Positive supercoiling catalysed in vitro by ATP-dependent topoisomerase from Desulfurococcus amylolyticus

A topoisomerase capable of introducing positive supercoils into closed-circular DNA has been isolated from the extremely thermophilic anaerobic archaebacterium Desulfurococcus amylolyticus. This polypeptide has an Mr of 135,000, as determined by electrophoresis under denaturing conditions. The enzyme is active in the temperature range from 65 degrees C to 100 degrees C and catalyzes positive supercoiling both in negatively supercoiled DNA and in relaxed DNA. These reactions require the presence of ATP. The enzyme's action on a single topoisomer has shown the linking number to increase by an integral number upon the relaxation of negative supercoils and the introduction of positive ones. This means that the reverse gyrase from D. amylolyticus is a type I topoisomerase. The presence of an extended AT sequence within the closed-circular DNA enhances the activity of the Desulfurococcus topoisomerase. Even though the enzyme is isolated from a strictly anaerobic bacterium, it is fully active in the presence of oxygen.     

Vaccinia virus encapsidates a novel topoisomerase with the properties of a eucaryotic type I enzyme

A DNA topoisomerase has been purified from vaccinia virus cores. The native enzyme is composed of a single subunit of 32,000 daltons. The enzyme relaxes both positively and negatively supercoiled DNA in the absence of an energy cofactor. Enzymatic activity is stimulated by magnesium ions and inhibited by ATP, and during relaxation the topoisomerase changes the linking number of the DNA substrate by steps of one. Trapping of the covalent DNA-enzyme intermediate has been achieved, and analysis of the cleavage of duplex DNA by the enzyme reveals that it makes a single-strand break and forms a covalent bond through the 3'-end of the broken strand. Enzymatic activity and formation of the trapped intermediate are inhibited by the drugs novobiocin, coumermycin A1, and berenil. The virally encapsidated enzyme has novel properties but most closely resembles a eucaryotic type I topoisomerase.     

Studies of a positive supercoiling machine. Nucleotide hydrolysis and a multifunctional "latch" in the mechanism of reverse gyrase

Reverse gyrase, the only topoisomerase known to positively supercoil DNA, has an N-terminal ATPase domain that drives the activity of a topoisomerase domain. This study shows that the N-terminal domain represses topoisomerase activity in the absence of nucleotide, and nucleotide binding is sufficient to relieve the repression. A "latch" region in the N-terminal part was observed to close over the topoisomerase domain in the reverse gyrase crystal structure. Mutants lacking all or part of the latch relax DNA in the absence of nucleotide, indicating that this region mediates topoisomerase repression. The mutants also show altered DNA-dependent ATPase activity, suggesting that the latch may be involved in coupling nucleotide hydrolysis to supercoiling. It is not required for this process, however, because the mutants can still positively supercoil DNA. Nucleotide hydrolysis is essential to the specificity of reverse gyrase for increasing the linking number of DNA. Although with ATP the enzyme performs strand passage always toward increasing linking number, it can increase or decrease the linking number in the presence of a nonhydrolyzable ATP analog. This suggests that the mechanism of reverse gyrase is best described by a combination of recently proposed models.     

Linking-number changes in the DNA substrate during Cre-mediated loxP site-specific recombination

We have examined the linking-number changes that occur during phage P1 Cre-mediated recombination in vitro between two loxP sites. Such recombination reactions can be divided into three types: intramolecular inversion, in which recombination occurs between two loxP sites in opposite orientations on the same DNA substrate; intramolecular excision, where recombination occurs between two loxP sites that are in the same orientation on the DNA substrate; and intermolecular recombination, which occurs between two loxP sites on separate DNA molecules. Our results indicate that inversion changes the linking number of the substrate DNA by two topological turns. With a negatively supercoiled substrate, the product is changed by +2 turns. A relaxed substrate yields products that have been changed by either +2 or -2 turns. For intermolecular reactions, the sum of the linking numbers of each of the two starting circles is equal to the linking number of the dimer circle generated by recombination, and no change occurs in linking number. For intramolecular excision reactions, the data are most consistent, with no change in linking number during recombination. These results are discussed in terms of models for alignment and synapsis of the recombining sites and the mechanism of strand exchange.     

