Efficient procedure for transferring specific human genes into Chinese hamster cell mutants: interspecific transfer of the human genes encoding leucyl- and asparaginyl-tRNA synthetases

Atypical X-chromosome inactivation in an X;1 translocation patient demonstrating Xq28 functional disomy

X-chromosome inactivation (XCI) is an epigenetic process used to regulate gene dosage in mammalian females by silencing genes on one X-chromosome. While the pattern of XCI is typically random in normal females, abnormalities of the X-chromosome may result in skewing due to disadvantaged cell growth. We describe a female patient with an X;1 translocation [46,X,t(X;1)(q28;q21)] and unusual pattern of XCI who demonstrates functional disomy of the Xq28 region distal to the translocation breakpoint. There was complete skewing of XCI in the patient, along with the atypical findings of an active normal X chromosome and an inactive derivative X. Characterization of the translocation revealed that the patient's Xq28 breakpoint interrupts the DKC1 gene. Molecular analysis of the breakpoint region revealed functional disomy of Xq28 genes distal to DKC1. We propose that atypical XCI occurred in the patient due to a post-inactivation cell selection mechanism likely initiated by disruption of DKC1. As a result, the pattern of XCI is opposite that of the expected for an X;autosome translocation. Therefore, we suggest the phenotypic abnormalities found in the patient are a result of functional disomy in the Xq28 region.

A radiation hybrid map of human chromosome 5 with integration of cytogenetic, genetic, and transcript maps

One of the major goals of the human genome project is to establish a physical map of each human chromosome with a density of sequence-tagged site (STS) markers exceeding one every 100 kb. We report here the generation of a human chromosome 5-specific radiation hybrid (RH) map that includes 556 markers. Of these markers, 132 loci are ordered with a maximum likelihood ratio of >1000:1 compared with the next most likely order. An additional 113 loci were ordered relative to these backbone markers with a maximum likelihood ratio of >10:1 but <1000:1. Together, these 245 loci form an ordered framework map for the chromosome. Using this framework, >300 more markers were localized based on two-point analysis with the ordered set. On average, there are 50 markers in common with the RH map presented here and other chromosome 5 maps included in the current whole genome cytogenetic, genetic, and physical maps. The accuracy of all the maps is evident in that there are no more than two discrepancies between any one of them and these data. All of the maps encompassing chromosome 5 complement each other providing excellent STS coverage with >2200 loci combined. The chromosome 5-specific RH map contains 20% of these independent loci. In addition, our RH map contains STSs derived from clones suitable for fluorescent in situ hybridization, allowing alignment to the cytogenetic map. Together, these maps will assist in the assembly of sequence-ready contigs and will aid in the identification of disease loci on chromosome 5 by positional cloning and positional candidate approaches.

An estimate of the number of genes in the Huntington disease gene region and the identification of 13 transcripts in the 4p16.3 segment

Physical mapping and genetic linkage studies have positioned the Huntington disease (HD) gene to a relatively large genomic region in the distal portion of the short arm of human chromosome 4 (4p16.3). To estimate the number of genes present in this region and to identify candidate disease genes, several clones that map to the 4p16.3 segment have been examined for clusters of CpG-rich restriction sites and transcribed sequences. Thirteen expressed sequences were identified and were shown by pulsed-field gel electrophoresis not to cluster into a small segment of the 4p16.3 band. The frequency of transcripts in these clones suggests that the putative HD gene region contains about 100 genes.

A radiation hybrid map of 18 growth factor, growth factor receptor, hormone receptor, or neurotransmitter receptor genes on the distal region of the long arm of chromosome 5

The distal portion of the long arm of human chromosome 5 contains an impressive number of genes encoding growth factors, growth factor receptors, and hormone/neurotransmitter receptors. The order of and relative distance between 18 of these genes was determined by radiation hybrid mapping. There is only a single gap in a contiguous radiation map from 5q22-5q35. For this set of radiation hybrids, one map unit (centiray) corresponds to 20-50 kb of DNA. Close physical proximity for several pairs of loci was predicted by the map. Two sets of these were found to be contained in single YAC clones. The physical map produced by radiation hybrid mapping should prove useful in efforts to identify four disease genes that have been assigned to distal 5q by linkage studies.

