New insights into the formation and resolution of ultra-fine anaphase bridges

Recent data indicate an unexpected requirement for proteins that were hitherto considered to be dedicated to DNA repair to facilitate the faithful disjunction of sister chromatids in anaphase. These include the Bloom's syndrome gene product, BLM and its partners, as well as a number of proteins that are important for preventing Fanconi anemia (FA) in man. As part of an analysis of the roles of these proteins in mitosis, we identified a novel class of anaphase bridge structure, called an ultra-fine anaphase bridge (UFB). These UFBs are also defined by the presence of a SNF2 family protein called PICH. In this review, we will discuss the possible sources of UFBs, and how the BLM, PICH and FA proteins might serve to process these structures in order to maintain genome stability.     

On the regulation,function, and localization of the DNA-dependent ATPase PICH

The putative chromatin remodeling enzyme Plk1-interacting checkpoint helicase (PICH) was discovered as an interaction partner and substrate of the mitotic kinase Plk1. During mitosis PICH associates with centromeres and kinetochores and, most interestingly, constitutes a robust marker for ultrafine DNA bridges (UFBs) that connect separating chromatids in anaphase cells. The precise roles of PICH remain to be clarified. Here, we have used antibody microinjection and siRNA-rescue experiments to study PICH function and localization during M phase progression, with particular emphasis on the role of the predicted ATPase domain and the regulation of PICH localization by Plk1. We show that interference with PICH function results in chromatin bridge formation and micronucleation and that ATPase activity is critical for PICH function. Interestingly, an intact ATPase domain of PICH is required for prevention of chromatin bridge formation but not for UFB resolution, and quantitative analyses of UFB and chromatin bridge frequencies suggest that these structures are of different etiologies. We also show that the ATPase activity of PICH is required for temporal and spatial control of PICH localization to chromatin and that Plk1 likely controls PICH localization through phosphorylation of proteins distinct from PICH itself. This work strengthens the view that PICH is an important, Plk1-regulated enzyme, whose ATPase activity is essential for maintenance of genome integrity. Although not required for the spindle assembly checkpoint, PICH is clearly important for faithful chromosome segregation.     

Bloom's syndrome and PICH helicases cooperate with topoisomerase IIα in centromere disjunction before anaphase

Centromeres are specialized chromosome domains that control chromosome segregation during mitosis, but little is known about the mechanisms underlying the maintenance of their integrity. Centromeric ultrafine anaphase bridges are physiological DNA structures thought to contain unresolved DNA catenations between the centromeres separating during anaphase. BLM and PICH helicases colocalize at these ultrafine anaphase bridges and promote their resolution. As PICH is detectable at centromeres from prometaphase onwards, we hypothesized that BLM might also be located at centromeres and that the two proteins might cooperate to resolve DNA catenations before the onset of anaphase. Using immunofluorescence analyses, we demonstrated the recruitment of BLM to centromeres from G2 phase to mitosis. With a combination of fluorescence in situ hybridization, electron microscopy, RNA interference, chromosome spreads and chromatin immunoprecipitation, we showed that both BLM-deficient and PICH-deficient prometaphase cells displayed changes in centromere structure. These cells also had a higher frequency of centromeric non disjunction in the absence of cohesin, suggesting the persistence of catenations. Both proteins were required for the correct recruitment to the centromere of active topoisomerase IIα, an enzyme specialized in the catenation/decatenation process. These observations reveal the existence of a functional relationship between BLM, PICH and topoisomerase IIα in the centromere decatenation process. They indicate that the higher frequency of centromeric ultrafine anaphase bridges in BLM-deficient cells and in cells treated with topoisomerase IIα inhibitors is probably due not only to unresolved physiological ultrafine anaphase bridges, but also to newly formed ultrafine anaphase bridges. We suggest that BLM and PICH cooperate in rendering centromeric catenates accessible to topoisomerase IIα, thereby facilitating correct centromere disjunction and preventing the formation of supernumerary centromeric ultrafine anaphase bridges.     

