Modulation of the relaxing activity of Escherichia coli topoisomerase I by single-stranded DNA binding proteins

Removal of negative superhelical turns in ColE1 plasmid DNA by Escherichia coli topoisomerase I was markedly enhanced by the presence of single-stranded DNA binding protein from E. coli. A lack of species specificity makes unlikely the possibility of physical association between topoisomerase I and single-stranded DNA binding proteins. Stabilization of single-stranded regions in supercoiled DNA by single-stranded DNA binding protein would appear to be the basis of the enhancement of topoisomerase activity.     

Induction of DNA replication-mediated double strand breaks by psoralen DNA interstrand cross-links

The effect of DNA interstrand cross-links (cross-links) on DNA replication was examined with a cell-free SV40 origin-dependent DNA replication system. A defined template DNA with a single psoralen cross-link and the SV40 origin of replication was replicated by HeLa cell-free extract in the presence of SV40 large T antigen. The psoralen cross-link inhibited DNA replication by terminating chain elongation at 1-50 nucleotides before the cross-linked sites. The termination of DNA replication by the cross-links mediated the generation of double strand breaks near the cross-linked sites. These results are the first biochemical evidence of the generation of double strand breaks by DNA replication.     

Uptake of homologous single-stranded fragments by superhelical DNA: II. Characterization of the reaction

We have studied the association of superhelical DNA (RFI)³ of phage G4 with defined single-stranded fragments isolated after cleavage of viral (+) strands by endonuclease R · HaeIII. The sedimentation rates of complexes formed by uptake of different single-stranded restriction fragments by G4 RFI were consistent with the view that base-pairing between the two components causes unwinding of superhelical turns, with one negative superhelical turn removed for every ten nucleotide residues of third strand taken up. The combining ratio of superhelical DNA and a single specific fragment was close to unity.At high concentrations of salt, nitrocellulose filters efficiently retained complexes of superhelical DNA and homologous fragments, which provided the basis for a rapid assay, and permitted the estimation of the thermodynamic and kinetic parameters of strand uptake in vitro. The reaction is reversible, with an apparent K_eq of approximately 10⁶m^?1. Apparent rate constants, k₁, for uptake of different fragments (85 to 1100 nucleotides long) varied about fourfold, with no obvious relationship to the length of the fragment. In 10 mm-Tris · HCl (pH 7.5), 200 mm-NaCl, fragments were taken up most rapidly at about 75 °C. Under these conditions, the apparent k₁ for a fragment 250 nucleotides long was approximately 600 m^?1s^?1, which is two or three orders of magnitude slower than the calculated rate of association of complementary strands of that length. At physiological temperatures, appreciable rates of strand uptake were seen only at low concentrations of salt (4 mm-Na⁺ in 10 mm-Tris · HCl), and were one or two orders of magnitude less than the rate at 75 °C in 200 mm-NaCl. At a given concentration of counterion a threshold temperature exists above which the rate of reaction rises sharply from an undetectable level.Thermodynamic calculations indicate that the reaction is entropically driven, and that the rate is limited by a step exhibiting a positive entropy and enthalpy of activation. The data are consistent with a model for strand uptake in which the rate-limiting step is the unstacking of a small number of base-pairs in the superhelical DNA. Stabilization and extension of the nucleus of base-pairs formed with the incoming strand is favored by the decrease in free energy associated with removal of superhelical turns.     

Alkali lability and rapid initiation of excision repair following photoaffinity damage by ethidium azide

DNA damage and repair provoked by ethidium azide (EA) photoaffinity labeling in mouse leukemia cells was studied by measuring sedimentation properties of nucleoids in neutral sucrose gradients, and it was found that the strand opening step was faster than that which followed damage of cells by ultraviolet (UV) light. The two insults were compared at levels of damage which gave the same overall rates of repair synthesis in intact cells and which required the same length of time to complete repair, as judged by the restoration of supercoiling of the isolated nucleoids. In the case of UV, single-strand breaks in DNA were detectable at 30 min, maximum at 2 h, and the superhelical properties restored at 21 h. With photoaffinity labeling, single-strand breaks were prominent immediately, even when photolabeling of cells was done on ice, but restoration of DNA supercoiling still required 21 h. Photolabeling of isolated nucleoids or isolated viral DNA with EA failed to introduce DNA strand breaks. However, it was discovered that photoaffinity labeling of DNA with EA resulted in alkali labile sites shown by single strand breaks produced on alkaline sucrose sedimentation or by alkali exposure followed by sedimentation on neutral formamide gradients. These results suggest that the drug attachment sites should be identifiable by the location of such single strand breaks.     

