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.     

ATP-independent DNA topoisomerase II as potential drug target in trypanosomes

Two categories of trypanosomal type II topoisomerases have been isolated from trypanosomes: one is unique since it is able to realize DNA topoisomerization reactions in the absence of ATP, in contrast to the other enzyme and mammalian topoisomerase II. The biochemical properties of ATP-independent topoisomerase II from Trypanosoma cruzi are described in this report. The enzyme can decatenate trypanosome kinetoplast DNA networks, catenate supercoiled DNA molecules, unknot P4 phage DNA, and cleave double-stranded DNA. The enzyme is inhibited by various classes of drugs and is more sensitive than mammalian topoisomerase II. Therefore, trypanosome ATP-independent topoisomerase II provides a potential target for chemotherapy.     

A homogeneous type II DNA topoisomerase from HeLa cell nuclei

Using kinetoplast DNA networks as a substrate in a decatenation assay, we have purified to apparent homogeneity a type II DNA topoisomerase from HeLa cell nuclei. The most pure preparations contain a single polypeptide of 172,000 daltons as determined by sodium dodecyl sulfate-gel electrophoresis. The molecular weight of the native protein, based on sedimentation and gel filtration analyses, is estimated to be 309,000. These results suggest that the enzyme is a dimer of 172,0090-dalton subunits. The enzyme is a type II topoisomerase as demonstrated by its ability to change the linking number of DNA circles in steps of two and to decatenate or unknot covalently closed DNA circles. No gyrase activity is detectable. ATP is required for the relaxation, decatenation, and unknotting of DNA, and a DNA-dependent ATPase activity is present in the most pure fractions. ATP is hydrolyzed to ADP in this properties to T4 DNA topoisomerase (Liu, L. F., Liu, C. C., and Alberts, B. M. (1979) Nature 281, 456-461).     

In vitro catenation and decatenation of DNA and a novel eucaryotic ATP-dependent topoisomerase

Extracts from X. laevis germinal vesicles interlock duplex DNA circles to form catenanes. The catenation activity requires Mg++ and ATP. Negatively supercoiled or relaxed DNA can be used as substrates for the catenation reaction. Homology between donor and acceptor DNA is not required, since catenanes are formed between DNA molecules with unrelated sequences. In the course of the isolation of the activity responsible for the catenation reaction, we discovered a new ATP-dependent topoisomerase. The fractions containing the novel topoisomerase catenate and decatenate DNA, the ionic strength dictating which of the two opposing reactions will occur.     

A quantitative decatenation assay for type II topoisomerases

Type II topoisomerases catalyze decatenation of the catenated network of kinetoplast DNA [J. C. Marini, K. G. Miller, and P. T. Englund (1980) J. Biol. Chem. 255, 4976-4979]. The individual DNA circles and small catenanes produced during the decatenation reaction can be separated from the large network of substrate DNA by 5 min centrifugation at 13,000g and quantitated. The appearance of these decatenated DNA molecules which appear in the supernatant first showed a lag, whose duration depended on the enzyme concentration, and then increased linearly with time until it reached a plateau. The slope of the linear part of the kinetic curve was directly proportional to the enzyme concentration, whether a purified or crude preparation of type II topoisomerase from mammalian cells was used. These findings led us to a rapid quantitative assay of type II topoisomerases not involving electrophoresis. The method was developed with purified enzyme but was also useful for assay of the activity in crude extracts. Surprisingly, the type I topoisomerase, even when present in large excess, failed to decatenate the nicked DNA circles often present in the kinetoplast DNA. This renders the assay virtually free from interference by type I enzyme. The method is sensitive and allowed quantitative estimation of the enzyme activity present in the crude extracts corresponding to that derived from 500 to 700 cultured mammalian cells. Since various type II topoisomerases from procaryotic, eucaryotic, and viral sources decatenate kinetoplast DNA and generate similar DNA products, the assay method is likely to be generally applicable.     

Reversible decatenation of kinetoplast DNA by a DNA topoisomerase from trypanosomatids.

