DNA topoisomerase II selects DNA cleavage sites based on reactivity rather than binding affinity

DNA topoisomerase II modulates DNA topology by relieving supercoil stress and by unknotting or decatenating entangled DNA. During its reaction cycle, the enzyme creates a transient double-strand break in one DNA segment, the G-DNA. This break serves as a gate through which another DNA segment is transported. Defined topoisomerase II cleavage sites in genomic and plasmid DNA have been previously mapped. To dissect the G-DNA recognition mechanism, we studied the affinity and reactivity of a series of DNA duplexes of varied sequence under conditions that only allow G-DNA to bind. These DNA duplexes could be cleaved to varying extents ranging from undetectable (<0.5%) to 80%. The sequence that defines a cleavage site resides within the central 20bp of the duplex. The DNA affinity does not correlate with the ability of the enzyme to cleave DNA, suggesting that the binding step does not contribute significantly to the selection mechanism. Kinetic experiments show that the selectivity interactions are formed before rather than subsequent to cleavage. Presumably the binding energy of the cognate interactions is used to promote a conformational change that brings the enzyme into a cleavage competent state. The ability to modulate the extent of DNA cleavage by varying the DNA sequence may be valuable for future structural and mechanistic studies that aim to determine topoisomerase structures with DNA bound in pre- and post-cleavage states and to understand the conformational changes associated with DNA binding and cleavage.     

Both ATPase sites of Escherichia coli UvrA have functional roles in nucleotide excision repair.

The roles of the two tandemly arranged putative ATP binding sites of Escherichia coli UvrA in UvrABC endonuclease-mediated excision repair were analyzed by site-directed mutagenesis and biochemical characterization of the representative mutant proteins. Evidence is presented that UvrA has two functional ATPase sites which coincide with the putative ATP binding motifs predicted from its amino acid sequence. The individual ATPase sites can independently hydrolyze ATP. The C-terminal ATPase site has a higher affinity for ATP than the N-terminal site. The invariable lysine residues at the ends of the glycine-rich loops of the consensus Walker type "A" motifs are indispensable for ATP hydrolysis. However, the mutations at these lysine residues do not significantly affect ATP binding. UvrA, with bound ATP, forms the most favored conformation for DNA binding. The initial binding of UvrA to DNA is chiefly at the undamaged sites. In contrast to the wild type UvrA, the ATPase site mutants bind equally to damaged and undamaged sites. Dissociation of tightly bound nucleoprotein complexes from the undamaged sites requires hydrolysis of ATP by the C-terminal ATPase site of UvrA. Thus, both ATP binding and hydrolysis are required for the damage recognition step enabling UvrA to discriminate between damaged and undamaged sites on DNA.     

Dissection of the nucleotide cycle of B. subtilis DNA gyrase and its modulation by DNA

DNA topoisomerases catalyze the inter-conversion of different topological forms of DNA. While all type II DNA topoisomerases relax supercoiled DNA, DNA gyrase is the only enyzme that introduces negative supercoils into DNA at the expense of ATP hydrolysis. We present here a biophysical characterization of the nucleotide cycle of DNA gyrase from Bacillus subtilis, both in the absence and presence of DNA. B. subtilis DNA gyrase is highly homologous to its well-studied Escherichia coli counterpart, but exhibits unique mechanistic features. The active heterotetramer of B. subtilis DNA gyrase is formed by mixing the GyrA and GyrB subunits. GyrB undergoes nucleotide-induced dimerization and is an ATP-operated clamp. The intrinsic ATPase activity of gyrase is stimulated tenfold in the presence of plasmid DNA. However, in contrast to the E. coli homolog, the rate-limiting step in the nucleotide cycle of B. subtilis GyrB is ATP hydrolysis, not product dissociation or an associated conformational change. Furthermore, there is no cooperativity between the two DNA and ATP binding sites in B. subtilis DNA gyrase. Nevertheless, the enzyme is as efficient in negative supercoiling as the E. coli DNA gyrase. Our results provide evidence that the evolutionary goal of efficient DNA supercoiling can be realized by similar architecture, but differences in the underlying mechanism. The basic mechanistic features are conserved among DNA gyrases, but the kinetics of individual steps can vary significantly even between closely related enzymes. This suggests that each topoisomerase represents a different solution to the complex reaction sequence in DNA supercoiling.     

