Catalysis of ATP hydrolysis by two NH(2)-terminal fragments of yeast DNA topoisomerase II.

Catalysis of ATP hydrolysis by two NH(2)-terminal fragments of yeast DNA topoisomerase II was studied in the absence and presence of DNA, and in the absence and presence of inhibitor ICRF-193. The results indicate that purified Top2-(1-409), a fragment containing the NH(2)-terminal 409 amino acids of the yeast enzyme, is predominantly monomeric, with a low level of ATPase owing to weak association of two monomers to form a catalytically active dimer. The ATPase activity of Top2-(1-409) is independent of DNA in a buffer containing 100 mM NaCl, in which intact yeast DNA topoisomerase II exhibits robust DNA-dependent ATPase and DNA transport activities. Purified Top2-(1-660), a fragment containing the NH(2)-terminal 660 amino acid of the yeast enzyme, appears to be dimeric in the absence or presence of DNA, and the ATPase activity of the protein is significantly stimulated by DNA. These results are consistent with a model in which binding of an intact DNA topoisomerase II to DNA places the various subfragments of the enzyme in a way that makes the intramolecular dimerization of the ATPase domains more favorable. We believe that this alignment of subfragments is mainly achieved through the binding of the enzyme to the DNA segment within which the enzyme makes transient breaks. The ATPase activity of Top2-(1-409) is inhibited by ICRF-193, suggesting that the bisdioxopiperazine class of DNA topoisomerase II inhibitors directly interacts with the paired ATPase domains of the enzyme.     

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.     

Indispensable, functionally complementing N and C-terminal domains constitute site-specific topoisomerase I

Mycobacterium smegmatis topoisomerase I differs from the typical type IA topoisomerase in many properties. The enzyme recognizes both single and double-stranded DNA with high affinity and makes sequence-specific contacts during DNA relaxation reaction. The enzyme has a conserved N-terminal domain and a highly varied C-terminal domain, which lacks the characteristic zinc binding motifs found in most of the type I eubacterial enzymes. The roles of the individual domains of the enzyme in the topoisomerase I catalyzed reactions were examined by comparing the properties of full-length topoisomerase I with those of truncated polypeptides lacking the conserved N-terminal or the divergent C-terminal region. The N-terminal larger fragment retained the site-specific binding, DNA cleavage and religation properties, hallmark characteristics of the full-length M.smegmatis topoisomerase I. In contrast, the non-conserved C-terminal fragment lacking the typical DNA binding motif, exhibited non-specific DNA binding behaviour. The two polypeptide fragments, on their own do not catalyze DNA relaxation reaction. The relaxation activity is restored when both the fragments are mixed in vitro reconstituting the enzyme function. These results along with the DNA interaction pattern of the proteins implicate an essential role for the C-terminal region in single-strand DNA passage between the two transesterification reactions catalyzed by the N-terminal domain.     

Dissection of reverse gyrase activities: insight into the evolution of a thermostable molecular machine

Reverse gyrase is a peculiar DNA topoisomerase, specific of thermophilic microorganisms, which induces positive supercoiling into DNA molecules in an ATP-dependent reaction. It is a modular enzyme and comprises an N-terminal helicase-like module fused to a C-terminal topoisomerase IA-like domain. The exact molecular mechanism of this unique reaction is not understood, and a fundamental mechanistic question is how its distinct steps are coordinated. We studied the cross-talk between the components of this molecular motor and probed communication between the DNA-binding sites and the different activities (DNA relaxation, ATP hydrolysis and positive supercoiling). We show that the isolated ATPase and topoisomerase domains of reverse gyrase form specific physical interactions, retain their own DNA binding and enzymatic activities, and when combined cooperate to achieve the unique ATP-dependent positive supercoiling activity. Our results indicate a mutual effect of both domains on all individual steps of the reaction. The C-terminal domain shows ATP-independent topoisomerase activity, which is repressed by the N-terminal domain in the full-length enzyme; experiments with the isolated domains showed that the C-terminal domain has stimulatory influence on the ATPase activity of the N-terminal domain. In addition, the two domains showed a striking reciprocal thermostabilization effect.     