DNA topoisomerase activity detected in cell extracts of the trypanosomatid Crithidia fasciculata interlocks kinetoplast DNA duplex minicircles into huge catenane forms resembling the natural kinetoplast DNA networks found in trypanosomes. Catenation of duplex DNA circles is reversible and equilibrium is affected by ionic strength, and by spermidine. The reaction requires magnesium, is ATP dependent and is inhibited by high concentrations of novobiocin. Extensive homology between duplex DNA rings was not required for catenane formation since DNA circles with unrelated sequences could be interlocked into mixed network forms. Covalently sealed catenaned DNA circles are specifically used as substrates for decatenation. No such preference for covalently sealed duplex DNA rings was observed for catenate formation. Its catalytic properties and DNA substrate preference, suggest a potential role for this eukaryotic topoisomerase activity in the replication of kinetoplast DNA.     

Isolation and partial characterization of two distinct DNA topoisomerases from cauliflower inflorescence

DNA topoisomerases which remove superhelical turns in closed circular DNA have been isolated from cauliflower inflorescences using polyethylene glycol fractionation, ammonium sulfate precipitation, and column chromatography on CM-Sephadex or CM-cellulose and DNA-cellulose. Two distinct enzymes, topoisomerase-I and ATP-dependent topoisomerase, were separated clearly by CM-Sephadex or CM-cellulose, and partially characterized using agarose gel electrophoresis with plasmid pBR322 DNA. Topoisomerase-I acts like other eucaryotic DNA topoisomerases in the absence of ATP, is stimulated by spermidine and inhibited by EDTA. The ATP-dependent topoisomerase acts like topoisomerase-I only in the presence of ATP in the reaction medium, is inhibited by spermidine and EDTA, and does not introduce supertwists into closed duplex DNA or produce catenate aggregates under the present reaction conditions.     

The structure of Escherichia coli DNA topoisomerase III

BACKGROUND: DNA topoisomerases are enzymes that change the topology of DNA. Type IA topoisomerases transiently cleave one DNA strand in order to pass another strand or strands through the break. In this manner, they can relax negatively supercoiled DNA and catenate and decatenate DNA molecules. Structural information on Escherichia coli DNA topoisomerase III is important for understanding the mechanism of this type of enzyme and for studying the mechanistic differences among different members of the same subfamily. RESULTS: The structure of the intact and fully active E. coli DNA topoisomerase III has been solved to 3.0 A resolution. The structure shows the characteristic fold of the type IA topoisomerases that is formed by four domains, creating a toroidal protein. There is remarkable structural similarity to the 67 kDa N-terminal fragment of E. coli DNA topoisomerase I, although the relative arrangement of the four domains is significantly different. A major difference is the presence of a 17 amino acid insertion in topoisomerase III that protrudes from the side of the central hole and could be involved in the catenation and decatenation reactions. The active site is formed by highly conserved amino acids, but the structural information and existing biochemical and mutagenesis data are still insufficient to assign specific roles to most of them. The presence of a groove in one side of the protein is suggestive of a single-stranded DNA (ssDNA)-binding region. CONCLUSIONS: The structure of E. coli DNA topoisomerase III resembles the structure of E. coli DNA topoisomerase I except for the presence of a positively charged loop that may be involved in catenation and decatenation. A groove on the side of the protein leads to the active site and is likely to be involved in DNA binding. The structure helps to establish the overall mechanism for the type IA subfamily of topoisomerases with greater confidence and expands the structural basis for understanding these proteins.     

Mitochondrial and nuclear localization of topoisomerase II in the flagellate Bodo saltans (Kinetoplastida), a species with non-catenated kinetoplast DNA

We have studied topoisomerase II (topo II) in the cells of Bodo saltans, a free-living bodonid (Kinetoplastida). Phylogenetic analysis based on the sequence of the entire topo II gene, which is a single-copy gene, confirmed that B. saltans is a predecessor of parasitic trypanosomatids. Antibodies generated against either an overexpressed unique C-terminal region of topo II or a synthetic oligopeptide derived from the same region did not cross-react with cell lysates of related trypanosomatids, while they recognized a single specific band in the B. saltans lysate. Immunolocalization experiments using both antibodies showed that topo II is evenly dispersed throughout the kinetoplast. This is in striking difference from the localization of topo II in other flagellates, where it occurs in two antipodal centers flanking the kinetoplast disk. Moreover, the same topo II has a distinct localization in multiple loci at the periphery of the nucleus of B. saltans. With a minicircle probe derived from the conserved region we have shown that all relaxed non-catenated minicircles are confined to the globular kinetoplast DNA bundle. Therefore, in the mitochondrion of this primitive eukaryote topo II does not catenate relaxed DNA circles into a network in vivo, while a decatenating activity is present in partially purified cell lysates.     

