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.     

Physical and topological properties of circular DNA

Several types of circular DNA molecules are now known. These are classified as single-stranded rings, covalently closed duplex rings, and weakly bonded duplex rings containing an interruption in one or both strands. Single rings are exemplified by the viral DNA from φX174 bacteriophage. Duplex rings appear to exist in a twisted configuration in neutral salt solutions at room temperature. Examples of such molecules are the DNA''s from the papova group of tumor viruses and certain intracellular forms of φX and λ-DNA. These DNA''s have several common properties which derive from the topological requirement that the winding number in such molecules is invariant. They sediment abnormally rapidly in alkaline (denaturing) solvents because of the topological barrier to unwinding. For the same basic reason these DNA''s are thermodynamically more stable than the strand separable DNA''s in thermal and alkaline melting experiments. The introduction of one single strand scission has a profound effect on the properties of closed circular duplex DNA''s. In neutral solutions a scission appears to generate a swivel in the complementary strand at a site in the helix opposite to the scission. The twists are then released and a slower sedimenting, weakly closed circular duplex is formed. Such circular duplexes exhibit normal melting behavior, and in alkali dissociate to form circular and linear single strands which sediment at different velocities. Weakly closed circular duplexes containing an interruption in each strand are formed by intramolecular cyclization of viral λ-DNA. A third kind of weakly closed circular duplex is formed by reannealing single strands derived from circularly permuted T2 DNA. These reconstituted duplexes again contain an interruption in each strand though not necessarily regularly spaced with respect to each other.     

Knotted single-stranded DNA rings: A novel topological isomer of circular single-stranded DNA formed by treatment with Escherichia coli ω protein

Treatment of single-stranded circular phage fd DNA with Escherichia coli ω protein yields a new species which sediments 1.2 to 1.5 times faster than the untreated DNA in an alkaline medium. The infectivity of this species in spheroplast assays, after purification of the DNA by zone sedimentation in an alkaline sucrose gradient, is only slightly lower than that of untreated fd DNA. The formation of this species requires Mg(II) and is strongly dependent on salt concentration and temperature. At 37 °C, over 85% of the input DNA can be converted to this form when incubation is carried out in media containing 0.15 to 0.25 m-salt. The yield decreases with increasing temperature or decreasing salt concentration. The increase in sedimentation coefficient of fd DNA in an alkaline medium following treatment with ω is not due to protein binding, as no change was observed upon treatment of the product with phenol or Pronase. Furthermore, neither the buoyant density of this new species in neutral CsCl nor its sedimentation coefficient in a neutral medium is significantly different from the corresponding properties of untreated fd DNA. Examination by electron microscopy shows that the new form has the appearance of a knotted ring of about the same contour length as an untreated monomeric single-stranded fd DNA. The new form can be converted to full-length linear fd DNA by treatment with pancreatic DNAase I. The rate of conversion is approximately the same as that of untreated circular fd DNA to the linear form. These results show that the new form of fd DNA is a novel topological isomer: a knotted single-stranded DNA ring. It is also found that further treatment of the knotted DNA rings with ω at low ionic strength can reverse the reaction, i.e. the knotted DNA rings can be converted back to simple DNA rings indistinguishable from fd DNA from the phage. At intermediate ionic strength the two forms are interconvertible and form an equilibrium mixture. Results similar to those obtained for fd DNA have also been observed for single-stranded circular φX174 DNA. A mechanism based on the known activity of ω protein on double-stranded DNA, the secondary structure of a single-stranded circular DNA, and the experimental results described here is proposed.     

Extracellular nucleases of Pseudomonas BAL 31. I. Characterization of single strand-specific deoxyriboendonuclease and double-strand deoxyriboexonuclease activities.

