5-Bromodeoxyuridine-dependent increase in sister chromatid exchange formation in Bloom's syndrome is associated with reduction in topoisomerase II activity

Bloom's syndrome is characterized by a high sister chromatid exchange (SCE) frequency, the basis for which is not yet understood. Immunofluorescent detection of SCE formation in dermal fibroblasts was employed over a wide range of 5-bromodeoxyuridine (BrdU) substitution into template DNA to show that this SCE elevation reflects both an increased baseline SCE frequency and an exaggerated increment in SCE formation as BrdU substitution increases. The impact of BrdU on SCE formation in Bloom's syndrome is paralleled by its ability to reduce the activity in nuclear extracts of topoisomerase II, an enzyme important for DNA replication and interchange. The extractable topoisomerase II activity of Bloom's syndrome fibroblasts, as measured by unknotting of page P4 DNA, is much more strongly inhibited by cell growth in medium containing BrdU than is that of normal fibroblasts. The results are consistent with the hypothesis that much of the BrdU-dependent component of SCE formation in Bloom's syndrome may be mediated by an effect of BrdU substitution of template DNA on topoisomerase II activity.     

Suppression of the frequencies of sister chromatid exchanges in Bloom's syndrome fibroblasts by co-cultivation with Chinese hamster cells

Summary The effect of co-cultivation of Bloom's syndrome fibroblasts with Chinese hamster ovary cells (CHO) on the incidence of sister chromatid exchanges (SCEs) was studied. The results show that suppression of the frequency of SCEs in Bloom's syndrome cells occurs only if cell to cell contact is present with CHO cells, without any effect on the SCE frequency in the latter.It is suggested that possible genetic heterogeneity between different Bloom's syndrome patients can be studied using the method of co-cultivation.     

Effects of mitomycin C on sister chromatid exchange in normal and Bloom's syndrome cells

Bloom's syndrome lymphocytes, which are characterized by a high incidence of sister chromatid exchanges (SCE: 80.6 per cell), were treated with mitomycin C (MMC) and the effect of the chemical on SCE frequency compared with that in normal cells. Raising the concentration of MMC from 1 X 10(-9) to 1 X 10(-7) g/ml led to about 10-fold increase (61.7 SCE per cell) in the SCE frequency over the base line in normal lymphocytes (6.4 SCE per cell), though chromosome aberrations remained at a relatively low frequency. MMC caused about a two-fold rise in SCE in cells of Bloom's syndrome (128.8 SCE at 10(-9) g/ml; 139.3 SCE at 10(-8) g/ml). The frequency of chromosome aberrations in Bloom's syndrome cells at concentrations of MMC of 1 X 10(-9) and 1 X 10(-8) g/ml was 0.350 and 0.825 per cell, respectively, and low when compared to the increased number of SCE. The increased frequency of SCE in normal and Bloom's syndrome cells is in contrast to the reported findings with cells from Fanconi's anemia and xeroderma pigmentosum. The distribution of SCE in MMC-treated normal cell correlates with that of spontaneous SCE in cells of Bloom's syndrome.     

O6-methylguanine methyltransferase increases before S phase in normal human cells but does not increase in hypermutable Bloom's syndrome cells

The regulation of the O6-methylguanine methyltransferase was examined during cell proliferation in hypermutable Bloom's syndrome fibroblasts and normal human skin fibroblasts. During synchronous growth following serum stimulation normal human cells enhanced methyltransferase activity 2.4-fold in the absence of exogenous damage as a normal regulatory event during the cell cycle. Methyltransferase activity was increased prior to the induction of DNA replication and of DNA polymerase and was diminished when each replicative activity was maximal. In contrast, although methyltransferase levels in quiescent cells are equivalent, hypermutable Bloom's syndrome cells did not increase methyltransferase at any interval in the cell cycle.     

Effect of incubation temperature on the frequency of sister chromatid exchanges in Bloom's syndrome lymphocytes

Summary The effect of incubation temperature on the frequency of sister chromatid exchange (SCE) has been studied in blood cultures from three Bloom's syndrome (BS) patients, three controls, and three BS heterozygotes. All cell types show slight increases of SCE at 39°C while at 35°C and 32°C, SCE is reduced considerably in BS and slightly increased in normal cells. Prolonging lymphocyte culture to 140 h and adding BUdR for the last two S periods causes a similar decrease in the percentage of SCE in normal and BS cells but, while the latter show a further reduction if they are incubated at 32°C during BUdR labelling, the normal cells show an increase. Therefore, BS and control lymphocytes respond similarly to changes in incubation time and differently to changes in incubation temperature. The possibility that the discrepant behaviour of the BS and control cultures may be due to different growth kinetics of their B and T lymphocytes has been discussed but considered unlikely. Since low temperature lengthens the cell cycle, it has been suggested that our findings and those published by others on co-cultivation experiments (except those of Tice et al. 1978) can be explained by assuming that slow growth reduces SCE in BS cells. This, and unpublished observations (Giannelli et al. 1981), suggest that some imbalance in the factors responsible for DNA replication may exist in BS and possibly account for the high level of SCE.     

