Molecular and Structural Transactions at Human DNA Replication Origins

The DNA replication origins of metazoan genomes are the sites of complex sequence-specific protein-DNA interactions determining their precise cycle of activation and deactivation, once only along each cell cycle. Some of the involved proteins have been identified (and particularly the essential six-protein Origin Recognition complex, ORC) thanks to their homology with the proteins identified in yeast. Whereas in the latter organism ORC has a specific affinity for an origin consensus, metazoan (and human) ORC shows no sequence specificity and no origin consensus is identifiable in their genomes. The modulation of topology around the origin sequence plays an essential role in the function of the human lamin B2 origin and the two topoisomerases interact specifically with it in a cell-cycle modulated way. The two enzymes are never present on the origin at the same time and compete, in different moments of the cell cycle, with the ORC2 subunit for the same sites in the origin area. The topoisomerases could give essential contributions to origin definition, as demonstrated by their capacity to bind specifically, in vitro the lamin B2 origin, either alone (topoisomerase I) or in a multi-protein complex (topoisomerase II). They also play critical roles in the origin activation-deactivation cycle, topoisomerase II probably contributing to attain and/or maintain a topological status fit for pre-replicative complex assembly and topoisomerase I allowing the topological adaptations necessary for initiation of bi-directional synthesis.     

Localization of proteins bound to a replication origin of human DNA along the cell cycle

The proteins bound in vivo at the human lamin B2 DNA replication origin and their precise sites of binding were investigated along the cell cycle utilizing two novel procedures based on immunoprecipitation following UV irradiation with a pulsed laser light source. In G(1), the pre-replicative complex contains CDC6, MCM3, ORC1 and ORC2 proteins; of these, the post-replicative complex in S phase contains only ORC2; in M phase none of them are bound. The precise nucleotide of binding was identified for the two ORC and the CDC6 proteins near the start sites for leading-strand synthesis; the transition from the pre- to the post-replicative complex is accompanied by a 17 bp displacement of the ORC2 protein towards the start site.     

Patterns of strongly protein-associated simian virus 40 DNA replication intermediates resulting from exposures to specific topoisomerase poisons

Exposure of infected CV-1 cells to specific type I and type II topoisomerase poisons caused strong protein association with distinct subsets of simian virus 40 (SV40) DNA replication intermediates. On the basis of the known specificity and mechanisms of action of these drugs, the proteins involved are assumed to be the respective topoisomerases. Camptothecin, a topoisomerase I poison, caused strong protein association with form II (relaxed circular) and form III (linear) viral genomes and replication intermediates having broken DNA replication forks but not with form I (superhelical) viral DNA or normal late replication intermediates which were present. In contrast, type II topoisomerase poisons caused completely replicated forms and late viral replication forms to be tightly bound to protein--some to a greater extent than others. Different type II topoisomerase inhibitors caused distinctive patterns of protein association with the replication intermediates present. Both intercalating and nonintercalating type II topoisomerase poisons caused a small amount of form I (superhelical) SV40 DNA to be protein-associated in vivo. The protein complex with form I viral DNA was entirely drug-dependent and strong, but apparently noncovalent. The protein associated with form I DNA may represent a drug-stabilized "topological complex" between type II topoisomerase and SV40 DNA.     

DNA topoisomerase I and II activities during cell proliferation and the cell cycle in cultured mouse embryo fibroblast (C3H 10T1/2) cells

We have used C3H 10T1/2 cells to examine the regulation of topoisomerase activities during cell proliferation and the cell cycle. The specific activity of topoisomerase I was about 4-fold greater in proliferating (log phase) cells than in non-proliferating (confluent) cells. In synchronized cells, the bulk of the increased activity occurred during or just prior to S phase, depending upon the method of synchronization. A smaller increase in activity also occurred during G1 phase. The increase in activity during S phase was not altered by a hydroxyurea block at the G1/S phase boundary indicating that it is not directly coupled to DNA synthesis and is not the result of topoisomerase I gene dosage. The increase was inhibited by blocking cells at mid-G1 phase using isoleucine deprivation. Thus, the increase in activity during S phase is dependent on events occurring during mid- to late G1 phase. In contrast to the changes in topoisomerase I levels, the specific activity of topoisomerase II showed no detectable difference in proliferating vs non-proliferating cells. In addition, no detectable difference in topoisomerase II specific activity was seen in G1, S and M phases of the cell cycle. The differences in the activity profiles of the topoisomerases I and II during the cell cycle suggest that the two activities are regulated independently and may be required for different functions.     