Strand scission of superhelical and linear duplex DNAs by the antitumor protein macromomycin. Relationship of in vitro DNA damage to cell growth inhibition.

Macromomycin, a protein antitumor drug, was found to cause strand scissions in vitro in superhelical PM2 and SV40 DNA as well as linear duplex lambda DNA. DNA damage appeared to be single rather than double-strand scissions, and there is an indication that DNA breaks occur at some preferential base sites. The DNA breaks were predominantly true single-strand scissions as opposed to alkali-labile bonds. The cutting reaction was inhibited by low temperature (0 degrees C) and reached a maximum at 45 degrees C. The reaction was not affected by 2-mercaptoethanol, although EDTA did cause a slight decrease in the reaction rate. MgCl2 was found to be an effective inhibitor of the strand scission activity of the drug. The rate of DNA cutting was linear over a wide range of DNA substrate levels. There appeared to be a correlation between the drug's ability to damage DNA and to inhibit cell growth in that similar losses of these two activities occurred as the drug was thermally denatured.     

Characterization of intracellular DNA strand breaks induced by neocarzinostatin in Escherichia coli cells.

DNA strand breaks induced by Neocarzinostatin in Escherichia coli cells have been characterized. Radioactively labeled phage lambda DNA was introduced into lysogenic host bacteria allowing the phage DNA to circularize into superhelical molecules. After drug treatment DNA single- and double-strand breaks were measured independently after neutral sucrose gradient sedimentation. The presence of alkali-labile lesions was measured in parallel in alkaline sucrose gradients. The cell envelope provided an efficient protection towards the drug, since no strand breaks were detected unless the cells were made permeable with toluene or with hypotonic Tris buffer. In permeable cells, no double strand breaks could be detected, even at high NCS concentration (100 micrograms/ml). Induction of single-strand breaks leveled off after 15 min at 20 degrees C in the presence of 2 mM mercaptoethanol. Exposure to 0.3N NaOH doubled the number of strand breaks. No enzymatic repair of the breaks could be observed.     

Formation of cruciform structures in pAO3 plasmid DNA on increasing superhelical density

The dependence of the crusiciform structure formation on superhelical density was studied by means of high resolution gel-electrophoresis. A short pAO3 DNA plasmid (1683 b. p.) which is a quarter of the ColE1 DNA plasmid and contains the main palindrome of ColE1 DNA was used. The excellent resolution of all topoisomers of pAO3 DNA in gel-electrophoresis made it possible to observe a sharp abruption in the pattern of pAO3 DNA topoisomers separation. The two-dimensional gel-electrophoresis data showed that observed abruption is caused by a sharp decrease of writhing in the molecules with superhelical density--sigma approximately equal to 0,05. An analysis of S1-nuclease digestion products of DNA with different superhelical density was accomplished and these data showed that a sharp structural transition in supercoiled DNA pAO3 is caused by formation of a cruciform structure in the main palindrome.     

Specificity of the S1 nuclease from Aspergillus oryzae.

Conditions are described for digesting single-stranded DNA by S1 nuclease without introducing breaks in double-stranded DNA. The enzyme is inhibited by low concentrations of various compounds of phosphate. Under certain conditions S1 nuclease cleaves the strand opposite a nick in bacteriophage T5 DNA; under other conditions, the enzyme cleaves a loop in one strand of heteroduplex lambdaDNA while leaving the opposite strand intact. S1 nuclease makes many single strand breaks in ultraviolet-irradiated duplex lambdaDNA. Superhelical DNA of phiX174 (Form I) is converted first to a relaxed circular molecule (Form II), and then to a linear molecule (Form III) by cleavage at one site per molecule. Since the cleavage occurs at many sites in the population of molecules, the partially single-stranded regions in phiX174 superhelical DNA are not determined by specific nucleotide sequences.     

