Effects of topoisomerase II inhibition in lymphoblasts from patients with progeroid and "chromosome instability" syndromes

Cockayne syndrome group B protein uses its DNA translocase activity to promote mitotic DNA synthesis

Mitotic DNA synthesis, also known as MiDAS, has been suggested to be a form of RAD52-dependent break-induced replication (BIR) that repairs under-replicated DNA regions of the genome in mitosis prior to chromosome segregation. Cockayne syndrome group B (CSB) protein, a chromatin remodeler of the SNF2 family, has been implicated in RAD52-dependent BIR repair of stalled replication forks. However, whether CSB plays a role in MiDAS has not been characterized. Here, we report that CSB functions epistatically with RAD52 to promote MiDAS at common fragile sites in response to replication stress, and prevents genomic instability associated with defects in MiDAS. We show that CSB is dependent upon the conserved phenylalanine at position 796 (F796), which lies in the recently-reported pulling pin that is required for CSB's translocase activity, to mediate MiDAS, suggesting that CSB uses its DNA translocase activity to promote MiDAS. Structural analysis reveals that CSB shares with a subset of SNF2 family proteins a translocase regulatory region (TRR), which is important for CSB's function in MiDAS. We further demonstrate that phosphorylation of S1013 in the TRR regulates the function of CSB in MiDAS and restart of stalled forks but not in fork degradation in BRCA2-deficient cells and UV repair. Taken together, these results suggest that the DNA translocase activity of CSB in vivo is likely to be highly regulated by post-translational modification in a context-specific manner.

Efficient UV repair requires disengagement of the CSB winged helix domain from the CSB ATPase domain

The ATP-dependent chromatin remodeler CSB is implicated in a variety of different DNA repair mechanisms, including transcription-coupled nucleotide excision repair (TC-NER), base excision repair and DNA double strand break (DSB) repair. However, how CSB is regulated in these various repair processes is not well understood. Here we report that the first 30 amino acids of CSB along with two phosphorylation events on S10 and S158, previously reported to be required for CSB function in homologous recombination (HR)-mediated repair, are dispensable for repairing UV-induced DNA damage, suggesting that the regulation of CSB in these two types of repair are carried out by distinct mechanisms. In addition, we show that although the central ATPase domain of CSB is engaged in interactions with both the N- and C-terminal regions, these interactions are disrupted following UV-induced DNA damage. The UV-induced disengagement of the C-terminal region of CSB from the ATPase domain requires two conserved amino acids W1486 and L1488, which are thought to contribute to the hydrophobic core formation of the winged helix domain (WHD) at its C-terminus. Failure to undergo UV-induced dissociation of the C-terminal region of CSB from the ATPase domain is associated with impairment in its UV-induced chromatin association, its UV-induced post-translational modification as well as cell survival. Collectively, these findings suggest that UV-induced dissociation of CSB domain interactions is a necessary step in repairing UV-induced DNA damage and that the WHD of CSB plays a key role in this dissociation.

CSA and CSB play a role in the response to DNA breaks

CS proteins have been involved in the repair of a wide variety of DNA lesions. Here, we analyse the role of CS proteins in DNA break repair by studying histone H2AX phosphorylation in different cell cycle phases and DNA break repair by comet assay in CS-A and CS-B primary and transformed cells. Following methyl methane sulphate treatment a significant accumulation of unrepaired single strand breaks was detected in CS cells as compared to normal cells, leading to accumulation of double strand breaks in S and G2 phases. A delay in DSBs repair and accumulation in S and G2 phases were also observed following IR exposure. These data confirm the role of CSB in the suppression of NHEJ in S and G2 phase cells and extend this function to CSA. However, the repair kinetics of double strand breaks showed unique features for CS-A and CS-B cells suggesting that these proteins may act at different times along DNA break repair.

The involvement of CS proteins in the repair of DNA breaks may play an important role in the clinical features of CS patients.

