Plant DNA topoisomerase I is recognized and inhibited by human Scl-70 sera autoantibodies

Type I topoisomerases (EC 5.99.1.2) are those enzymes capable of relaxing negatively supercoiled DNA without the need for ATP. The central role played by these enzymes in cell function suggests that the structure of type I topoisomerases may be highly conserved in eukaryotic cells. However, the extent of the conservation among eukaryotes is unknown. Human DNA topoisomerase I is an autoimmune antigen (Scl-70) of scleroderma patients. We have found that the autoimmune antibodies in human Scl-70 sera recognize protein from various plants, and these proteins display DNA relaxation function. In addition, Scl-70 antibodies were able to inhibit enzymatic activity of plant topoisomerase I. Therefore, the immunological cross-reactivity of the plant topoisomerase with human antibodies demonstrates that, despite divergence of eukaryotic organisms, these plant and animal enzymes retain structurally similar enzymatic features.     

Purification and characterization of Plasmodium berghei DNA topoisomerases I and II: drug action, inhibition of decatenation and relaxation, and stimulation of DNA cleavage

It has recently been suggested that topoisomerases could be important targets for drugs used in several diseases. This prompted us to purify and characterize the topoisomerases I and II present in the erythrocytes of protozoan parasites of the genus Plasmodium, the causative agent of malaria, in order to later use these enzymatic systems in antimalarial drug assays. The topoisomerases were purified from Plasmodium berghei, a parasite of mouse red cells. The Plasmodium topoisomerase II consists of two subunits with a molecular weight of about 160K. The enzyme is ATP- and Mg2+-dependent. The conditions for the reactions of relaxation, unknotting, decatenation, and catenation were found to be similar to those observed with enzymes from other eukaryotic cells. The Plasmodium topoisomerase I is a monomeric enzyme with a Mr of 70K-100K. It is ATP-independent and K+- or Na-dependent. Mg2+ is not required for relaxation but stimulates the reaction. Topoisomerase II was more sensitive to drug action than topoisomerase I. The most active drugs were the ellipticine derivatives. The antimalarial drugs, currently used in human clinical therapy, were poor inhibitors. Some antitumoral drugs stimulated the double-stranded DNA cleavage activity of Plasmodium topoisomerase II, like that of mammalian topoisomerases II. Antimalarial drugs had no stimulating activity. It is therefore suggested that Plasmodium topoisomerases are not good targets for antimalarial drugs.     

Sequence specific interaction of Mycobacterium smegmatis topoisomerase I with duplex DNA.

We have identified strong topoisomerase sites (STS) for Mycobacteruim smegmatis topoisomerase I in double-stranded DNA context using electrophoretic mobility shift assay of enzyme-DNA covalent complexes. Mg2+, an essential component for DNA relaxation activity of the enzyme, is not required for binding to DNA. The enzyme makes single-stranded nicks, with transient covalent interaction at the 5'-end of the broken DNA strand, a characteristic akin to prokaryotic topoisomerases. More importantly, the enzyme binds to duplex DNA having a preferred site with high affinity, a property similar to the eukaryotic type I topoisomerases. The preferred cleavage site is mapped on a 65 bp duplex DNA and found to be CG/TCTT. Thus, the enzyme resembles other prokaryotic type I topoisomerases in mechanistics of the reaction, but is similar to eukaryotic enzymes in DNA recognition properties.     

The structure of the transition state of the heterodimeric topoisomerase I of Leishmania donovani as a vanadate complex with nicked DNA

Type IB topoisomerases are essential enzymes that are responsible for relaxing superhelical tension in DNA by forming a transient covalent nick in one strand of the DNA duplex. Topoisomerase I is a target for anti-cancer drugs such as camptothecin, and these drugs also target the topoisomerases I in pathogenic trypanosomes including Leishmania species and Trypanosoma brucei. Most eukaryotic enzymes, including human topoisomerase I, are monomeric. However, for Leishmania donovani, the DNA-binding activity and the majority of residues involved in catalysis are located in a large subunit, designated TOP1L, whereas the catalytic tyrosine residue responsible for covalent attachment to DNA is located in a smaller subunit, called TOP1S. Here, we present the 2.27A crystal structure of an active truncated L.donovani TOP1L/TOP1S heterodimer bound to nicked double-stranded DNA captured as a vanadate complex. The vanadate forms covalent linkages between the catalytic tyrosine residue of the small subunit and the nicked ends of the scissile DNA strand, mimicking the previously unseen transition state of the topoisomerase I catalytic cycle. This structure fills a critical gap in the existing ensemble of topoisomerase I structures and provides crucial insights into the catalytic mechanism.     