The culture medium of Pseudomonas BAL 31 contains endonuclease activities which are highly specific for single-stranged DNA and for the single-stranded or weakly hydrogen-bonded regions in supercoiled closed circular DNA. Exposure of nicked DNA to the culture medium results in cleavage of the strang opposite the sites of preexisting single-strand scissions. At least some of the linear duplex molecules derived by cleavage of supercoiled closed circular molecules contain short single-stranded ends. Single-strand scissions are not introduced into intact, linear duplex DNA or unsupercoiled covalently closed circular DNA. Under these same reaction conditions, 0X174 phage DNA is extensively degraded and PM2 form I DNA is quantitatively converted to PM2 form III linear duplexes. Prolonged exposure of this linear duplex DNA to the concentrated culture medium reveals the presence of a double-strand exonuclease activity that progressively reduces the average length of the linear duplex. These nuclease activities persist at ionic strengths up to 4 M and are not eliminated in the presence of 5% sodium dodecyl sulfate. Calcium and magnesium ion are both required for optimal activity. Although the absence of magnesium ion reduces the activities, the absence of calcium ion irreversibly eliminates all the activities.     

Presynapsis and synapsis of DNA promoted by the STP alpha and single-stranded DNA-binding proteins from Saccharomyces cerevisiae

We previously purified an activity from meiotic cell extracts of Saccharomyces cerevisiae that promotes the transfer of a strand from a duplex linear DNA molecule to complementary circular single-stranded DNA, naming it Strand Transfer Protein alpha (STP alpha) (Sugino, A., Nitiss, J., and Resnick, M. A. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3683-3687). This activity requires no nucleotide cofactor but is stimulated more than 10-fold by the addition of yeast single-stranded DNA-binding proteins (ySSBs). In this paper, we describe the aggregation and strand transfer of double-stranded and single-stranded DNA promoted by STP alpha and ySSB. There is a good correlation between the aggregation induced by various DNA-binding proteins (ySSBs, DBPs and histone proteins) and the stimulation of STP alpha-mediated DNA strand transfer. This implies that the stimulation by ySSBs and other binding proteins is probably due to the condensation of single-stranded and double-stranded DNA substrates into coaggregates. Within these coaggregates there is a higher probability of pairing between homologous double-stranded and single-stranded DNA, favoring the initiation of strand transfer. The aggregation reaction is rapid and precedes any reactions related to DNA strand transfer. We propose that condensation into coaggregates is a presynaptic step in DNA strand transfer promoted by STP alpha and that pairing between homologous double- and single-stranded DNA (synapsis) occurs in these coaggregates. Synapsis promoted by STP alpha and ySSBs also occurs between covalently closed double-stranded DNA and single-stranded linear DNA as well as linear double-stranded and linear single-stranded DNAs in the absence of any nucleotide cofactors.     

Interlocked DNA rings. II. Physicochemical studies

Several species of topologically interlocked λb2b5c DNA rings (catenanes) have been prepared in vitro. The sedimentation behavior of dimeric catenanes containing 0, 1, or 2 covalently closed duplex rings has been studied as a function of the superhelical density of the covalently closed ring or rings. In general, if XtpY represents rings X and Y topologically interlocked, the sedimentation coefficient of this species, ^SXtpY, is related to the sedimentation coefficients ^SX and ^SY of the component rings by the empirical relationship ^SXtpY/^SY = [(M_X + M_Y)/M_Y] [1 + (M_X/M_Y)^1.78(^SY/^SX)^1.78]^?0.56 This equation can also be extended to the case where three monomeric rings are topologically linked in a chain. For two topologically interlocked monomeric rings with neither ring covalently closed, the sedimentation coefficient is 1.35 times that of the monomeric ring. This is different from results reported for mitochondrial and P22 catenanes by others. Several possibilities are discussed to account for this discrepancy. The sedimentation coefficient of a species containing one covalently closed duplex ring and a single-stranded ring was also measured in an alkaline medium. This species, which can be easily derived from a dimeric catenane containing two covalently closed duplex rings, is particularly useful for the identification of covalently closed dimeric catenanes. Some electron microscopic studies of these interlocked rings are presented in an accompanying paper.     

On the degree of unwinding of the DNA helix by ethidium. II. Studies by electron microscopy.