Inhibition of Mycobacterium smegmatis topoisomerase I by specific oligonucleotides

DNA topoisomerase I from Mycobacterium smegmatis unlike many other type I topoisomerases is a site specific DNA binding protein. We have investigated the sequence specific DNA binding characteristics of the enzyme using specific oligonucleotides of varied length. DNA binding, oligonucleotide competition and covalent complex assays show that the substrate length requirement for interaction is much longer ( approximately 20 nucleotides) in contrast to short length substrates (eight nucleotides) reported for Escherichia coli topoisomerase I and III. P1 nuclease and KMnO(4) footprinting experiments indicate a large protected region spanning about 20 nucleotides upstream and 2-3 nucleotides downstream of the cleavage site. Binding characteristics indicate that the enzyme interacts efficiently with both single-stranded and double-stranded substrates containing strong topoisomerase I sites (STS), a unique property not shared by any other type I topoisomerase. The oligonucleotides containing STS effectively inhibit the M. smegmatis topoisomerase I DNA relaxation activity.     

Control over DNA replication in time and space

DNA replication is precisely regulated in time and space, thereby safeguarding genomic integrity. In eukaryotes, replication initiates from multiple sites along the genome, termed origins of replication, and propagates bidirectionally. Dynamic origin bound complexes dictate where and when replication should initiate. During late mitosis and G1 phase, putative origins are recognized and become "licensed" through the assembly of pre-replicative complexes (pre-RCs) that include the MCM2-7 helicases. Subsequently, at the G1/S phase transition, a fraction of pre-RCs are activated giving rise to the establishment of replication forks. Origin location is influenced by chromatin and nuclear organization and origin selection exhibits stochastic features. The regulatory mechanisms that govern these cell cycle events rely on the periodic fluctuation of cyclin dependent kinase (CDK) activity through the cell cycle.     

Role of topoisomerases in cytotoxicity induced by DNA ligand Hoechst-33342 and UV-C in a glioma cell line

DNA ligand Hoechst-33342 significantly enhances UV induced cytotoxicity in human glioma cell lines (BMG-1 & U-87) with supra additive increase in cell death, cytogenetic damage, cell cycle delay, apoptosis and inhibition of PLDR. Cytotoxicity of Hoechst-33342 arises due to its interference in the breakage-rejoining reaction of DNA topoisomerases by stabilization of cleavable complexes. Since topoisomerases have also been implicated in the generation of potentially lethal DNA breaks by interaction with various types of DNA damage including UV induced DNA lesions, we investigated in present studies the role of functional topoisomerases in the synergistic cytotoxicity of Hoechst-33342 and UV in a human glioma cell line (BMG-1). Topoisomerase I activity analyzed by the plasmid relaxation assay, was significantly enhanced upon UV irradiation, implying a possible role of this enzyme in the processing of UV induced lesions. However, this increase in the activity was reduced by >50% in cells incubated with Hoechst-33342 for 1 hr prior to irradiation. Imunoflowcytometric analysis of the chromatin bound topoisomerases I and II levels (cleavable complex) using topoisomerases I and II anti-antibodies showed a good correlation between the induction of apoptosis by Hoechst-33342 and UV and enhancement in the level of topoisomerase II mediated cleavable complexes. Induction of apoptosis was associated with a decline in the level of Bcl2. Taken together, these studies show that supra additive cytotoxic effects of UV-C and Hoechst-33342 in BMG-1 cells are consequences of enhanced stabilization of topo II mediated cleavable complexes and alterations in specific signal transduction pathways of apoptosis, besides the inhibition of topoisomerase mediated repair processes.     