A model for ATP hydrolysis-dependent binding of cohesin to DNA

BACKGROUND: Cohesion between sister chromatids is promoted by the chromosomal cohesin complex that forms a proteinaceous ring, large enough in principle to embrace two sister strands. The mechanism by which cohesin binds to DNA, and how sister chromatid cohesion is established, is unknown. RESULTS: Biochemical studies of cohesin have largely been limited to protein isolated from soluble cellular fractions. Here, we characterize cohesin purified from budding yeast chromatin, suggesting that chromosomal cohesin is sufficiently described by its known distinctive ring structure. We present evidence that the two Smc subunits of cohesin by themselves form a ring, closed at interacting ATPase head domains. A motif in the Smc1 subunit implicated in ATP hydrolysis is essential for loading cohesin onto DNA. In addition to functional ATPase heads, an intact cohesin ring structure is indispensable for DNA binding, suggesting that ATP hydrolysis may be coupled to DNA transport into the cohesin ring. DNA is released in anaphase when separase cleaves cohesin's Scc1 subunit. We show that a cleavage fragment of Scc1 disrupts the interaction between the two Smc heads, thereby opening the ring. CONCLUSIONS: We present a model for cohesin binding to chromatin by ATP hydrolysis-dependent transport of DNA into the cohesin ring. After DNA replication, two DNA strands may be trapped to promote sister chromatid cohesion. In anaphase, Scc1 cleavage opens the ring to release sister chromatids.     

Evidence for the role of DNA strand passage in the mechanism of action of microcin B17 on DNA gyrase

Microcin B17 (MccB17) is a DNA gyrase poison; in previous work, this bacterial toxin was found to slowly and incompletely inhibit the reactions of supercoiling and relaxation of DNA by gyrase and to stabilize the cleavage complex, depending on the presence of ATP and the DNA topology. We now show that the action of MccB17 on the gyrase ATPase reaction and cleavage complex formation requires a linear DNA fragment of more than 150 base pairs. MccB17 is unable to stimulate the ATPase reaction by stabilizing the weak interactions between short linear DNA fragments (70 base pairs or less) and gyrase, in contrast with the quinolone ciprofloxacin. However, MccB17 can affect the ATP-dependent relaxation of DNA by gyrase lacking its DNA-wrapping or ATPase domains. From these findings, we propose a mode of action of MccB17 requiring a DNA molecule long enough to allow the transport of a segment through the DNA gate of the enzyme. Furthermore, we suggest that MccB17 may trap a transient intermediate state of the gyrase reaction present only during DNA strand passage and enzyme turnover. The proteolytic signature of MccB17 from trypsin treatment of the full enzyme requires DNA and ATP and shows a protection of the C-terminal 47-kDa domain of gyrase, indicating the involvement of this domain in the toxin mode of action and consistent with its proposed role in the mechanism of DNA strand passage. We suggest that the binding site of MccB17 is in the C-terminal domain of GyrB.     