Cockayne syndrome group B protein regulates DNA double-strand break repair and checkpoint activation

Mutations of CSB account for the majority of Cockayne syndrome (CS), a devastating hereditary disorder characterized by physical impairment, neurological degeneration and segmental premature aging. Here we report the generation of a human CSB-knockout cell line. We find that CSB facilitates HR and represses NHEJ. Loss of CSB or a CS-associated CSB mutation abrogating its ATPase activity impairs the recruitment of BRCA1, RPA and Rad51 proteins to damaged chromatin but promotes the formation of 53BP1-Rif1 damage foci in S and G2 cells. Depletion of 53BP1 rescues the formation of BRCA1 damage foci in CSB-knockout cells. In addition, knockout of CSB impairs the ATM- and Chk2-mediated DNA damage responses, promoting a premature entry into mitosis. Furthermore, we show that CSB accumulates at sites of DNA double-strand breaks (DSBs) in a transcription-dependent manner. The kinetics of DSB-induced chromatin association of CSB is distinct from that of its UV-induced chromatin association. These results reveal novel, important functions of CSB in regulating the DNA DSB repair pathway choice as well as G2/M checkpoint activation.

Serines 440 and 467 in the Werner syndrome protein are phosphorylated by DNA-PK and affects its dynamics in response to DNA double strand breaks

WRN protein, defective in Werner syndrome (WS), a human segmental progeria, is a target of serine/threonine kinases involved in sensing DNA damage. DNA-PK phosphorylates WRN in response to DNA double strand breaks (DSBs). However, the main phosphorylation sites and functional importance of the phosphorylation of WRN has remained unclear. Here, we identify Ser-440 and -467 in WRN as major phosphorylation sites mediated by DNA-PK.In vitro, DNA-PK fails to phosphorylate a GST-WRN fragment with S440A and/or S467A substitution. In addition, full length WRN with the mutation expressed in 293T cells was not phosphorylated in response to DSBs produced by bleomycin. Accumulation of the mutant WRN at the site of laser-induced DSBs occurred with the same kinetics as wild type WRN in live HeLa cells. While the wild type WRN relocalized to the nucleoli after 24 hours recovery from etoposide-induced DSBs, the mutant WRN remained mostly in the nucleoplasm. Consistent with this, WS cells expressing the mutants exhibited less DNA repair efficiency and more sensitivity to etoposide, compared to those expressing wild type. Our findings indicate that phosphorylation of Ser-440 and -467 in WRN are important for relocalization of WRN to nucleoli, and that it is required for efficient DSB repair.

Mouse WRN Helicase Domain Is Not Required for Spontaneous Homologous Recombination-Mediated DNA Deletion

Werner syndrome is a rare disorder that manifests as premature aging and age-related diseases. WRN is the gene mutated in WS, and is one of five human RecQ helicase family members. WS cells exhibit genomic instability and altered proliferation, and in vitro studies suggest that WRN has a role in suppressing homologous recombination. However, more recent studies propose that other RecQ helicases (including WRN) promote early events of homologous recombination. To study the role of WRN helicase on spontaneous homologous recombination, we obtained a mouse with a deleted WRN helicase domain and combined it with the in vivo pink-eyed unstable homologous recombination system. In this paper, we demonstrate that WRN helicase is not necessary for suppressing homologous recombination in vivo contrary to previous reports using a similar mouse model.

The cyclin-dependent kinase inhibitor 5, 6-dichloro-1-beta-D-ribofuranosylbenzimidazole induces nongenotoxic, DNA replication-independent apoptosis of normal and leukemic cells, regardless of their p53 status

Background

Current chemotherapy of human cancers focuses on the DNA damage pathway to induce a p53-mediated cellular response leading to either G1 arrest or apoptosis. However, genotoxic treatments may induce mutations and translocations that result in secondary malignancies or recurrent disease. In addition, about 50% of human cancers are associated with mutations in the p53 gene. Nongenotoxic activation of apoptosis by targeting specific molecular pathways thus provides an attractive therapeutic approach.