Double-minute chromosomes as megabase cloning vehicles

Radiation-reduced chromosomes provide valuable reagents for cloning and mapping genes, but they require multiple rounds of x-ray deletion mutagenesis to excise unwanted chromosomal DNA while maintaining physical attachment of the desired DNA to functional host centromere and telomere sequences. This requirement for chromosomal rearrangements can result in undesirable x-ray induced chromosome chimeras where multiple non-contiguous chromosomal fragments are fused. We have developed a cloning system for maintaining large donor subchromosomal fragments of mammalian DNA in the megabase size range as acentric chromosome fragments (double-minutes) in cultured mouse cells. This strategy relies on randomly inserted selectable markers for donor fragment maintenance. As a test case, we have cloned random segments of Chinese hamster ovary (CHO) chromosomal DNA in mouse EMT-6 cells. This was done by cotransfecting plasmids pZIPNeo and pSV2dhfr into DHFR-CHO cells followed by isolation of a Neo + DHFR + CHO donor colony and radiation-fusion-hybridization (RFH) to EMT-6 cells. We then selected for initial resistance to G418 and then to increasing levels of methotrexate (MTX). Southern analysis of pulsed-field gel electrophoresis of rare-cutting restriction endonuclease digestions of DNA from five RFH isolates indicated that all five contain at least 600 kb of unrearranged CHO DNA. In situ hybridization with the plasmids pZIPNeo and pSV2dhfr to metaphase chromosomes of MTX-resistant hybrid EMT-6 lines indicated that these markers reside on double-minute chromosomes.

Radiation fusion hybrids for human chromosomes 3 and X generated at various irradiation doses

We have used a gamma-irradiation (2.5-25 krads) cell fusion procedure to generate human-hamster somatic cell hybrids (IHB, irradiated human fragments in B14-150 cells), retaining small fragments derived from human chromosomes 3 and X. By using Alu-element mediated PCR amplification and dot-blot hybridization with human alphoid or total human DNA as probes, 86 positive hybrids were identified and selected for further analysis. Nonisotopic fluorescence in situ hybridization (FISH) with human DNA in a set of eight hybrids demonstrated the presence of from one to eight human fragments per cell independent of irradiation dose. In contrast, a significant dose-dependent variation of fragment sizes was shown in the analysis of the 86 hybrids with markers previously mapped to 3p (seven markers) and to Xq (21 markers). Using the Xq27-28 region as a model, 40% of the hybrids generated at 5 krads or less were found to have retained fragments in the range of 3-30 Mb, 10% retained the whole chromosome arm, and the remaining 50% retained fragments of less than 2-3 Mb. The proportion of fragments of 3 Mb or larger decreased rapidly at higher irradiation doses and was very low (less than 6%) in hybrids generated at 25 krads. Upon further characterization, the 86 hybrids analyzed here will provide a mapping panel for the entire chromosomes 3 and X with an estimated resolution in the range of 1-2 Mb on average, a size range amenable to PFGE and YAC contig mapping.

Radiation hybrid map of 13 loci on the long arm of chromosome 5

Radiation hybrid mapping was used in conjunction with a natural deletion mapping panel to predict the order of and distance between 13 loci in the distal portion of the long arm of human chromosome 5. A panel of irradiation hybrids containing fragments of 5q was generated from an HPRT+ Chinese hamster-human cell hybrid containing a derivative chromosome 5 [der(5)t(4;5)(5qter----5p15.1::4p15.1----4pter)] as its only human DNA. One hundred nine radiation hybrids containing human DNA were screened with polymerase chain reaction primer sets representing nine genes encoding growth factors, growth factor receptors, or hormone receptors (IL3, IL4, IL5, CSF1R, FGFA, ADRB2, GRL, GABRA1, and DRD1) as well as four other loci (FER, SPARC, RPS14, and CD14) to generate a radiation hybrid map of the area 5q21-q35. A physical map predicting the order of and distance between the 13 loci was constructed based on segregation of the 13 loci in hybrid clones. The radiation hybrid panel will be useful as a mapping tool for determining the location and order of other genes and polymorphic loci in this region as well as for generating new DNA probes from specific regions.

Gene mapping in cancer

Observation of genetic alterations that appear consistently in specific types and stages of cancer provides a strong impetus to cancer geneticists to focus their investigations on the exploration of such volatile regions of the human genome. Introduction of powerful molecular cytogenetic and molecular genetic methods in recent years permits more detailed analysis, which will help researchers in their efforts to determine if such areas of the human genome have a functional role in the initiation and progressive development of leukemias and solid tumors. This discussion will focus on several provocative molecular cytogenetic tools that are currently available to localize potential cancer-associated genes and on how these methods are being used in conjunction with the current modes of analysis, including cytogenetics and somatic cell genetics. In addition, we will explore how these methods will help to isolate and dissect recently discovered cancer-associated genes within the human genome. All of these methods used in combination with each other will provide essential DNA markers for future diagnostic and prognostic evaluation of cancer.

