Topoisomerase II deficiency leads to a postreplicative structural shift in all Saccharomyces cerevisiae chromosomes.

The key role of Topoisomerase II (Top2) is the removal of topological intertwines between sister chromatids. In yeast, inactivation of Top2 brings about distinct cell cycle responses. In the case of the conditional top2-5 allele, interphase and mitosis progress on schedule but cells suffer from a chromosome segregation catastrophe. We here show that top2-5 chromosomes fail to enter a Pulsed-Field Gel Electrophoresis (PFGE) in the first cell cycle, a behavior traditionally linked to the presence of replication and recombination intermediates. We distinguished two classes of affected chromosomes: the rDNA-bearing chromosome XII, which fails to enter a PFGE at the beginning of S-phase, and all the other chromosomes, which fail at a postreplicative stage. In synchronously cycling cells, this late PFGE retention is observed in anaphase; however, we demonstrate that this behavior is independent of cytokinesis, stabilization of anaphase bridges, spindle pulling forces and, probably, anaphase onset. Strikingly, once the PFGE retention has occurred it becomes refractory to Top2 re-activation. DNA combing, two-dimensional electrophoresis, genetic analyses, and GFP-tagged DNA damage markers suggest that neither recombination intermediates nor unfinished replication account for the postreplicative PFGE shift, which is further supported by the fact that the shift does not trigger the G2/M checkpoint. We propose that the absence of Top2 activity leads to a general chromosome structural/topological change in mitosis.

Recent Advances in Use of Topoisomerase Inhibitors in Combination Cancer Therapy.

Inhibitors targeting human topoisomerase I and topoisomerase II alpha have provided a useful chemotherapy option for the treatment of many patients suffering from a variety of cancers. While the treatment can be effective in many patient cases, use of these human topoisomerase inhibitors is limited by side-effects that can be severe. A strategy of employing the topoisomerase inhibitors in combination with other treatments can potentially sensitize the cancer to increase the therapeutic efficacy and reduce resistance or adverse side effects. The combination strategies reviewed here include inhibitors of DNA repair, epigenetic modifications, signaling modulators and immunotherapy. The ongoing investigations on cellular response to topoisomerase inhibitors and newly initiated clinical trials may lead to adoption of novel cancer therapy regimens that can effectively stop the proliferation of cancer cells while limiting the development of resistance.

Dynamic behavior of DNA topoisomerase IIß in response to DNA double-strand breaks.

DNA topoisomerase II (Topo II) is crucial for resolving topological problems of DNA and plays important roles in various cellular processes, such as replication, transcription, and chromosome segregation. Although DNA topology problems may also occur during DNA repair, the possible involvement of Topo II in this process remains to be fully investigated. Here, we show the dynamic behavior of human Topo IIß in response to DNA double-strand breaks (DSBs), which is the most harmful form of DNA damage. Live cell imaging coupled with site-directed DSB induction by laser microirradiation demonstrated rapid recruitment of EGFP-tagged Topo IIß to the DSB site. Detergent extraction followed by immunofluorescence showed the tight association of endogenous Topo IIß with DSB sites. Photobleaching analysis revealed that Topo IIß is highly mobile in the nucleus. The Topo II catalytic inhibitors ICRF-187 and ICRF-193 reduced the Topo IIß mobility and thereby prevented Topo IIß recruitment to DSBs. Furthermore, Topo IIß knockout cells exhibited increased sensitivity to bleomycin and decreased DSB repair mediated by homologous recombination (HR), implicating the role of Topo IIß in HR-mediated DSB repair. Taken together, these results highlight a novel aspect of Topo IIß functions in the cellular response to DSBs.

Genome-Scale Genetic Interactions and Cell Imaging Confirm Cytokinesis as Deleterious to Transient Topoisomerase II Deficiency in Saccharomyces cerevisiae.