Escherichia coli DNA topoisomerase III: purification and characterization of a new type I enzyme

A new topoisomerase capable of relaxing negatively supercoiled DNA in Escherichia coli has been identified during chromatography on novobiocin-Sepharose. A simple and reproducible purification procedure is described to obtain this enzyme, called topoisomerase III (topo III), in a homogeneous form. The protein is a single polypeptide with a molecular weight of 74 000 +/- 2000 and is a type I topoisomerase, changing the linking number of DNA circles in steps of one. It is present in deletion strains lacking the topA gene and further differs from the well-studied topoisomerase I (omega protein; Eco topo I) in (1) its requirement for K+ in addition to Mg2+ to exhibit optimal activity and (2) its affinity to novobiocin-Sepharose. Positively supercoiled DNA is not relaxed during exposure to the enzyme. Topo III has no ATPase activity, and ATP does not show any discernible effect on the reduction of superhelical turns. The purified topoisomerase has no supercoiling activity and is unaffected by high concentrations of oxolinic acid and novobiocin in the relaxing reaction. Single-stranded DNA and spermidine strongly inhibit the topoisomerase activity.     

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).     

Isolation and characterisation of DNA cytosine 5-methyltransferase from human placenta

DNA cytosine 5-methyltransferase has been extensively purified (about 2600-fold) from the soft tissue of human placenta by chromatography on DEAE-cellulose and hydroxyapatite, and by an affinity step on agarose-immobilized S-adenosylhomocysteine. The isolated enzyme has a molecular weight of 135000 and methylates DNA from various sources in native and heat-denatured forms. The synthetic copolymer poly(dG-dC)·poly(dG-dC) is methylated in B- and Z-conformation to about the same extent. DNA containing hemimethylated sites was isolated from P815 cells grown in the presence of 5-azacytidine. This P815 DNA was used to measure the ‘maintenance’ DNA methylase activity, whereas 5-methylcytosine-free procaryotic DNA served as a substrate for the ‘de novo’ DNA methylase activity in our enzyme preparation. The crude extract as well as the highly purified DNA methylase are capable of transferring methyl groups to these two types of substrate. The fact that both types of activity co-chromatograph during the isolation procedure suggests that one enzyme molecule may exercise both the ‘maintenance’ and ‘de novo’ activity.     

Isolation of a Type I Topoisomerase from Carrot Cells

Carbonera, D., Cella, R., Montecucco, A. and Ciarrocchi, G.1988. Isolation of a type I topoisomerase from carrot cells.—J.exp. Bot. 39: 70–78. A DNA topoisomerase activity has been isolated from suspension-culturedcells of Daucus carota, the enzyme has been chromatographedon CM-cellulose, DNA-cellulose and Sephadex G100. Its Mr appearsto be about 100000 by gel filtration. Carrot DNA topoisomeraserelaxes both positively and negatively supercoiled DNA by changingthe linking number of the substrate in steps of one and is notable to unknot the knotted P4 DNA. It does not require ATP orMg²⁺ , has an optimal salt concentration between 40 and 120mol m^–3 KCl and is resistant to nalidixic acid and novobiocine.This carrot enzyme can be designated as a eukaryotic type IDNA topoisomerase. Key words: DNA topoisomerase, Daucus carota     

A human telomerase-associated nuclease

Ciliate and yeast telomerase possess a nucleolytic activity capable of removing DNA from the 3' end of a single-stranded oligonucleotide substrate. The nuclease activity is thought to assist in enzyme proofreading and/or processivity. Herein, we report a previously uncharacterized human telomerase-associated nuclease activity that shares several properties with ciliate and yeast telomerases. Partially purified human telomerase, either from cell extracts or recombinantly produced, demonstrated an ability to remove 3' nontelomeric nucleotides from a substrate containing 5' telomeric DNA, followed by extension of the newly exposed telomeric sequence. This cleavage/extension activity was apparent at more than one position within the telomeric DNA and was influenced by sequences 5' to the telomeric/nontelomeric boundary and by substitution with a methylphosphonate moiety at the telomeric/nontelomeric DNA boundary. Our data suggest that human telomerase is associated with an evolutionarily conserved nucleolytic activity and support a model in which telomerase-substrate interactions can occur distal from the 3' primer end.     