When a negatively twisted covalently closed DNA is annealed with single-stranded fragments of the same DNA, under proper conditions a loop (or loops) may form by the disruption of a segment (or segments) of base pairs between the complementary strands of the covalently closed DNA, and the formation of base pairs between the strands of the covalently closed DNA and the single-stranded fragments. Since such a process involves essentially no net gain or loss of the number of base pairs, it is driven by the free energy favoring the reduction of the number of superhelical turns. If the fragments are sufficiently long or are present at a sufficiently hig concentration during annealing, the most stable product between a covalently closed DNA and the DNA fragments (under conditions favoring the formation of double-stranded DNA) is a looped molecule devoid of superhelical turns. The size of the looped region or regions, which can be measured by electron microscopy, provides a way to determine the degree of superhelicity of the covalently closed DNA in the absence of the fragments. When this is compared with the degree of superhelicity of the covalently closed DNA determined by titration with the intercalative dye ethidium, the unwinding angle of the DNA double helix due to the intercalation of an ethidium can be calculated. Such measurements were done on two samples of phage PM2 DNA with different extents of supercoiling. The results are in agreement with the value 26 degree obtained recently by alkaline titration of covalently closed PM2 DNA samples in CsC1 density gradients (Wange, J.C., (1974) J. Mol. Biol. 89, 783-801).     

On the mechanism of pairing of single- and double-stranded DNA molecules by the recA and single-stranded DNA-binding proteins of Escherichia coli

The pairing of single- and double-stranded DNA molecules at homologous sequences promoted by recA and single-stranded DNA-binding proteins of Escherichia coli follows apparent first-order kinetics. The initial rate and first-order rate constant for the reaction are maximal at approximately 1 recA protein/3 and 1 single-stranded DNA-binding protein/8 nucleotides of single-stranded DNA. The initial rate increases with the concentration of duplex DNA; however, the rate constant is independent of duplex DNA concentration. Both the rate constant and extent of reaction increase linearly with increasing length of duplex DNA over the range 366 to 8623 base pairs. In contrast, the rate constant is independent of the size of the circular single-stranded DNA between 6,400 and 10,100 nucleotides. No significant effect on reaction rate is observed when a single-stranded DNA is paired with 477 base pairs of homologous duplex DNA joined to increasing lengths of heterologous DNA (627-2,367 base pairs). Similarly, heterologous T7 DNA has no effect on the rate of pairing. These findings support a mechanism in which a recA protein-single-stranded DNA complex interacts with the duplex DNA to produce an intermediate in which the two DNA molecules are aligned at homologous sequences. Conversion of the intermediate to a paranemic joint then occurs in a rate-determining unimolecular process.     

Interaction between DNA and an Escherichia coli protein omega

An E. coli protein, designated ω, has been purified at least 1000-fold. Treatment of a eovalently closed DNA duplex containing negative superhelical turns with ω results in the loss of most of the superhelical turns. The loss of superhelical turns follows a gradual course rather than a one-hit mechanism. This reaction does not require a cofactor. No other change in the physical properties of the DNA could be detected. The DNA remains covalently closed. Its ultraviolet absorption spectrum, circular dichroism, buoyant density in CsCl, sedimentation properties in neutral media containing varying amounts of ethidium and in an alkaline medium, and its susceptibility toward Neurospora endonuclease, are not significantly different from an untreated DNA containing the same number of superhelical turns. Thus it appears that ω is capable of introducing a “swivel” reversibly into a DNA. A plausible mechanism is postulated.     