Communication between the ATPase and cleavage/religation domains of human topoisomerase IIalpha

The DNA strand passage activity of eukaryotic topoisomerase II relies on a cascade of conformational changes triggered by ATP binding to the N-terminal domain of the enzyme. To investigate the interdomain communication between the ATPase and cleavage/religation domains of human topoisomerase IIalpha, we characterized a mutant enzyme that contains a deletion at the interface between the two domains, covering amino acids 350-407. The ATPase domain retained full activity with a rate of ATP hydrolysis that was severalfold higher than normal, but the ATPase activity was unaffected by DNA. The cleavage and religation activities of the enzyme were comparable with those of the wild-type enzyme both in the absence and presence of cancer chemotherapeutic agents. However, neither ATP nor a nonhydrolyzable ATP analog stimulated cleavage complex formation. Although both conserved domains retained full activity, the mutant enzyme was unable to coordinate these activities into strand passage. Our findings suggest that the normal conformational transitions occurring in the enzyme upon ATP binding are hampered or lacking in the mutant enzyme. Consistent with this hypothesis, the enzyme displayed an abnormal clamp closing activity. In summary, the region covering amino acids 350-407 in human topoisomerase IIalpha seems to be essential for correct interdomain communication and probably is involved in signaling ATP binding to the rest of the enzyme.     

Investigating the role of the latch in the positive supercoiling mechanism of reverse gyrase

Reverse gyrase is the only topoisomerase known to positively supercoil DNA and the only protein unique to hyperthermophiles. The enzyme comprises an N-terminal ATPase domain and a C-terminal topoisomerase I domain, which interact to couple the hydrolysis of ATP to the overwinding of DNA. The part of the ATPase domain termed the "latch" represses topoisomerase activity in the absence of nucleotide. Here I provide evidence that the latch, in addition to its regulatory role, participates in the supercoiling mechanism during the DNA cleavage and religation steps. The latch also contributes to the coordination of ATP hydrolysis and positive supercoiling by inhibiting ATPase activity in the absence of supercoiling. The latch therefore plays an important role in the communication between the two domains of reverse gyrase.     

Stability of the topoisomerase II closed clamp conformation may influence DNA-stimulated ATP hydrolysis

Type II DNA topoisomerases catalyze changes in DNA topology and use nucleotide binding and hydrolysis to control conformational changes required for the enzyme reaction. We examined the ATP hydrolysis activity of a bisdioxopiperazine-resistant mutant of human topoisomerase II alpha with phenylalanine substituted for tyrosine at residue 50 in the ATP hydrolysis domain of the enzyme. This substitution reduced the DNA-dependent ATP hydrolysis activity of the mutant protein without affecting the relaxation activity of the enzyme. A similar but stronger effect was seen when the homologous mutation (Tyr28 --> Phe) was introduced in yeast Top2. The ATPase activities of human TOP2alpha(Tyr50 --> Phe) and yeast Top2(Tyr28 --> Phe) were resistant to both bisdioxopiperazines and the ATPase inhibitor sodium orthovanadate. Like bisdioxopiperazines, vanadate traps the enzyme in a salt-stable closed conformation termed the closed clamp, which can be detected in the presence of circular DNA substrates. Consistent with the vanadate-resistant ATPase activity, salt-stable closed clamps were not detected in reactions containing the yeast or human mutant protein, vanadate, and ATP. Similarly, ADP trapped wild-type topoisomerase II as a closed clamp, but could not trap either the human or yeast mutant enzymes. Our results demonstrate that bisdioxopiperazine-resistant mutants exhibit a difference in the stability of the closed clamp formed by the enzyme and that this difference in stability may lead to a loss of DNA-stimulated ATPase. We suggest that the DNA-stimulated ATPase of topoisomerase II is intimately connected with steps that occur while the N-terminal domain of the enzyme is dimerized.     