Effect of 2-chloroethylnitrosoureas on plasmid DNA including formation of strand breaks and interstrand cross-links

Plasmid [3H]pBR 322 was incubated with various alkylating agents including chlorozotocin, N,N'-bis(2-chloroethyl)-N'-nitrosourea (BCNU), N-ethyl-N-nitrosourea (Enu) and dimethylsulfate (DMS). Formation of DNA strand breaks was followed by separation of the various forms of DNA on agarose gels and liquid scintillation counting of the bands. All alkylating agents examined were capable of rapidly producing strand breaks in time and concentration dependent fashion. Bands migrating as relaxed circular and supercoiled forms of the plasmid disappeared, and extensive alkylation resulted in formation of a band that migrated faster than the linear form of DNA. Electron microscopy of this band showed that it consisted of relaxed circles. Prolonged storage of alkylated plasmid resulted in fragmentation of the DNA, possibly due to strand scission at apurinic sites. A new neutral denaturation technique was developed, which allowed for the detection of DNA interstrand cross-links with minimal effects on other potentially labile sites of the alkylated DNA. The level of alkylation was quantitated by incubating [3H]pBR 322 with [2-chloroethyl-U-14C]chlorozotocin and was shown to be independent of DNA concentration but have a linear relationship with drug concentration. Linear and relaxed circular forms of the plasmid were alkylated to a somewhat higher extent than supercoiled DNA. Alkylation of pBR 322 with defined superhelical densities showed no preferential loss in DNA with a specific superhelical density, indicating that alkylation-induced unwinding is independent of superhelicity under the experimental conditions used.     

The use of Haemophilus gallinarum DNA-relaxing enzyme to investigate the relationship between the number of superhelical turns and the molecular weight in a negatively twisted DNA.

Covalently closed-circular, superhelical DNAs, including viral DNAs, bacterial plasmid DNAs, and bacteriophage replicative-form DNA, were treated with a small amount of Haemophilus gallinarum DNA-relaxing enzyme to generate incompletely relaxed DNA molecules. Each sample consisted of a set of closed-circular DNA molecules differing by one turn in their number of superhelical turns. The DNA samples were analyzed by agarose gel electrophoresis under conditions such that the electrophoretic mobility was a function of the number of turns. The numbers of superhelical turns (at 37 degrees C in 20 mM Tris-HCl (pH 7.5)-5 mM MgCl2) in the DNAs of pSC101 (5.8 megadaltons), Colicin E1 (4.2 megadaltons), pMR4 (4.0 megadaltons; recombinant between pBR322 and lambda DNA fragment), phi X174 replicative-form (RF) I, Simian virus 40 (SV40), and polyoma virus (3.4--3.6 megadaltons each), and lambda dv021 (2.05 megadaltons) were estimated to be 36, 27, 23--24, 20--21, 20--21, 20--21, and 11--13, respectively. It appears that the number of superhelical turns is mainly a function of the molecular weight of the DNA, at least in the substrates tested here.     

Rifampicin-resistant initiation of DNA synthesis on the isolated strands of ColE plasmid DNA.

The opposite strands of the ColE1 and ColE3 plasmids were isolated as circular single-stranded DNA molecules. These molecules were compared with M13 and phi X174 viral DNA with respect to their capacity to function as templates for in vitro DNA synthesis by a replication enzyme fraction from Escherichia coli. It was found for both ColE plasmids that the conversion of H as well as L strands to duplex DNA molecules closely resembles phi X174 complementary strand synthesis and occurs by a rifampicin-resistant priming mechanism involving the dnaB, dnaC, and dnaG gene products. Restriction analysis of partially double-stranded intermediates indicates that preferred start sites for DNA synthesis are present on both strands of the ColE1 HaeII-C fragment. Inspection of the nucleotide sequence of this region reveals structural similarities with the origin of phi X174 complementary strand synthesis. We propose that the rifampicin-resistant initiation site (rri) in the ColE1 L strand is required for the priming of discontinuous lagging strand synthesis during vegetative replication and that the rri site in the H strand is involved in the initiation of L strand synthesis during conjugative transfer.     