Hypersensitivity of Bloom's syndrome fibroblasts to N-ethyl-N-nitrosourea

Fibroblast cells from two Japanese patients with Bloom's syndrome (BS) and normal donors were studied for the inactivation of colony-forming ability and the induction of sister-chromatid exchanges (SCEs) after N-ethyl-N-nitrosourea (ENU) treatment. The reduction of ENU-induced SCEs as a function of post-treatment incubation time was also compared between BS and normal fibroblasts. BS cells were approximately 4 times more sensitive than normal cells to the lethal effect of ENU and remarkably hypersensitive to the SCE induction by ENU. The post-treatment incubation of ENU-treated normal cells in the fresh medium resulted in a time-dependent decrease of the SCE level until 6 h after which time the SCE level remained the plateau of about 50% of the initial level. In contrast, the ENU-induced SCEs in BS cells decreased much more slowly with post-treatment incubation time and its half life was 24 h. These results collectively support the view that BS cells may be defective in the rapid repair of certain type(s) of DNA damages induced by ENU.     

Cytogenetic investigations in a new case of Bloom's syndrome

Summary Cytogenetic studies of an 8-year-old caucasian girl with typical but mild manifestation of Bloom's syndrome showed a characteristic increase of homologous chromatid translocations and prematurely condensed chromosomes. The average frequency of sister chromatid exchanges (SCE) in lymphocytes with 133 was much higher than in skin fibroblasts with 49. The inter- and intrachromosomal distributions of SCE in lymphocytes were analyzed.Prof. Dr. H.-R. Wiedemann to his 60th birthday.     

Detection of free radical-induced DNA damage with bromodeoxyuridine/Hoechst flow cytometry: implications for Bloom's syndrome.

The clinical radiosensitizer bromodeoxyuridine (BrdU) was shown to enhance oxygen free radical-mediated growth inhibition. Cells from Bloom's syndrome, a rare autosomal recessive disorder characterized by pre- and post-natal growth deficits, telangiectatic erythema, recurrent respiratory infections and a high incidence of cancer, exhibit in culture a hypersensitivity to BrdU. We analysed disturbed cell kinetics of Bloom's syndrome fibroblasts and permanent B-cell lines with a novel cell kinetic method: BrdU/Hoechst flow cytometry. Fibroblasts show a pattern similar to that of normal cells exposed to a breakdown product of lipid peroxides, whereas B-cells exhibit the cell kinetic disturbance provoked by elevated oxygen concentrations in normal cells. In both cell types the cell kinetic pattern was dependent upon the BrdU concentration in the culture medium. These data suggest an elevated endogenous generation of oxygen free radicals in Bloom's syndrome cells, which may relate to the elevated incidence of malignancies in these patients.     

Superoxide dismutase activity and chromosome damage in cultured chromosome instability syndrome cells

The basal levels of superoxide dismutase (SOD) activity and chromosome aberration (CA) and sister-chromatid exchange (SCE) frequencies were examined in cultured fibroblasts or Epstein-Barr virus (EBV)-transformed lymphoblastoid cell lines (LCLs). These cells were derived from patients with chromosome instability syndromes (CISs) including Bloom's syndrome (BS), Fanconi's anemia (FA) and ataxia telangiectasia (AT). Embryonal fibroblasts and LCLs from normal subjects served as controls. Although LCLs tended to exhibit a higher SOD level than fibroblasts due to an elevation of Cu/Zn-SOD activity, BS and FA fibroblasts with increased frequencies of CAs and/or SCEs showed abnormally elevated SOD activity due to the manifold increase of Mn-SOD levels compared with control cells. However, BS and AT LCLs with almost control levels of CA and SCE frequencies showed no, or a slightly elevated, SOD activity, suggesting a possible selection of such cells during EBV transformation. The observed parallelism between the SOD activity and the cytogenetic manifestation may imply an involvement of active oxygen species, especially superoxide radicals, in the increased chromosome damage of CIS cells.     

