XRCC1 protects cells from chromate-induced chromosome damage, but does not affect cytotoxicity

Hexavalent chromium Cr(VI) is a well known human carcinogen. This genotoxic metal induces DNA strand breaks and chromosome damage. However, the relationship between these lesions is uncertain. Our study focused on examining the role of XRCC1 in sodium chromate-induced cytotoxicity and chromosomal aberrations in Chinese Hamster Ovary (CHO) cells. Three different cell lines were used: AA8 (parental), EM9 (XRCC1 mutant) and H9T3 (EM9 complemented with human XRCC1 gene). Results show that concentration-dependent decreases in relative survival are similar in all three cell lines, indicating that XRCC1 is not crucial for protecting cells from sodium chromate-induced cytotoxicity. Similarly the frequency of damaged metaphase cells was not affected by XRCC1 deficiency. However, the total number of Cr(VI)-induced chromosome aberrations was exacerbated by XRCC1 deficiency and the spectrum of chromosome damage changed dramatically. Specifically, chromatid and isochromatid lesions were the most prominent aberrations induced in the cell lines and XRCC1 was essential to reduce the formation of chromatid lesions. In addition, XRCC1 deficiency caused a dramatic increase in the number of chromatid exchanges indicating that it is involved in protection from Cr(VI)-induced chromosome instability.     

XRCC1 protects cells from chromate-induced chromosome damage, but does not affect cytotoxicity

Hexavalent chromium Cr(VI) is a well known human carcinogen. This genotoxic metal induces DNA strand breaks and chromosome damage. However, the relationship between these lesions is uncertain. Our study focused on examining the role of XRCC1 in sodium chromate-induced cytotoxicity and chromosomal aberrations in Chinese Hamster Ovary (CHO) cells. Three different cell lines were used: AA8 (parental), EM9 (XRCC1 mutant) and H9T3 (EM9 complemented with human XRCC1 gene). Results show that concentration-dependent decreases in relative survival are similar in all three cell lines, indicating that XRCC1 is not crucial for protecting cells from sodium chromate-induced cytotoxicity. Similarly the frequency of damaged metaphase cells was not affected by XRCC1 deficiency. However, the total number of Cr(VI)-induced chromosome aberrations was exacerbated by XRCC1 deficiency and the spectrum of chromosome damage changed dramatically. Specifically, chromatid and isochromatid lesions were the most prominent aberrations induced in the cell lines and XRCC1 was essential to reduce the formation of chromatid lesions. In addition, XRCC1 deficiency caused a dramatic increase in the number of chromatid exchanges indicating that it is involved in protection from Cr(VI)-induced chromosome instability.     

Hybridization with human cells corrects the elevated SCE frequency and BrdU hypersensitivity of hamster cell line EM9

Cells of the Chinese hamster line EM9 exhibit an elevated SCE frequency and a decreased proliferative response in bromodeoxyuridine (BrdU)-containing medium. Here, these phenotypic features were examined experimentally using polyethylene glycol fusion of EM9 and normal human cells. EM9/human hybrids exhibited both normal SCE frequencies and normal proliferative responses in BrdU-containing medium, suggesting that SCE elevation and BrdU hypersensitivity in EM9 have a common molecular basis.     

Sister chromatid exchanges and heterochromatin

Summary The inter- and intrachromosomal distribution patterns of SCEs obtained with or without mutagen treatment are reviewed and compared, with each other as to their relation to heterochromatin and with the distribution patterns of chromatid aberrations that occurred either spontaneously in chromosomes of repair-defective human syndromes or after treatment with the mutagens (BrdU, ethylalcohol, DMBA, TMBA, maleic hydrazide, MMS, MMC). The conclusions are: No general rule is detectable for nonrandom involvement of heterochromatin in spontaneous SCEs. Mutagen-induced SCEs show the same or very similar distribution patterns as the spontaneous ones and are in no case as preferentially located as chromatid aberrations (which involve mainly the junctions between eu- and heterochromatin or other special regions). Therefore, a specific mutagen sensitivity of heterochromatincontaining chromosome regions as observed for chromatid aberrations does not exist (or is less pronounced) for SCEs. This supports the inference that different mechanisms underlie the origins of the two phenomena.     

