NIH 3T3 cells or psi 2 cells carrying a single copy of SVX HPRT B were either transfected or infected by Moloney leukemia virus. The SVX HPRT B defective virus partially corrected the HPRT deficiency (4 to 56% of normal) of cultured rodent and human Lesch-Nyhan cells. However, instability of HPRT expression was detected in several infected clones. In these unstable variants, both retention and loss of the SVX HPRT B sequences were observed. In the former category, cells which became HPRT- (6-thioguanine resistant [6TGr]) also became G418s, indicative of a cis-acting down regulation of expression. Both hypoxanthine-aminopterin-thymidine resistance (HATr) and G418r could be regained by counterselection in hypoxanthine-aminopterin-thymidine. In vitro mouse bone marrow experiments indicated low-level expression of the neo gene in in vitro CFU assays. Individual CFU were isolated and pooled, and the human hprt gene was shown to be expressed. These studies demonstrated the applicability of vectors like SVX HPRT B for high-titer production of defective retroviruses required for hematopoietic gene transfer and expression.     

Association of human chromosome 14 with a ts defect in G1 of Chinese hamster K12 cells.

Somatic cell hybrids between human lymphoblastoid cells (Raji) and temperature-sensitive Chinese hamster cells (K12) were selected from monolayer cultures in MEM at 40 degrees C. A total of 21 hybrid clones were isolated and karyotyped. All clones contained a near complete set of Chinese hamster chromosomes and 1 to 5 human chromosomes. Human chromosome 14 present in the hybrid cells of all clones; and was the only human chromosome retained in 10 clones. The presence of human chromosome 14 in hybrids was further confirmed by the demonstration of human nucleoside phosphorylase activity in the hybrid cells. Only one hybrid clone was positive for EBNA, the Epstein-Barr virus antigen present in Raji cells. These findings indicate that human chromosome 14 contains the necessary information for the K12 cells to overcome their G1 defect in the cell cycle and grow at non-permissive temperature. The present study lends strong support to the possibility that different steps in the G1 phase of the cell cycle are controlled by genes located on different chromosomes.     

Chinese hamster x American mink somatic cell hybrids: characterization of a clone panel and assignment of the mink genes for malate dehydrogenase,NADP-1 and malate dehydrogenase,NAD-1

Summary Chinese hamster x American mink somatic cell hybrids were obtained and examined for chromosome content and expression of mink malate dehydrogenase, NADP (MOD-1; EC 1.1.1.40), malate dehydrogenase, NAD (MOR-1; EC 1.1.1.37), glucose-6-phosphate dehydrogenase (G6PD; EC 1.1.1.49) and hypoxanthine phosphoribosyltransferase (HPRT; EC 2.4.2.8). All the hybrid clones examined were found to segregate mink chromosomes. A clone panel containing 25 clones was set up. The possibilities and limitations of this panel for mink gene mapping are analysed. Using this panel, it is feasible to rapidly map genes located on chromosomes 1–13 and to provisionally assign genes located on chromosome 14 and the X. Based on the data obtained, the genes for MOD-1 and MOR-1 were firmly assigned to mink chromosomes 1 and 11, respectively, and the genes for G6PD and HPRT were provisionally assigned to the X.     

Segregation of rat chromosomes in somatic cell hybrids between rat cells and HT 1080 human fibrosarcoma cells

Summary We produced somatic cell hybrids between HT 1080-6TG human fibrosarcoma cells and either rat white blood cells (WBC) or cells directly derived from rat spleen. Karyologic and isozyme analyses of hybrid cells indicated that they preferentially lose rat chromosomes. Hypoxanthine-aminopterine thymidine-selected hybrid clones expressing rat hypoxanthine phosphoribosyltransferase (HPRT), glucose-6-phosphate dehydrogenase (G6PD), and phosphoglycerate kinase (PGK) and containing the rat X chromosome were counterselected in a medium containing 30 g/ml of 6-thioguanine. Concordant loss of the rat X chromosome and of the expression of rat HPRT and G6PD was observed in the hybrid clones.     