Identification of deletion mutations and three new genes at the familial polyposis locus

Small (100-260 kb), nested deletions were characterized in DNA from two unrelated patients with familial adenomatous polyposis coli (APC). Three candidate genes located within the deleted region were ascertained and a previous candidate gene, MCC, was shown to be located outside the deleted region. One of the new genes contained sequence identical to SRP19, the gene coding for the 19 kd component of the ribosomal signal recognition particle. The second, provisionally designated DP1 (deleted in polyposis 1), was found to be transcribed in the same orientation as MCC. Two other cDNAs, DP2 and DP3, were found to overlap, forming a single gene, DP2.5, that is transcribed in the same orientation as SRP19.

Development of new cell lines for animal cell biotechnology

Mammalian cell culture has been an important technique in laboratory-scale experimentation for many decades. Developments in large-scale culture have been due to the need to grow large numbers of cells to support the growth of viruses for vaccine production, and more recently, for growing hybridoma cells as a source of monoclonal antibody. Increasingly, however, pharmaceutical products such as hormones, enzymes, growth factors, and clotting factors are being produced from cell lines which have been manipulated by recombinant DNA techniques. It is clear, therefore, that the high cost of growing mammalian cells on a large scale does not necessarily prohibit their use for biotechnology, and indeed there is considerable evidence to suggest that animal cell biotechnology will continue to be a major growth area in the future.

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.

Segregation of the Huntington disease region of human chromosome 4 in a somatic cell hybrid

We have developed an X-irradiation:cell fusion procedure that segregates segments of human chromosomes lacking selectable markers and have used this approach to construct somatic cell hybrids retaining fragments of human chromosome 4 as the only human material. To identify hybrids retaining a small chromosomal fragment in the region of the Huntington disease (HD) gene, we used Southern blot analysis to screen 72 hybrid lines for the presence or absence of seven chromosome 4 single-copy loci. These data, combined with in situ hybridization experiments, identified three hybrids of interest. One of these cell lines, C25, stably retains a 10,000- to 20,000-kb fragment of distal 4p in the vicinity of the HD gene, translocated to a hamster chromosome. Field-inversion gel electrophoresis revealed no evidence of rearrangements in the human DNA present in C25. In combination with similar radiation hybrids, C25 is a valuable tool for isolating DNA probes near the HD gene.

Localization of the genetic defect in familial adenomatous polyposis within a small region of chromosome 5

Familial adenomatous polyposis (FAP), a Mendelian disorder that includes familial polyposis coli (FPC) and Gardner syndrome (GS), has an autosomal dominant mode of inheritance. It is characterized by hundreds to thousands of adenomatous polyps that can progress to carcinoma of the colon, suggesting that the gene that harbors the FAP germ-line mutation may play an important role in the somatic genetic pathway to colon cancer. The defect responsible for FAP was recently mapped to the long arm of chromosome 5 by linkage between the FPC phenotype and a locus defined by DNA probe pC11p11 (D5S71), located at 5q21-22. Because an important next step in the paradigm for identification of a disease gene is to obtain a more precise localization, we isolated and mapped by linkage six additional polymorphic DNA markers in the FAP region. Subsequent linkage analysis in six pedigrees, three having the FPC phenotype and three segregating GS, placed the FAP locus very close to a new marker, YN5.48 (D5S81), that is approximately 17 centimorgans distal to C11p11 on the genetic map. The analysis revealed no evidence of genetic heterogeneity between the two phenotypes, a question that had not been clearly resolved by the earlier studies. The new set of markers in the near vicinity of the FAP locus represents a further step toward isolation of the genetic defect and provides the opportunity for preclinical diagnosis of risk status for colon cancer among individuals in families that are segregating adenomatous polyposis.

Irradiation-reduced human chromosome 21 hybrids

Rodent-human somatic cell hybrids have been constructed which contain fragments of human chromosome 21 as their only human material. This was done by irradiating rodent-human somatic cell hybrids containing a complete chromosome 21 to fragment the genome and then rescuing human GAR synthetase and various amounts of flanking chromosome 21 DNA by fusing with GAR synthetase-deficient hamster cells and selecting for growth in purine-free medium. Four irradiation-reduction hybrids were produced by this method and contain the distal, proximal, and central portions of the long arm of human chromosome 21, all centered about GAR synthetase. These irradiation-reduction hybrids were used as a panel to regionally map single-copy and individual copies of repetitive sequences. Using these hybrids along with another independently constructed hybrid, the GAR synthetase gene was mapped distal to SOD-1 and proximal to CP21G1(D21S60). Of special interest is the regional mapping of the gene for the amyloid beta-protein distal to pPW236B(D21S11) and proximal to SOD-1.