ATPase cycle and DNA unwinding kinetics of RecG helicase

The superfamily 2 bacterial helicase, RecG, is a monomeric enzyme with a role in DNA repair by reversing stalled replication forks. The helicase must act specifically and rapidly to prevent replication fork collapse. We have shown that RecG binds tightly and rapidly to four-strand oligonucleotide junctions, which mimic a stalled replication fork. The helicase unwinds such DNA junctions with a step-size of approximately four bases per ATP hydrolyzed. To gain an insight into this mechanism, we used fluorescent stopped-flow and quenched-flow to measure individual steps within the ATPase cycle of RecG, when bound to a DNA junction. The fluorescent ATP analogue, mantATP, was used throughout to determine the rate limiting steps, effects due to DNA and the main states in the cycle. Measurements, when possible, were also performed with unlabeled ATP to confirm the mechanism. The data show that the chemical step of hydrolysis is the rate limiting step in the cycle and that this step is greatly accelerated by bound DNA. The ADP release rate is similar to the cleavage rate, so that bound ATP and ADP would be the main states during the ATP cycle. Evidence is provided that the main structural rearrangements, which bring about DNA unwinding, are linked to these states.     

Hindering the strand passage reaction of human topoisomerase IIalpha without disturbing DNA cleavage, ATP hydrolysis, or the operation of the N-terminal clamp

DNA topoisomerase II is an essential enzyme that releases a topological strain in DNA by introduction of transient breaks in one DNA helix through which another helix is passed. While changing DNA topology, ATP is required to drive the enzyme through a series of conformational changes dependent on interdomain communication. We have characterized a human topoisomerase IIalpha enzyme with a two-amino acid insertion at position 351 in the transducer domain. The mutation specifically abolishes the DNA strand passage event of the enzyme, probably because of a sterical hindrance of T-segment transport. Thus, the enzyme fails to decatenate and relax DNA, even though it is fully capable of ATP hydrolysis, closure of the N-terminal clamp, and DNA cleavage. The cleavage activity is increased, suggesting that the transducer domain has a role in regulating DNA cleavage. Furthermore, the enzyme has retained a tendency to increase DNA cleavage upon nucleotide binding and also responds to DNA with elevated ATP hydrolysis. However, the DNA-mediated increase in ATP hydrolysis is lower than that obtained with the wild-type enzyme but similar to that of a cleavage-deficient topoisomerase IIalpha enzyme. Our results strongly suggest that the strand passage event is required for efficient DNA stimulation of topoisomerase II-mediated ATP hydrolysis, whereas the stimulation occurs independent of the DNA cleavage reaction per se. A comparison of the strand passage deficient-enzyme described here and the cleavage-deficient enzyme may have applications in other studies where a clear distinction between strand passage and topoisomerase II-mediated DNA cleavage is desirable.     

DNA cleavage by type III restriction-modification enzyme EcoP15I is independent of spacer distance between two head to head oriented recognition sites

The type III restriction-modification enzyme EcoP15I requires the interaction of two unmethylated, inversely oriented recognition sites 5'-CAGCAG in head to head configuration to allow an efficient DNA cleavage. It has been hypothesized that two convergent DNA-translocating enzyme-substrate complexes interact to form the active cleavage complex and that translocation is driven by ATP hydrolysis. Using a half-automated, fluorescence-based detection method, we investigated how the distance between two inversely oriented recognition sites affects DNA cleavage efficiency. We determined that EcoP15I cleaves DNA efficiently even for two adjacent head to head or tail to tail oriented target sites. Hence, DNA translocation appears not to be required for initiating DNA cleavage in these cases. Furthermore, we report here that EcoP15I is able to cleave single-site substrates. When we analyzed the interaction of EcoP15I with DNA substrates containing adjacent target sites in the presence of non-hydrolyzable ATP analogues, we found that cleavage depended on the hydrolysis of ATP. Moreover, we show that cleavage occurs at only one of the two possible cleavage positions of an interacting pair of target sequences. When EcoP15I bound to a DNA substrate containing one recognition site in the absence of ATP, we observed a 36 nucleotide DNaseI-footprint that is asymmetric on both strands. All of our footprinting experiments showed that the enzyme did not cover the region around the cleavage site. Analyzing a DNA fragment with two head to head oriented recognition sites, EcoP15I protected 27-33 nucleotides around the recognition sequence, including an additional region of 26 bp between both cleavage sites. For all DNA substrates examined, the presence of ATP caused altered footprinting patterns. We assume that the altered patterns are most likely due to a conformational change of the enzyme. Overall, our data further refine the tracking-collision model for type III restriction enzymes.     