N-terminal region of the large subunit of Leishmania donovani bisubunit topoisomerase I is involved in DNA relaxation and interaction with the smaller subunit

Leishmania donovani topoisomerase I is an unusual bisubunit enzyme. We have demonstrated earlier that the large and small subunit could be reconstituted in vitro to show topoisomerase I activity. We extend our biochemical study to evaluate the role of the large subunit in topoisomerase activity. The large subunit (LdTOP1L) shows a substantial degree of homology with the core DNA binding domain of the topoisomerase IB family. Two N-terminal truncation constructs, LdTOP1Delta39L (lacking amino acids 1-39) and LdTOP1Delta99L (lacking amino acids 1-99) of the large subunit were generated and mixed with intact small subunit (LdTOP1S). Our observations reveal that residues within amino acids 1-39 of the large subunit have significant roles in modulating topoisomerase I activity (i.e. in vitro DNA relaxation, camptothecin sensitivity, cleavage activity, and DNA binding affinity). Interestingly, the mutant LdTOP1Delta99LS was unable to show topoisomerase I activity. Investigation of the loss of activity indicates that LdTOP1Delta99L was unable to pull down glutathione S-transferase-LdTOP1S in an Ni(2+)-nitrilotriacetic acid co-immobilization experiment. For further analysis, we co-expressed LdTOP1L and LdTOP1S in Escherichia coli BL21(DE3)pLysS cells. The lysate shows topoisomerase I activity. Immunoprecipitation revealed that LdTOP1L could interact with LdTOP1S, indicating the subunit interaction in bacterial cells, whereas immunoprecipitation of bacterial lysate co-expressing LdTOP1Delta99L and LdTOP1S reveals that LdTOP1Delta99L was significantly deficient at interacting with LdTOP1S to reconstitute topoisomerase I activity. This study demonstrates that heterodimerization between the large and small subunits of the bisubunit enzyme appears to be an absolute requirement for topoisomerase activity. The residue within amino acids 1-39 from the N-terminal end of the large subunit regulates DNA topology during relaxation by controlling noncovalent DNA binding or by coordinating DNA contacts by other parts of the enzyme.     

Interaction between yeast sgs1 helicase and DNA topoisomerase III

The Saccharomyces cerevisiae Sgs1 protein is a member of the RecQ family of DNA helicases that includes the human Bloom's syndrome and Werner's syndrome proteins. In this work, we report studies on the interaction between Sgs1 and DNA topoisomerase III in vitro and in vivo. Affinity chromatography experiments with various fragments of Sgs1, a 1447-amino acid polypeptide, suggested that its N-terminal one-fifth was sufficient for interaction with DNA topoisomerase III. Gel electrophoretic mobility shift assays also indicated that a fragment Sgs1(1-283), containing residues 1-283, inhibited the binding of DNA topoisomerase III to single-stranded DNA. A shorter protein fragment containing residues 1-107 also showed partial inhibition in these assays. Studies of a sgs1 top1 double mutant lacking both Sgs1 and DNA topoisomerase I showed that the slow growth phenotype of this double mutant is suppressed by expressing full-length Sgs1, but not Sgs1 without the N-terminal 107 amino acid residues. In sgs1 top3 cells devoid of DNA topoisomerase III, however, expression of full-length Sgs1 or Sgs1 lacking the N-terminal 107 amino acid residues has the same effect of reducing the growth rate of the double mutant. These in vitro and in vivo data indicate that Sgs1 and DNA topoisomerase III physically interact and that this interaction is physiologically significant.     

Histone H1 inhibits eukaryotic DNA topoisomerase I.

Histone H1 inhibits the catalytic activity of topoisomerase I in vitro. The relaxation activity of the enzyme is partially inhibited at a molar ratio of one histone H1 molecule per 40 base pairs (bp) of DNA and completely inhibited at a molar ratio of one histone H1 molecule per 10 base pairs of DNA. Increasing the amount of enzyme at a constant histone H1 to DNA ratio antagonizes the inhibition. This indicates that topoisomerase I and histone H1 compete for binding sites on the substrate DNA molecules. Consistent with this we show on the sequence level that histone H1 inhibits the cleavage reaction of topoisomerase I on linear DNA fragments.     

Enzymatic properties of pierisin-1 and its N-terminal domain, a guanine-specific ADP-ribosyltransferase from the cabbage butterfly