Mitotic crossing-over and segregation in man

Summary Although clear genetic evidence of mitotic crossing-over is lacking in man, observations of mitotic chiasmata in normal cells (0.1–1 per 1000) and in Bloom's syndrome (BS) cells (5–150 per 1000) demonstrate its occurrence. That mitotic chiasmata are true exchanges is concluded from the occurrence of heteromorphic bivalents and the pattern of sister chromatid exchanges in mitotic bivalents. Several observations demonstrate that chiasmata are different in principle from chromatid translocations which simply happen to take place at homologous loci. For example, the ratio of adjacent exchanges to mitotic chiasmata is 1/20–1/60, whereas this ratio is approximately 1:1 for chromatid translocations. Furthermore, mitotic chiasmata make up a very high proportion of total quadriradials (QRs): 48% in normal untreated cells and 90% in BS cells.Close proximity of homologous chromosomes promotes mitotic crossing-over. Thus in normal diplochromosomes, the incidence is increased a hundred-fold as compared to diploid cells. However, closeness of homologues is not the only factor promoting crossing-over; the BS gene specifically promotes exchanges between homologous segments as shown by the roughly 15-fold increase of chiasmata in BS diplochromosomes as compared to normal diplochromosomes.Mitotic chiasmata are distributed extremely nonrandomly in different chromosomes and chromosome segments. The preferred sites are short Q-dark regions, 3p21, 6p21, 11q13, 12q13, 17q12, and 19p13 or q13 being veritable hot spots. Our preferred hypothesis is that the hot spots have higher gene densities than other regions. Consequently they are active and extended in interphase which would promote their pairing and chiasma formation.Segregation after mitotic corssing-over in satellite stalks can be demonstrated by means of distinct satellites. In a BS patient there were 31 different patterns for Q-bright satellites in 58 cells. Segregation after presumed crossing-over has also been seen in three dicentric chromosomes with one centromere inactivated. Recombination in satellite stalks in BS resulted in 12/58 cells homozygous for Q-bright satellites. In two of these cells, two chromosomes were homozygous for Q-bright satellites, and in one cell, three chromosomes were homozygous. This high degree of homozygosity which obviously applies to other chromosome regions too, may explain the high incidence of malignant disease in BS on the assumption that cancer is caused by recessive genes.     

The relation between chemically induced sister-chromatid exchanges and chromatid breakage.

Studies of classical chromosome aberrations and sister-chromatid exchanges (SCES) suggest independent mechanisms for the two events despite some common features. Examination of chromosome breakage caused by X-rays, visible light, and viruses has shown that few chromatid breaks are accompanied by SCEs at the sites of breaks. No similar observations were available for chemically induced breaks, but it has been reported that rat chromosomes exposed to dimethylbenzanthracene (DMBA) contained a preponderance of both aberrations and SCEs in certain specific regions, implicating a common process in their formation. These conclusions were drawn from a comparison of breaks induced in vivo with SCEs induced in vitro. However, we used 7 chemical mutagens to induce both chromatid breaks and SCEs in "harlequin" chromosomes of cultured rat and Chinese hamster ovary (CHO) cells and found that 25% of the 914 breaks scored were associated with SCEs. The proportion of breaks accompanied by SCEs is related to the overall SCE frequency and falls into the range predicted on the basis that breaks and SCEs occur independently. The reported association between sites for SCEs and aberrations also reflects secondary factors, such as induction of SCEs and aberrations during DNA synthesis in late replicating regions of the chromosomes.     