Methods

Normal and leukemic cells were evaluated for their sensitivity to 5, 6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) through cell viability and caspase activation tests. The apoptotic pathway induced by DRB was analysed by immunfluorescence and immunoblot analysis. H2AX phosphorylation and cell cycle analysis were performed to study the dependance of apoptosis on DNA damage and DNA replication, respectively. To investigate the role of p53 in DRB-induced apoptosis, specific p53 inhibitors were used. Statistical analysis on cell survival was performed with the test of independence.

Results

Here we report that DRB, an inhibitor of the transcriptional cyclin-dependent kinases (CDKs) 7 and 9, triggers DNA replication-independent apoptosis in normal and leukemic human cells regardless of their p53 status and without inducing DNA damage. Our data indicate that (i) in p53-competent cells, apoptosis induced by DRB relies on a cytosolic accumulation of p53 and subsequent Bax activation, (ii) in the absence of p53, it may rely on p73, and (iii) it is independent of ATM and NBS1 proteins. Notably, even apoptosis-resistant leukemic cells such as Raji were sensitive to DRB.

Conclusion

Our results indicate that DRB represents a potentially useful cancer chemotherapeutic strategy that employs both the p53-dependent and -independent apoptotic pathways without inducing genotoxic stress, thereby decreasing the risk of secondary malignancies.

Severe toxicity following induction chemotherapy for acute myelogenous leukemia in a patient with Werner's syndrome

Werner's syndrome is an autosomal recessive disorder resulting in premature aging. Most patients die in their fifth decade from malignancies or heart disease. The gene for Werner's syndrome (WRN) encodes a recQ helicase. Cells from patients with Werner's syndrome have increased sensitivity to DNA-damaging drugs in vitro. Here we present a patient with Werner's syndrome who developed severe chemotherapy-induced toxicity during treatment for acute myelogenous leukemia. We propose that lack of WRN resulted in increased sensitivity of the patient's cells to the toxicity of chemotherapy.

Role of Werner syndrome gene product helicase in carcinogenesis and in resistance to genotoxins by cancer cells

Werner syndrome (WS) is an autosomal recessive genetic disorder causing premature aging, and WRN has been identified as the causative gene of WS. The product of the WRN gene (WRN) acts as a DNA helicase with exonuclease activity, and data have accumulated showing that the WRN gene strongly participates in carcinogenesis: (1) the normal WRN gene likely participates in the immortalization of B-lymphoblastoid cell lines through telomeric crisis caused by telomere shortening, (2) a much higher incidence of rare cancers occurs in WS patients than in other kinds of patients, and (3) levels of WRN expressed in virus-transformed cells and cancer cells are usually markedly up-regulated and are inversely correlated with the sensitivity of these cells against various genotoxins, including camptothecin. In this paper, we review the events that show a close correlation of the WRN gene and WRN with carcinogenesis and their underlying molecular mechanisms.

The role of cellular senescence in Werner syndrome: toward therapeutic intervention in human premature aging

Werner syndrome (WS) is a premature aging disorder used as a model of normal human aging. WS individuals have several characteristics of normal aging, such as cataracts, hair graying, and skin aging, but manifest these at an early age. Additionally, WS individuals have high levels of inflammatory diseases, such as atherosclerosis and type 2 diabetes. The in vivo aging in WS is associated with accelerated aging of fibroblasts in culture. The cause of the accelerated senescence is not understood, but may be due to the genomic instability that is a hallmark of WS. Genome instability results in activation of stress kinases, such as p38, and the p38-specific inhibitor SB203580, prevents the accelerated senescence seen in WS fibroblasts. However, oxidative damage plays a role, as low oxygen conditions and antioxidant treatment revert some of the accelerated senescence phenotype. The effects of oxidative stress appear to be suppressible by SB203580; however, it does not appear to be transduced by p38. As SB203580 is known to inhibit other kinases in addition to p38, this suggests that more than one kinase pathway is involved. The recent development of p38 inhibitors with different binding properties, specificities, and oral bioavailability, and of new potent and selective inhibitors of JNK and MK2, will make it possible to dissect the roles of various kinase pathways in the accelerated senescence of WS cells. If this accelerated senescence is reflective of WS aging in vivo, these kinase inhibitors may well form the basis of antiaging therapies for individuals with WS.