Topoisomerases of kinetoplastid parasites: why so fascinating?

DNA topoisomerases are the key enzymes involved in carrying out high precision DNA transactions inside the cells. However, they are detrimental to the cell when a wide variety of topoisomerase-targeted drugs generate cytotoxic lesions by trapping the enzymes in covalent complexes on the DNA. The discovery of unusual heterodimeric topoisomerase I in kinetoplastid family added a new twist in topoisomerase research related to evolution, functional conservation and their preferential sensitivity to Camptothecin. On the other hand, structural and mechanistic studies on kinetoplastid topoisomerase II delineate some distinguishing features that differentiate the parasitic enzyme from its prokaryotic and eukaryotic counterparts. This review summarizes the recent advances in research in kinetoplastid topoisomerases, their evolutionary significance and the death of the unicellular parasite Leishmania donovani induced by topoisomerase I inhibitor camptothecin.     

Studies on DNA polymerases and topoisomerases in archaebacteria

We have isolated DNA polymerases and topoisomerases from two thermoacidophilic archaebacteria: Sulfolobus acidocaldarius and Thermoplasma acidophilum. The DNA polymerases are composed of a single polypeptide with molecular masses of 100 and 85 kDa, respectively. Antibodies against Sulfolobus DNA polymerase did not cross react with Thermoplasma DNA polymerase. Whereas the major DNA topoisomerase activity in S. acidocaldarius is an ATP-dependent type I DNA topoisomerase with a reverse gyrase activity, the major DNA topoisomerase activity in T. acidophilum is a ATP-independent relaxing activity. Both enzymes resemble more the eubacterial than the eukaryotic type I DNA topoisomerase. We have found that small plasmids from halobacteria are negatively supercoiled and that DNA topoisomerase II inhibitors modify their topology. This suggests the existence of an archaebacterial type II DNA topoisomerase related to its eubacterial and eukaryotic counterparts. As in eubacteria, novobiocin induces positive supercoiling of halobacterial plasmids, indicating the absence of a eukaryotic-like type I DNA topoisomerase that relaxes positive superturns.     

Topoisomerase function during replication-independent chromatin assembly in yeast.

DNA topoisomerases I and II are the two major nuclear enzymes capable of relieving torsional strain in DNA. Of these enzymes, topoisomerase I plays the dominant role in relieving torsional strain during chromatin assembly in cell extracts from oocytes, eggs, and early embryos. We tested if the topoisomerases are used differentially during chromatin assembly in Saccharomyces cerevisiae by a combined biochemical and pharmacological approach. As measured by plasmid supercoiling, nucleosome deposition is severely impaired in assembly extracts from a yeast mutant with no topoisomerase I and a temperature-sensitive form of topoisomerase II (strain top1-top2). Expression of wild-type topoisomerase II in strain top1-top2 fully restored assembly-driven supercoiling, and assembly was equally efficient in extracts from strains expressing either topoisomerase I or II alone. Supercoiling in top1-top2 extract was rescued by adding back either purified topoisomerase I or II. Using the topoisomerase II poison VP-16, we show that topoisomerase II activity during chromatin assembly is the same in the presence and absence of topoisomerase I. We conclude that both topoisomerases I and II can provide the DNA relaxation activity required for efficient chromatin assembly in mitotically cycling yeast cells.     

Topoisomerase II from Chlorella virus PBCV-1. Characterization of the smallest known type II topoisomerase

Type II topoisomerases, a family of enzymes that govern topological DNA interconversions, are essential to many cellular processes in eukaryotic organisms. Because no data are available about the functions of these enzymes in the replication of viruses that infect eukaryotic hosts, this led us to express and characterize the first topoisomerase II encoded by one of such viruses. Paramecium bursaria chlorella virus 1 (PBCV-1) infects certain chlorella-like green algae and encodes a 120-kDa protein with a similarity to type II topoisomerases. This protein was expressed in Saccharomyces cerevisiae and was highly active in relaxation of both negatively and positively supercoiled plasmid DNA, catenation of plasmid DNA, and decatenation of kinetoplast DNA networks. Its optimal activity was determined, and the omission of Mg(2+) or its replacement with other divalent cations abolished DNA relaxation. All activities of the recombinant enzyme were ATP dependent. Increasing salt concentrations shifted DNA relaxation from a normally processive mechanism to a distributive mode. Thus, even though the PBCV-1 enzyme is considerably smaller than other eukaryotic topoisomerase II enzymes (whose molecular masses are typically 160-180 kDa), it displays all the catalytic properties expected for a type II topoisomerase.     