The role of acentric chromosome fragments in gene amplification

We assessed the role of acentric chromosome fragments in gene amplification by using cell fusion techniques to introduce the fragmented chromosomes of a donor Chinese hamster ovary (CHO) cell line that contained the dihydrofolate reductase (dhfr) gene(s) into a CHO cell line deficient for dhfr. Chromosome fragments were successfully integrated into cells at a frequency of approximately 3%. Methotrexate-resistant variants arose much more frequently in two cell lines derived from these successful cell fusions than in wild-type CHO cells. The hybrid cell lines also amplified their dhfr genes more readily than did the CHO cell line used as dhfr donor.

Cloning of a human S-phase cell cycle gene: use of transient expression for screening

We report here the cloning of a human cell cycle gene capable of complementing a temperature-sensitive (ts) S-phase cell cycle mutation in a Chinese hamster cell line. Cloning was performed as follows. A human genomic library in phage lambda containing 600,000 phages was screened with labeled cDNA synthesized from an mRNA fraction enriched for the specific cell cycle gene message. Plaques containing DNA inserts which hybridized to the cDNA were picked, and their DNAs were assayed for transient complementation in DNA transformation experiments. The transient complementation assay we developed is suitable for most cell cycle genes and indeed for many genes whose products are required for cell proliferation. Of 845 phages screened, 1 contained an insert active in transient complementation of the ts cell cycle mutation. Introduction of this phage into the ts cell cycle mutant also gave rise to stable transformants which grew normally at the restrictive temperature for the ts mutant cells.

Parasexual approaches to the study of human genetic disease

We have used two different strategies to construct hybrid cells in which specific, individual human chromosomes or fragments thereof are maintained by direct selective pressure. Our first approach was to introduce a drug-resistance gene into human chromosomes using a retroviral vector, and to transfer the marked chromosomes via microcells into mouse cells. The second method was to fuse gamma-irradiated human cells with rodent cells to produce hybrids containing fragments of the human X chromosome. Such hybrid cell lines should greatly facilitate both human gene mapping and the isolation of human genes by molecular cloning. The gene-transfer technologies described here can also be used to construct cell lines in which the expression of genes involved in human diseases can be studied in vitro.

Identification of a DNA segment containing the human DNA polymerase alpha gene

We isolated a temperature-sensitive mutant from mouse FM3A cells, designated as tsFT20, the DNA polymerase alpha activity of which is heat-labile. A hybrid clone (M6-39 cells) between human cells and tsFT20 cells contained one or two human chromosomes. M6-39 cells (primary hybrid) were exposed to gamma-ray and re-fused with tsFT20, after which we isolated two temperature-resistant secondary hybrids, both of which retained an identical minute portion of the human chromosome, 400-500 kilobase pairs (kbp). Immunological studies demonstrated that this secondary hybrid expressed human DNA polymerase alpha. Thus, the human DNA polymerase alpha gene was located within a DNA region of 400-500 kbp.

Chinese hamster cells with a minichromosome containing the centromere region of human chromosome 1

We describe a series of primary and secondary hamster-human hybrids which have selectively retained a small amount of human DNA. The hybrid XJM12.1.3 contains an estimated 4000-8000 kb of human DNA, and for a secondary hybrid derived from it, XEW8.2.3, our estimate is 1000-2000 kb. The hybridization of Southern blots of DNA from these hybrids with a variety of human satellite DNA probes reveals that these lines include centromere sequences of human chromosome 1. The identifiable human DNA is in the form of a minichromosome, as detected by in situ hybridization in the light microscope and in the electron microscope. At mitosis, the minichromosome can be observed to have kinetochores and to be associated with microtubules. Therefore, it can segregate in a stable fashion. It may be significant that in the selection of the hybrids we had selected for a human gene which has been mapped on human chromosome 1.

The laser method for efficient introduction of foreign DNA into cultured cells

A minute hole upon a cultured cell, perforated with a finely focused laser beam, was found to repair itself within a short period of time. The procedure constitutes a new way of introducing exogenous gene materials dissolved in medium into cells. The 'laser-aided' DNA transfection is better than the existing methods because it allows the treatment of a large number of cells in a shorter time, and an improved success rate.