Characterization of a potent catenation activity of HeLa cell nuclei

Using an assay which measures catenation of a supercoiled DNA template, we have characterized and quantitated a potent activity identified in crude fractions of HeLa cell nuclei. Catenation requires Mg-ATP and a DNA-condensing agent, polyvinyl alcohol. A filter-binding or agarose gel assay can be used to quantitate activity. In this reaction, DNA topoisomerase I relaxes the input supercoiled DNA to provide DNA topoisomerase II, a strongly favored template for catenation. DNA topoisomerase II preferentially catenates relaxed DNA over supercoiled DNA by a factor of 100. One molecule of DNA topoisomerase II is able to catenate about 20 circles of relaxed DNA/min at 30 degrees C but only 0.16 circle of supercoiled DNA/min at 30 degrees C. The purified HeLa topoisomerase I can also catenate DNA under these assay conditions, yet in an ATP-independent fashion. It is much less efficient than topoisomerase II; one molecule of topoisomerase I catenates only about 3.8 X 10(-3) molecules of supercoiled DNA/min at 30 degrees C with a DNA template containing 5% nicked circles. This remarkable difference between the two enzymes allows quantitation of DNA topoisomerase II activity seen in the presence of excess topoisomerase I. Unlike Escherichia coli topoisomerase I (omega), catenation by the HeLa topoisomerase I is not stimulated by gapped circles.     

Type I DNA topoisomerases from mammalian cell nuclei interlock strains and promote renaturation of denatured closed circular PM2 DNA

Type I DNA topoisomerases from mouse ascites cell nuclei and from rat liver cell nuclei act on denatured viral closed circular PM2 DNA to produce molecules with a highly contracted structure as well as fully duplex non-supercoiled covalently closed circular molecules. Highly contracted DNA molecules contain a novel type of topological linkage in which a strand in one region of the double-stranded molecule passes between the strands in another region of the circular molecule one or more times. Since it is also found that the action of the topoisomerase promotes renaturation of complementary strands in denatured closed circular DNA, it is suggested that formation of contracted DNA structures proceeds through renatured, duplex intermediates with highly negative superhelix densities that contain small single-stranded regions.     

Characterization of topoisomerase I and II activities in nuclear extracts during callogenesis in immature embryos of Zea mays

We have characterized the topoisomerase I and II activities in nuclear extracts from immature embryos of Zea mays and the effect of the treatment with 2,4-dichlorophenoxyacetic acid (2,4-D) and abscisic acid (ABA). These extracts were shown to be essentially devoid of protease and nuclease activities and they were tested for their ability to relax supercoiled DNA, unknotting P4 DNA and catenate circular duplex DNA under catalytic conditions. Unknotting and catenation reactions are strictly magnesium- and ATP-dependent, but not the relaxation of circular supercoiled DNA allowing the detection of both topoisomerase I and II activities. Two cytotoxic drugs, camptothecin, a plant alkaloid that inhibits cukaryotic topoisomerase I, and epipodophyllotoxin VM-26 (teniposide) that inhibits topoisomerase II, have been assayed in our extracts showing similar inhibitory effects on topoisomerase enzymes. Alkaline phosphatase treatment of nuclear extracts abolishes both topoisomerase activities. Nuclear extracts from embryos treated with 2,4-D showed 200% increase on topoisomerase II activity as compared with untreated ones, but only residual activity was detected in ABA-treated embryos. Nuclear extracts from hormone-treated and untreated embryos showed similar topoisomerase I activity with deviations of less than 25%. These differences are discussed in terms of possible post-translational modifications of the enzymes associated with the increase in proliferation activity of calli.     

