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.     

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.     

Premature aging in RecQ helicase-deficient human syndromes

The RecQ family of DNA helicases have potential roles in DNA repair, replication and/or recombination pathways. In humans, a defect in the RecQ family helicases encoded by the BLM, WRN and RECQ4 genes gives rise to Bloom's (BS), Werner's (WS) and Rothmund-Thomson (RTS) syndromes, respectively. These disorders are associated with cancer predisposition and/or premature aging. In Bloom's syndrome, affected individuals are predisposed to many types of cancer at an early age. Werner's syndrome is a premature aging disorder with a complex phenotype, which includes many age-related disorders that develop from puberty, including greying and thinning of the hair, bilateral cataract formation, type II diabetes mellitus, osteoporosis and atherosclerosis. The phenotype of Rothmund-Thomson syndrome patients also consists of some features associated with premature aging, as well as predispositon to certain cancers. Here, we discuss the molecular basis of these RecQ helicase-deficient disorders.     

The Bloom's syndrome helicase is critical for development and function of the alphabeta T-cell lineage

Bloom's syndrome is a genetic disorder characterized by increased incidence of cancer and an immunodeficiency of unknown origin. The BLM gene mutated in Bloom's syndrome encodes a DNA helicase involved in the maintenance of genomic integrity. To explore the role of BLM in the immune system, we ablated murine Blm in the T-cell lineage. In the absence of Blm, thymocytes were severely reduced in numbers and displayed a developmental block at the beta-selection checkpoint that was partially p53 dependent. Blm-deficient thymocytes rearranged their T-cell receptor (TCR) beta genes normally yet failed to survive and proliferate in response to pre-TCR signaling. Furthermore, peripheral T cells were reduced in numbers, manifested defective homeostatic and TCR-induced proliferation, and produced extensive chromosomal damage. Finally, CD4(+) and CD8(+) T-cell responses were impaired upon antigen challenge. Thus, by ensuring genomic stability, Blm serves a vital role for development, maintenance, and function of T lymphocytes, suggesting a basis for the immune deficiency in Bloom's syndrome.     

Cleavage of BLM and sensitivity of Bloom's syndrome cells to hydroxurea and UV-C radiation

Patients with Bloom's syndrome (BS) show a strong genetic instability and a predisposition to all types of cancer. Here, we report that the Bloom's syndrome protein (BLM) is cleaved in response to hydroxyurea (HU)- or UVC-induced apoptosis. The appearance and solubility of BLM proteolytic products differed according to whether proteolysis occurred in response to HU or UVC. One BS cell line homozygous for a null mutation in BLM was resistant to both UVC- and HU-induced apoptosis, while another one expressing a mutated BLM protein was resistant to HU-induced apoptosis but displayed normal sensitivity to UVC. Thus, UVC and HU appear to induce apoptosis through distinct pathways.     

Purification and properties of the uracil DNA glycosylase from Bloom's syndrome.

Bloom's syndrome uracil DNA glycosylase was highly purified from two non-transformed cell strains derived from individuals from different ethnic groups. Their properties were then compared to two different highly purified normal human uracil DNA glycosylases. A molecular mass of 37 kDa was observed for each of the four human enzymes as defined by gel-filtration column chromatography and by SDS-PAGE. Each of the 37 kDa proteins was identified as a uracil DNA glycosylase by electroelution from the SDS polyacrylamide gel, determination of glycosylase activity by in vitro biochemical assay and identification of the reaction product as free uracil by co-chromatography with authentic uracil. Bloom's syndrome enzymes differed substantially in their isoelectric point and were thermolabile as compared to the normal human enzymes. Bloom's syndrome enzymes displayed a different Km, Vmax and were strikingly insensitive to 5-fluorouracil and 5-bromouracil, pyrimidine analogues which drastically decreased the activity of the normal human enzymes. In particular, each Bloom's syndrome enzyme required 10-100-fold higher concentrations of each analogue to achieve comparable inhibition of enzyme activity. Potential mechanisms are considered through which an altered uracil DNA glycosylase characterizing this cancer-prone human genetic disorder may arise.     

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.     