Cytochemical Localization of Polyphenol Oxidase Activity in K2‐Bodies of Saprolegnia ferax Secondary Zoospores

Zoospores of the oomycete Saprolegnia ferax release adhesive material from K‐bodies at the onset of attachment to substrates. To understand more fully how K‐bodies function in adhesion, enzyme activity was investigated cytochemically in secondary zoospores. Presence of catalase, a marker enzyme for microbodies, was explored in the diaminobenzidine (DAB) reaction. Although pH 9.2 DAB‐staining characteristic of catalase activity was detected in the granular matrix regions of K‐bodies, reaction controls indicated that the reaction was due to oxidative enzyme activity other than catalase. Because polyphenol oxidase (PPO) is another metal‐containing enzyme capable of oxidizing DAB, activity of this enzyme was tested with a more specific substrate, dihydroxyphenylalanine (DOPA). In the DOPA procedure, reaction product was exclusively localized within K‐bodies, indicating the presence of PPO. Results with three methods of reaction controls (elimination of substrate, addition of a PPO enzyme inhibitor, and heat‐inactivation of enzymes) all supported the presence of PPO in K‐bodies. This study highlights potential roles for K‐body PPO in stabilization of adhesion bodies by: cross‐linking matrix phenolic proteins or glycoproteins as K‐bodies discharge adhesives onto substrates, or polymerizing phenolics protective against microbial attacks of the adhesion pad.     

Human HeLa cell enzymes that remove phosphoglycolate 3''-end groups from DNA.

We have purified three chromatographically distinct human enzyme activities from HeLa cells, that are capable of converting bleomycin-treated DNA into a substrate for E. coli DNA polymerase I. The bleomycin-treated DNA substrate used in this study has been characterized via a 32P-postlabeling assay and shown to contain strand breaks with 3'-phosphoglycolate termini as greater than 95% of the detectable dose-dependent lesions. The purified HeLa cell enzymes were shown to be capable of removing 3'-phosphoglycolates from this substrate. Also 3'-phosphoglycolate removal and nucleotide incorporation were enzyme dependent. In addition, all three Hela cell enzymes have been determined to possess Class II AP endonuclease activity. The enzymes lack 3'----5' exonuclease activity and are, therefore, dissimilar to exonuclease III--an E. coli enzyme that can remove 3'-phosphoglycolate.     

Isolation and characterization of DNA cytosine 5-methyltransferase from human placenta

DNA cytosine 5-methyltransferase has been extensively purified (about 2600-fold) from the soft tissue of human placenta by chromatography on DEAE-cellulose and hydroxyapatite, and by an affinity step on agarose-immobilized S-adenosylhomocysteine. The isolated enzyme has a molecular weight of 135,000 and methylates DNA from various sources in native and heat-denatured forms. The synthetic copolymer poly(dG-dC) . poly(dG-dC) is methylated in B- and Z-conformation to about the same extent. DNA containing hemimethylated sites was isolated from P815 cells grown in the presence of 5-azacytidine. This P815 DNA was used to measure the "maintenance' DNA methylase activity, whereas 5-methylcytosine-free procaryotic DNA served as a substrate for the "de novo' DNA methylase activity in our enzyme preparation. The crude extract as well as the highly purified DNA methylase are capable of transferring methyl groups to these two types of substrate. The fact that both types of activity co-chromatograph during the isolation procedure suggests that one enzyme molecule may exercise both the "maintenance' and "de novo' activity.     

Biochemical Characterization of Adeno-Associated Virus Rep68 DNA Helicase and ATPase Activities

The adeno-associated virus (AAV) nonstructural proteins Rep68 and Rep78 are site-specific DNA binding proteins, ATP-dependent site-specific endonucleases, helicases, and ATPases. These biochemical activities are required for viral DNA replication and control of viral gene expression. In this study, we characterized the biochemical properties of the helicase and ATPase activities of homogeneously pure Rep68. The enzyme exists as a monomer in solution at the concentrations used in this study (<380 nM), as judged by its mobility in sucrose density gradients. Using a primed single-stranded (ss) circular M13 substrate, the helicase activity had an optimum pH of 7 to 7.5, an optimum temperature of 45°C, and an optimal divalent-cation concentration of 5 mM MgCl₂. Several nucleoside triphosphates could serve as cofactors for Rep68 helicase activity, and the order of preference was ATP = GTP > CTP = dATP > UTP > dGTP. The K_m values for ATP in both the DNA helicase reaction and the site-specific trs endonuclease reaction were essentially the same, approximately 180 μM. Both reactions were sigmoidal with respect to ATP concentration, suggesting that a dimer or higher-order multimer of Rep68 is necessary for both DNA helicase activity and terminal resolution site (trs) nicking activity. Furthermore, when the enzyme itself was titrated in the trs endonuclease and ATPase reactions, both activities were second order with respect to enzyme concentration. This suggests that a dimer of Rep68 is the active form for both the ATPase and nicking activities. In contrast, DNA helicase activity was linear with respect to enzyme concentration. When bound to ssDNA, the enzyme unwound the DNA in the 3′-to-5′ direction. DNA unwinding occurred at a rate of approximately 345 bp per min per monomeric enzyme molecule. The ATP turnover rate was approximately 30 to 50 ATP molecules per min per enzyme molecule. Surprisingly, the presence of DNA was not required for ATPase activity. We estimated that Rep translocates processively for more than 1,300 bases before dissociating from its substrate in the absence of any accessory proteins. DNA helicase activity was not significantly stimulated by substrates that have the structure of a replication fork and contain either a 5′ or 3′ tail. Rep68 binds only to ssDNA, as judged by inhibition of the DNA helicase reaction with ss or double-stranded (ds) DNA. Consistent with this observation, no helicase activity was detected on blunt-ended ds oligonucleotide substrates unless they also contained an ss 3′ tail. However, if a blunt-ended ds oligonucleotide contained the 22-bp Rep binding element sequence, Rep68 was capable of unwinding the substrate. This means that Rep68 can function both as a conventional helicase for strand displacement synthesis and as a terminal-repeat-unwinding protein which catalyzes the conversion of a duplex end to a hairpin primer. Thus, the properties of the Rep DNA helicase activity suggest that Rep is involved in all three of the key steps in AAV DNA replication: terminal resolution, reinitiation, and strand displacement.     