Analysis of single and twin sister chromatid exchanges in endoreduplicated normal and bloom syndrome B-lymphoid cells

Single and twin sister chromatid exchanges (SCEs) were analysed in the colcemid-induced endoreduplicated normal and Bloom syndrome (BS) B-lymphoid cells with diplochromosomes. In normal cells, an equal number of SCEs occur in each of the two cell cycles; the ratio of single (= 5.51 SCEs/cell) to twins (= 2.64 SCEs/cell) was 21 on the endoreduplicated-cell basis, and it was 11 on the diploid-cell basis. In contrast, in 29 endomitoses from one BS B-lymphoid line, a manyfold increase of single SCEs was detected and 139.4 single SCEs on the average were counted, whereas twin SCEs were rare and only 4.9 twin SCEs were countable. In BS cells, the ratio of single (= 139.4 SCEs/cell) to twins (4.9 SCEs/cell) was 281 on the endoreduplicated-cell basis, and it was 141 on the diploid cell-basis; the rates of S1 and S2 exchanges were 4.9 and 69.7 SCEs/cell, respectively. The present study strongly indicates that most of BS SCEs occur during the second cell cycle when BrdU-containing DNA is used as template for replication and that BrdU enhances BS SCEs.     

Chromosome breakage and rejoining of sister chromatids in Bloom's syndrome

The occurrence of chromosome breaks and reunion of sister chromatids in lymphocytes of two patients with Bloom's syndrome has been compared with those found in X-rayed and control cells. The distribution of breaks in BS is non-random both between and within chromosomes, the centric regions of certain chromosomes being preferentially involved. The following working hypotheses are put forward: When chromosome breaks in human lymphocytes occur in G₀— G₁, practically no sister chromatid reunion (SCR) takes place, whereas ends created by an S—G₂ break show a considerable tendency to SCR. We propose further that chromosome aberrations in BS mainly result from breaks in S—G₂, including possible U-type rejoining of sister chromatid exchanges. Fragments extra to an intact chromosome complement result from a chromatid break or an asymmetrical chromatid translocation in a previous mitosis.     

Studies of mammalian chromosome replication

Sister chromatids of metaphase chromosomes can be differentially stained if the cells have replicated their DNA semiconservatively for two cell cycles in a medium containing 5-bromodeoxyuridine (BrdU). When prematurely condensed chromosomes (PCC) are induced in cells during the second S phase after BrdU is added to the medium, the replicated chromosome segments show sister chromatid differential (SCD) staining. Employing this PCC-SCD system on synchronous and asynchronous Chinese hamster ovary (CHO) cells, we have demonstrated that the replication patterns of the CHO cells can be categorized into G₁/S, early, early-mid, mid-late, and late S phase patterns according to the amount of replicated chromosomes. During the first 4 h of the S phase, the replication patterns show SCD staining in chains of small chromosome segments. The amount of replicated chromosomes increase during the mid-late and late S categories (last 4 h). Significantly, small SCD segments are also present during these late intervals of the S phase. Measurements of these replicated segments indicate the presence of characteristic chromosome fragment sizes between 0.2 to 1.2 m in all S phase cells except those at G₁/S which contain no SCD fragments. These small segments are operationally defined as chromosome replicating units or chromosomal replicons. They are interpreted to be composed of clusters of molecular DNA replicons. The larger SCD segments in the late S cells may arise by the joining of adjacent chromosomal replicons. Further application of this PCC-SCD method to study the chromosome replication process of two other rodents, Peromyscus eremicus and Microtus agrestis, with peculiar chromosomal locations of heterochromatin has demonstrated an ordered sequence of chromosome replication. The euchromatin and heterochromatin of the two species undergo two separate sequences of decondensation, replication, and condensation during the early-mid and mid-late intervals respectively of the S phase. Similar-sized chromosomal replicons are present in both types of chromatin. These data suggest that mammalian chromosomes are replicated in groups of replicating units, or chromosomal replicons, along their lengths. The organization and structure of these chromosomal replicons with respect to those of the interphase nucleus and metaphase chromosomes are discussed.     

Induction of chromosomal aberrations in Chinese hamster ovary cells by the restriction endonuclease Dra I: dose-effect relationships and effect of substitution of chromosomal DNA with bromodeoxyuridine

Treatment of G1-phase Chinese hamster ovary (CHO) cells with the restriction endonuclease Dra I (recognition site TTT/AAA) leads to the induction of chromosome-type aberrations. The dose-effect relationships or the frequencies of polycentric chromosomes have a strong linear component. Prelabelling of the cells with bromodeoxyuridine (B) leads to a strong suppression by the chromosome breaking activity of Dra I. This may be explained by assuming that substitution of T by B renders the recognition site of Dra I resistant to being cut by the enzyme.     