TopBP1/Dpb11 binds DNA anaphase bridges to prevent genome instability

DNA anaphase bridges are a potential source of genome instability that may lead to chromosome breakage or nondisjunction during mitosis. Two classes of anaphase bridges can be distinguished: DAPI-positive chromatin bridges and DAPI-negative ultrafine DNA bridges (UFBs). Here, we establish budding yeast Saccharomyces cerevisiae and the avian DT40 cell line as model systems for studying DNA anaphase bridges and show that TopBP1/Dpb11 plays an evolutionarily conserved role in their metabolism. Together with the single-stranded DNA binding protein RPA, TopBP1/Dpb11 binds to UFBs, and depletion of TopBP1/Dpb11 led to an accumulation of chromatin bridges. Importantly, the NoCut checkpoint that delays progression from anaphase to abscission in yeast was activated by both UFBs and chromatin bridges independently of Dpb11, and disruption of the NoCut checkpoint in Dpb11-depleted cells led to genome instability. In conclusion, we propose that TopBP1/Dpb11 prevents accumulation of anaphase bridges via stimulation of the Mec1/ATR kinase and suppression of homologous recombination.     

PICH and BLM limit histone association with anaphase centromeric DNA threads and promote their resolution

Centromeres nucleate the formation of kinetochores and are vital for chromosome segregation during mitosis. The SNF2 family helicase PICH (Plk1-interacting checkpoint helicase) and the BLM (the Bloom's syndrome protein) helicase decorate ultrafine histone-negative DNA threads that link the segregating sister centromeres during anaphase. The functions of PICH and BLM at these threads are not understood, however. Here, we show that PICH binds to BLM and enables BLM localization to anaphase centromeric threads. PICH- or BLM-RNAi cells fail to resolve these threads in anaphase. The fragmented threads form centromeric-chromatin-containing micronuclei in daughter cells. Anaphase threads in PICH- and BLM-RNAi cells contain histones and centromere markers. Recombinant purified PICH has nucleosome remodelling activities in vitro. We propose that PICH and BLM unravel centromeric chromatin and keep anaphase DNA threads mostly free of nucleosomes, thus allowing these threads to span long distances between rapidly segregating centromeres without breakage and providing a spatiotemporal window for their resolution.     

Cohesin removal precedes topoisomerase IIα-dependent decatenation at centromeres in male mammalian meiosis II

Sister chromatid cohesion is regulated by cohesin complexes and topoisomerase IIα. Although relevant studies have shed some light on the relationship between these two mechanisms of cohesion during mammalian mitosis, their interplay during mammalian meiosis remains unknown. In the present study, we have studied the dynamics of topoisomerase IIα in relation to that of the cohesin subunits RAD21 and REC8, the shugoshin-like 2 (Schizosaccharomyces pombe) (SGOL2) and the polo-like kinase 1-interacting checkpoint helicase (PICH), during both male mouse meiotic divisions. Our results strikingly show that topoisomerase IIα appears at stretched strands connecting the sister kinetochores of segregating early anaphase II chromatids, once the cohesin complexes have been removed from the centromeres. Moreover, the number and length of these topoisomerase IIα-connecting strands increase between lagging chromatids at anaphase II after the chemical inhibition of the enzymatic activity of topoisomerase IIα by etoposide. Our results also show that the etoposide-induced inhibition of topoisomerase IIα is not able to rescue the loss of centromere cohesion promoted by the absence of the shugoshin SGOL2 during anaphase I. Taking into account our results, we propose a two-step model for the sequential release of centromeric cohesion during male mammalian meiosis II. We suggest that the cohesin removal is a prerequisite for the posterior topoisomerase IIα-mediated resolution of persisting catenations between segregating chromatids during anaphase II.     

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 IIβ, 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 IIβ 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 G₂. These results define the effects of decreased Topo II activity, rather than intermediate complex stabilization, on the mammalian cell cycle.     

Localization of anti-topoisomerase IIα antibodies under normal conditions and after artificial chromosome condensation and decondensation

By means of immunofluorescence method, localization of DNA-topoisomerase IIα (Topo IIα) in interphase nuclei and chromosomes at different stages of mitosis was studied in situ under normal conditions and after treatment with condensing and decondensing solutions. In non-isolated mitotic M-HeLa cell chromosomes, Topo IIα was uniformly distributed along chromatids after fixation and permeabilization in situ. After treatment of cells with decondensing solutions (10 mM Tris; 0.1 mM CaCl₂ in 10 mM Tris; 0.3 mM CaCl₂ in 10 mM Tris; 15% DMEM; 75 mM KCl), Topo IIα was evenly distributed along chromatids in prophase, prometaphase and metaphase; its concentration was the highest in the pericentromere region. After treatment of cells with condensing solutions containing 0.7 mM, 1 mM, 2 mM or 3 mM CaCl₂ in 10 mM Tris, Topo IIα was not detected in prophase, metaphase and anaphase. However, in late telophase anti-Topo IIα antibodies were found in reforming nuclei under identical conditions. After sequential treatment with condensing and decondensing solutions, the distribution patterns of Topo IIα in chromosomes were the same as after treatment with only decondensing solutions. In anaphase and telophase, Topo IIα was evenly distributed along chromatids, while in prophase, prometaphase and metaphase it was predominantly localized in the pericentromere region. After the treatment of cells with condensing solutions chromosome staining was not observed, apparently due to “masking” of binding sites for anti-Topo IIα antibodies. Homogenous distribution of Topo IIα along chromatids in non-isolated chromosomes was preserved after the treatment of cells with hypotonic solutions; however, under these conditions Topo IIα concentration was higher in centromeres.     