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.     

Topoisomerase II plays an essential role as a swivelase in the late stage of SV40 chromosome replication in vitro.

The effects of topoisomerases I and II on the replication of SV40 DNA were examined using an in vitro replication system of purified proteins that constitutes the monopolymerase system. In the presence of the two topoisomerases, two distinct nascent DNAs were formed. One product arising from the replication of the leading template strand was approximately half the size of the template DNA, whereas the other product derived from the lagging template strand consisted of short DNAs. These products were synthesized from both SV40 naked DNA and SV40 chromosomes. For the replication of SV40 naked DNA, either topoisomerase I or II maintained replication fork movement and supported complete leading strand synthesis. When SV40 chromosomes were replicated with the same proteins, reactions containing only topoisomerase I produced shorter leading strands. However, mature size DNA products accumulated in reactions supplemented with topoisomerase II, as well as in reactions containing only topoisomerase II. In the presence of crude extracts of HeLa cells, VP-16, a specific inhibitor of topoisomerase II, blocked elongation of the nascent DNA during the replication of SV40 chromosomes. These results indicate that topoisomerase II plays a crucial role as a swivelase in the late stage of SV40 chromosome replication in vitro.     

Human Orc2 localizes to centrosomes, centromeres and heterochromatin during chromosome inheritance

The initiation of DNA replication in S phase requires the prior assembly of an origin recognition complex (ORC)-dependent pre-replicative complex on chromatin during G1 phase of the cell division cycle. In human cells, the Orc2 subunit localized to the nucleus as expected, but it also localized to centrosomes throughout the entire cell cycle. Furthermore, Orc2 was tightly bound to heterochromatin and heterochromatin protein 1alpha (HP1alpha) and HP1beta in G1 and early S phase, but during late S, G2 and M phases tight chromatin association was restricted to centromeres. Depletion of Orc2 by siRNA caused multiple phenotypes. A population of cells showed an S-phase defect with little proliferating cell nuclear antigen (PCNA) on chromatin, although MCM proteins remained. Orc2 depletion also disrupted HP1 localization, but not histone-H3-lysine-9 methylation at prominent heterochromatic foci. Another subset of Orc2-depleted cells containing replicated DNA arrested with abnormally condensed chromosomes, failed chromosome congression and multiple centrosomes. These results implicate Orc2 protein in chromosome duplication, chromosome structure and centrosome copy number control, suggesting that it coordinates all stages of the chromosome inheritance cycle.     

The concentration-dependent diversity of effects of DNA topoisomerase I and II inhibitors on the cell cycle of HL-60 cells.

Exposure of promyelocytic leukemic HL-60 cells to 3-60 nM of the DNA topoisomerase I inhibitor camptothecin (CAM) or to 30-450 nM and 0.12-1.5 microM of DNA topoisomerase II inhibitors teniposide (TN) and 4-(9-acridynylamino)-3-methanesulfon-m-anisidide (m-AMSA), respectively, resulted in two distinct kinetic effects: (1) the cells entered S phase but the rate of DNA replication was reduced in proportion to the inhibitor concentration; (2) the transition from G2 to M was impaired, approximately 1 h after addition of the inhibitor. As a consequence, the cells accumulated in the S (preferentially in early S) and in G2 phases of the cell cycle. Whereas CAM was more efficient in suppressing cell progression through S phase, TN and m-AMSA were more potent G2 blockers. At these low inhibitor concentrations no signs of immediate cytotoxicity or DNA degradation were apparent. However, above 145 nM of CAM, 900 nM of TN, or 2 microM of m-AMSA extensive DNA degradation in nuclei of S phase cells was evident within 6 h of addition of the inhibitor, resulting in the loss of S and G2 + M cells from these cultures. The data indicate that depending on concentration, mechanisms mediating the cytostatic/cytotoxic activity of both DNA topoisomerase I and II inhibitors may be quite different. Suppression of the DNA replication and the G2 to M transition, seen at low inhibitor concentrations, is compatible with the assumption that the inhibitor-induced stabilization of the topoisomerase-DNA cleavable complexes interferes with DNA replication and chromosome condensation/segregation, respectively. Above the threshold concentration for each inhibitor, an endonucleolytic activity is triggered, resulting in rapid DNA degradation in nuclei of S and G2 phase cells. The endonucleolytic effect is not only cell cycle phase-specific but is also modulated by tissue-specific factors because it cannot be observed, e.g., in the lymphocytic leukemic cell lines.     