Structure of reaction intermediates formed during Saccharomyces cerevisiae Rad51-catalyzed strand transfer

The process by which the Saccharomyces cerevisiae strand transfer protein, Rad51, seeks out homologous sequences in vivo can be modeled by an in vitro reaction between a single-stranded DNA circle and a double-stranded linear DNA. In addition to the substrates and products, electrophoresis of reaction mixtures resolves two groups of low mobility bands. Here we show that the low mobility bands formed during strand transfer by Rad51 (or Escherichia coli RecA) represent joint molecules (JM) between the two substrates. One group, which we name JM1, is an obligatory reaction intermediate in which the complementary strand from the duplex substrate has been partially transferred to the single-stranded circle. Our assignment is based on pulse-chase and restriction enzyme digestion experiments and verified by electron microscopy. The slower moving group of bands, designated JM2, is formed by an unexpected reaction between JM1 and a second double-stranded linear substrate. Strand transfer of the second duplex initiates noncanonically from the end where the complementary strand is recessed. Thus JM2 is formed by two strand transfer reactions with the same single-stranded circular substrate but with opposite polarities. Finally, we show that the multiple sharp bands in JM1 and JM2 are the result of substrate sequences that pause strand transfer.     

A spectrophotometric method to quantify linear DNA

A spectrophotometric method for quantification of linear DNA is described. The assay measures ADP produced following digestion of linear DNA by an ATP-dependent deoxyribonuclease. Cleavage of the phosphodiester bond of the DNA substrate is proportional to ADP formed in the reaction which follows typical Michaelis-Menten kinetics (K(m) of 0.6 microM, and a V(max) of 30 nmol/min/mg). The enzyme requires Mg(2+)-ATP and Mg(2+)-DNA as substrates, although the results suggest a requirement for yet another metal ion which may be enzyme bound. Both single-stranded and double-stranded linear DNA are substrates, as demonstrated by comparable initial velocity measurements. However, covalently closed circular (CCC) and nicked open circular DNA are not substrates for the enzyme. The rate of hydrolysis of ATP is not inhibited by 1 microg RNA or covalently closed circular DNA. The product (ADP) formed in the reaction is coupled to NADH oxidation using pyruvate kinase and lactate dehydrogenase. NAD formed in the reaction is monitored spectrophotometrically as a loss in absorbance at 340 nm. This assay directly measures the amount of linear DNA present in preparations of supercoiled (CCC) plasmid DNA, and has direct utility for monitoring the quality of plasmid preparations for gene therapy.     

Isolation and structural characterization of monomeric and dimeric forms of replicative intermediates of Kilham rat virus DNA.

Two virus-specific species of newly synthesized DNA were isolated from rat fibroblast cell cultures infected with the Kilham rat virus (RV). These two DNA species were purified; their behavior on hydroxyapatite chromatography and their sedimentation coefficients in sucrose gradients were determined. One of the two species corresponds to the linear double-stranded form of the RV DNA, and the other corresponds to the dimeric duplex form. After denaturation, a fraction of both species showed an intramolecular renaturation; these molecules are composed of viral strand covalently linked to complementary strand. Models for the structure of both species are posposed. Both species may be considered as double-strand replicative intermediates of the single-stranded RV DNA.     

Topological testing of the mechanism of homology search promoted by RecA protein

To initiate homologous recombination, sequence similarity between two DNA molecules must be searched for and homology recognized. How the search for and recognition of homology occurs remains unproven. We have examined the influences of DNA topology and the polarity of RecA–single-stranded (ss)DNA filaments on the formation of synaptic complexes promoted by RecA. Using two complementary methods and various ssDNA and duplex DNA molecules as substrates, we demonstrate that topological constraints on a small circular RecA–ssDNA filament prevent it from interwinding with its duplex DNA target at the homologous region. We were unable to detect homologous pairing between a circular RecA–ssDNA filament and its relaxed or supercoiled circular duplex DNA targets. However, the formation of synaptic complexes between an invading linear RecA–ssDNA filament and covalently closed circular duplex DNAs is promoted by supercoiling of the duplex DNA. The results imply that a triplex structure formed by non-Watson–Crick hydrogen bonding is unlikely to be an intermediate in homology searching promoted by RecA. Rather, a model in which RecA-mediated homology searching requires unwinding of the duplex DNA coupled with local strand exchange is the likely mechanism. Furthermore, we show that polarity of the invading RecA–ssDNA does not affect its ability to pair and interwind with its circular target duplex DNA.     