The phosphoform of the regulatory subunit RII of cyclic AMP-dependent protein kinase possesses intrinsic topoisomerase activity

The phosphoform of the type II regulatory subunit (phospho-RII-cAMP) of cAMP-dependent protein kinase from rat liver was found to possess intrinsic topoisomerase activity towards several DNA substrates such as phi X174, pBR322, SV40, and M13. Like the type I topoisomerases from several eukaryotic cells, phospho-RII X cAMP can relax both positive and negative superhelical turns of phi X174 DNA. Topological isomers with a decreasing number of superhelical turns can be identified as transient products. Conditions under which phospho-RII X cAMP relaxes superhelical phi X174 DNA lead to transient formation of a DNA-phospho-RII X cAMP complex via DNA strand breakage and covalent attachment of the DNA to a tyrosine residue of phospho-RII X cAMP via a phospho-RII X cAMP depends on the presence of cAMP and is altered by changes in the degree of phosphorylation of RII. Both dephosphorylation and removal of cAMP from phospho-RII X cAMP abolish its topoisomerase activity.     

Torsional tension in the DNA double helix measured with trimethylpsoralen in living E. coli cells: analogous measurements in insect and human cells

The rate of covalent photobinding of trimethylpsoralen to DNA is greater when the DNA is wound with negative superhelical tension than when it is relaxed. In vitro the rate of photobinding is directly proportional to the negative superhelical density of the DNA. Thus measurement of the rate of photobinding provides an assay for probing in vivo unrestrained tension in the winding of the DNA double helix. This approach has been applied to measure torsional tension in DNA as it is packaged in living E. coli. Drosophila and HeLa cells. A method is described for measuring the rate of photobinding to intracellular DNA and rRNA, and for using the latter measurement as an internal control of the rate of me3-psoralen photobinding in vivo. This permits more accurate and reproducible measurement of changes in the DNA-psoralen photobinding reaction. The me3-psoralen probe interacts with intracellular bacterial DNA as expected for a purified DNA duplex wound with superhelical density sigma = -0.05 +/- 0.01. This superhelical tension is relaxed in cells when multiple single-strand breaks are introduced into the chromosomal DNA by gamma-irradiation. Similar relaxation occurs when cells are treated with the DNA gyrase inhibitor coumermycin. The results suggest that the DNA double helix is wound with torsional tension in vivo and that DNA supercoils which are equilibrated with this tension are not completely restrained in nucleosome-like structures. Torsional tension in the DNA of eucaryotic cells is not detectable in analogous measurements of the packaged DNA of HeLa and Drosophila cells. The simplest interpretation of this finding is that, within the limits of detection, all superhelical turns in the DNA are restrained in nucleosomes or nucleosome-like structures in these eucaryotic cells.     

Action of T4 endonuclease V on DNA containing various photoproducts

The action of T4 endonuclease V on DNA containing various photoproducts was investigated. (1) The enzyme introduced strand breaks in DNA from ultraviolet-irradiated vegetative cells of Bacillus subtilis but not in DNA from irradiated spores of the same organism. DNA irradiated with long wavelength (360 nm peak) ultraviolet light in the presence of 4,5',8-trimethylpsoralen was not attacked by the enzyme. These results indicate that 5-thyminyl 5,6-dihydrothymine (spore photoproduct) and psoralen mediated cross-links in DNA are not recognized by T4 endonuclease V. (2) DNA of phage PBS1, containing uracil in place of thymine, and DNA of phage SPO1, containing hydroxymethyluracil in place of thymine, were fragmented by the enzyme when the DNA's had been irradiated with ultraviolet light. T4 endonuclease V seems to act on DNA with pyrimidine dimers whether the dimers contain thymine residues or not.     

Structure of F-actin needles from extracts of sea urchin oocytes

The mouse L-cell line LD maintains its mitochondrial DNA genome in the form of a head-to-tail unicircular dimer of the monomeric 16,000 base-pair species. This situation permits a comparison of the mechanism of replication of this dimeric molecule with our previous studies of replication of monomeric mouse L-cell mitochondrial DNA. Whereas monomeric mitochondrial DNA requires about one hour for a round of replication, the dimeric molecule requires almost three hours. Denaturing agarose gel electrophoretic analyses of replicative intermediates reveals several discrete size classes of partially replicated daughter strands of dimeric mitochondrial DNA. This suggests that replication occurs with specific discontinuities in the rate of daughter strand synthesis. The strand specificity of these daughter strands was determined by hybridization with ³²P-labeled DNA representing either the heavy or light strand mitochondrial DNA sequence. The sizes and strand specificities of these discrete daughter strands indicate that the same set of control sequences is functional in both dimer and monomer mitochondrial DNA replication.Immediately following a round of replication, the majority of dimeric mitochondrial DNA molecules contain displacement loops, as assessed by their sensitivity to nicking within the displaced DNA strand by single-strand DNA specific S₁ nuclease under conditions which leave supercoiled DNA intact. This result is in contrast with the conformation of newly replicated monomeric mitochondrial DNA molecules, which lack both superhelical turns and displacement loops. This indicates that dimeric mitochondrial DNA proceeds through a different series of post-replicative processing steps than does monomeric mitochondrial DNA. We postulate that intermediates at late stages of dimeric mitochondrial DNA replication contain displacement loops which remain intact following closure of the full-length daughter strands.     