Characterisation of the DNA-dependent ATPase activity of human DNA topoisomerase IIbeta: mutation of Ser165 in the ATPase domain reduces the ATPase activity and abolishes the in vivo complementation ability

We report for the first time an analysis of the ATPase activity of human DNA topoisomerase (topo) IIβ. We show that topo IIβ is a DNA-dependent ATPase that appears to fit Michaelis–Menten kinetics. The ATPase activity is stimulated 44-fold by DNA. The k_cat for ATP hydrolysis by human DNA topo IIβ in the presence of DNA is 2.25 s^–1. We have characterised a topo IIβ derivative which carries a mutation in the ATPase domain (S165R). S165R reduced the k_cat for ATP hydrolysis by 7-fold, to 0.32 s^–1, while not significantly altering the apparent K_m. The specificity constant for the interaction between ATP and topo IIβ (k_cat/K_mapp) showed a 90% reduction for βS165R. The DNA binding affinity and ATP-independent DNA cleavage activity of the enzyme are unaffected by this mutation. However, the strand passage activity is reduced by 80%, presumably due to reduced ATP hydrolysis. The mutant enzyme is unable to complement ts yeast topo II in vivo. We have used computer modelling to predict the arrangement of key residues at the ATPase active site of topo IIβ. Ser165 is predicted to lie very close to the bound nucleotide, and the S165R mutation could thus influence both ATP binding and ADP dissociation.     

Bound adenosine 5'-triphosphate formation, bound adenosine 5'-diphosphate and inorganic phosphate retention, and inorganic phosphate oxygen exchange by chloroplast adenosinetriphosphatase in the presence of Ca2+ or Mg2+

When the heat-activated chloroplast F1 ATPase hydrolyzes [3H, gamma-32P]ATP, followed by the removal of medium ATP, ADP, and Pi, the enzyme has labeled ATP, ADP, and Pi bound to it in about equal amounts. The total of the bound [3H]ADP and [3H]ATP approaches 1 mol/mol of enzyme. Over a 30-min period, most of the bound [32P]Pi falls off, and the bound [3H]ATP is converted to bound [3H]ADP. Enzyme with such remaining tightly bound ADP will form bound ATP from relatively high concentrations of medium Pi with either Mg2+ or Ca2+ present. The tightly bound ADP is thus at a site that retains a catalytic capacity for slow single-site ATP hydrolysis (or synthesis) and is likely the site that participates in cooperative rapid net ATP hydrolysis. During hydrolysis of 50 microM [3H]ATP in the presence of either Mg2+ or Ca2+, the enzyme has a steady-state level of about one bound [3H]ADP per mole of enzyme. Because bound [3H]ATP is also present, the [3H]ADP is regarded as being present on two cooperating catalytic sites. The formation and levels of bound ATP, ADP, and Pi show that reversal of bound ATP hydrolysis can occur with either Ca2+ or Mg2+ present. They do not reveal why no phosphate oxygen exchange accompanies cleavage of low ATP concentrations with Ca2+ in contrast to Mg2+ with the heat-activated enzyme. Phosphate oxygen exchange does occur with either Mg2+ or Ca2+ present when low ATP concentrations are hydrolyzed with the octyl glucoside activated ATPase. Ligand binding properties of Ca2+ at the catalytic site rather than lack of reversible cleavage of bound ATP may underlie lack of oxygen exchange under some conditions.     

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.     