The replication factory targeting sequence/PCNA-binding site is required in G(1) to control the phosphorylation status of DNA ligase I.

The recruitment of DNA ligase I to replication foci in S phase depends on a replication factory targeting sequence that also mediates the interaction with proliferating cell nuclear antigen (PCNA) in vitro. By exploiting a monoclonal antibody directed at a phospho-epitope, we demonstrate that Ser66 of DNA ligase I, which is part of a strong CKII consensus site, is phosphorylated in a cell cycle-dependent manner. After dephosphorylation in early G(1), the level of Ser66 phosphorylation is minimal in G(1), increases progressively in S and peaks in G(2)/M phase. The analysis of epitope-tagged DNA ligase I mutants demonstrates that dephosphorylation of Ser66 requires both the nuclear localization and the PCNA-binding site of the enzyme. Finally, we show that DNA ligase I and PCNA interact in vivo in G(1) and S phase but not in G(2)/M. We propose that dephosphorylation of Ser66 is part of a novel control mechanism to establish the pre-replicative form of DNA ligase I.     

Mouse geminin inhibits not only Cdt1-MCM6 interactions but also a novel intrinsic Cdt1 DNA binding activity

DNA replication is controlled by the stepwise assembly of a pre-replicative complex and the replication apparatus. Cdt1 is a novel component of the pre-replicative complex and plays a role in loading the minichromosome maintenance (MCM) 2-7 complex onto chromatin. Cdt1 activity is inhibited by geminin, which is essential for the G(2)/M transition in metazoan cells. To understand the molecular basis of the Cdt1-geminin regulatory mechanism in mammalian cells, we cloned and expressed the mouse Cdt1 homologue cDNA in bacterial cells and purified mouse Cdt1 to near homogeneity. We found by yeast two-hybrid analysis that mouse Cdt1 associates with geminin, MCM6, and origin recognition complex 2. MCM6 interacts with the Cdt1 carboxyl-terminal region (amino acids 407-477), which is conserved among eukaryotes, whereas geminin associates with the Cdt1 central region (amino acids 177-380), which is conserved only in metazoans. In addition, we found that Cdt1 can bind DNA in a sequence-, strand-, and conformation-independent manner. The Cdt1 DNA binding domain overlaps with the geminin binding domain, and the binding of Cdt1 to DNA is inhibited by geminin. Taken together, we have defined structural domains and novel biochemical properties for mouse Cdt1 that suggest that Cdt1 behaves as an intrinsic DNA binding factor in the pre-replicative complex.     

Induction of mammalian DNA topoisomerase I and II mediated DNA cleavage by saintopin, a new antitumor agent from fungus.