Involvement of sulfhydryl groups of chromosomal proteins in sister chromatid differentiation

The fluorescence of human lymphocyte chromosomes stained with sulfhydryl group-specific fluorochromes is markedly enhanced by a mild near-ultraviolet irradiation pretreatment, indicating breakage of protein disulfide bonds. When metaphase preparations of cells cultured in the presence of BrdU during two cell cycles are irradiated and subsequently stained with the sulfhydryl group-specific fluorescent reagents used in this study, a differential fluorescence of sister chromatids is observed. After staining with the DNA-specific fluorochrome DAPI an opposite pattern of lateral differentiation appears. It can be concluded that the chromatid containing bifilarly BrdU-substituted DNA has a higher content of sulfhydryl groups than the chromatid containing unifilarly BrdU-substituted DNA. This implies a more pronounced effect of breakage of disulfide bonds in the chromatid with the higher degree of BrdU-substitution. BrdU-containing chromosomes pretreated with the mild near-ultraviolet irradiation procedure used by us, do not show any differentiation of sister chromatids after Feulgen staining. Using sulfhydryl group-specific reagents, differential fluorescence of sister chromatids could still be induced by irradiation with near-ultraviolet light after the complete removal of DNA from the chromosomes by incubation with DNase I. Thus, the protein effect of irradiation of BrdU-containing chromosomes takes place independently of what occurs to DNA.Our results indicate that subsequent to the primary alteration of chromatin structure caused by the incorporation of BrdU into DNA, breakage of disulfide bonds of chromosomal proteins might play an important role in bringing about differential staining of sister chromatids, at least for those procedures that use irradiation as a pretreatment or prolonged illumination during microscopic examination.     

Construction of midget chromosomes in wheat.

To test the usefulness of breakage-fusion-bridge (BFB) cycles in generating new chromosome aberrations in bread wheat (Triticum aestivum L.) and to extend the range of aberrations available, a series of midget chromosomes was produced from the long arm of chromosome 1B. Using a reverse tandem duplication initiated chromatid type BFB cycle, the 1BL arm was broken and fused with centromeres of either chromosome 5BL or 1RS to form dicentric chromosomes. The 1R and 5B centromeres were broken by centric misdivision. Among the progenies of plants with dicentric chromosomes, two classes of monocentric chromosomes were selected: deficient chromosomes 1B and chromosomes that had 1RS or 5BL for one arm and various fragments of 1BL for the other arm. Following centric misdivision of these monocentrics, midget chromosomes 1BL were isolated: deficient and deletion telocentrics and telocentrics derived from interstitial regions of 1BL. By chance, one deficient chromosome 1BS and one deletion chromosome 1BS were identified in unrelated lines of the same wheat. Following centric misdivision of these chromosomes, two midget chromosomes covering the whole of 1BS were added to the set.     

The influence of exogenous DNA of different origin on the mitosis and chromosomes of irradiated meristematic cells ofVicia faba

In this paper we compare the influence of heterologous and isologous DNA on the radiation damage repair of primary root meristematic cells ofVicia faba. Roots, irradiated by exposure of 150 r were cultivated at different time intervals either in tap water, or in a solution of heterologous or isologous DNA. In comparing mitotic activity of meristematic cells it was found that both types of DNA studied enhance the recovery of irradiated cells. The frequency of postmetaphase chromosomal aberrations of irradiated cells was influenced also by post-irradiation action of exogenous DNA. While heterologous DNA exhibited synergical effect with radiation in the sense that it increased the post-irradiation incidence of aberrations in all time intervals studied, isologous DNA had a strong repair effect—the application caused a significant decrease of the percentage of post-metaphase aberrations. Both kinds of DNA caused changes in the relation of chromosome to chromatid aberrations; a higher percentage of chromatid aberrations was registered. The study of the distribution of aberrations between large and small chromosomes ofVicia faba showed that the post-irradiation application of heterologous DNA increases damage of small chromosomes while isologous DNA caused an increased repair ability in this chromosomal group.     