In vivo misregulation of genes involved in apoptosis, development and oxidative stress in mice lacking both functional Werner syndrome protein and poly(ADP-ribose) polymerase-1

Werner syndrome (WS) is a rare disorder characterized by the premature onset of a number of age-related diseases. The gene responsible for WS is believed to be involved in different aspects of transcription, replication and/or DNA repair. The poly(ADP-ribose) polymerase-1 (PARP-1) enzyme is also involved in DNA repair and is known to affect transcription of several genes. In this study, we examined the expression profile of cells lacking the normal function of either or both enzymes. All mutant cells exhibited altered expression of genes normally responding to oxidative stress. Interestingly, more than 58% of misregulated genes identified in double mutant cells were not altered in cells with either the Wrn or PARP-1 mutation alone. So, the impact on gene expression profile when both Wrn and PARP-1 are mutated was greater than a simple addition of individual mutant genotype. In addition, double mutant cultured cells showed major misregulation of genes involved in apoptosis, cell cycle control, embryonic development, metabolism and signal transduction. More importantly, in vivo analyses of double mutant mice have confirmed the increased apoptosis and the developmental defects in embryos as well as the major increase in intracellular phosphorylation and oxidative DNA damage in adult tissues. They also exhibited a progressive increase in oxidative stress with age. Thus, a major result of this study is that changes in expression of several genes and physiological functions identified in vitro were confirmed in mouse embryonic and adult tissues.

Characterization of the hsp70 response in lymphoblasts from aged and centenarian subjects and differential effects of in vitro zinc supplementation

Human centenarians attract increasing interest as they hold some still undefined molecular mechanisms resulting in the achievement of exceptional old age. Recent data suggest the ability of centenarians to efficiently counter the increased cellular stress normally associated with ageing. The ubiquitous heat shock (HS) protein HSP70, expressed under the control of the heat shock transcription factor 1 (HSF-1), is recognized as one of the main chaperones associated with cell protection against stresses. In fact, HSP70 protein induction by heat, a classic well characterized cellular stress, was recently reported to be reduced in cells of most aged humans but not in centenarians. In order to investigate the molecular basis of this feature, we analyzed in vitro the time course expression of the hsp70 gene and the activation of HSF-1 in heat treated Epstein Barr virus transformed B-lymphocytes of centenarians. Our study demonstrates that lymphoblasts from centenarians maintain the transcriptional response of hsp70 gene to heat stress similar to young subjects. Such normal induction of hsp70 is associated to higher binding activity of HSF-1 that compensates an age-dependent delay in HSF-1 phosphorylation. Moreover, in vitro zinc supplementation had an age-dependent effect on hsp70 expression, indicating a role for this nutritionally important molecule and suggesting its involvement in cellular stress responses.

Increased frequency of multiradial chromosome structures in mouse embryonic fibroblasts lacking functional Werner syndrome protein and poly(ADP-ribose) polymerase-1

To determine whether the mouse Werner syndrome homologue (Wrn) and the poly (ADP-ribose) polymerase-1 (PARP-1) enzymes act in concert to prevent specific chromosomal rearrangements, mice with a mutation in the helicase domain of the Wrn gene (Wrn(Deltahel/Deltahel) mice) were crossed to PARP-1 null mice. Spectral karyotyping of the mouse metaphases was used in correlation with conventional G-banded karyotype analysis to precisely define the chromosomal aberrations in cells. Although there was no recurrent clonal chromosome aberration, PARP-1 null/Wrn(Deltahel/Deltahel) fibroblasts were distinguished by an increased frequency of chromatid breaks. Interestingly, multiradial structures were the only type of DNA rearrangement that was significantly higher in such PARP-1 null/Wrn(Deltahel/Deltahel) cells. These results indicate that Wrn and PARP-1 enzymes may be part of a protein complex involved in the processing of DNA breaks that can ultimately lead to multiradial structures when both enzymes are nonfunctional. Finally, regions of chromosomes known to be fragile sites in the mouse genome are not more prone to DNA rearrangements in the absence of both PARP-1 and functional Wrn proteins. Moreover, the low number of recurrent rearranged chromosome at any given site suggest a random mutagenesis process in PARP-1 null/Wrn(Deltahel/Deltahel) fibroblasts.