The cabbage butterfly, Pieris rapae, produces an ADP-ribosylating cytotoxic protein, pierisin-1. Unlike other ADP-ribosylating toxins, the acceptor site for ADP-ribosylation by pierisin-1 is the N-2 position of guanine bases in DNA. The present study was designed to characterize this novel guanine-specific ADP-ribosyltransferase, pierisin-1. The N-terminal polypeptide from Met-1 to Arg-233, but not the C-terminal Ser-234-Met-850 polypeptide, was found to exhibit guanine ADP-ribosyltransferase activity. Trypsin-treated pierisin-1, which is considered to be a "nicked" full-length form composed of associated N- and C-terminal fragments, also demonstrated such activity. Optimum conditions for the N-terminal polypeptide of pierisin-1 were pH 8-10, 37-40 degrees C, in the presence of 100-200 mM NaCl or KCl. Other metal ions such as Ca(2+) or Mg(2+) were not required. Kinetic studies demonstrated potent ADP-ribosyltransferase activity with a K(M) value for NAD of 0.17 mM and k(cat) of 55 per second. Under these optimum conditions, the specific activity of trypsin-treated pierisin-1 was about half (k(cat) = 25 per second). When the conditions were changed to pH 5-7 or 10-20 degrees C, some activity (6-55% or 5-20%, respectively, of that under optimal conditions) of the N-terminal polypeptide was still evident; however, almost all of the trypsin-treated enzyme activity disappeared. This implies the inhibition of the N-terminal enzyme domain by the associated C-terminal fragment. Long-term reactions indicated that a single molecule of pierisin-1 has the capacity to generate more than 10(6) ADP-ribosylated DNA adducts, which could cause the death of a mammalian cell.     

Separation of bisdioxopiperazine- and vanadate resistance in topoisomerase II

Bisdioxopiperazines are inhibitors of topoisomerase II trapping this protein as a closed clamp on DNA with concomitant inhibition of its ATPase activity. Here, we analyse the effects of N-terminal mutations identified in bisdioxopiperazine-resistant cells on ATP hydrolysis by this enzyme. We present data consistent with bisdioxopiperazine resistance arising by two different mechanisms; one involving reduced stability of the N-terminal clamp (the N-gate) and one involving reduced affinity for bisdioxopiperazines. Vanadate is a general inhibitor of type P ATPases and has recently been demonstrated to lock topoisomerase II as a salt-stable closed clamp on DNA analogous to the bisdioxopiperazines. We show that a R162K mutation in human topoisomerase II alpha renders this enzyme highly resistant towards vanadate while having little effect on bisdioxopiperazine sensitivity. The implications of these findings for the mechanism of action of bisdioxopiperazines versus vanadate with topoisomerase II are discussed.     

Regions within the N-terminal domain of human topoisomerase I exert important functions during strand rotation and DNA binding

The human topoisomerase I N-terminal domain is the only part of the enzyme still not crystallized and the function of this domain remains enigmatical. In the present study, we have addressed the specific functions of individual N-terminal regions of topoisomerase I by characterizing mutants lacking amino acid residues 1-202 or 191-206 or having tryptophane-205 substituted by glycine in a broad variety of in vitro activity assays. As a result of these investigations we find that mutants altered in the region 191-206 distinguished themselves from the wild-type enzyme by a faster strand rotation step, insensitivity towards the anti-cancer drug camptothecin in relaxation and the inability to ligate blunt end DNA fragments. The mutant lacking amino acid residues 1-202 was impaired in blunt end DNA ligation and showed wild-type sensitivity towards camptothecin in relaxation. Taken together, the presented data support a model according to which tryptophane-205 and possibly other residues located between position 191-206 coordinates the restriction of free strand rotation during the topoisomerization step of catalysis. Moreover, tryptophane-205 appears important for the function of the bulk part of the N-terminal domain in direct DNA interaction.     

Purification and characterization of a type II DNA topoisomerase from bovine calf thymus

We report here the large scale purification of DNA topoisomerase II from calf thymus glands, using the unknotting of naturally knotted P4 phage DNA as an assay for enzymatic activity. Topoisomerase II was purified more than 1300-fold as compared to the whole cell homogenate, with 22% yield. Analysis of the purified enzyme by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed two bands of apparent molecular masses of 125 and 140 kDa. Tryptic maps of the two bands indicated that they derive from the same protein. Using these fragments, specific polyclonal antisera to topoisomerase II were raised in rabbits. Immunoblotting of whole cell lysates from various species indicated that topoisomerase II is well conserved among mammals and has a native subunit molecular mass of 180 kDa. Analytical sedimentation and gel filtration were used to determine a sedimentation coefficient of 9.8 S and a Stokes radius of 68 A. The calculated solution molecular mass of 277 kDa implies a dimer structure in solution. The purified topoisomerase II unknots P4 DNA in an ATP-dependent manner and is highly stimulated in its relaxation activity by ATP. A DNA-stimulated ATPase activity, as has been found with other type II topoisomerases, is associated with the purified enzyme. Approximate kinetic parameters for the ATPase reaction were determined to be: a Vmax of 0.06 nmol of ATP/(micrograms of protein) (min) and Km of 0.2 mM in the absence of DNA, and a Vmax of 0.2 nmol of ATP/(micrograms of protein) (min) and Km of 0.4 mM ATP in the presence of supercoiled plasmid DNA.     