Immunological alteration of the Bloom's syndrome uracil DNA glycosylase in Epstein-Barr virus-transformed human lymphoblastoid cells

The immunological reactivity of the uracil DNA glycosylase was investigated in three Epstein-Barr virus-transformed human lymphoblastoid cell lines. Two were derived from normal human lymphocytes while the third was derived from a Bloom's syndrome patient. A panel of 3 anti-human placental uracil DNA glycosylase monoclonal antibodies (37.04.12, 40.10.09 and 42.08.07) was used. Immunological reactivity was determined in a double-blind enzyme-linked immunosorbent assay (ELISA); by inhibition of enzyme activity; and by immunoblot analysis. In the ELISA, the glycosylase from each lymphoblastoid cell line was recognized by glycosylase antibodies 37.04.12 and 42.08.07. In contrast, antibody 40.10.09 failed to recognize the glycosylase from the Bloom's syndrome cell line. Further analysis demonstrated that the 40.10.09 antibody was unable to inhibit catalysis by the Bloom's syndrome lymphoblast glycosylase. In contrast, the 40.10.09 antibody inhibited the activity of the two normal human lymphoblast enzymes. Denaturation of the Bloom's syndrome lymphoblast glycosylase rendered that protein immunoreactive with the 40.10.09 antibody. These results demonstrated that: (1) the immunological alteration in the Bloom's syndrome uracil DNA glycosylase was detected in hematopoietic cells; and (2) viral transformation did not affect the immunoreactivity of the enzyme from either normal human or Bloom's syndrome cells.     

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.     

Bloom's syndrome: DNA replication in cultured fibroblasts and lymphocytes

Summary Analysis of DNA fiber autoradiograms from Bloom's syndrome skin fibroblasts and blood lymphocytes shows a retarded rate of replication fork movement compared to normal adult controls. Other measurements from the autoradiograms—replication unit length, incidence of bidirectional replication, and degree of initiation synchrony—are normal in Bloom's syndrome cells. These results suggest that a slow rate of fork movement is a specific manifestation of defective DNA synthesis in all Bloom's syndrome cells.     

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.     

Bloom's syndrome in an Iranian Jewish male.

Bloom's syndrome is described in an Iranian Jewish male who subsequently developed myocardial disease. This may represent the first definitely non Ashkenazi Jewish patient in the literature and the only one to develop this complication.     

The human RAD51/RecA homologue gene is not a candidate gene for Bloom's syndrome

The human gene HSRAD51/RecA homologue has been investigated as a possible candidate gene involved in Bloom's syndrome. No mutations were found in the cDNA isolated from three different Bloom's syndrome cell lines, thus excluding the possibility that HSRAD51 is directly involved in the syndrome. Other possible candidates are discussed.     

Oligomeric ring structure of the Bloom's syndrome helicase.

Bloom's syndrome is a recessive human genetic disorder associated with an elevated incidence of many types of cancer. The Bloom's syndrome gene product, BLM, belongs to the RecQ subfamily of DNA helicases and is required for the maintenance of genomic stability in human cells - in particular, the suppression of reciprocal exchanges between sister chromatids. We have investigated the quaternary structure of BLM using a combination of size-exclusion chromatography and electron microscopy with reference-free image processing. We found that BLM forms hexameric ring structures with an overall diameter of approximately 13 nm surrounding a central hole of approximately 3.5 nm diameter. A fourfold symmetric square form with approximately 11 nm sides and a hole of approximately 4 nm diameter was also detected, which might represent a distinct oligomeric species or a side view of the hexameric form. Chromatography studies indicated that the majority of enzymatically active BLM has an apparent molecular mass of > 700 kDa, which is consistent with an oligomeric structure for BLM. This provides the first structural analysis of an oligomeric ring helicase of eukaryotic cellular origin. These results have implications for the mechanism of action of BLM and suggest that other RecQ family helicases, including the WRN protein associated with Werner's syndrome, might also adopt ring structures.     

Sister chromatid exchange and cell cycle in fibroblasts of Bloom's syndrome

Summary Sister chromatid exchange (SCE) has been studied in the fibroblasts of five Bloom's syndrome patients, one heterozygote, and two normal individuals. The high frequency of SCE already known in the lymphocytes of Bloom's syndrome was also found in the fibroblasts of all five patients. However, populations with low and high frequency of SCE were not found. In addition, chromosome aberrations appeared with a lower frequency.The cell cycle duration in the Bloom's fibroblasts appeared to be similar to that in the normal cell line, and the difference in the growth pattern appeared to be due to the variation in the mitotic index. The cell cycle lasted about 24 h in at least four of the Bloom's lines studied during the present experiments.     

