Raghbir S. Athwal

Kinetochore identification in micronuclei in mouse bone-marrow erythrocytes: An assay for the detection of aneuploidy-inducing agents

An in vivo micronucleus assay using mouse bone marrow for identifying the ability of chemicals to induce aneuploidy and/or chromosome breaks is described. Micronucleus formation in bone-marrow erythrocytes of mice is commonly used as an index for evaluating the clastogenicity of environmental agents. However, micronuclei may also originate from intact lagging chromosomes resulting from the effect of aneuploidy-inducing agents. We have used immunofluorescent staining using anti-kinetochore antibodies to classify micronuclei for the presence or absence of kinetochores. Micronuclei positive for kinetochores are assumed to contain intact chromosomes and result from induced aneuploidy; while those negative for kinetochores contain acentric chromosomal fragments and originate from clastogenic events. The assay was evaluated using X-irradiation (a known clastogen) and vincristine sulfate (an aneuploidy-inducing agent). A dose-related response for the induction of micronuclei was observed for both agents. Micronuclei induced by X-irradiation were negative for kinetochores while the majority of the micronuclei resulting from vincristine treatment contained kinetochores. Thus, the micronucleus assay in combination with immunofluorescent staining for kinetochores may provide a useful method to simultaneously assess the ability of chemicals to induce aneuploidy and/or chromosome breaks.

Integration of a dominant selectable marker into human chromosomes and transfer of marked chromosomes to mouse cells by microcell fusion.

A method for the production of stable mouse-human cell hybrids containing a single human chromosome is described. As a first step in this method, a cloned selectable marker, the E. coli xanthine-guanine phosphoribosyltransferase (Ecogpt) gene, was transferred to human cells to generate cell lines each carrying Ecogpt integrated into a different site. Human chromosomes marked with Ecogpt were transferred further into mouse cells by microcell fusion. Monochromosomal hybrids, in which the human chromosome is maintained by selection, have been produced for chromosomes 2, 5, 16, and a rearranged chromosome involving a translocation between chromosomes 1 and 2. In addition to these monochromosomal hybrids, we have also obtained monochromosomal hybrids for human chromosomes 6, 12, and 17 by selection for the loss of marked chromosome from the microcell hybrids each containing two human chromosomes. Although the human chromosome present in these hybrids cannot be maintained by selection, 80–90% of cells retained the transferred chromosome on continuous growth for 15 days. Monochromosomal hybrids would provide biological materials to construct genetic maps of human chromosomes. In addition, chromosomes marked with dominant selectable markers can be transferred further to any cell line of interest in inter- or intra-species combination.

Use of human × mouse hybrid cell line to detect aneuploidy induced by environmental chemicals

A short-term assay utilizing a human/mouse monochromosomal hybrid cell line R3-5, to detect chemically induced aneuploidy in mammalian cells is described. A single human chromosome transferred into mouse cells was used as a cytogenetic marker to quantitate abnormal chromosome segregation following chemical treatment. The human chromosome present in the mouse cells can be readily identified by differential staining procedures. The frequency of cells containing 0 or 2 human chromosomes in the progeny of chemically treated monochromosomal hybrid cells provided a direct measure of aneuploidy. We tested the sensitivity of the proposed system with 3 model chemicals (colcemid, cyclophosphamide and benomyl) known to induce numerical or structural changes in chromosomes. The frequency of an abnormal segregation of the human chromosome was found to be dose dependent and consistently higher than controls. This system has the capability to detect gain as well as loss of a chromosome resulting from nondisjunction or other mechanisms leading to aneuploidy.

Subchromosomal localization of a gene (XRCC5) involved in double strand break repair to the region 2q34-36

We have previously shown that human chromosome 2 can complement both the radiation sensitivity and the defect in double strand break rejoining characteristic of ionizing radiation (IR) group 5 mutants. A number of human-hamster hybrids containing segments of human chromosome 2 were obtained by microcell transfer into two group 5 mutants. In most, but not all, of these hybrids, the repair defect was complemented by the human chromosomal DNA. Two complementing microcell hybrids were irradiated and fused to XR-V15B, an IR group 5 mutant, to generate further hybrids bearing smaller regions of chromosome 2. All hybrids were examined for complementation of the repair defect. The region of chromosome 2 present was determined using PCR with primers specific for various human genes located on chromosome 2. A complementing hybrid bearing only a small region of chromosome 2 was finally generated. From this analysis we deduced that theXRCC5 gene was tightly linked to the marker,TNP1, which is located in the region 2q35.

A xeroderma pigmentosum complementation group A related gene: confirmation using monoclonal antibodies against the cyclobutane dimer and (6-4) photoproduct

Xeroderma pigmentosum complementation group A was partially complemented by a cosmid genomic clone containing a 42-kb human DNA insert selected with a cDNA clone that we obtained through cDNA competition between the repair-proficient and repair-deficient cell line. The relationship between these two clones was confirmed using PCR amplifications. The enhancement in DNA-repair capacity of the transformants was assessed with the monoclonal antibodies specific for cyclobutane dimers and (6-4) photoproducts and partially correct the xeroderma pigmentosum complementation group A defect. Furthermore, the level of the photoproduct-repair capacity is in agreement with the survival enhancement calculated from the D37 values. This gene was mapped to chromosome 8, suggesting that this may represent one of the defective gene(s) in xeroderma pigmentosum complementation group A.