Cloning,expression and characterization of a gene which encodes a topoisomerase I with positive supercoiling activity in pea

We have isolated and sequenced the full length cDNA for topoisomerase I. Using degenerate primers, based on the conserved amino acid sequences of five eukaryotic topoisomerase I, a 386 bp fragment was PCR amplified using pea cDNA as template. This fragment was used as a probe to screen a pea cDNA library. Two partial cDNA clones were isolated which were truncated at the 5 end. RACE-PCR was employed to isolate the remaining portion of the gene. The total size of the gene was 3055 bp with an open reading frame of 2676 bp. The deduced structure of pea topoisomerase I contain 892 amino acids with a calculated molecular weight of 100 kDa and an estimated pI of 9.3. A comparison of the deduced amino acid sequences of the pea topo I with the other eukaryotic topoisomerases clearly suggested that they are all related. Pea topoisomerase I has been overexpressed in E. coli system and the recombinant topoisomerase purified to homogeneity. The purified protein relaxes both positive and negative supercoiled DNA in the absence of divalent cation Mg²⁺. In the presence of Mg²⁺ ions the purified enzyme introduces positive supercoils a unique property not reported in any other organism except in archaebacterial topoisomerase I. Polyclonal antibodies were raised against recombinant topoisomerase I and western blotting with sub-cellular fractions indicated the localization of this topoisomerase in pea nuclei.     

The ATPase domain of the large terminase protein, gp17, from bacteriophage T4 binds DNA: implications to the DNA packaging mechanism

Translocation of double-stranded DNA into a preformed capsid by tailed bacteriophages is driven by powerful motors assembled at the special portal vertex. The motor is thought to drive processive cycles of DNA binding, movement, and release to package the viral genome. In phage T4, there is evidence that the large terminase protein, gene product 17 (gp17), assembles into a multisubunit motor and translocates DNA by an inchworm mechanism. gp17 consists of two domains; an N-terminal ATPase domain (amino acids 1-360) that powers translocation of DNA, and a C-terminal nuclease domain (amino acids 361-610) that cuts concatemeric DNA to generate a headful-size viral genome. While the functional motifs of ATPase and nuclease have been well defined and the ATPase atomic structure has been solved, the DNA binding motif(s) responsible for viral DNA recognition, cutting, and translocation are unknown. Here we report the first evidence for the presence of a double-stranded DNA binding activity in the gp17 ATPase domain. Binding to DNA is sensitive to Mg²⁺ and salt, but not the type of DNA used. DNA fragments as short as 20 bp can bind to the ATPase but preferential binding was observed to DNA greater than 1 kb. A high molecular weight ATPase-DNA complex was isolated by gel filtration, suggesting oligomerization of ATPase following DNA interaction. DNA binding was not observed with the full-length gp17, or the C-terminal nuclease domain. The small terminase protein, gp16, inhibited DNA binding, which was further accentuated by ATP. The presence of a DNA binding site in the ATPase domain and its binding properties implicate a role in the DNA packaging mechanism.     

Probing the limits of the DNA breakage-reunion domain of the Escherichia coli DNA gyrase A protein.