Increased sister chromatid exchange in bone marrow and blood cells from Bloom's syndrome.

Bone-marrow cells from a patient with Bloom's syndrome cultured for 48 h in the presence of BudR exhibited a striking increase in the number of sister chromatid exchanges (SCEs) in comparison to that in the marrow cells of a patient with treated polycythemia vera (PV). Thus, it appears that an increased incidence of SCE in Bloom's syndrome occurs in various differentiated types of cells, not just blood lymphocytes, and constitutes the syndrome's most characteristic cytogenetic feature. In contrast, the incidence of SCE was not increased in marrow cells and lymphocytes of the particular PV patient studied here, whose cells did exhibit increased numbers of chromatid and chromosome gaps and breaks, presumably as result of the patient's earlier treatment. An increased frequency of SCE was demonstrated in Bloom's syndrome lymphocytes using both a technique based on BudR incorporation and one based on labeling with tritated deoxycytidine. This observation constitutes evidence against the increase of SCE being due to an unusual reaction to BudR. By conventional cytogenetic techniques, chromosome instability, including chromatid and chromosome breaks, but no homologous chromatid interchanges were also recognized in Bloom's syndrome bone-marrow cells incubated in vitro (without BudR) for either 1.k or 16 h. This observation points to the existence of chromosome instability in vivo.     

No relationship between genetic instability in Bloom's syndrome and DNA hypomethylation of some major repetitive sequences

Bloom's syndrome (BS) is an autosomal recessive disorder, characterized by a high incidence of cancer at a young age. Cytogenetically, BS cells exhibit a high frequency of chromosomal damage and sister chromatid exchange (SCE). Thus, BS provides a human model of a genetic disorder exhibiting both chromosomal instability and a high incidence of cancer. In addition to its involvement in gene regulation, CpG methylation has recently been suggested to play an important role in the evolution and stability of chromosome structure. We have examined DNA methylation profiles of total DNA and some selected repeated sequences in normal and BS cells. No specific DNA hypomethylation in either total blood or lymphoblastoid cell lines from BS patients has been detected, suggesting that the genomic instability observed in BS is not directly related to a major DNA demethylation of the total CCGG sites, or of Alu or chromosome 1 satellite 2 repeated sequences.     

Loss of high frequency of sister chromatid exchanges in Epstein-Barr virus-established lymphoblastoid cell lines from two patients with Bloom's syndrome

Seven lymphoblastoid cell lines were established through transformation by Epstein-Barr virus of peripheral blood lymphocytes from two patients with Bloom's syndrome (BS), the parents of a patient, and normal controls. High baseline levels of sister chromatid exchanges (SCEs) in peripheral blood lymphocytes of BS were reduced to about 10% of their initial value in BS lymphoblastoid cell lines, and the elevation of SCE frequencies induced by ethylmethanesulfonate was the same as in controls.     

Cell cycle rate and sister chromatid exchange profile in polyethylene glycol-exposed/unexposed Bloom syndrome and normal cells

Summary A delay in cell cycle progression and a decrease in sister chromatid exchange (SCE) frequency was observed in Bloom syndrome (BS) cells when exposed to polyethylene glycol (PEG) treatment followed by co-cultivation with unexposed normal cells, whereas the SCE rate of both normal and BS cells increased when PEG-exposed normal cells were co-cultured with unexposed BS high SCE cells. This indicates the role of normal cells, probably of cell membranes (which were disturbed or disrupted by PEG treatment), in complementing the deficiency of BS cells under co-culture conditions, and suggests that BS cells may be deficient in membrane bound factor(s) present in normal cells.     

Chromosomal localization of the Epstein-Barr virus (EBV) genome in Bloom's syndrome B-lymphoblastoid cell lines transformed with EBV

The localization of the Epstein-Barr virus (EBV) genome in chromosomes of human B-lymphoblastoid cell lines (LCLs) transformed with EBV, and the effect of EBV DNA on the level of sister chromatid exchange (SCE) in Bloom's syndrome (BS) B-LCLs, were examined with chromosomal in situ hybridization techniques using a ³H-EBV DNA probe. EBV DNA was detected in chromosomes 1–5 and 13–15 at specific G band regions in BS as well as in normal B-LCLs, regardless of SCE. Several chromosomal sites (1p31, 1q31, 4q22–24, 5q21, 13q21, 14q21) carrying EBV DNA seemed to be very characteristic in normal as well as in BS B-LCLs. There was no statistically significant difference in silver grain counts due to EBV DNA and their distribution in different chromosomes or groups among normal and BS B-LCLs with normal and high SCE. These findings strongly indicate that EBV infection did not introduce a correcting factor for BS SCE.     