Reverse gyrase; ATP-dependent type I topoisomerase from Sulfolobus

Reverse gyrase, a topoisomerase which introduces positive superhelical turns into DNA, has been purified from Sulfolobus to near homogeneity. It is a single polypeptide with a mol. wt. of 120 000 as determined by denaturing gel electrophoresis. Contrary to a previous report, it is a type I topoisomerase as judged by the linking-number change of closed circular DNA topoisomer. Unlike other known type I topoisomerases, ATP or dATP is required for introducing positive superhelical turns. In order to relax negatively supercoiled DNA, other nucleotide triphosphates (XTP) are also effective with low efficiency. In the absence of either XTP or divalent cations, the enzyme introduces nicks into closed circular DNA when the reaction is stopped by SDS. This suggests that reverse gyrase cuts one of the two strands of DNA in the course of its enzymatic reaction.     

An ATP-independent catenating enzyme from the kinetoplast hemoflagellate Leishmania donovani.

An enzyme from Leishmania donovani that catenates monomeric pBR322 into huge catenanes has been isolated and characterized. The enzyme also decatenates kinetoplast DNA networks into covalently closed monomeric circles and relaxes supercoiled pBR322. The catenation, decatenation and relaxation reactions do not require ATP. The formation of topological isomers of unique linking numbers suggest that the enzyme is a type II DNA topoisomerase.     

Purification and characterization of yeast topoisomerase I

Yeast topoisomerase I (Mr = 76,000) has been purified to 80% homogeneity using a combination of ion exchange, gel filtration, and DNA-cellulose chromatography. The enzyme was characterized with respect to its ability to relax supercoiled DNA and to catenate nicked circular DNA. Yeast topoisomerase I will remove both positive and negative turns in DNA supercoils in the absence of ATP and magnesium ion. The products of the catenating activity of the enzyme were examined on agarose gels and in the electron microscope. These analyses indicate that yeast topoisomerase I will generate large catenated DNA networks which appear to rearrange to multimeric linear structures upon long incubation time.     

Single-molecule analysis uncovers the difference between the kinetics of DNA decatenation by bacterial topoisomerases I and III

Escherichia coli topoisomerases I and III can decatenate double-stranded DNA (dsDNA) molecules containing single-stranded DNA regions or nicks as well as relax negatively supercoiled DNA. Although the proteins share a mechanism of action and have similar structures, they participate in different cellular processes. Whereas topoisomerase III is a more efficient decatenase than topoisomerase I, the opposite is true for DNA relaxation. In order to investigate the differences in the mechanism of these two prototypical type IA topoisomerases, we studied DNA decatenation at the single-molecule level using braids of intact dsDNA and nicked dsDNA with bulges. We found that neither protein decatenates an intact DNA braid. In contrast, both enzymes exhibited robust decatenation activity on DNA braids with a bulge. The experiments reveal that a main difference between the unbraiding mechanisms of these topoisomerases lies in the pauses between decatenation cycles. Shorter pauses for topoisomerase III result in a higher decatenation rate. In addition, topoisomerase III shows a strong dependence on the crossover angle of the DNA strands. These real-time observations reveal the kinetic characteristics of the decatenation mechanism and help explain the differences between their activities.     

DNA Topological Context Affects Access to Eukaryotic DNA Topoisomerase I

Abstract

We have analyzed the reactivity of a 217 base pair segment of the intrinsically curved Crithidia fasciculata kinetoplast DNA towards eukaryotic DNA topoisomerase I. The substrates were open [linear fragment and nicked circle] and closed minidomains [closed relaxed circle and circles with linking differences of ?1 and ?2], We interpreted the results with the aid of a model that was used to predict the structures of the topoisomers. The modelling shows that the ΔLk(?l) form is unusually compact because of the curvature in the DNA. To determine the role of sequence-directed curvature in both the experimental and modeling studies, controls were examined in which the curved Crithidia sequence was replaced by an uncurved sequence obtained from the plasmid pBR322.

Reactivity of the Crithidia DNA [as analyzed both by the cleavage and the topoisomerization reactions] markedly varied among the DNA forms: (i) the hierarchy of overall reactivity observed is: linear fragment > nicked circular, closed circular [ΔLk(O)], interwound [ΔLk(?2)] > bent interwound [ΔLk(?l)]; (ii) the intensity of several cleavage positions differs among DNA forms.