Purification and characterization of Xenopus laevis topoisomerase II

We have purified to apparent homogeneity a type II DNA topoisomerase from Xenopus laevis oocyte nuclei (germinal vesicles, or GV). The most pure preparations contain a single polypeptide of 175,000 daltons as determined by SDS-gel electrophoresis. The enzyme changes the linking number of DNA circles in steps of two and reversibly knots or catenates DNA rings. No gyrase activity is detectable and ATP is required.     

Active-site modification of mammalian DNA polymerase beta with pyridoxal 5'-phosphate: mechanism of inhibition and identification of lysine 71 in the deoxynucleoside triphosphate binding pocket

Pyridoxal 5'-phosphate is a potent inhibitor of the DNA polymerase activity of recombinant rat DNA polymerase beta. Kinetic studies indicate that the mechanism of PLP inhibition is complex. In a lower range of PLP concentration, inhibition is competitive with respect to substrate dNTP, whereas at higher levels of PLP several forms of enzyme combine with PLP and are involved in the overall inhibition, and a possible model for these interactions during the catalytic process is suggested. Reduction of the PLP-treated enzyme with sodium [3H]borohydride results in covalent incorporation of about 4 mol of PLP/mol of enzyme, and the modified enzyme is not capable of DNA polymerase activity. The presence of dNTP during the modification reaction blocks incorporation of 1 mol of PLP/mol of enzyme, and the enzyme so modified is almost fully active. This protective effect is not observed in the absence of template-primer. Tryptic peptide mapping of the PLP-modified enzyme reveals four major sites of modification. Of these four sites, only one is protected by dNTP from pyridoxylation. Sequence analysis of the tryptic peptide corresponding to the protected site reveals that it spans residues 68-80 in the amino acid sequence of the enzyme, with Lys 71 as the site of pyridoxylation. These results indicate that Lys 71 is at or near the binding pocket for the dNTP substrate.     

Hepatitis C virus NS3 helicase forms oligomeric structures that exhibit optimal DNA unwinding activity in vitro

HCV NS3 helicase exhibits activity toward DNA and RNA substrates. The DNA helicase activity of NS3 has been proposed to be optimal when multiple NS3 molecules are bound to the same substrate molecule. NS3 catalyzes little or no measurable DNA unwinding under single cycle conditions in which the concentration of substrate exceeds the concentration of enzyme by 5-fold. However, when NS3 (100 nm) is equimolar with the substrate, a small burst amplitude of approximately 8 nm is observed. The burst amplitude increases as the enzyme concentration increases, consistent with the idea that multiple molecules are needed for optimal unwinding. Protein-protein interactions may facilitate optimal activity, so the oligomeric properties of the enzyme were investigated. Chemical cross-linking indicates that full-length NS3 forms higher order oligomers much more readily than the NS3 helicase domain. Dynamic light scattering indicates that full-length NS3 exists as an oligomer, whereas NS3 helicase domain exists in a monomeric form in solution. Size exclusion chromatography also indicates that full-length NS3 behaves as an oligomer in solution, whereas the NS3 helicase domain behaves as a monomer. When NS3 was passed through a small pore filter capable of removing protein aggregates, greater than 95% of the protein and the DNA unwinding activity was removed from solution. In contrast, only approximately 10% of NS3 helicase domain and approximately 20% of the associated DNA unwinding activity was removed from solution after passage through the small pore filter. The results indicate that the optimally active form of full-length NS3 is part of an oligomeric species in vitro.     