Yeast recombination pathways triggered by topoisomerase II-mediated DNA breaks

Topoisomerase II is a ubiquitous enzyme that removes knots and tangles from the genetic material by generating transient double-strand DNA breaks. While the enzyme cannot perform its essential cellular functions without cleaving DNA, this scission activity is inherently dangerous to chromosomal integrity. In fact, etoposide and other clinically important anticancer drugs kill cells by increasing levels of topoisomerase II-mediated DNA breaks. Cells rely heavily on recombination to repair double-strand DNA breaks, but the specific pathways used to repair topoisomerase II-generated DNA damage have not been defined. Therefore, Saccharomyces cerevisiae was used as a model system to delineate the recombination pathways that repair DNA breaks generated by topoisomerase II. Yeast cells that expressed wild-type or a drug-hypersensitive mutant topoisomerase II or overexpressed the wild-type enzyme were examined. Based on cytotoxicity and recombination induced by etoposide in different repair-deficient genetic backgrounds, double-strand DNA breaks generated by topoisomerase II appear to be repaired primarily by the single-strand invasion pathway of homologous recombination. Non-homologous end joining also was triggered by etoposide treatment, but this pathway was considerably less active than single-strand invasion and did not contribute significantly to cell survival in S.cerevisiae.

Asymmetry of DNA replication fork progression in Werner's syndrome

Human aging is associated with accumulation of cells that have undergone replicative senescence. The rare premature aging Werner's syndrome (WS) provides a phenocopy of normal human aging and WS patient cells recapitulate the aging phenotype in culture as they rapidly lose the ability to proliferate or replicate their DNA. WS is associated with loss of functional WRN protein. Although the biochemical properties of WRN protein, which possesses both helicase and exonuclease activities, suggest an involvement in DNA metabolism, its action in cells is not clear. Here, we provide experimental evidence for a role of the WRN protein in DNA replication in normally proliferating cells. Most importantly, we demonstrate that in the absence of functional WRN protein, replication forks from origins of bidirectional replication fail to progress normally, resulting in marked asymmetry of bidirectional forks. We propose that WRN acts in normal DNA replication to prevent collapse of replication forks or to resolve DNA junctions at stalled replication forks, and that loss of this capacity may be a contributory factor in premature aging.

Werner and Bloom helicases are involved in DNA repair in a complementary fashion

Werner syndrome (WS) is a recessive disorder characterized by premature senescence. Bloom syndrome (BS) is a recessive disorder characterized by short stature and immunodeficiency. A common characteristic of both syndromes is genomic instability leading to tumorigenesis. WRN and BLM genes causing WS and BS, encode proteins that are closely related to the RecQ helicase. We produced WRN-/-, BLM-/- and WRN(-/-)/BLM(-/-) mutants in the chicken B-cell line DT40. WRN-/- cells showed hypersensitivities to genotoxic agents, such as 4-nitroquinoline 1-oxide, camptothecin and methyl methanesulfonate. They also showed a threefold increase in targeted integration rate of exogenous DNAs, but not in sister chromatid exchange (SCE) frequency. BLM-/- cells showed hypersensitivities to the genotoxic agents as well as ultraviolet (UV) light, in addition to a 10-fold increase in targeted integration rate and an 11-fold increase in SCE frequency. In WRN(-/-)/BLM(-/-) cells, synergistically increased hypersensitivities to the genotoxic agents were observed whereas both SCE frequencies and targeted integration rates were partially diminished compared to the single mutants. Chromosomal aberrations were also synergistically increased in WRN(-/-)/BLM(-/-) cells when irradiated with UV light in late S to G(2) phases. These results suggest that both WRN and BLM may be involved in DNA repair in a complementary fashion.