A hamster-human subchromosomal hybrid cell panel for chromosome 2

We have constructed hamster-human hybrid cell lines containing fragments of human chromosome 2 as their only source of human DNA. Microcell-mediated chromosome transfer was used to transfer human chromosome 2 from a monochromosomal mouse-human hybrid line to a radiation-sensitive hamster mutant (XR-V15B) defective in double-strand break rejoining. The human chromosome 2 carried theEcogpt gene and hybrids were selected using this marker. The transferred human chromosome was frequently broken, and the resulting microcell hybrids contained different sized segments of the q arm of chromosome 2. Two microcell hybrids were irradiated and fused to XR-V15B to generate additional hybrids bearing reduced amounts of human DNA. All hybrids were analyzed by PCR using primers specific for 27 human genes located on chromosome 2. From these data we have localized the integratedgpt gene on the human chromosome 2 to the region q36–37 and present a gene order for chromosome 2 markers.

A genetic assay for aneuploidy: quantitation of chromosome loss using a mouse/human monochromosomal hydrid cell line

A genetic assay is described in which a mouse/human hybrid cell line R3-5 containing a single human chromosome (a monochromosomal hybrid) is used to detect chemically induced aneuploidy. In this assay the frequency of chromosome loss determined by the cloning efficiency of the cells in a selection medium is used as an index for the potential of a chemical to induce aneuploidy. The hybrid cells are deficient in hypoxanthine guanine phosphoribosyltransferase (HGPRT) and contain human chromosome 2, marked with Ecogpt, an E. coli gene for xanthine guanine phosphoribosyltransferase. These cells with a genotype of hgprt-/Ecogpt+ can grow in medium containing mycophenolic acid and xanthine (MX medium) but not in medium containing 6-thioguanine (6-TG). The loss of the human chromosome from R3-5 cells as a result of chemical treatment produces cells with a genotype of hgprt-/Ecogpt- which are capable of growth in the medium containing 6-TG. Thus, the cloning efficiency of cells treated with a test chemical in 6-TG provides a method to determine the frequency of cells that have lost the human chromosome. Two chemicals, colcemid and nocodazole, previously known to induce aneuploidy in mammalian cells were used for a preliminary evaluation of this test system. Both of these compounds at concentrations ranging from 0.002 to 0.032 micrograms/ml showed a concentration-related positive response in this assay.

The defect in the AT-like hamster cell mutants is complemented by mouse chromosome 9 but not by any of the human chromosomes

X-ray sensitive Chinese hamster V79 cells mutants, V-C4, V-E5 and V-G8, show an abnormal response to X-ray-induced DNA damage. Like ataxia telangiectasia (AT) cells, they display increased cell killing, chromosomal instability and a diminished inhibition of DNA synthesis following ionizing radiation. To localize the defective hamster gene (XRCC8) on the human genome, human chromosomes were introduced into the AT-like hamster mutants, by microcell mediated chromosome transfer. Although, none of the human chromosomes corrected the defect in these mutants, the defect was corrected by a single mouse chromosome, derived from the A9 microcell donor cell line. In four independent X-ray-resistant microcell hybrid clones of V-E5, the presence of the mouse chromosome was determined by fluorescent in situ hybridization, using a mouse cot-1 probe. By PCR analysis with primers specific for different mouse chromosomes and Southern blot analysis with the mouse Ldlr probe, the mouse chromosome 9, was identified in all four X-ray-resistant hybrid clones. Segregation of the mouse chromosome 9 from these hamster-mouse microcell hybrids led to the loss of the regained X-ray-resistance, confirming that mouse chromosome 9 is responsible for complementation of the defect in V-E5 cells. The assignment of the mouse homolog of the ATM gene to mouse chromosome 9, and the presence of this mouse chromosome only in the radioresistant hamster cell hybrids suggest that the hamster AT-like mutant are homologous to AT, although they are not complemented by hamster chromosome 11.

Complementation of DNA repair defect in xeroderma pigmentosum cells of group C by the transfer of human chromosome 5

Complementation of DNA excision repair defect in xeroderma pigmentosum cells of group C (XP-C) has been achieved by the transfer of human chromosome 5. Individual human chromosomes tagged with a selectable marker were transferred to XP-C cells by microcell fusion from mouse-human hybrid cell lines each bearing a single different human chromosome. Analysis of the chromosome transfer clones revealed that introduction of chromosome 5 into XP-C cells corrected the DNA repair defect as well as UV-sensitive phenotypes, while chromosomes 2, 6, 7, 9, 13, 15, 17, and 21 failed to complement. The introduced chromosome 5 in complemented UVr clones was distinguished from the parental XP-C chromosomes by polymorphism for dinucleotide (CA)n repeats at two loci, D5S117 and D5S209. In addition, an intact marked chromosome 5 was rescued into mouse cells from a complemented UVr clone by microcell fusion. Five subclones of a complemented clone that had lost the marked chromosome 5 exhibited UV-sensitive and repair-deficient phenotypes identical to parental XP-C cells. Concordant loss of the transferred chromosome and reappearance of XP-C phenotype further confirmed the presence of a DNA repair gene on human chromosome 5.

Sequence of centromere separation: separation in a quasi-stable mouse-human somatic cell hybrid.

A quasi-stable mouse-human hybrid cell line, HR61, containing between one and ten human chromosomes was analyzed for the sequence of centromere separation. The purpose was to determine which genome of the two initiates centromere separation first. The data clearly indicate that the separation of centromeres of the human genome is not only initiated but is completed before any centromeres from the mouse chromosomes start splitting into daughter units. The information on whether uniparental chromosome loss results from a lack of deposition of kinetochore proteins was equivocal. The human genome also completes its DNA replication before the mouse genome does. Our studies, therefore, show that the timing of centromere separation is tightly linked to the completion of replication of DNA. At least in this cell line the segregant genome is not the one which exhibits delayed DNA replication.