Extracellular α-Glucosidase with Dextran-Hydrolyzing Activity from the Thermophilic Fungus,Thermomyces lanuginosus

The thermophilic fungus Thermomyces lanuginosus, which is able to use dextran as primary carbon source for growth, excreted during the early phases of growth an enzyme activity capable of degrading dextran. The activity peaked at 22 h and decreased rapidly after the culture entered the stationary phase, probably caused by protease activity. Results from growth on a number of different carbon sources showed that polymer carbohydrates yielded the highest dextranase activities. On the basis of the substrate specificity and the release of glucose in the α-anomeric form from the hydrolysis of maltose, it is proposed that the enzyme responsible for the necessary degradation of dextran to smaller saccharides is an α-glucosidase. Received: 30 November 1995 / Accepted: 14 February 1996     

Type II DNA topoisomerases: enzymes that can unknot a topologically knotted DNA molecule via a reversible double-strand break

The T4 DNA topoisomerase is a recently discovered multisubunit protein that appears to have an essential role in the initiation of T4 bacteriophage DND replication. Treatment of double-stranded circular DNA with large amounts of this topoisomerase in the absence of ATP yields new DNA species which are knotted topological isomers of the double-stranded DNA circle. These knotted DNA circles, whether covalently closed or nicked, are converted to unknotted circles by treatment with trace amounts of the T4 topoisomerase in the presence of ATP. Very similar ATP-dependent enzyme activities capable of unknotting DNA are present in extracts of Drosophila eggs. Xenopus laevis eggs and mammalian tissue culture cells. The procaryotic enzyme, DNA gyrase, is also capable of unknotting DNA. We propose that these unknotting enzymes constitute a new general class of DNA topoisomerases (type II DNA topoisomerases). These enzymes must act via mechanisms that involve the concerted cleavage and rejoining of two opposite DNA strands, such that the DNA double helix is transiently broken. The passage of a second double-stranded DNA segment through this reversible double-strand break results in a variety of DNA topoisomerization reactions, including relaxation:super-coiling; knotting:unknotting and catenation:decatenation. In support of this type of mechanism, we demonstrate that the T4 DNA topoisomerase changes the linking number of a covalently closed double-stranded circular DNA molecule only by multiples of two. We discuss the possible roles of such enzymes in a variety of biological functions, along with their probable molecular mechanisms.     

Chemiluminescent detection of DNA: application for DNA sequencing and hybridization.

A non-radioactive DNA detection chemistry is described and its application is shown for DNA hybridization and standard dideoxy DNA sequencing. The method employes a biotin-streptavidin system which binds an enzyme specifically to a target DNA and upon exposure to substrate, the enzyme catalyzes a chemiluminescent reaction. The image is captured within seconds by a Polaroid or X-ray film. The method is capable of detecting DNA in the hundred attomol range.     

Covalent joining of the subunits of a homodimeric type II restriction endonuclease: single-chain PvuII endonuclease

The PvuII restriction endonuclease has been converted from its natural homodimeric form into a single polypeptide chain by tandemly linking the two subunits through a short peptide linker. The arrangement of the single-chain PvuII (sc PvuII) is (2-157)-GlySerGlyGly-(2-157), where (2-157) represents the amino acid residues of the enzyme subunit and GlySerGlyGly is the peptide linker. By introducing the corresponding tandem gene into Escherichia coli, PvuII endonuclease activity could be detected in functional in vivo assays. The sc enzyme was expressed at high level as a soluble protein. The purified enzyme was shown to have the molecular mass expected for the designed sc protein. Based on the DNA cleavage patterns obtained with different substrates, the cleavage specificity of the sc PvuII is indistinguishable from that of the wild-type (wt) enzyme. The sc enzyme binds specifically to the cognate DNA site under non-catalytic conditions, in the presence of Ca2+, with the expected 1:1 stoichiometry. Under standard catalytic conditions, the sc enzyme cleaves simultaneously the two DNA strands in a concerted manner. Steady-state kinetic parameters of DNA cleavage by the sc and wt PvuII showed that the sc enzyme is a potent, but somewhat less efficient catalyst; the k(cat)/K(M) values are 1.11 x 10(9) and 3.50 x 10(9) min(-1) M(-1) for the sc and wt enzyme, respectively. The activity decrease is due to the lower turnover number and to the lower substrate affinity. The sc arrangement provides a facile route to obtain asymmetrically modified heterodimeric enzymes.