Absorption and fluorescence studies of the binding of the recA gene product from E. coli to single-stranded and double-stranded DNA. Ionic strength dependence

The binding of the recA gene product from E. coli to double-stranded and single-stranded nucleic acids has been investigated by following the change in melting temperature of duplex DNA and the fluorescence of single-stranded DNA or poly(dA) modified by reaction with chloroacetaldehyde. At low ionic strength, in the absence of Mg2+ ions, RecA protein binds preferentially to duplex DNA or poly(dA-dT). This leads to an increase of the DNA melting temperature. Stabilization of duplex DNA decreases when ionic strength or pH increases. In the presence of Mg2+ ions, preferential binding to single-stranded polynucleotides is observed. Precipitation occurs when duplex DNA begins to melt in the presence of RecA protein. From competition experiments, different single-stranded and double-stranded polydeoxynucleotides can be ranked according to their ability to bind RecA protein. Structural changes induced in nucleic acids upon RecA binding are discussed together with conformational changes induced in RecA protein upon magnesium binding.     

Characterization of mycoplasmavirus MVL2 DNA.

The size and molecular configuration of mycoplasmavirus MVL2 DNA are presented. The DNA was shown to be a covalently closed circular duplex molecule with a molecular weight of 7.4 X 10(6). In sucrose gradients at neutral pH, the form I and form II DNA molecules have sedimentation values of approximately 29S and 23S, respectively. Under alkaline conditions, the form I and form II have S values of 70 and 20, respectively.     

Plasmid transformation in Bacillus subtilis: Fate of plasmid DNA

Summary Only multimeric, and not monomeric forms of B. subtilis plasmids can transform B. subtilis cells (Canosi et al. 1978). This finding prompted us to study the physico-chemical fate of plasmid DNA in transformation. Competent cells of B. subtilis were exposed to either unfractionated preparations or to preparations of multimeric plasmid DNA. Plasmid DNA was re-extracted from such cells and then analyzed by sedimentation and isopycnic centrifugation and also defined by its sensitivity to nuclease S1 degradation. No double-stranded plasmid DNA could be recovered from cells transformed with unfractionated plasmid preparations which contained predominantly monomeric covalently closed circular (CCC) DNA, Re-extracted plasmid DNA was single-stranded, had a molecular weight considerably smaller than monomer length DNA and had been subject to degradation to acid soluble products. However, when transformations were performed with multimeric DNA (constructed by in vitro ligation of linearized pC194 DNA), both double-stranded and partially double-stranded DNA could be recovered in addition to single-stranded DNA.We assume that plasmid DNA is converted to a single-stranded form in transformation, irrespective of its molecular structure. Double-stranded and partially double-stranded DNAs found in transformation with multimeric DNA would be the products of intramolecular annealing.Some of these results were presented at the 5th European Meeting on Bacterial Transformation and Transfection, September 1980, Florence     

F deoxyribonucleic acid superinfected into phenocopies of donor strains.

When F+ donor cells of Escherichia coli are conjugated with F-, F+, or Hfr recipients under the conditions of phenocopy mating, the male recipients are found capable of accepting the F episome as effectively as the F- recipients. The F deoxyribonucleic acid (DNA) superinfected into the male recipients is converted to the covalently closed, circular duplex form, as in the F- recipients. It is also found that the synthesis of the strand complementary to the transferred single strand and its subsequent conversion to the covalently closed, circular duplex occur effectively in male recipients as well as in female recipients. Under these mating conditions, F-ilv+ episome superinfected to F+ and Hfr cells is diluted out during growth, whereas F-ilv+ transferred into F-cells is replicated and established in almost all progeny cells. These results suggest that the incompatibility of the F episome is not due to the reduction in the rate of the conversion of transferred single-straned F DNA to covalently closed, circular duplex, but, rather, to an inhibition of further replication of the covalently closed, circular F DNA.     