Deletion mapping of human chromosome 5 using chromosome-specific DNA probes

A complete genomic DNA library was prepared from a Chinese hamster-human cell hybrid that contains human chromosome 5 as its only human DNA. Unique or low-copy DNA fragments, isolated form recombinant bacteriophage that contained human DNA inserts, were regionally mapped on chromosome 5 using Southern blot analysis of genomic DNA from a series of hybrid cell lines that were selected as having deletions of various portions of 5q. The chromosome 5-specific DNA library, together with a genetic selective procedure allowing the isolation of hybrid cell lines with deletions of virtually any portion of 5q, will provide a means to construct very accurate physical and recombinational maps of this human chromosome. This system represents an excellent opportunity to examine very precisely the relationship between physical and genetic distances for many loci along the length of this autosome.

Genetic complementation between UV-sensitive CHO mutants and xeroderma pigmentosum fibroblasts

The purpose of this study was to determine the feasibility of doing complementation analysis between DNA-repair mutants of CHO cells and human fibroblasts based on the recovery of hybrid cells resistant to DNA damage. Two UV-sensitive CHO mutant lines, UV20 and UV41, which belong to different genetic complementation groups, were fused with fibroblasts of xeroderma pigmentosum in various complementation groups. Selection for complementing hybrids was performed using a combination of ouabain to kill the XP cells and mitomycin C to kill the CHO mutants. Because the frequency of viable hybrid clones was generally less than 10(-6) and the frequency of revertants of each CHO mutant was approximately 2 X 10(-7), putative hybrids required verification. The hybrid character of clones was established by testing for the presence of human DNA in a dot-blot procedure. Hybrid clones were obtained from 9 of the 10 different crosses involving 5 complementation groups of XP cells. The 4 attempted crosses with 2 other XP groups yielded no hybrid colonies. Thus, a definitive complementation analysis was not possible. Hybrids were evaluated for their UV resistance using a rapid assay that measures differential cytotoxicity (DC). All 9 hybrids were more resistant than the parental mutant CHO and XP cells, indicating that in each case complementation of the CHO repair defect by a human gene had occurred. 3 hybrids were analyzed for their UV-radiation survival curves and shown to be much more resistant that the CHO mutants but less resistant than normal CHO cells. With 2 of these hybrids, sensitive subclones, which had presumably lost the complementing gene, were found to have similar sensitivity to the parental CHO mutants. We conclude that the extremely low frequency of viable hybrids in this system limits the usefulness of the approach. The possibility remains that each of the nonhybridizing XP strains could be altered in the same locus as one of the CHO mutants.

Molecular approach to analyzing the human 5p deletion syndrome, cri du chat

DNA unique or low-copy fragments were isolated from a genomic DNA library specific for the short (p) arm of human chromosome 5. These chromosome 5p-specific DNA fragments were used to analyze, by Southern blot experiments, somatic cell hybrids that retained either a normal chromosome 5 homolog or a homolog with a partial deletion of 5p, which was derived from either of two persons with the common human deletion syndrome, cri du chat or 5p- syndrome. In these studies, two classes of DNA fragments were identified, those located outside the region deleted in the persons with cri du chat and those located within the deleted region. This latter class of DNA probes will help to define, at the molecular level, a region of 5p that is critical in producing the phenotype associated with the cri du chat syndrome.

Assignment of the human MARS gene, encoding methioninyl-tRNA synthetase, to chromosome 12 using human X Chinese hamster cell hybrids

We have isolated interspecific somatic cell hybrids between a temperature-sensitive Chinese hamster ovary (CHO) cell methioninyl -tRNA synthetase mutant and human peripheral leukocytes. The hybrids were selected at 39 degrees C which requires the retention and expression of the human gene, MARS , which complements the defective CHO gene. In vitro heat-inactivation experiments on the methioninyl -tRNA synthetase activity in cell-free extracts from heat-resistant hybrids indicate that the human form of this enzyme and, therefore, the human MARS gene is present in hybrid cells. Cytogenetic analysis of three independent temperature-resistant hybrids revealed the presence of a single human chromosome, number 12. Two other independent hybrids examined contained human chromosome 12 as well as a second human chromosome. Electrophoretic analysis of extracts from hybrid cell lines for a human chromosome 12 marker isozyme, LDH-B, showed a pattern of heterotetrameric bands consistent with the presence of the human form of this enzyme in these cells. The correlation between the presence of the human form of methioninyl -tRNA synthetase and human chromosome 12 in temperature-resistant hybrids indicates that the human MARS locus is located on this chromosome.