The transducer domain is important for clamp operation in human DNA topoisomerase IIalpha

DNA topoisomerase II is a multidomain homodimeric enzyme that changes DNA topology by coupling ATP hydrolysis to the transport of one DNA helix through a transient double-stranded break in another. The process requires dramatic conformational changes including closure of an ATP-operated clamp, which is comprised of two N-terminal domains from each protomer. The most N-terminal domain contains the ATP-binding site and is directly involved in clamp closure, undergoing dimerization upon ATP binding. The second domain, the transducer domain, forms the walls of the N-terminal clamp and connects the clamp to the enzyme core. Although structurally conserved, it is unclear whether the transducer domain is involved in clamp mechanism. We have purified and characterized a human topoisomerase II alpha enzyme with a two-amino acid insertion at position 408 in the transducer domain. The enzyme retains both ATPase and DNA cleavage activities. However, the insertion, which is situated far from the N-terminal dimerization area, severely disrupts the function of the N-terminal clamp. The clamp-deficient enzyme is catalytically inactive and lacks most aspects of interdomain communication. Surprisingly, it seems to have retained the intersubunit communication, allowing it to bind ATP cooperatively in the presence of DNA. The results show that even distal parts of the transducer domain are important for the dynamics of the N-terminal clamp and furthermore indicate that stable clamp closure is not required for cooperative binding of ATP.     

Action of ATP-dependent DNase from Hemophilus influenzae on cross-linked DNA molecules.

The ATP-dependent DNase from Hemophilus influenzae digests double-stranded linear DNA molecules exonucleolytically while hydrolyzing large amounts of ATP to ADP. Various cross-linked linear duplex DNA molecules are partially resistant to the exonuclease action. Vaccinia DNA, containing natural terminal cross-links (probably in the form of terminal single-stranded loops), is much more slowly degraded than comparable "open-ended" DNA molecules, and ATP is consumed at a proportionately lower rate. It is postulated that the vaccinia DNA molecules undergo slow terminal cleavage by the single strand specific endonuclease activity of the enzyme, and are then rapidly degraded by the double strand exonuclease activity. Phage T7 DNA, containing an average of 100 4',5'8-trimethylpsoralen cross-links/molecule at random internal sites, is digested only to the extent of 2 to 3%. However, ATP hydrolysis continues at a linear rate long after DNA digestion has ceased. A stable enzyme-DNA complex is formed as demonstrated by co-sedimentation of DNA and ATPase activity in sucrose gradients. The hypothesis is advanced that the enzyme digests exonucleolytically to the first cross-link at each end of the DNA molecules where further movement is prevented. The enzyme then remains bound at the cross-links and functions continuously as an ATPase.     

A human topoisomerase II alpha heterodimer with only one ATP binding site can go through successive catalytic cycles

Eukaryotic DNA topoisomerase II is a dimeric nuclear enzyme essential for DNA metabolism and chromosome dynamics. It changes the topology of DNA by coupling binding and hydrolysis of two ATP molecules to the transport of one DNA duplex through a temporary break introduced in another. During this process the structurally and functionally complex enzyme passes through a cascade of conformational changes, which requires intra- and intersubunit communication. To study the importance of ATP binding and hydrolysis in relation to DNA strand transfer, we have purified and characterized a human topoisomerase II alpha heterodimer with only one ATP binding site. The heterodimer was able to relax supercoiled DNA, although less efficiently than the wild type enzyme. It furthermore possessed a functional N-terminal clamp and was sensitive to ICRF-187. This demonstrates that human topoisomerase II alpha can pass through all the conformations required for DNA strand passage and enzyme resetting with binding and hydrolysis of only one ATP. However, the heterodimer lacked the normal stimulatory effect of DNA on ATP binding and hydrolysis as well as the stimulatory effect of ATP on DNA cleavage. The results can be explained in a model, where efficient catalysis requires an extensive communication between the second ATP and the DNA segment to be cleaved.     