Comparative analysis of mitochondrial and nuclear DNA topoisomerase I from maize

We conducted a comparative study of the properties of topoisomerase I isolated from maize nuclei and mitochondria. We found that nuclear and mitochondrial enzymes possess different ability to bind single stranded DNA. Study of the enzyme activity dependence on Mg2+ demonstrated an absolute dependence of the mitochondrial topoisomerase activity. Contrary, nuclear enzyme activity was not absolutely dependent but stimulated by the magnesium cation. Mitochondrial topoisomerase formed covalent bond with the 5'-end of the cleaved DNA what is unique property of prokaryotic topoisomerase I. Nuclear enzyme bound covalently to the 3'-end like all eukaryotic topoisomerases I. The search through databases revealed genes which could encode mitochondrial topoisomerase I in the genomes of higher plants. Using both cDNA sequencing and in silico methods we demonstrated an existence of the ortholog gene in the maize genome. This gene shares significant homology with prokaryotic topoisomerase I genes that may explain differences in the properties of the mitochondrial and nuclear enzyme. Data obtained is of a significant interest both from the point of view of plant organelle evolution and mitochondrial genome expression mechanisms study.     

Eukaryotic DNA topoisomerase I reaction is topology dependent.

The effects of supercoiling on the topoisomerization reaction by eukaryotic DNA topoisomerases I have been analyzed. The systems used were: DNA topoisomerase I from wheat germ, chicken erythrocyte and calf thymus on a 2.3 kb DNA fragment which encompasses the immunoglobulin kappa-light chain (L kappa) promoter of the mouse plasmacytoma MPC11; S. cerevisiae DNA topoisomerase I on a 2.2 kb DNA fragment from the same organism which encompasses the regulatory and the coding region of the ADH II gene; wheat germ DNA topoisomerase I on the plasmid pUC18. It was found in every system that lack of torsional stress prevents topoisomerization of the substrate. A simple regulatory model of DNA topoisomerase I function, based on topological considerations, is presented.     

DNA topoisomerases from rat liver: physiological variations

Besides the nicking-closing (topoisomerase I) activity, an ATP-dependent DNA topoisomerase is present in rat liver nuclei. The enzyme, partially purified, is able to catenate in vitro closed DNA circles in a magnesium-dependent, ATP-dependent, histone H1-dependent reaction, and to decatenate in vitro kinetoplast DNA networks to yield free minicircles in a magnesium-dependent and ATP-dependent reaction. It is largely similar to other eukaryotic type II topoisomerases in its requirements, and presumably belongs to this class of enzymes. Type I and type II activities were measured in rat liver nuclei as a function of regenerating time after partial hepatectomy: type I activity was not significantly changed during this process. In contrast, type II activity was considerably increased, suggesting a possible involvement of the enzyme in DNA replication.     

An insight into the active site of a type I DNA topoisomerase from the kinetoplastid protozoan Leishmania donovani

DNA topoisomerases are ubiquitous enzymes that govern the topological interconversions of DNA thereby playing a key role in many aspects of nucleic acid metabolism. Recently determined crystal structures of topoisomerase fragments, representing nearly all the known subclasses, have been solved. The type IB enzymes are structurally distinct from other known topoisomerases but are similar to a class of enzymes referred to as tyrosine recombinases. A putative topoisomerase I open reading frame from the kinetoplastid Leishmania donovani was reported which shared a substantial degree of homology with type IB topoisomerases but having a variable C-terminus. Here we present a molecular model of the above parasite gene product, using the human topoisomerase I crystal structure in complex with a 22 bp oligonucleotide as a template. Our studies indicate that the overall structure of the parasite protein is similar to the human enzyme; however, major differences occur in the C-terminal loop, which harbors a serine in place of the usual catalytic tyrosine. Most other structural themes common to type IB topoisomerases, including secondary structural folds, hinged clamps that open and close to bind DNA, nucleophilic attack on the scissile DNA strand and formation of a ternary complex with the topoisomerase I inhibitor camptothecin could be visualized in our homology model. The validity of serine acting as the nucleophile in the case of the parasite protein model was corroborated with our biochemical mapping of the active site with topoisomerase I enzyme purified from L.donovani promastigotes.     

A ParE-ParC fusion protein is a functional topoisomerase.