26 S proteasome-mediated degradation of topoisomerase II cleavable complexes

DNA topoisomerase II (TOP2) cleavable complexes represent an unusual type of DNA damage characterized by reversible TOP2-DNA cross-links and DNA double strand breaks. Many antitumor drugs and physiological stresses are known to induce TOP2 cleavable complexes leading to apoptotic cell death and genomic instability. However, the molecular mechanism(s) for repair of TOP2 cleavable complexes remains unclear. In the current studies, we show that TOP2 cleavable complexes induced by the prototypic TOP2 poison VM-26 are proteolytically degraded by the ubiquitin/26 S proteasome pathway. Surprisingly the TOP2beta isozyme is preferentially degraded over TOP2alpha isozyme. In addition, transcription inhibitors such as 5,6-dichlorobenzimidazole riboside and camptothecin can substantially block VM-26-induced TOP2beta degradation. These results are consistent with a model in which the repair of TOP2beta cleavable complexes may involve transcription-dependent proteolysis of TOP2beta to reveal the protein-concealed double strand breaks.

Werner's syndrome cell lines are hypersensitive to camptothecin-induced chromosomal damage

Werner's syndrome (WS) is a recessive human genetic disorder associated with an elevated incidence of many types of cancer. The WS gene product, WRNp, belongs to the RecQ family of DNA helicases and is required for the maintenance of genomic stability in human cells. A possible interaction between helicases and topoisomerases that could co-operate in many aspects of DNA metabolism such as progression of the replication forks, recombination and repair has been recently suggested. In addition, sgs1 gene product in yeast, homologous to WS gene, has been shown to physically interact with topoisomerase types I and II. Earlier data from our laboratory suggested that WRN helicase might play a role in a G2 recombinational pathway of double strand breaks (DSBs) repair, co-operating with topoisomerase II. In this work, the effect of the topoisomerase I inhibitor camptothecin in WS cells has been investigated at the chromosomal level. The data from the present work suggest that the inhibition of topoisomerase I activity by camptothecin results in a higher induction of chromosomal damage in WS cell lines in the G2-phase and in the S-phase of the cell cycle compared to normal cells, perhaps associated with the defects in DNA replication synthesis.

Werner's syndrome lymphoblastoid cells are hypersensitive to topoisomerase II inhibitors in the G2 phase of the cell cycle

Werner's syndrome (WS) is a rare autosomal recessive human disorder and the patients exhibit many symptoms of accelerated ageing in their early adulthood. The gene (WRN) responsible for WS has been biochemically characterised as a 3'-5' helicase and is homologous to a number of RecQ superfamily of helicases. The yeast SGS1 helicase is considered as a human WRN homologue and SGS1 physically interacts with topoisomerases II and III. In view of this, it has been hypothesised that the WRN gene may also interact with topoisomerases II and III. The purpose of this study is to determine whether the loss of function of WRN protein alters the sensitivity of WS cells to agents that block the action of topoisomerase II. This study deals with the comparison of the chromosomal damage induced by the two anti-topoisomerase II drugs, VP-16 and amsacrine, in both G1 and G2 phases of the cell cycle, in lymphoblastoid cells from WS patients and from a healthy donor. Our results show that the WS cell lines are hypersensitive to chromosome damage induced by VP-16 and amsacrine only in the G2 phase of the cell cycle. No difference either in the yield of the induced aberrations or SCEs was found after treatment of cells at G1 stage. These data might suggest that in WS cells, because of the mutation of the WRN protein, the inhibition of topoisomerase II activity results in a higher rate of misrepair, probably due to some compromised G2 phase processes involving the WRN protein.

The Werner syndrome gene product co-purifies with the DNA replication complex and interacts with PCNA and topoisomerase I

Werner syndrome (WS) is a recessive disorder characterized by genomic instability and by the premature onset of a number of age-related diseases. To understand the molecular basis of this disease, we deleted a segment of the murine Wrn gene and created Wrn-deficient embryonic stem (ES) cells. At the molecular level, wild type-but not mutant-WS protein co-purifies through a series of centrifugation, chromatography, and sucrose gradient steps with the well characterized 17 S multiprotein DNA replication complex. Furthermore, wild type WS protein co-immunoprecipitates with a prominent component of the multiprotein replication complex, proliferating cell nuclear antigen (PCNA). In vitro studies also indicate that PCNA binds to a region in the N terminus portion of the WS protein containing a potential 3'-5' exonuclease domain. Finally, human WS protein also co-immunoprecipitates with both PCNA and topoisomerase I. These results suggest that the WS protein interacts with several components of the DNA replication fork.