In a previous report (Reece, R. J., and Maxwell, A. (1989) J. Biol. Chem. 264, 19648-19653) we showed that treatment of the Escherichia coli DNA gyrase A protein with trypsin generates two stable fragments. The N-terminal 64-kDa fragment supports DNA supercoiling, while the C-terminal 33-kDa fragment shows no enzymic activity. We proposed that the 64-kDa fragment represents the DNA breakage-reunion domain of the A protein. We have now engineered the gyrA gene such that the 64-kDa protein is generated as a gene product. The properties of this protein confirm the findings of the experiments with the 64-kDa tryptic fragment. We have also generated a series of deletions of the gyrA gene such that C-terminal and N-terminal truncated versions of the A protein are produced. The smallest of the N-terminal fragments found to be able to carry out the DNA breakage-reunion reaction is GyrA(1-523). The cleavage reaction mediated by this protein occurs with equal efficacy as that performed by the intact GyrA protein. Deletion of the N-terminal 6 amino acids from either the A protein or these deletion derivatives has no effect on enzymic activity, while deletion of the N-terminal 69 amino acids completely abolishes the DNA breakage-reunion reaction. Therefore the smallest GyrA protein we have found that will perform DNA breakage and reunion is GyrA(7-523). A model is proposed for the domain organization of the gyrase A protein.     

Leishmania donovani bisubunit topoisomerase I gene fusion leads to an active enzyme with conserved type IB enzyme function

All eukaryotic topoisomerase I enzymes are monomeric enzymes, whereas the kinetoplastid family (Trypanosoma and Leishmania) possess an unusual bisubunit topoisomerase I. To determine what happens to the enzyme architecture and catalytic property if the two subunits are fused, and to explore the functional relationship between the two subunits, we describe here in vitro gene fusion of Leishmania bisubunit topoisomerase I into a single ORF encoding a new monomeric topoisomerase I (LdTOPIL-fus-S). It was found that LdTOPIL-fus-S is active. Gene fusion leads to a significant modulation of in vitro topoisomerase I activity compared to the wild-type heterodimeric enzyme (LdTOPILS). Interestingly, an N-terminal truncation mutant (1-210 amino acids) of the small subunit, when fused to the intact large subunit [LdTOPIL-fus-Delta(1-210)S], showed reduced topoisomerase I activity and camptothecin sensitivity in comparison to LdTOPIL-fus-S. Investigation of the reduction in enzyme activity indicated that the nonconserved 1-210 residues of LdTOPIS probably act as a 'pseudolinker' domain between the core and catalytic domain of the fused Leishmania enzyme, whereas mutational analysis of conserved His453 in the core DNA-binding domain (LdTOPIL) strongly suggested that its role is to stabilize the enzyme-DNA transition state through hydrogen bonding to one of the nonbridging oxygens. Taken together, our findings provide an insight into the details of the unusual structure of bisubunit topoisomerase I of Leishmania donovani.     

Purification and enzymological characterization of DNA-dependent ATPase IV from the Novikoff hepatoma.

DNA-dependent ATPase IV has been purified to near homogeneity from the Novikoff rat hepatoma. The enzyme is devoid of DNA polymerase, RNA polymerase, exonuclease, endonuclease, phosphomonoesterase, 3'- or 5'-phosphodiesterase, polynucleotide kinase, protein kinase, topoisomerase, helicase or DNA reannealing activities at a detection level of 10(-5) to 10(-7) relative to the ATPase activity. The enzyme is a monomer of Mr 110,000, has a sedimentation coefficient of 5.9 S, a Stokes radius of 40 A and a frictional coefficient of 1.32. In the presence of Mg2+ ion and a polynucleotide effector, ATPase IV hydrolyzes either ATP or dATP to the nucleoside diphosphate plus Pi. Other ribo- or deoxyribonucleoside triphosphates are not substrates. ATPase IV utilizes double-stranded DNA and single-stranded DNA as effector; however, it does not utilize poly(dT). The Km for dsDNA or ssDNA is 2.2 microM (nucleotide). A variety of ATP analogues were found to be competitive inhibitors of ATPase IV.     

Phosphorylation of mammalian DNA topoisomerase I and activation by protein kinase C

The influence of mammalian DNA topoisomerase I phosphorylation on enzyme activity has been investigated. Dephosphorylation by calf intestine alkaline phosphatase abolished the DNA relaxing activity of DNA topoisomerase I and the sensitivity of the enzyme to its specific inhibitor, camptothecin. DNA topoisomerase I could be reactivated by incubation with purified protein kinase C. DNA topoisomerase I was then able to relax supercoiled DNA processively, like the native enzyme, and to cleave 32P-end-labeled SV40 DNA fragments at the same sequences as the native enzyme in the presence of camptothecin. These results show that active DNA topoisomerase I is a phosphoprotein and suggest a possible regulatory role of protein kinase on topoisomerase I activity and on its sensitivity to camptothecin.