Topoisomerase II (Top2) is an essential protein that resolves DNA catenations. When Top2 is inactivated, mitotic catastrophe results from massive entanglement of chromosomes. Top2 is also the target of many first-line anticancer drugs, the so-called Top2 poisons. Often, tumors become resistant to these drugs by acquiring hypomorphic mutations in the genes encoding Top2 Here, we have compared the cell cycle and nuclear segregation of two coisogenic Saccharomyces cerevisiae strains carrying top2 thermosensitive alleles that differ in their resistance to Top2 poisons: the broadly-used poison-sensitive top2-4 and the poison-resistant top2-5 Furthermore, we have performed genome-scale synthetic genetic array (SGA) analyses for both alleles under permissive conditions, chronic sublethal Top2 downregulation, and acute, yet transient, Top2 inactivation. We find that slowing down mitotic progression, especially at the time of execution of the mitotic exit network (MEN), protects against Top2 deficiency. In all conditions, genetic protection was stronger in top2-5; this correlated with cell biology experiments in this mutant, whereby we observed destabilization of both chromatin and ultrafine anaphase bridges by execution of MEN and cytokinesis. Interestingly, whereas transient inactivation of the critical MEN driver Cdc15 partly suppressed top2-5 lethality, this was not the case when earlier steps within anaphase were disrupted; i.e., top2-5 cdc14-1 We discuss the basis of this difference and suggest that accelerated progression through mitosis may be a therapeutic strategy to hypersensitize cancer cells carrying hypomorphic mutations in TOP2.

Topoisomerase IIß Selectively Regulates Motor Neuron Identity and Peripheral Connectivity through Hox/Pbx-Dependent Transcriptional Programs.

Vital motor functions, such as respiration and locomotion, rely on the ability of spinal motor neurons (MNs) to acquire stereotypical positions in the ventral spinal cord and to project with high precision to their peripheral targets. These key properties of MNs emerge during development through transcriptional programs that dictate their subtype identity and connectivity; however, the molecular mechanisms that establish the transcriptional landscape necessary for MN specification are not fully understood. Here, we show that the enzyme topoisomerase IIß (Top2ß) controls MN migration and connectivity. Surprisingly, Top2ß is not required for MN generation or survival but has a selective role in columnar specification. In the absence of Top2ß, phrenic MN identity is eroded, while other motor columns are partially preserved but fail to cluster to their proper position. In Top2ß-/- mice, peripheral connectivity is impaired as MNs exhibit a profound deficit in terminal branching. These defects likely result from the insufficient activation of Hox/Pbx-dependent transcriptional programs as Hox and Pbx genes are downregulated in the absence of Top2ß. Top2ß mutants recapitulate many aspects of Pbx mutant mice, such as MN disorganization and defects in medial motor column (MMC) specification. Our findings indicate that Top2ß, a gene implicated in neurodevelopmental diseases such as autism spectrum disorders, plays a critical, cell-specific role in the assembly of motor circuits.

Topoisomerases facilitate transcription of long genes linked to autism.

Topoisomerases are expressed throughout the developing and adult brain and are mutated in some individuals with autism spectrum disorder (ASD). However, how topoisomerases are mechanistically connected to ASD is unknown. Here we find that topotecan, a topoisomerase 1 (TOP1) inhibitor, dose-dependently reduces the expression of extremely long genes in mouse and human neurons, including nearly all genes that are longer than 200 kilobases. Expression of long genes is also reduced after knockdown of Top1 or Top2b in neurons, highlighting that both enzymes are required for full expression of long genes. By mapping RNA polymerase II density genome-wide in neurons, we found that this length-dependent effect on gene expression was due to impaired transcription elongation. Interestingly, many high-confidence ASD candidate genes are exceptionally long and were reduced in expression after TOP1 inhibition. Our findings suggest that chemicals and genetic mutations that impair topoisomerases could commonly contribute to ASD and other neurodevelopmental disorders.

Topoisomerase IIß deficiency enhances camptothecin-induced apoptosis.