Type II topoisomerases are responsible for DNA unlinking during DNA replication and chromosome segregation. Although eukaryotic enzymes are homodimers and prokaryotic enzymes are heterotetramers, both prokaryotic and eukaryotic type II topoisomerases belong to a single protein family. The amino- and carboxyl-terminal domains of eukaryotic enzymes are homologous to the ATP-binding and catalytic subunits of prokaryotic enzymes, respectively. Topoisomerase IV, a prokaryotic type II topoisomerase, consists of the ATP-binding subunit, ParE, and the catalytic subunit, ParC. We have joined the coding regions of parE and parC in frame and constructed a fusion protein of the two subunits of topoisomerase IV. This fusion protein, ParEC, can catalyze both decatenation and relaxation reactions. The ParEC protein is also capable of decatenating replicating daughter DNA molecules during oriC DNA replication in vitro. Furthermore, the fusion gene, parEC, complements the temperature-sensitive growth of both parC and parE strains, indicating that the ParEC protein can substitute for topoisomerase IV in vivo. These results demonstrate that a fusion protein of the two subunits of topoisomerase IV is a functional topoisomerase. Thus, a heterotetrameric type II topoisomerase can be converted into a homodimeric type II topoisomerase by gene fusion.     

The twisted 'life' of DNA in the cell: bacterial topoisomerases

DNA topoisomerases are essential to the cell for the regulation of DNA supercoiling levels and for chromosome decatenation. The proposed mechanisms for these reactions are essentially the same, except that a change in supercoiling is due to an intramolecular event, while decatenation requires an intermolecular event. The characterized bacterial topoisomerases appear capable of both types of reaction in vitro. Four DNA topoisomerases have been identified in Escherichia coli. Topoisomerase I, gyrase, and topoisomerase IV normally appear to have distinct essential functions within the cell, Gyrase and topoisomerase I are responsible for the regulation of DNA supercoiling. Both gyrase and topoisomerase IV are necessary for chromosomal decatenation. Multiple topoisomerases with distinct functions may give the cell more precise control over DNA topology by allowing tighter regulation of the principal enzymatic activities of these different proteins.     

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.     

DNA supercoiling during ATP-dependent DNA translocation by the type I restriction enzyme EcoAI

Type I restriction enzymes cleave DNA at non-specific sites far from their recognition sequence as a consequence of ATP-dependent DNA translocation past the enzyme. During this reaction, the enzyme remains bound to the recognition sequence and translocates DNA towards itself simultaneously from both directions, generating DNA loops, which appear to be supercoiled when visualised by electron microscopy. To further investigate the mechanism of DNA translocation by type I restriction enzymes, we have probed the reaction intermediates with DNA topoisomerases. A DNA cleavage-deficient mutant of EcoAI, which has normal DNA translocation and ATPase activities, was used in these DNA supercoiling assays. In the presence of eubacterial DNA topoisomerase I, which specifically removes negative supercoils, the EcoAI mutant introduced positive supercoils into relaxed plasmid DNA substrate in a reaction dependent on ATP hydrolysis. The same DNA supercoiling activity followed by DNA cleavage was observed with the wild-type EcoAI endonuclease. Positive supercoils were not seen when eubacterial DNA topoisomerase I was replaced by eukaryotic DNA topoisomerase I, which removes both positive and negative supercoils. Furthermore, addition of eukaryotic DNA topoisomerase I to the product of the supercoiling reaction resulted in its rapid relaxation. These results are consistent with a model in which EcoAI translocation along the helical path of closed circular DNA duplex simultaneously generates positive supercoils ahead and negative supercoils behind the moving complex in the contracting and expanding DNA loops, respectively. In addition, we show that the highly positively supercoiled DNA generated by the EcoAI mutant is cleaved by EcoAI wild-type endonuclease much more slowly than relaxed DNA. This suggests that the topological changes in the DNA substrate associated with DNA translocation by type I restriction enzymes do not appear to be the trigger for DNA cleavage.     

DNA substrate specificity of reverse gyrase from extremely thermophilic archaebacteria

It has been shown earlier that eukaryotic type I DNA topoisomerases act on duplex DNA regions, while eubacterial type I topoisomerases require single-stranded regions. The present paper demonstrates that the type I topoisomerase from extremely thermophilic archaebacteria, reverse gyrase, winds DNA by binding to single-stranded DNA regions. Thus, type I topoisomerases, both relaxing one in eubacteria and reverse gyrase in extremely thermophilic archaebacteria share a substrate specificity to melted DNA regions. The important consequence of this specificity is that the cellular DNA superhelical stress actively controlled by bacterial topoisomerases is confined to a narrow range characterized by a low stability of the double helix. Hence we suppose that bacterial topoisomerase systems control duplex stability near its minimum, for which purpose they create an appropriate negative superhelicity at moderate temperatures or a positive one at extremely high temperatures, the feedback being ensured by the aforesaid specificity of type I bacterial topoisomerases.