The Bloom's syndrome gene product interacts with topoisomerase III

Bloom's syndrome is a rare genetic disorder associated with loss of genomic integrity and a large increase in the incidence of many types of cancer at an early age. The Bloom's syndrome gene product, BLM, belongs to the RecQ family of DNA helicases, which also includes the human Werner's and Rothmund-Thomson syndrome gene products and the Sgs1 protein of Saccharomyces cerevisiae. This family shows strong evolutionary conservation of protein structure and function. Previous studies have shown that Sgs1p interacts both physically and genetically with topoisomerase III. Here, we have investigated whether this interaction has been conserved in human cells. We show that BLM and hTOPO IIIalpha, one of two human topoisomerase III homologues, co-localize in the nucleus of human cells and can be co-immunoprecipitated from human cell extracts. Moreover, the purified BLM and hTOPO IIIalpha proteins are able to bind specifically to each other in vitro, indicating that the interaction is direct. We have mapped two independent domains on BLM that are important for mediating the interaction with hTOPO IIIalpha. Furthermore, through characterizing a genetic interaction between BLM and TOP3 in S. cerevisiae, we have identified a functional role for the hTOPO IIIalpha interaction domains in BLM.     

Transferable clastogenic activity in plasma from patients with Fanconi anemia

The present study was conducted on 13 patients with Fanconi anemia, 25 parents and 12 siblings. The chromosomal instability characteristic of this congenital breakage syndrome was associated with the presence of transferable clastogenic material in the plasma, as also reported previously for ataxia telangiectasia and Bloom's syndrome. While all plasma ultrafiltrates from homozygotes had chromosome damaging properties, the clastogenic material had to be concentrated in most heterozygotes to reach detectable levels. The clastogenic effect was exerted via the intermediacy of superoxide radicals, since it was regularly inhibited by superoxide dismutase (SOD). This adds further evidence for a prooxidant state in this hereditary disease. The autosustained clastogenic activity possibly plays a role in the progressive impairment of blood cell-producing bone marrow and may predispose patients to develop cancer and leukemia. Prophylactic use of antioxidants may be recommended, using clastogenic plasma activity as a guide.     

Position of chromosomes in the human interphase nucleus

Summary The problem of localization of chromosomes in relation to each other in the interphase nucleus of human lymphocytes was investigated by analysis of chromatid and chromosome aberrations observed in lymphocyte cultures of three patients with Fanconi's anemia, one patient with Bloom's syndrome, and in Trenimon-treated (Trenimon, Bayer) normal cells. Distribution of open gaps and breaks is highly correlated with chromosome length and distribution of breaks involved in chromatid translocations in Fanconi's anemia and in Trenimontreated cells. Both correlations are much lower in Bloom's syndrome. In Fanconi's anemia and in normal cells after Trenimon-treatment, the majority of chromatid translocations are between nonhomologous chromosomes, whereas in Bloom's syndrome mainly homologous chromosomes are involved. Statistical localization of chromosomes in relation to each other in the three-dimensional space by multidimensional scaling gives results consistent with the limited amount of independent evidence.     

Role for BLM in replication-fork restart and suppression of origin firing after replicative stress

Mutations in BLM give rise to Bloom's syndrome, a genetic disorder associated with cancer predisposition and chromosomal instability. Using a dual-labeling system in isolated chromosome fibers, we show that the BLM protein is required for two aspects of the cellular response to replicative stress: efficient replication-fork restart and suppression of new origin firing. These functions require the helicase activity of BLM and the Thr99 residue targeted by stress-activated kinases.     

Mitotic recombination and segregation of satellites in Bloom's syndrome

Mitotic recombination in satellite stalks — a phenomenon often difficult to distinguish from satellite association — was studied in a sister and a brother with Bloom's syndrome. Segregation after recombination was analyzed in the lymphocytes of the sister who had Q-bright satellites. Her cells varied greatly both in regard to the acrocentrics which displayed Q-bright satellites and the number of such satellites per cell. In 58 cells a total of 31 different patterns were seen. In 83 cells of 6 controls who also had Q-bright satellites on at least one acrocentric chromosome, not one cell was found in which the pattern differed from that characteristic of the person. Obviously exchanges between satellite stalks in patients with Bloom's syndrome are fairly frequent (estimated lower limit 6/1000) and very rare in persons who do not have this syndrome (estimated 0.1/1000).