Camptothecin (CPT), a topoisomerase (Top) I-targeting drug that stabilizes Top1-DNA covalent adducts, can induce S-phase-specific cytotoxicity due to the arrest of progressing replication forks. However, CPT-induced non-S-phase cytotoxicity is less well characterized. In this study, we have identified topoisomerase IIß (Top2ß) as a specific determinant for CPT sensitivity, but not for many other cytotoxic agents, in non-S-phase cells. First, quiescent mouse embryonic fibroblasts (MEFs) lacking Top2ß were shown to be hypersensitive to CPT with prominent induction of apoptosis. Second, ICRF-187, a Top2 catalytic inhibitor known to deplete Top2ß, specifically sensitized MEFs to CPT. To explore the molecular basis for CPT hypersensitivity in Top2ß-deficient cells, we found that upon CPT exposure, the RNA polymerase II large subunit (RNAP LS) became progressively depleted, followed by recovery to nearly the original level in wild-type MEFs, whereas RNAP LS remained depleted without recovery in Top2ß-deficient cells. Concomitant with the reduction of the RNAP LS level, the p53 protein level was greatly induced. Interestingly, RNAP LS depletion has been well documented to lead to p53-dependent apoptosis. Altogether, our findings support a model in which Top2ß deficiency promotes CPT-induced apoptosis in quiescent non-S-phase cells, possibly due to RNAP LS depletion and p53 accumulation.

Effects of conditional depletion of topoisomerase II on cell cycle progression in mammalian cells.

Topoisomerase II (Topo II) that decatenates newly synthesized DNA is targeted by many anticancer drugs. Some of these drugs stabilize intermediate complexes of DNA with Topo II and others act as catalytic inhibitors of Topo II. Simultaneous depletion of Topo IIα and Topo IIß, the two isoforms of mammalian Topo II, prevents cell growth and normal mitosis, but the role of Topo II in other phases of mammalian cell cycle has not yet been elucidated. We have developed a derivative of p53-suppressed human cells with constitutive depletion of Topo IIß and doxycycline-regulated conditional depletion of Topo IIα. The effects of Topo II depletion on cell cycle progression were analyzed by time-lapse video microscopy, pulse-chase flow cytometry and mitotic morphology. Topo II depletion increased the duration of the cell cycle and mitosis, interfered with chromosome condensation and sister chromatid segregation and led to frequent failure of cell division, ending in either cell death or restitution of polyploid cells. Topo II depletion did not change the rate of DNA replication but increased the duration of G 2. These results define the effects of decreased Topo II activity, rather than intermediate complex stabilization, on the mammalian cell cycle.

Dietary isothiocyanate-induced apoptosis via thiol modification of DNA topoisomerase IIα.

Studies in animal models have indicated that dietary isothiocyanates (ITCs) exhibit cancer preventive activities through carcinogen detoxification-dependent and -independent mechanisms. The carcinogen detoxification-independent mechanism of cancer prevention by ITCs has been attributed at least in part to their ability to induce apoptosis of transformed (initiated) cells (e.g. through suppression of IκB kinase and nuclear factor κB as well as other proposed mechanisms). In the current studies we show that ITC-induced apoptosis of oncogene-transformed cells involves thiol modification of DNA topoisomerase II (Top2) based on the following observations. 1) siRNA-mediated knockdown of Top2α in both SV40-transformed MEFs and Ras-transformed human mammary epithelial MCF-10A cells resulted in reduced ITC sensitivity. 2) ITCs, like some anticancer drugs and cancer-preventive dietary components, were shown to induce reversible Top2α cleavage complexes in vitro. 3) ITC-induced Top2α cleavage complexes were abolished by co-incubation with excess glutathione. In addition, proteomic analysis revealed that several cysteine residues on human Top2α were covalently modified by benzyl-ITC, suggesting that ITC-induced Top2α cleavage complexes may involve cysteine modification. Interestingly, consistent with the thiol modification mechanism for Top2α cleavage complex induction, the thiol-reactive selenocysteine, but not the non-thiol-reactive selenomethionine, was shown to induce Top2α cleavage complexes. In the aggregate, our results suggest that thiol modification of Top2α may contribute to apoptosis induction in transformed cells by ITCs.

Depletion of topoisomerase IIalpha leads to shortening of the metaphase interkinetochore distance and abnormal persistence of PICH-coated anaphase threads.