Strandedness and Complementarity of DNA from Long-Term RNA-Dependent DNA Polymerase Reactions of Soehner-Dmochowski Murine Sarcoma Virus

The DNA product of the endogenously instructed RNA-dependent DNA polymerase reaction of murine sarcoma virus continued to be synthesized for as long as 64 h in the presence of 0.008% Triton X-100. Higher detergent concentrations and actinomycin D inhibited DNA product synthesis. The DNA product from long-term polymerase reactions consisted of small DNA fragments as shown by sedimentation in alkaline sucrose gradients. The enzymatic DNA product was separated into a slow sedimenting fraction and a fast sedimenting fraction by rate-zonal centrifugation. Fast sedimenting DNA was the predominant fraction made in viral polymerase reactions containing 262 mM NaCl. By using a combination of S-1 nuclease and pancreatic RNase A, the amount of single-stranded DNA, double-stranded DNA, and DNA-RNA hybrid present in the slow-sedimenting and fast-sedimenting fractions was determined. Under standard polymerase conditions of 70 mM NaCl, single-stranded DNA was the major form of DNA found in both fractions. In contrast, the prevalent form of DNA made in the presence of 262 mM NaCl was DNA-RNA hybrid. Hybridization studies in which either S-1 nuclease or pancreatic RNase A was used to measure hybrid formation demonstrated not only that the DNA product was complementary in base sequence to the RNA genome, but also that at least 79 to 84% of the RNA genome was transcribed into complementary DNA.     

DNA-DNA gyrase complex: the wrapping of the DNA duplex outside the enzyme.

Digestion of the complex between double-stranded DNA and M. luteus or E. coli DNA gyrase with staphylococcal nuclease gives a 143 ± 3 base pair DNA fragment containing no single-chain scissions. Digestion of the same complex with bovine pancreatic DNAase I gives six discernible single-stranded DNA bands upon electrophoresis of the product in a denaturing gel. The lengths of these fragments, in number of nucleotides, are measured to be 47 ± 1, 57 ± 1, 67 ± 1, 77 ± 1, 86 ± 1 and 96 ± 1, respectively. These results support the notion that in the DNA-gyrase complex, a segment(s) of the DNA helix is wrapped around the enzyme. The wrapping of the DNA around the enzyme has been proposed previously based on the observation that in the absence of ATP, the linking number of a duplex DNA ring covalently closed by ligase in the presence of bound gyrase is higher than in the absence of gyrase (Liu and Wang, 1978). The coiling of DNA around the enzyme in the complex is believed to be intimately related to the ATP-dependent negative supercoiling of covalently closed duplex DNA ring by DNA gyrase. It has also been observed that digestion of pure double-stranded DNA by pancreatic DNAase I in the presence of calcium phosphate precipitate or solid hydroxylapatite gives a ladder of single-stranded DNA fragments of integral multiples of 10 nucleotides. This finding suggests that such a pancreatic DNAase I cleavage pattern is indicative of a DNA duplex lying on the outside of a surface.     

Structure of replicating DNA molecules of Bacillus subtilis bacteriophage phi 29.

We isolated phi 29 DNA replicative intermediates from extracts of phage-infected Bacillus subtilis, pulsed-labeled with [3H]thymidine, by velocity sedimentation in neutral sucrose followed by CsCl equilibrium density gradient centrifugation. During a chase, the DNA with a higher sedimentation coefficient in neutral sucrose and a lower sedimentation rate in alkaline sucrose than that of viral phi 29 DNA was converted into mature DNA. The material with a density higher than that of mature phi 29 DNA consisted of replicative intermediates, as analyzed with an electron microscope. We found two major types of molecules. One consisted of unit-length duplex DNA with one single-stranded branch at a random position. The length of the single-stranded branches was similar to that of one of the double-stranded regions. The other type of molecules was unit-length DNA with one double-stranded region and one single-stranded region extending a variable distance from one end. Partial denaturation of the latter molecules showed that replication was initiated with a similar frequency from either DNA end. These findings suggest that phi 29 DNA replication occurs by a mechanism of strand displacement and that replication starts non-simultaneously from either DNA end, as in the case of adenovirus.