Disparate effects of 5-bromodeoxyuridine on sister-chromatid exchanges and chromosomal aberrations in Bloom syndrome fibroblasts

The existence of a high frequency of spontaneous sister-chromatid exchanges (SCEs) in Bloom syndrome (BS) has thus far been supported by data on a small number of BS cell lines. To examine the cause of baseline SCEs more broadly, the frequencies of SCEs, as well as chromosomal aberrations (CAs) in 4 additional BS fibroblast strains were compared, under different assay and cell culture conditions, with those of normal cells in the range of approximately 0.9-90% 5-bromodeoxyuridine (BrdUrd) substitution into template DNA. SCEs at low levels of BrdUrd substitution were detected by an extremely sensitive immunofluorescent technique. From approximately 0.9% to 4.5% BrdUrd substitution, the SCE frequency in BS cells remained constant, at a level (40/cell) 8 times higher than that of normal cells. As BrdUrd substitution increased further, the SCE frequency in BS cells increased almost linearly, reaching 70-100 per cell at approximately 90% substitution, while the SCE increment in control fibroblasts was less than 5 per cell. Analysis of SCEs in 3 successive replication cycles similarly revealed that the SCE increment in BS cells depended on BrdUrd only at a high BrdUrd substitution level. In contrast to data on SCEs, CA induction by incorporated BrdUrd in BS cells was only slightly higher than that in normal cells. Thus, BS cells are extremely sensitive to BrdUrd for SCE induction, but much less so for CA induction.     

Sister-chromatid exchanges induced by ultraviolet light in Bloom's syndrome fibroblasts

The relationships between the cytotoxic effect of ultraviolet light and the UV-induced sister-chromatid exchanges (SCEs) were compared among fibroblast cell strains from two unrelated Bloom's syndrome (BS) patients, one xeroderma pigmentosum (XP) patient belonging to complementation group A and two unrelated normal controls. The "net" induced SCEs as a function of UV fluence, obtained by subtracting spontaneous SCEs from observed SCEs, were much higher in both BS cells and XP group A cells than in normal cells. The relative efficiency of induced SCE, defined as the "net" induced SCEs as a function of surviving fraction after UV irradiation, was higher in BS cells than in normal and XP cells, and there was essentially no difference between XP and normal cells. These results imply that in addition to the extremely high frequency of spontaneous SCEs, the increased efficiency in UV induction of SCEs may reflect the intrinsic defect(s) in BS cells.     

Cell cycle progression and SCE rate of Bloom syndrome cells with/without co-cultivation in the presence/absence of normal cells

The present study was undertaken to examine cell cycle progression and SCE rate in three types of B-lymphoid cell line, viz., normal (KS-86), high-SCE Bloom syndrome (BS (BS2-2) and dimorphic BS (BS-SYW). In order to compare the dimorphic condition (BS-SYW) with artificial dimorphism (co-cultivation of BS2-2 with KS-86) these experiments were designed to test whether the BS B-lymphoid cell line cultures would influence the cell cycle progression and SCE rates of a normal B-lymphoid cell line, and vice versa. The present study resolved the controversy reported in the literature, by finding a definite time period under co-cultivation conditions when the SCE in normal cells was increased after 8 days of co-culture, whereas SCE in the BS cells decreased immediately with co-cultivation. In the dimorphic BS cell line (BS-SYW) the SCE frequency of a high-SCE cell population was also observed to be lower than that of a non-dimorphic BS cell line (BS2-2), thus corroborating the experimental observations under co-cultivation conditions. The decrease in BS SCE and increase in normal SCE (after a particular time period) is attributed to numerous causes discussed in relation to the cell cycle progression.     