Topoisomerase II (topo II) is a major component of mitotic chromosomes, and its unique decatenating activity has been implicated in many aspects of chromosome dynamics, of which chromosome segregation is the most seriously affected by loss of topo II activity in living cells. There is considerable evidence that topo II plays a role at the centromere including: the centromere-specific accumulation of topo II protein; cytogenetic/molecular mapping of the catalytic activity of topo II to active centromeres; the influence of sumoylated topo II on sister centromere cohesion; and its involvement in the activation of a Mad2-dependent spindle checkpoint. By using a human cell line with a conditional-lethal mutation in the gene encoding DNA topoisomerase IIalpha, we find that depletion of topo IIalpha, while leading to a disorganised metaphase plate, does not have any overt effect on general assembly of kinetochores. Fluorescence in situ hybridisation suggested that centromeres segregate normally, most segregation errors being chromatin bridges involving longer chromosome arms. Strikingly, a linear human X centromere-based minichromosome also displayed a significantly increased rate of missegregation. This sensitivity to depletion of topo IIalpha might be linked to structural alterations within the centromere domain, as indicated by a significant shortening of the distance across metaphase sister centromeres and the abnormal persistence of PICH-coated connections between segregating chromatids.

Role of DNA topoisomerase IIbeta in neurite outgrowth.

Failure to establish neuromuscular junctions is a major phenotype of top2beta knockout mice. However, the precise mechanism for this defect is not known. In the current study, we have investigated the role of TopIIbeta in cultured neurons. We showed that the TopII inhibitor ICRF-193 significantly blocked neurite outgrowth and growth cone formation in cultured cerebellar granule neurons (CGNs), dorsal root ganglions (DRGs) and cortical neurons (CNs). In addition, ICRF-193 also blocked neurite outgrowth and growth cone formation of PC12 cells undergoing NGF-induced differentiation. Isolated cortical neurons from top2beta knockout embryos elaborated shorter neurites than did those from their wild type counterparts, confirming the role of TopIIbeta in neurite outgrowth. Together, these results demonstrate a critical role of TopIIbeta in neurite outgrowth in cultured neurons. Furthermore, we demonstrated that neurons derived from top2beta knockout mice failed to form contacts with muscle cells in co-cultures. These results suggest that the defect in establishing neuromuscular junctions in top2beta knockout mice could be due to the lack of TopIIbeta-mediated neurite outgrowth.

Cells lacking DNA topoisomerase II beta are resistant to genistein.

Evidence suggests that DNA topoisomerases (topos) may be involved in the anticancer and carcinogenic properties attributed to flavonoids. Using the cell-based assay TARDIS, the dietary flavonoids genistein (1) and luteolin (2) have been evaluated as topo I and topo II poisons and catalytic inhibitors in K562 leukemia cells. Both flavonoids induced topo II-DNA complexes, but they did not induce significant levels of topo I-DNA complexes. Genistein decreased the topo II-DNA complexes induced by the topo II poison etoposide, suggestive of a catalytic inhibition of topo II, and luteolin decreased the topo I-DNA complexes induced by the topo I poison camptothecin, indicative of a catalytic inhibition of topo I. Murine transgenic cells lacking topo II beta were resistant to genistein-induced cell growth inhibition (XTT assays) and cytotoxicity (clonogenic assay). High levels of topo II beta-DNA complexes were also observed in K562 cells exposed to genistein. These data suggest that topo II beta has an important function in genistein-induced cell growth inhibition and cell death. The possible role of topoisomerases in the putative anticancer and carcinogenic properties of genistein and luteolin is discussed.

Sequence-specific potentiation of topoisomerase II inhibitors by the histone deacetylase inhibitor suberoylanilide hydroxamic acid.