The results show that eukaryotic DNA topoisomerase I is very sensitive to the conformation of the substrates and that its reactivity is modulated by the variation of the compactness of the DNA molecule. The C. fasciculata sequence contains a highly curved segment that determines the conformation of the closed circle in a complex way.     

DNA topoisomerase II from Drosophila melanogaster. Purification and physical characterization

A type II DNA topoisomerase has been purified from the nuclei of Drosophila melanogaster 6- to 18-h-old embryos. The enzyme, as assayed by its ability to catenate supercoiled DNA, behaved as a single homogeneous species throughout the procedure and the yield was approximately 0.5 mg of protein/100 g of dechorionated embryos. The final product was entirely ATP-dependent and free of topoisomerase I, endonuclease and protease activities. The purified topoisomerase II had a Stokes radius of 69 A and a sedimentation coefficient (S20,w) of 9.2 S, leading to a calculated native molecular weight of approximately 261,000. The protein consists of a single polypeptide of molecular weight 166,000, as determined by electrophoresis on sodium dodecyl sulfate-polyacrylamide gels. Taken together with the above hydrodynamic studies, the Drosophila enzyme is probably a homodimer, as has been observed for other eukaryotic type II enzymes. Thus, it appears that during the course of evolution the heterologous subunits which comprise bacterial type II topoisomerases have been combined into a single polypeptide chain in eukaryotes.     

The structure of kinetoplast DNA. I. Properties of the intact multi-circular complex from Crithidia luciliae.

We have developed a modified isolation procedure that yields kinetoplast DNA networks containing more than 90% closed circular DNA, as judged by two criteria: (a) In 0.15 M NaCl/0.015 M sodium citrate (pH 7.0), less than 10% of the intact kinetoplast DNA melts in the temperature region of sonicated kinetoplast DNA. In 7.2 M NaCl04 the kinetoplast DNA melts with a Tm 26 degrees C higher than sonicated kinetoplast DNA. Even after complete melting in 7.2 M NaClO4 at 90 degrees C, the network remains intact, as judged by regain of hypochromicity on cooling and analysis in CsCl containing propidium dixodide. (b) In alkaline sucrose gradients more than 90% of the kinetoplast DNA sediments in a single peak. 2. In CsCl gradients containing ethidium bromide of propidium diiodide intact kinetoplast DNA gives a single uni-modal band showing an extremely restricted dye uptake. From the position of the bank relative to the bands of PM2 DNA, the superhelix density of these networks is calculated to be +3.9 twists per 1000 base pairs. The superhelix density of closed mini-circles, efficiently liberated from the networks by shear in a French press, is -0.5 twists per 1000 base pairs. We attribute the high superhelix density (the highest yet observed in any DNA) of intact networks to their compact, highly catenated structure, leading to an additional constraint on dye uptake, superimposed on the restriction due to closed circularity.     

Replication of DNA minicircles in kinetoplasts isolated from Crithidia fasciculata: structure of nascent minicircles.

We have previously described an isolated kinetoplast system from Crithidia fasciculata capable of ATP-dependent replication of kinetoplast DNA minicircles (L. Birkenmeyer and D.S. Ray, J. Biol. Chem. 261: 2362-2368, 1986). We present here the identification of two new minicircle species observed in short pulse-labeling experiments in this system. The earliest labeled minicircle species (component A) contains both nascent H and L strands and is heterogeneous in sedimentation and electrophoretic migration. Component A has characteristics consistent with a Cairns-type structure in which the L strand is the leading strand and the H strand is the lagging strand. The other new species (component B) has a nascent 2.5-kilobase linear L strand with a single discontinuity that mapped to either of two alternative origins located 180 degrees apart on the minicircle map. Component B could be repaired to a covalently closed form by Escherichia coli polymerase I and T4 ligase but not by T4 polymerase and T4 ligase. Even though component B has a single gap in one strand, it had an electrophoretic mobility on an agarose gel (minus ethidium bromide) similar to that of a supercoiled circle with three supertwists. Treatment of component B with topoisomerase II converted it to a form that comigrated with a nicked open circular form (replicative form II). These results indicate that component B is a knotted topoisomer of a kinetoplast DNA minicircle with a single gap in the L strand.