Dynamic association of topoisomerase II to the mitotic chromosomes in live cells of Aspergillus nidulans

DNA topoisomerase II (Topo II) is an essential enzyme that catalyzes topological changes of DNA and consists of a major member of mitotic chromosomes. To investigate the dynamic localization of Topo II in nuclei, we engineered the strain of Aspergillus nidulans expressing Topo II fused with green fluorescent protein (GFP). Time-lapse microscopy revealed that the distribution of Topo II-GFP in nuclei varied depending on the cell cycle. In interphase, Topo II-GFP distributed evenly in the nucleoplasm and at the onset of G2 phase became concentrated into nucleolus. During mitosis, Topo II-GFP accumulated on chromosomes, when the chromosomes condensed. In the early mitosis, the Topo II also showed a single or two brighter spots among the fluorescence of clumped chromosomes. The spots once divided into several spots and then concentrated again into a spot per nucleus in the dividing nuclei of anaphase. Along with the subsequent decondensation of chromosomes, Topo II diffused back into nucleoplasm.     

Chromosome length and perinuclear attachment constrain resolution of DNA intertwines

To allow chromosome segregation, topoisomerase II (topo II) must resolve sister chromatid intertwines (SCI) formed during deoxynucleic acid (DNA) replication. How this process extends to the full genome is not well understood. In budding yeast, the unique structure of the ribosomal DNA (rDNA) array is thought to cause late SCI resolution of this genomic region during anaphase. In this paper, we show that chromosome length, and not the presence of rDNA repeats, is the critical feature determining the time of topo II–dependent segregation. Segregation of chromosomes lacking rDNA also requires the function of topo II in anaphase, and increasing chromosome length aggravates missegregation in topo II mutant cells. Furthermore, anaphase Stu2-dependent microtubule dynamics are critical for separation of long chromosomes. Finally, defects caused by topo II or Stu2 impairment depend on attachment of telomeres to the nuclear envelope. We propose that topological constraints imposed by chromosome length and perinuclear attachment determine the amount of SCI that topo II and dynamic microtubules resolve during anaphase.     

Condensin-dependent rDNA decatenation introduces a temporal pattern to chromosome segregation

The chromosomal condensin complex gives metaphase chromosomes structural stability. In addition, condensin is required for sister-chromatid resolution during their segregation in anaphase [1-7]. How condensin promotes chromosome resolution is poorly understood. Chromosome segregation during anaphase also fails after inactivation of topoisomerase II (topo II), the enzyme that removes catenation between sister chromatids left behind after completion of DNA replication [8, 9]. This has led to the proposal that condensin promotes DNA decatenation [3, 10, 11], but direct evidence for this is missing and alternative roles for condensin in chromosome resolution have been suggested [12-14]. Using the budding-yeast rDNA as a model, we now show that anaphase bridges in a condensin mutant are resolved by ectopic expression of a foreign (Chlorella virus) but not endogenous topo II. This suggests that catenation prevents sister-rDNA segregation but that yeast topo II is ineffective in decatenating the locus without condensin. Condensin and topo II colocalize along both rDNA and euchromatin, consistent with coordination of their activities. We investigate the physiological consequences of condensin-dependent rDNA decatenation and find that late decatenation determines the late segregation timing of this locus during anaphase. Regulation of decatenation therefore provides a means to fine tune the segregation timing of chromosomes in mitosis.     