Acetylation of histones leads to conformational changes of DNA. We have previously shown that the histone deacetylase (HDAC) inhibitor, suberoylanilide hydroxamic acid (SAHA), induced cell cycle arrest, differentiation, and apoptosis. In addition to their antitumor effects as single agents, HDAC inhibitors may cause conformational changes in the chromatin, rendering the DNA more vulnerable to DNA damaging agents. We examined the effects of SAHA on cell death induced by topo II inhibitors in breast cancer cell lines. Topo II inhibitors stabilize the topo II-DNA complex, resulting in DNA damage. Treatment of cells with SAHA promoted chromatin decondensation associated with increased nuclear concentration and DNA binding of the topo II inhibitor and subsequent potentiation of DNA damage. While SAHA-induced histone hyperacetylation occurred as early as 4 h, chromatin decondensation was most profound at 48 h. SAHA-induced potentiation of topo II inhibitors was sequence-specific. Pre-exposure of cells to SAHA for 48 h was synergistic, whereas shorter pre-exposure periods abrogated synergy and exposure of cells to SAHA after the topo II inhibitor resulted in antagonistic effects. Synergy was not observed in cells with depleted topo II levels. These effects were not limited to specific types of topo II inhibitors. We propose that SAHA significantly potentiates the DNA damage induced by topo II inhibitors; however, synergy is dependent on the sequence of drug administration and the expression of the target. These findings may impact the clinical development of combining HDAC inhibitors with DNA damaging agents.

Aberrant lamination in the cerebral cortex of mouse embryos lacking DNA topoisomerase IIbeta.

We have examined corticogenesis in mouse embryos lacking DNA topoisomerase IIbeta (IIbeta) in the brain or in all tissues. The absence of IIbeta, a type II DNA topoisomerase normally expressed in postmitotic cells in the developing cortex, severely affects cerebral stratification: no subplate is discernible, and neurons born at later stages of corticogenesis fail to migrate to the superficial layers. This abnormal pattern of neuron positioning in the cerebral cortex is reminiscent of that observed in mouse mutants defective in the reelin-signaling pathway. Significantly, the level of reelin in the neocortex is much reduced when IIbeta is absent. These results implicate a role of IIbeta in brain development. The enzyme may be required in implementing particular genetic programs in postmitotic cells, such as reelin expression in Cajal-Retzius cells, perhaps through its action on nucleoprotein structure of particular chromosomal regions.

Enforced cytokinesis without complete nuclear division in embryonic cells depleting the activity of DNA topoisomerase IIalpha.

BACKGROUND: There are two distinct DNA topoisomerase II (topo II) isoforms, designated topo IIalpha and topo IIbeta, in mammalian cells. The function of topo IIalpha in the development of mammalian cells has not been elucidated because of a lack of topo IIalpha mutants. RESULTS: We generated mice with a targeted disruption of the topo IIalpha gene. The development of topo IIalpha-/- embryos was terminated at the 4- or 8-cell stage. When wild-type embryos at the 2- or 4-cell stage were treated with ICRF-193, a catalytic inhibitor of topo II, nuclear division occurred followed by cytokinesis to form 4 or 8 cells, respectively, then development was terminated. Microscope analysis of 4,6-diamidino-2-phenylindole (DAPI)-stained nuclei of both topo IIalpha-/- and ICFR-193-treated embryonic cells revealed a droplet-like structure connecting the terminals of two adjacent nuclei forming a bridge-like structure. Phosphorylated histone H3, a marker for the M phases, disappeared from the nuclei of the topo IIalpha-depleted embryonic cells. Laser scanning cytometry of the topo IIalpha-depleted cells revealed the presence of 2N DNA cells. CONCLUSIONS: Our results indicate that topo IIalpha has an essential role in the early stages of mouse development and that depletion of topo IIalpha from the embryonic cells causes incomplete nuclear division followed by enforced cytokinesis.

Design, synthesis, and biological evaluation of a series of fluoroquinoanthroxazines with contrasting dual mechanisms of action against topoisomerase II and G-quadruplexes.