Influence of low doses of BrdU and estimation of spontaneous SCE in CHO chromosomes: three-way differential staining and an immunoperoxidase method

The influence of low doses of 5-bromodeoxyuridine (BrdU) on the occurrence of sister chromatid exchanges (SCEs) during the first cell cycle, when unsubstituted DNA templates replicate in the presence of the halogenated nucleoside (SCE1) has been assessed in third mitosis (M3) Chinese hamster ovary (CHO) cells showing three-way differential (TWD) staining. In addition, lower concentrations of BrdU, not detectable by Giemsa staining, have been tested by a high resolution immunoperoxidase method (anti-BrdU monoclonal antibody) and SCEs were scored in second mitosis (M2) cells. Our findings was a dose-response curve for SCE1 that allows an estimated mean spontaneous yield of 1.32/cell per cell cycle by extrapolation to zero concentration of BrdU. On the other hand, when the total SCE frequency corresponding to the first and second rounds of replication (SCE1+SCE2) found in M3 chromosomes was compared with the yield of SCEs scored in M2 cells grown in BrdU at doses lower than 1 M no further reduction was achieved. This seems to indicate that SCEs can occur spontaneously in this cell line, though the estimated frequency is higher than that reported in vivo.by S. Wolff     

Chromosome-damaging activity of a ruthenium radiosensitizer, RuCl2 (DMSO)2 (4-nitroimidazole)2, in Chinese hamster ovary cells in vitro

The metal complex, RuCl2 (DMSO)2 (4-nitroimidazole)2, 1, which has hypoxic radiosensitizing properties, was examined for genotoxic activity, as measured by the in vitro induction of chromosome aberrations (chromatid breaks and chromatid exchanges) in Chinese hamster ovary (CHO) cells. A dose-dependent increase in the frequencies of metaphases with chromatid aberrations was observed for 1. Addition of S9 liver microsomal mixture and 1 to the cultured CHO cells did not alter the clastogenic activity noted for the complex itself. The clastogenic (chromosome damaging) activity of a precursor complex, cis-RuCl2(DMSO)4 and the ligand, 4-nitroimidazole (4-NO2-Im) were found to be less than that of 1 at corresponding concentrations. A comparison with two drugs used clinically with radiation, cis-dichlorodiammineplatinum(II) (cis-DDP) and misonidazole (miso), indicated that the clastogenic activity of 1 was similar to miso and much less than that of cis-DDP.     

Effects of X-irradiation in G1 and G2 on Bloom's syndrome and normal chromosomes

Summary The X-ray sensitivity of chromosomes from a Bloom's syndrome patient and a normal control was compared in G₁ and G₂. There was no significant difference in the number of aberrations induced by irradiation in G₁. An increased sensitivity of the BS chromosomes was found in G₂. The frequency of mitotic chiasmata in the BS cells was not increased by the G₂-irradiation, even though the frequency of chromatid translocations was much increased. This provides further evidence for the fundamental difference of these two phenomena. Evidence from the types of aberrations induced suggests that there is no appreciably increased frequency of pairing of homologous chromosomes in the BS cells over that in normal cells.     

Three-way differentiation of sister chromatids in endoreduplicated (M3) chromosomes of Bloom syndrome B-lymphoid cell line

Summary The three-way differentiation of sister chromatids (3-way SCD) in M₃ endoreduplicated chromosomes in a Bloom syndrome (BS) B-lymphoid cell line, suggested that in addition to exchanges between sister chromatids (intra-exchanges), non-sister chromatid exchanges (inter-exchanges) also occur, especially in BS high SCE cells. In BS diploid chromosomes such inter-exchanges probably get confused with intra-exchanges when total SCEs are accounted for. Bloom syndrome high SCE cells probably do not follow the same bromodeoxyuridine (BrdU) uptake pattern over three cell cycles as normal cells. The 3-way SCD in M₃ endoreduplicated chromosomes can be explained on the basis of Schvartzman's second model (1979) as well as Miller's model (1976), depending on the pattern of uptake of BrdU over three cell cycles. An interference in the previous events of exchanges in the following cell cycle (i.e., cancellation of SCEs) in BS chromosomes was observed in some regions, though not in high numbers.     