Biochemical heterogeneity and developmental varieties in T-cell leukemia

During mitosis, chromosomes undergo dynamic structural changes that include condensation of chromosomes – the formation of individual compact chromosomes necessary for faithful segregation of sister chromatids in anaphase. Polo-like kinase 1 (Plk1) regulates multiple mitotic events by binding to targeting factors at different mitotic structures in a phosphorylation dependent manner. In this study, we report the identification of a putative ATPase that targets Plk1 to chromosome arms during mitosis. PICH (Plk1-interacting checkpoint “helicase”) displays a temporal localization on chromosome arms and kinetochores during early mitosis. Interaction with PICH recruits Plk1 to chromosome arms and disruption of this interaction abolishes Plk1 localization on chromosome arms. Moreover, depletion of PICH or overexpression of PICH mutant that is defective in Plk1 binding or ATP binding causes defects in mitotic chromosome compaction, formation of anaphase bridge and cytokinesis failure. We provide data to show that both PICH phosphorylation and its ATPase activity are required for mitotic chromosome compaction. Our study provides a mechanism for targeting Plk1 to chromosome arms and suggests that the PICH ATPase activity is important for the regulation of mitotic chromosome architecture.     

SUMO-interacting motifs (SIMs) in Polo-like kinase 1-interacting checkpoint helicase (PICH) ensure proper chromosome segregation during mitosis

Polo-like kinase 1 (Plk1)-interacting checkpoint helicase (PICH) localizes at the centromere and is critical for proper chromosome segregation during mitosis. However, the precise molecular mechanism of PICH's centromeric localization and function at the centromere is not yet fully understood. Recently, using Xenopus egg extract assays, we showed that PICH is a promiscuous SUMO binding protein. To further determine the molecular consequence of PICH/SUMO interaction on PICH function, we identified 3 SUMO-interacting motifs (SIMs) on PICH and generated a SIM-deficient PICH mutant. Using the conditional expression of PICH in cells, we found distinct roles of PICH SIMs during mitosis. Although all SIMs are dispensable for PICH's localization on ultrafine anaphase DNA bridges, only SIM3 (third SIM, close to the C-terminus end of PICH) is critical for its centromeric localization. Intriguingly, the other 2 SIMs function in chromatin bridge prevention. With these results, we propose a novel SUMO-dependent regulation of PICH's function on mitotic centromeres.     

Is DNA topoisomerase IIβ a nucleolar protein?

We have carried out immunofluorescence labelling of two human cell types, HeLa cells and peripheral blood lymphocytes, prepared by several different fixation/permeabilization protocols using a variety of antibodies against DNA Topoisomerase II (Topo II). We have found that the distribution of Topo IIα was overall similar during interphase and mitosis to that previously reported, regardless of antibody and of sample preparation. On the other hand, the interphase distribution of Topo IIβ was quite variable, depending both on the antibody and on the method used to prepare the sample. Our interpretation of the data is that, like Topo IIα, Topo IIβ is primarily a nucleoplasmic protein, but that unlike Topo IIα, small amounts are also associated with intranucleolar chromatin. © 1996 Wiley-Liss, Inc.     

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 IIβ, 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 IIβ 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 G₂. These results define the effects of decreased Topo II activity, rather than intermediate complex stabilization, on the mammalian cell cycle.Key words: topoisomerase II, mitosis, G₂, conditional knockdown, S phase, mitotic catastrophe     

BLM is required for faithful chromosome segregation and its localization defines a class of ultrafine anaphase bridges

Mutations in BLM cause Bloom's syndrome, a disorder associated with cancer predisposition and chromosomal instability. We investigated whether BLM plays a role in ensuring the faithful chromosome segregation in human cells. We show that BLM-defective cells display a higher frequency of anaphase bridges and lagging chromatin than do isogenic corrected derivatives that eptopically express the BLM protein. In normal cells undergoing mitosis, BLM protein localizes to anaphase bridges, where it colocalizes with its cellular partners, topoisomerase IIIalpha and hRMI1 (BLAP75). Using BLM staining as a marker, we have identified a class of ultrafine DNA bridges in anaphase that are surprisingly prevalent in the anaphase population of normal human cells. These so-called BLM-DNA bridges, which also stain for the PICH protein, frequently link centromeric loci, and are present at an elevated frequency in cells lacking BLM. On the basis of these results, we propose that sister-chromatid disjunction is often incomplete in human cells even after the onset of anaphase. We present a model for the action of BLM in ensuring complete sister chromatid decatenation in anaphase.     