Localization of the Bloom syndrome helicase to punctate nuclear structures and the nuclear matrix and regulation during the cell cycle: comparison with the Werner's syndrome helicase

The Bloom (BLM) and Werner's (WRN) syndrome proteins may regulate recombination and DNA repair. Using a novel polyclonal antibody to human BLM, we detected the 170-kda BLM antigen in wild-type but not Bloom syndrome cells. BLM was localized to punctate nuclear structures. The level of BLM but not WRN was 3.6 fold-higher in G(1)/S-synchronized fibroblasts than in G(0)-synchronized fibroblasts. BLM-positive cells invariably expressed topoisomerase IIalpha, whereas topoisomerase IIbeta was expressed constitutively. Transfections of BLM deletion mutants demonstrated that the C-terminal domain of BLM mediated nuclear entry and the central helicase domain was necessary for producing the punctate pattern. By subcellular fractionation, BLM was found primarily in high-salt extracts of the nucleoplasm and the nuclear matrix and was enriched in G(1)/S-synchronized cells compared with G(0)-synchronized cells. There was no interaction between BLM and WRN or topoisomerases IIalpha and IIbeta in fibroblasts. These results demonstrate that BLM is targeted to specific nuclear structures and that its expression is enhanced during cell growth. The known nucleolar localization of WRN, its invariant expression during the cell cycle, and the lack of interaction between BLM and WRN suggest distinct roles for BLM and WRN in processes such as DNA repair and recombination.

RNA synthesis block by 5, 6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) triggers p53-dependent apoptosis in human colon carcinoma cells

Most modern chemo- and radiotherapy treatments of human cancers use the DNA damage pathway, which induces a p53 response leading to either G1 arrest or apoptosis. However, such treatments can induce mutations and translocations leading to secondary malignancies or recurrent disease, which often have a poor prognosis because of resistance to therapy. Here we report that 5, 6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), an inhibitor of CDK7 TFIIH-associated kinase, CKI and CKII kinases, blocking RNA polymerase II in the early elongation stage, triggers p53-dependent apoptosis in human colon adenocarcinoma cells in a transcription independent manner. The fact that DRB kills tumour-derived cells without employment of DNA damage gives rise to the possibility of the development of a new alternative chemotherapeutic treatment of tumours expressing wild type p53, with a decreased risk of therapy-related, secondary malignancies.

A deletion within the murine Werner syndrome helicase induces sensitivity to inhibitors of topoisomerase and loss of cellular proliferative capacity

Werner syndrome (WS) is an autosomal recessive disorder characterized by genomic instability and the premature onset of a number of age-related diseases. The gene responsible for WS encodes a member of the RecQ-like subfamily of DNA helicases. Here we show that its murine homologue maps to murine chromosome 8 in a region syntenic with the human WRN gene. We have deleted a segment of this gene and created Wrn-deficient embryonic stem (ES) cells and WS mice. While displaying reduced embryonic survival, live-born WS mice otherwise appear normal during their first year of life. Nonetheless, although several DNA repair systems are apparently intact in homozygous WS ES cells, such cells display a higher mutation rate and are significantly more sensitive to topoisomerase inhibitors (especially camptothecin) than are wild-type ES cells. Furthermore, mouse embryo fibroblasts derived from homozygous WS embryos show premature loss of proliferative capacity. At the molecular level, wild-type, but not mutant, WS protein copurifies through a series of centrifugation and chromatography steps with a multiprotein DNA replication complex.