Topoisomerase inhibitors are important and clinically effective drugs, while G-quadruplex-interactive compounds that disrupt telomere maintenance mechanisms have yet to be proven useful in the clinic. If G-quadruplex-interactive compounds are to be clinically useful, it will most likely be in combination with more established cytotoxic agents. We have previously reported on a family of topoisomerase II inhibitors that also interact with G-quadruplexes. On the basis of previously established structure-activity relationships (SARs) for compounds that are able to inhibit topoisomerase II or interact with G-quadruplex to varying degrees, we have now designed and synthesized four new fluoroquinoanthroxazines (FQAs) that have different profiles of mixed topoisomerase II poisoning effects and G-quadruplex interactions. The biological profiles of the four new compounds were determined with respect to G-quadruplex interaction (polymerase stop and photocleavage assays) and topoisomerase II interaction (DNA cleavage and kDNA decatenation assays), alongside cytotoxicity tests with matched pairs of topoisomerase II-resistant and topoisomerase II-sensitive cells and with telomerase (+) and ALT (+) cell lines (ALT = alternative lengthening of telomeres). From this study, we have identified two FQAs with sharply contrasting profiles of potent G-quadruplex interaction with a weak topoisomerase II poisoning effect, and vice versa, for further evaluation to determine the optimum combination of these activities in subsequent in vivo studies.

Mice deficient for the type II topoisomerase-like DNA transesterase Spo11 show normal immunoglobulin somatic hypermutation and class switching.

Somatic hypermutation in B cells undergoing T cell dependent immune responses generates high affinity antibodies that provide protective immunity. B cells also switch from the expression of immunoglobulin (Ig) M and IgD to that of other Ig classes through somatic DNA recombination. Recent work has implicated DNA strand breaks, possibly DNA double strand breaks (DSB), as the initiating lesions in both class switch recombination and hypermutation, although the etiology of these lesions is not understood. Spo11, a protein structurally related to archaeal type II topoisomerases, generates DSB that initiate meiotic recombination. This characteristic, together with its expression pattern, marks this enzyme as a potential candidate for the initiation of hypermutation, and perhaps also for Ig class switching. To investigate whether Spo11 is involved in these processes, we studied the T cell dependent immune response of Spo11-deficient (Spo11(-/-)) mice against the hapten nitrophenyl (NP). We found that V186.2-bearing IgG1 transcripts had normal levels and patterns of somatic hypermutation. Furthermore, Spo11(-/-) mice showed normal serum levels of all Ig isotypes. These results indicate that Spo11 is not required for Ig hypermutation or class switch recombination.

Quantitation of DNA topoisomerase IIalpha and beta in human leukaemia cells by immunoblotting.

DNA topoisomerase II (topo II) is an essential nuclear enzyme and is the target for etoposide, which is used in the therapy of childhood acute lymphoblastic leukaemia (ALL). Topo II exists as two isoforms referred to as topo IIalpha and topo IIbeta. To determine whether cellular levels of topo IIalpha and beta are an important factor in determining drug sensitivity/resistance requires accurate, precise measurements of the two isoforms. We have developed a quantitative Western blotting method to accurately measure the absolute amounts of human topo IIalpha and beta, using recombinant human topo IIalpha and beta as standards. This quantitative method has been used to assess the efficiency of several commonly used topo II extraction protocols. The extractable amount of topo IIalpha and beta was found to be salt-dependent. However extraction using the optimal salt concentration was found to be as efficient as extraction with DNase I/Rnase A digestion and SDS solubilisation. Using the optimum extraction procedure and the quantitative immunoblotting method, topo IIalpha and beta was quantified in cell lines, peripheral blood lymphocytes and in lymphoblasts from children with newly diagnosed ALL.

Absence of topoisomerase IIbeta in an amsacrine-resistant human leukemia cell line with mutant topoisomerase IIalpha.

Numerous chemotherapeutic agents act via stabilization of a topoisomerase (topo) II-DNA complex. HL-60/AMSA, a human leukemia cell line, is resistant to intercalator-mediated DNA complex formation and cytotoxicity. HL-60/AMSA contains a mutant form of topo IIalpha that was thought to explain this resistance. However, our present data show that expression of topo IIbeta RNA in HL-60/AMSA is only 10% of that in HL-60, and topo IIbeta protein levels are undetectable. Southern analysis of topo IIbeta shows no differences in gene dosage between the two cell lines but does show differences in the restriction patterns. These data suggest that decreased topo IIbeta expression may contribute to the intercalator resistance of HL-60/AMSA cells.