Saintopin is an antitumor antibiotic recently discovered in mechanistically oriented screening using purified calf thymus DNA topoisomerases. Saintopin induced topoisomerase I mediated DNA cleavage comparable to that of camptothecin, and topoisomerase II mediated DNA cleavage equipotent to those of 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) or 4'-demethylepipodophyllotoxin 9-(4,6-O-ethylidene-beta-D-glucopyranoside) (VP-16). Treatment of a reaction mixture containing saintopin and topoisomerase I or II with either elevated temperature (65 degrees C) or higher salt concentration (0.5 M NaCl) resulted in a substantial reduction in DNA cleavage, suggesting that the topoisomerase I and II mediated DNA cleavage induced by saintopin is through the mechanism of stabilizing the reversible enzyme-DNA "cleavable complex". Consistent with the cleavable complex formation with both topoisomerases, saintopin inhibited catalytic activities of both topoisomerase I and topoisomerase II. The DNA cleavage intensity pattern induced by saintopin with topoisomerase I was different from that by camptothecin. A difference in cleavage pattern was also detected between saintopin and m-AMSA or VP-16 in topoisomerase II mediated DNA cleavage. DNA unwinding assay using T4 DNA ligase showed that saintopin is a weak DNA intercalator like m-AMSA. Thus, saintopin represents a new class of antitumor agent that can induce both mammalian DNA topoisomerase I and mammalian DNA topisomerase II mediated DNA cleavage.     

Cell Cycle–coupled Relocation of Types I and II Topoisomerases and Modulation of Catalytic Enzyme Activities

We visualized DNA topoisomerases in A431 cells and isolated chromosomes by isoenzyme-selective immunofluorescence microscopy. In interphase, topoisomerase I mainly had a homogeneous nuclear distribution. 10–15% of the cells exhibited granular patterns, 30% showed bright intranucleolar patches. Topoisomerase II isoenzymes showed spotted (α) or reticular (β) nuclear patterns throughout interphase. In contrast to topoisomerase IIα, topoisomerase IIβ was completely excluded from nucleoli. In mitosis, topoisomerase IIβ diffused completely into the cytosol, whereas topoisomerases I and IIα remained chromosome bound. Chromosomal staining of topoisomerase I was homogeneous, whereas topoisomerase IIα accumulated in the long axes of the chromosome arms and in the centriols. Topoisomerase antigens were 2–3-fold higher in mitosis than in interphase, but specific activities of topoisomerase I and II were reduced 5- and 2.4-fold, respectively. These changes were associated with mitotic enzyme hyperphosphorylation. In interphase, topoisomerases could be completely linked to DNA by etoposide or camptothecin, whereas in mitosis, 50% of topoisomerase IIα escaped poisoning. Refractoriness to etoposide could be assigned to the salt-stable scaffold fraction of topoisomerase IIα, which increased from <2% in G₁ phase to 48% in mitosis. Topoisomerases I and IIβ remained completely extractable throughout the cell cycle. In summary, expression of topoisomerases increases towards mitosis, but specific activities decrease. Topoisomerase IIβ is released from the heterochromatin, whereas topoisomerase I and IIα remain chromosome bound. Scaffold-associated topoisomerase IIα appears not to be involved in catalytic DNA turnover, though it may play a role in the replicational cycle of centriols, where it accumulates during M phase.     

Evodiamine, a dual catalytic inhibitor of type I and II topoisomerases, exhibits enhanced inhibition against camptothecin resistant cells

DNA topoisomerases are nuclear enzymes that are the targets for several anticancer drugs. In this study we investigated the antiproliferative activity against human leukaemia cell lines and the effects on topoisomerase I and II of evodiamine, which is a quinazolinocarboline alkaloid isolated from the fruit of a traditional Chinese medicinal plant, Evodia rutaecarpa. We report here the anti-proliferative activity against human leukaemia cells K562, THP-1, CCRF-CEM and CCRF-CEM/C1 and the inhibitory mechanism on human topoisomerases I and II, important anti-cancer drugs targets, of evodiamine. Evodiamine failed to trap [Topo-DNA] complexes and induce any detectable DNA damage in cells, was unable to bind or intercalate DNA, and arrested cells in the G(2)/M phase. The results suggest evodiamine is a dual catalytic inhibitor of topoisomerases I and II, with IC(50) of 60.74 and 78.81 μM, respectively. The improved toxicity towards camptothecin resistant cells further supports its inhibitory mechanism which is different from camptothecin, and its therapeutic potential.