用人DNA介导的基因转移修复中国仓鼠细胞的HPRT缺陷

 中国仓鼠卵巢细胞(CHO-K1)经N-甲基-N'-硝基-N-亚硝基胍(MNNG)诱变和6-巯基鸟嘌呤(6-TG)选择,得到稳定的次黄嘌呤磷酸核糖转移酶(HPRT)缺陷细胞株,酶活性仅为野生型的6.5％。用磷酸钙共沉淀法和电脉冲法向HPRT-细胞转移人宫颈癌细胞(HeLaS_3)基因组DNA,纠正了CHO细胞的HPRT缺陷。酶活性提高了6.9倍,达到野生型的45％。用Alu序列探针进行分子杂交,证实经过基因转移并连续传代15次以上的受体细胞中含人DNA序列。表明人的有关基因已稳定地整合到CHO细胞的染色体中。     

Centromeric index measurement by slit-scan flow cytometry

We report here the application of slit-scan flow cytometry (SSFCM) in the classification of muntjac, Chinese hamster, and human chromosomes according to centromeric index (CI) and total fluorescence. Chromosomes were isolated from mitotic cells, stained with propidium iodide and processed through the SSFCM where fluorescence profiles were measured. The centromere for each profile was taken as the point of maximum difference between the measured profile and a standard profile having no centromeric dip. The areas under the profile on either side of the centromere were then calculated and the CI was calculated as the ratio of the larger area to the total area under the profile. Relative DNA contents for each chromosome were taken to be proportional to the total fluorescence. Mean CI's for muntjac chromosomes 1, 2, and X + 3 were 0.52, 0.88, and 0.73, respectively; CI's for Chinese hamster M3-1 chromosomes 1, 2, 5, 8, and M2 were 0.53, 0.55, 0.57, 0.77, and 0.86, respectively; and average CI's for chromosome groups 4 + t (X;5), 6 + 7 + Y, 9 + M1, and 10 + 11 were 0.56, 0.82, 0.58, and 0.60, respectively. These results were, on average, within 4.4% of CI measurements made by image cytometry. CI's measured for human chromosomes 9 through 12, were, on average, within 2.0% of those made by image cytometry.     

Requirement of human chromosomes 19, 6 and possibly 3 for infection of hamster x human hybrid cells with baboon M7 type C virus.

The replication pattern of the endogenous baboon type C virus M7 was studied in 29 primary Chinese hamster × human hybrid clones generated with leukemic cells from two different patients with acute lymphoblastic or myeloblastic leukemia. There was no evidence of viral particulate RDDP or M7 antigen before viral infection. M7 virus replicated in human and some hybrid cells but not in Chinese hamster cells, indicating that M7 requires dominantly expressed human gene(s) for replication. Enzyme and cytogenetic analyses show that a gene(s) coded for by human chromosome 19 is necessary for M7 infection of these hybrids. Detailed cytogenetic correlations revealed, however, that the chromosome 19+/M7 + hybrid clones with intact chromosomes also had copies of chromosomes 3 and 6. Previously, Bevi, the putative integration site for M7 virus, has been assigned to human chromosome 6. Many clones with various combinations of chromosomes 3 and 6 lacked chromosome 19, however, and failed to replicate exogenously applied M7 virus, while tests of 27 secondary clones showed that M7 markers co-segregated with chromosome 19 markers. These findings all confirm the need for a chromosome 19-coded function in Chinese hamster × human hybrids. In addition, the yield of viral particulate RDDP produced into the culture fluid was 50–100 fold less per viral antigen-positive cell in the hybrids compared with human cells. Thus some form of regulation of viral components exists in the hybrid cells. When the virus replicating in hybrid cells was transferred back to human cells, this regulation was relaxed and the yield of RDDP per FA(+) cell greatly increased. We conclude that human chromosomes 6 and 19 code for functions involved in M7 virus metabolism, and we cannot exclude a function coded for by chromosome 3.