PICH, a centromere-associated SNF2 family ATPase, is regulated by Plk1 and required for the spindle checkpoint

We identify PICH (Plk1-interacting checkpoint "helicase"), a member of the SNF2 ATPase family, as an interaction partner and substrate of Plk1. Following phosphorylation of PICH on the Cdk1 site T1063, Plk1 is recruited to PICH and controls its localization. Starting in prometaphase, PICH accumulates at kinetochores and inner centromeres. Moreover, it decorates threads that form during metaphase before increasing in length and progressively diminishing during anaphase. PICH-positive threads connect sister kinetochores and are dependent on tension, sensitive to DNase, and exacerbated in response to premature loss of cohesins or inhibition of topoisomerase II, suggesting that they represent stretched centromeric chromatin. Depletion of PICH causes the selective loss of Mad2 from kinetochores and completely abrogates the spindle checkpoint, resulting in massive chromosome missegregation. These data identify PICH as a novel essential component of checkpoint signaling. We propose that PICH binds to catenated centromere-related DNA to monitor tension developing between sister kinetochores.     

Flow cytometric analysis of ICRF-193 influence on cell passage through mitosis

Studying the effect of topoisomerase II (topo II) inhibitors on cell passage through mitosis seems to be important for understanding the role of this enzyme during chromosome condensation and segregation. A flow cytometric assay (Zenin et al., 2001) allowed to determine the mitotic index, and to discriminate between not only cells in G2 and M phases (including metaphase and anaphase cells), but also cells in pseudo-G1 with 4c DNA content. It is shown that topo II catalytic inhibitor ICRF-193 blocks G2-M transition in a lymphoblastoid cell line GM-130. Addition of caffeine to cells abrogated a block of their entering mitosis but not the inhibitor action. Cells entered mitosis, which was proven by the presence of chromosomes in the examined specimen, and, bypassing anaphase, appeared in pseudo-G1 with 4c DNA content. We have found that in the presence of ICRF-193 cells, GM-130 and Hep-2 lines, previously blocked by nocodazole when in mitosis and then washed, pass through metaphase, enter anaphase and leave it to pass to pseudo-G1 with the 4c DNA content. Thus, by inhibiting topo II activity ICRF-193 causes abnormal mitotic transition.     

Rice SNF2 family helicase ENL1 is essential for syncytial endosperm development

The endosperm of cereal grains represents the most important source of human nutrition. In addition, the endosperm provides many investigatory opportunities for biologists because of the unique processes that occur during its ontogeny, including syncytial development at early stages. Rice endospermless 1 (enl1) develops seeds lacking an endosperm but carrying a functional embryo. The enl1 endosperm produces strikingly enlarged amoeboid nuclei. These abnormal nuclei result from a malfunction in mitotic chromosomal segregation during syncytial endosperm development. The molecular identification of the causal gene revealed that ENL1 encodes an SNF2 helicase family protein that is orthologous to human Plk1‐Interacting Checkpoint Helicase (PICH), which has been implicated in the resolution of persistent DNA catenation during anaphase. ENL1‐Venus (enhanced yellow fluorescent protein (YFP)) localizes to the cytoplasm during interphase but moves to the chromosome arms during mitosis. ENL1‐Venus is also detected on a thread‐like structure that connects separating sister chromosomes. These observations indicate the functional conservation between PICH and ENL1 and confirm the proposed role of PICH. Although ENL1 dysfunction also affects karyokinesis in the root meristem, enl1 plants can grow in a field and set seeds, indicating that its indispensability is tissue‐dependent. Notably, despite the wide conservation of ENL1/PICH among eukaryotes, the loss of function of the ENL1 ortholog in Arabidopsis (CHR24) has only marginal effects on endosperm nuclei and results in normal plant development. Our results suggest that ENL1 is endowed with an indispensable role to secure the extremely rapid nuclear cycle during syncytial endosperm development in rice.     

PIASy-dependent SUMOylation regulates DNA topoisomerase IIalpha activity

DNA topoisomerase IIα (TopoIIα) is an essential chromosome-associated enzyme with activity implicated in the resolution of tangled DNA at centromeres before anaphase onset. However, the regulatory mechanism of TopoIIα activity is not understood. Here, we show that PIASy-mediated small ubiquitin-like modifier 2/3 (SUMO2/3) modification of TopoIIα strongly inhibits TopoIIα decatenation activity. Using mass spectrometry and biochemical analysis, we demonstrate that TopoIIα is SUMOylated at lysine 660 (Lys660), a residue located in the DNA gate domain, where both DNA cleavage and religation take place. Remarkably, loss of SUMOylation on Lys660 eliminates SUMOylation-dependent inhibition of TopoIIα, which indicates that Lys660 SUMOylation is critical for PIASy-mediated inhibition of TopoIIα activity. Together, our findings provide evidence for the regulation of TopoIIα activity on mitotic chromosomes by SUMOylation. Therefore, we propose a novel mechanism for regulation of centromeric DNA catenation during mitosis by PIASy-mediated SUMOylation of TopoIIα.