Chromosome instability associated with human alphoid DNA transfected into the Chinese hamster genome.

Repetitive DNA sequences have been implicated in the mediation of DNA rearrangement in mammalian cells. We have tested this hypothesis by using a dihydrofolate reductase (DHFR) expression vector into which candidate sequences were inserted. DHFR- Chinese hamster ovary (CHO) cells were transfected with this vector, the amplification of which was then selected for by methotrexate (MTX) exposure. Cells transfected with the vector alone (and resistant to 0.02 or 1.0 microM MTX) or with a poly(dG-dT) insert (and resistant to 0.05 or 1.0 microM MTX) showed little change in chromosome aberrations or sister chromatid exchange frequencies. In contrast, transfection of DHFR- CHO cells with a vector containing either of two distinct 0.34-kilobase human alphoid DNA segments (and selection to 0.05 to 10.0 microM MTX) showed an approximately 50% increase in chromosome number and marked changes in chromosome structure, including one or two dicentric or ring forms per cell. The sister chromatid exchange frequency also increased, to more than double the frequency of that in cells transfected without insert or those containing poly(dG-dT). In situ hybridization of one 0.34-kilobase insert in some cells suggested clustering of homologous sequences in structurally abnormal recipient CHO cell chromosomes. The approach described provides an introduction to a unique means for a coordinate molecular and cytological study of dynamic changes in chromosome structure.     

Assignment of a human DNA-repair gene associated with sister-chromatid exchange to chromosome 19

The Chinese hamster ovary (CHO) cell mutant, EM9, is defective in rejoining strand breaks, hypersensitive to chlorodeoxyuridine (CldUrd), and has a high frequency of sister-chromatid exchange (SCE). Somatic cell hybrids constructed from fusion of EM9 cells with normal human lymphocytes and fibroblasts, and selected in CldUrd, extensively segregate human chromosomes but preferentially retain markers of human chromosome 19. The SCE frequency in the hybrid clones is low as in normal CHO cells, but in CldUrd-sensitive subclones, which lose the human chromosome 19 markers, SCE frequencies return to mutant levels. We therefore assign a human gene designated repair complementing defective repair in Chinese-hamster (RCC) to chromosome 19. Since this is the second (of two) human genes complementing repair-deficiency mutations in CHO cells assigned to the 19, the assignment and organization of DNA-repair genes is discussed in the light of hemizygosity in CHO cells and the evolutionary conservation of mammalian linkage groups.     

Banding pattern analysis of initial structural chromosome alterations induced by n-methyl-n'-nitro-n-nitrosoguanidine in Syrian hamster cells

Cultured secondary Syrian hamster embryo cells exposed to 0.5 N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) microgram/ml medium exhibited chromatid type of aberrations consisting of gaps, breaks and exchanges. Although no specific chromosome or chromosome segment was preferentially affected, chromosomes belonging to the larger groups tended to more often involved. G-band analysis demonstrated that 80% of the lesions occurred in negative bands, 9% involved the centromere, 3% were on non-banded heterochromatin, and approximately 8% of the lesions could not be definitely categorized by G-band analysis. Whether the lesions occur at positive bands or at the interface between negative and positive bands is difficult to discern by the G-band resolution. The Y chromosome compared to autosomes of similar size rarely had lesions. X chromosome damage was found in both the euchromatic and heterochromatic arms. However, both sex chromosomes, as well as an autosome (E20) which is heterochromatic on its long arm, were not found joined to the chromatids of other chromosomes, further emphasizing that chromosomes with large heterochromatic areas are isolated in terms of chromatid exchange events. The analysis of MNNG induced chromosome damage indicates that the negative bands are the primary site of damage and points of exchange.