Characterization of the adenosinetriphosphatase activity of the Escherichia coli RecBCD enzyme: relationship of ATP hydrolysis to the unwinding of duplex DNA

We find that the rate of dsDNA-dependent ATPase activity is biphasic, with a fast component which represents the unwinding of the dsDNA and a slow component which results from the ssDNA-dependent ATPase activity of recBCD enzyme. Comparison of the ATPase and helicase activities permits evaluation of the efficiency of ATP hydrolysis during unwinding. This efficiency can be calculated from the maximum rates of ATPase and helicase activities and is found to range between 2.0 and 3.0 ATP molecules hydrolyzed per base pair of DNA unwound. The number of ATP molecules hydrolyzed per base pair unwound is not altered by temperature but does increase at low concentrations of DNA and high concentrations of sodium chloride and magnesium acetate. The apparent Km values for the DNA and ATP substrates of recBCD enzyme dsDNA-dependent ATPase activity at 25 degrees C were determined to be 0.13 nM DNA molecules and 85 microM ATP, respectively. The observed kcat value is approximately 45 microM ATP s-1 (microM recBCD enzyme)-1. If this rate is corrected for the measured stoichiometry of recBCD enzyme binding to dsDNA, the kcat for ATPase activity corresponds to an ATP hydrolysis rate of approximately 740 ATP molecules s-1 (functional recBCD complex)-1 at 25 degrees C.     

Interaction of homogeneous mitochondrial ATPase from rat liver with adenine nucleotides and inorganic phosphate

Mitochondrial ATPase from rat liver mitochondria contains multiple nucleotide binding sites. At low concentrations ADP binds with high affinity (1 mole/mole ATPase, K_D = 1–2 μM). At high concentrations, ADP inhibits ATP hydrolysis presumably by competing with ATP for the active site (K_I = 240–300 μM). As isolated, mitochondrial ATPase contains between 0.6 and 2.5 moles ATP/mole ATPase. This “tightly bound” ATP can be removed by repeated precipitations with ammonium sulfate without altering hydrolytic activity of the enzyme. However, the ATP-depleted enzyme must be redissolved in high concentrations of phosphate to retain activity. AMP-PNP (adenylyl imidodiphosphate) replaces tightly bound ATP removed from the enzyme and inhibits ATP hydrolysis. AMP-PNP has little effect on high affinity binding of ADP. Kinetic studies of ATP hydrolysis reveal hyperbolic velocity vs. ATP plots, provided assays are done in bicarbonate buffer or buffers containing high concentrations of phosphate. Taken together, these studies indicate that sites on the enzyme not directly associated with ATP hydrolysis bind ATP or ADP, and that in the absence of bound nucleotide, P_i can maintain the active form of the enzyme.     

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.     

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.     

A cellular single-stranded DNA-dependent ATPase associated with simian virus 40 chromatin

A single-stranded DNA-dependent ATPase from monkey kidney tissue culture cells (CV-1) has been found associated with SV40 chromatin. This ATPase activity is distinguishable from the ATPase activity of T-antigen by the following properties: the Km for ATP, elution from phosphocellulose, and stimulation of the ATPase activity by single-stranded DNA but not by double-stranded DNA. The ATPase has been isolated and characterized from the nuclei of uninfected cells. ATP hydrolysis is dependent on single-stranded DNA and a divalent cation. The km values for ATP and single-stranded DNA are 0.024 mM and 0.09 microgram/ml, respectively. The affinity of the ATPase for single-stranded DNA is sufficiently high that the enzyme co-sediments with single-stranded DNA in glycerol gradients. The binding of single-stranded DNA is independent of ATP and MgCl2; however, ATP hydrolysis increases the exchange of enzyme between different DNA molecules. Form I (superhelical) SV40 DNA is also a substrate for ATPase binding, but relaxed Form I, Form II (nicked circular), and double-stranded linear SV40 DNAs are not substrates. Because the DNA helix within chromatin is not under the same kind of tortional strain as Form I DNA, we hypothesize that the ATPase is bound to the single-stranded regions of replication forks in the SV40 chromatin.