Cellular resistance to topoisomerase-targeted drugs: from drug uptake to cell death

DNA topoisomerase inhibitors are important antineoplastic agents used in the treatment of both leukemias and solid tumors, such as breast, lung and colon cancers. Their clinical usefulness is limited by both natural and acquired tumor cell resistance, which almost always is multifactorial in nature. The resistance can be due to pretarget events, such as drug accumulation, metabolism and intracellular drug distribution, or due to reduced drug-target interaction. More recently, post-target events, such as macromolecular synthesis, cell cycle progression, DNA repair/recombination and regulation of cell death, have been shown to play an important role in the sensitivity toward topoisomerase inhibitors. The different mechanisms involved in the cellular resistance toward clinically used topoisomerase inhibitors will be reviewed in this article with particular emphasis on post-target events.

Aging and apoptosis control

The phenomenon of aging is distinct from processes associated with advanced age known to increase risk of diseases, such as cancer. Furthermore, the process of aging is not necessarily related to phenomena such as in vitro replicative senescence; however, any unifying hypothesis of aging must account for all age-dependent phenomena, including senescence. It is proposed that apoptosis forms the ultimate protective process for preservation of phenotypic fidelity in multicellular organisms since it is the process by which the organism detects damage and replaces the defective cell. Time-dependent degeneration of apoptosis control is the rate-limiting step in the process of aging.

Hutchinson-Gilford progeria: faithful DNA maintenance, inheritance and allelic transcription of beta(1-4) galactosyltransferase

Hutchinson-Gilford progeria syndrome (HGPS) is a fatal segmental aging disorder affecting children. There is a paucity of prior data at the nucleotide level on DNA maintenance in HGPS. We have examined the specific nucleotide sequences and production of allelic transcripts from the locus GGTB2 encoding beta(1-4) galactosyltransferase. Quantitative Northern blots of mRNA from HGPS and control fibroblasts indicated identical mature beta(1-4) galactosyltransferase transcript sizes and amounts, regardless of their altered glycosylation status. DNA sequencing of cDNA derived from HGPS beta(1-4) galactosyltransferase mRNA populations confirmed the encoded amino acid sequence was unaffected. Population studies of 41 unrelated individuals provided allelic frequency estimates for a novel FokI polymorphism, which was identified in two of six progeria cell strains. The polymorphism was faithfully inherited in a progeria pedigree in a Mendelian manner. Furthermore, the polymorphism provided direct evidence through sequencing of reverse transcription polymerase chain reaction products that both alleles were transcribed and generated mature mRNA. Any defects in transcripts were below detectable levels over the lengths of coding sequences examined, despite multiple replication events from conception leading to the production and maintenance of patient-derived cells. These results indicate faithful transcription in HGPS.

Detection of hyperdiploidy and chromosome breakage affecting the 1 (1cen-q12) region in lentigo malignant melanoma (LMM), superficial spreading melanoma (SSM) and congenital nevus (CN) cells in vitro by the multicolor FISH technique

The centric/pericentric region of chromosome 1 (cen-q 2) of human melanoma cells of different stages of carcinogenicity (superficial spreading melanoma (SSM), lentigo malignant melanoma (LMM)) and premalignant precursor lesions (congenital nevus (CN)) were investigated by fluorescence in situ hybridization (FISH) with tandem DNA probes. The pericentric heterochromatin region 1(q12) is large and highly prone to breakage in contrast to the adjacent centromeric region which is much smaller and less prone to such events. All samples of melanoma cells were obtained from patients and cultivated in vitro. LMM cells showed the highest number of breakage events within the 1q12 region (90% of cells). The number of hyperdiploid cells was not increased in comparison to CN cells. In contrast to LMM cells, SSM cells showed a significant increased number of hyperdiploid cells which were mainly tetrasomic for chromosome 1 (P < or = 0.05). The number of chromosome breaks was not significantly increased in this type of melanoma cells. The spontaneous rates of chromosomal breakage and hyperdiploidy is relatively low in CN cells (1.5-2.5% and 3.2-5.8%, respectively) but these frequencies also differ between CN samples from different patients. These results show that the multicolor FISH technique represents a fast and reliable detection method, distinguishing structural and numerical chromosomal alterations in interphase nuclei. This technique is useful as a histological marker to differentiate between specific tumor subtypes and to investigate the relationship between genomic instability and clinopathological parameters (tumor grading and staging).