Presence of abnormally high incidences of sister chromatid exchanges in three successive cell cycles in Bloom's syndrome lymphocytes

The frequencies of sister chromatid exchanges (SCEs) were examined in phytohaemagglutinin-stimulated blood lymphocytes of a normal individual, a Bloom's syndrome heterozygote (bl/+), and two Bloom's syndrome homozygotes (bl/bl). To determine the baseline SCE frequencies, lymphocytes were cultured with various concentrations of 5-bromodeoxyuridine (BrdUrd) for two cell cycles. The incidence of SCEs per two cell cycles inbl/bl lymphocytes levelled off at BrdUrd concentrations below 10 g/ml while that in normal andbl/+ lymphocytes stayed constant below 7.5 g/ml. The baseline SCE frequency in bl/bl cells was ten times higher than that in normal andbl/+ cells. At BrdUrd concentrations above 15 g/ml, SCEs inbl/bl cells were induced more frequently than in normal andbl/+ cells. These results indicate that at low concentrations BrdUrd has a minimal effect on the induction of SCEs in all individuals, while at higher concentrations the BrdUrd incorporated inbl/bl cells has a larger effect than that in normal andbl/+ cells. To elucidate the effect of BrdUrd incorporated into the daughter and parental DNA strands on SCE induction, SCEs occurring during each cell cycle were examined separately in three-way or two-way differentially stained, third-cycle metaphases. The incidence of SCEs detected in each cell cycle at 5 g/ml BrdUrd was constant in all individuals and the rates of SCEs in each cell cycle inbl/bl cells were remarkably higher than those observed in normal andbl/+ cells. These findings strongly indicate that most of the abnormally increased SCEs in thebl/bl cells used in our study occurred independently of any effect of BrdUrd incorporated into both the daughter and parental DNA strands. In addition, an abnormal response ofbl/bl cells to BrdUrd was not found for cell cycle progression or chromosomal aberration induction. Thus, the bl/bl cells did not exhibit an abnormal hypersensitivity to BrdUrd. From these results, it seems quite probable that the abnormally increased SCEs in thebl/bl lymphocytes used here were spontaneous.     

Effects of caffeine-pretreatment on SCE and chromosome aberrations induced by monofunctional- and bifunctional-mitomycin C in bloom syndrome lymphocytes

Bloom syndrome (BS) lymphocytes, which are characterized by a high incidence (75.4 per cell) of SCE, were treated with caffeine (CAF) during the first cell cycle and with monofunctional-(M-MC) and bifunctional-(MC)mitomycin C during the second cycle. The effect on the SCE level was synergistic. The CAF-pretreated cells in combination with M-MC and MC post-treatments, had significantly higher (SCE values 152.5 and 167.9 SCE per cell, resp.) than those treated with M-MC or MC alone during the second cycle (101.1 and 116.4 SCE per cell, resp.). M-MC and MC in the presence of BrdU (without CAF) for 2 cell cycles increased SCE to 157.6 and 169.4 per cell (about twice the control level). M-MC + CAF and MC + CAF treatments for 2 cell cycles did not produce a synergistic effect on the SCE frequency in BS cells; the SCE level was not significantly greater than that with M-MC or MC alone. Normal cells treated with MC and CAF for 2 cycles had a maximum SCE frequency of 156 per cell. This suggests that cells with SCE frequencies above this level may not be able to survive, i.e., this is the “saturation” level of SCE. However, CAF alone had almost no effect on SCE in either BS or normal cells and did not produce multiple chromosome aberrations. The lack of CAF effect on BS cells suggests that the lesions in DNA strands of BS cells which lead to SCE are double-strand lesions. In normal cells CAF is known to significantly slow down DNA-chain growth; the reduced rate of DNA-chain growth in BS is an inherent defect of the cells. Therefore, though CAF enhanced SCE and chromosome aberrations (shattered chromosomes) in combination with alkylating agents, CAF alone did not significantly increase the SCE rate in either BS cells or in normal cells. Thus, processes which may induce SCE are not only related to retarded rate of DNA-chain growth, but also to breaks in the template strand permitting double-strand exchanges to occur.     

Normal uracil-DNA glycosylase activity in Bloom's syndrome cells

Cells from patients with Bloom's syndrome, a rare human disease with autosomal recessive mode of inheritance, exhibit cytological abnormalities involving DNA metabolism. Bloom's syndrome is characterized by a greatly increased cancer frequency which may reflect a specific defect in DNA repair and replication. Evidence has recently been presented of the existence in Bloom's syndrome of an abnormality of the DNA ligase involved in semiconservative DNA replication. Another abnormality, in the excision-repair pathway of Bloom's syndrome cells, is reportedly due to an aberrant immunological reactivity of the DNA-repair enzyme uracil-DNA glycosylase. In this investigation we show, however, that the catalytic activity of uracil-DNA glycosylase appears to be normal in Bloom's syndrome lymphoblastoid cells.