Caged single and double strand breaks

Ionizing radiation and radiomimetic drugs such as bleomycin, calichieamycin, neocarzinostatin chromophore, and other synthetic agents can produce both single and double strand breaks in DNA. The ability to study the structure-activity relationships of single and double-strand break repair, lethality, and mutagenesis in vivo is complicated by the numerous types and sites of DNA cleavage products that can be induced by such agents. The ability to "cage" such breaks in DNA might help to further such studies and additionally afford a mechanism for activating and deactivating nucleic acid based drugs and probes. The major type of single strand break induced by ionizing radiation is a 3'- and 5'-phosphate terminated single nucleotide gap. Previously, a caged strand break of this type had been developed that was designed to produce the 5'-phosphate directly upon irradiation with 366 nm light, and the 3'-phosphate by a subsequent beta-elimination reaction [Ordoukhanian, P., and Taylor, J.-S. (1995) J. Am. Chem. Soc. 117, 9570]. Unfortunately, the release of the 3'-phosphate group was quite slow at pH 7. To circumvent this problem, a second caged strand break has been developed that produces the 3'-phosphate directly upon irradiation, and the 5'-phosphate by a subsequent beta-elimination reaction. When this caged strand break was used in tandem with the previous caged strand break, 5'- and 3'-phosphate terminated gaps could be directly produced by irradiation with 366 nm light. These caged single strand breaks were also incorporated in tandem into hairpin substrates to demonstrate that they could be used to cage double strand breaks. These caged single strand breaks should be generally useful for generating site-specific DNA single and double strand breaks and gaps, using wavelengths and doses of light that are nondetrimental to biological systems. Because the position of the single strand break can be varied, it should now be possible to examine the effect of the sequence context and cleavage pattern of single and double strand breaks on the lethality and mutagenicity of this important class of DNA damage.     

Measurements of nucleic bases released after gamma irradiation of DNA in solution in air.

The release of unaltered nucleic bases from gamma-irradiated DNA in a dilute buffered aqueous solution was studied in both salmon sperm and superhelical viral DNA. Analyses of freed bases were made by high-performance liquid chromatography. An elution protocol was developed for maximum separation of the four nucleic bases and nucleosides with a sensitivity of 10-20 pmol of nucleic base. It was found that: (i) both prompt and delayed release of bases postirradiation occur in both types of DNA; (ii) these yields (G-values) were measured to be 10-15 times higher for the salmon sperm DNA in comparison to the SV40 DNA; (iii) the A-T/G-C ratio in the DNA was not reflected in the ratios of the released base; and (iv) based on measurements made by us of DNA strand breaks in SV40 DNA (unpublished results), less than half of all breaks result in the release of an undamaged base.     

Induction of multiple plasmid recombination in Saccharomyces cerevisiae by psoralen reaction and double strand breaks.

DNA damage-induced multiple recombination was studied by cotransforming yeast cells with pairs of nonreplicating plasmids carrying different genetic markers. Reaction of one of the plasmids with the interstrand crosslinking agent, psoralen, stimulated cellular transformation by the undamaged plasmid. The cotransformants carried copies of both plasmids cointegrated in tandem arrays at chromosomal sites homologous to either the damaged or the undamaged DNA. Plasmid linearization, by restriction endonuclease digestion, was also found to stimulate the cointegration of unmodified plasmids. Disruption of the RAD1 gene reduced the psoralen damage-induced cotransformation of intact plasmid, but had no effect on the stimulation by double strand breaks. Placement of the double strand breaks within yeast genes produced cointegration only at sequences homologous to the damaged plasmids, while digestion within vector sequences produced integration at chromosomal sites homologous to either the damaged or the undamaged plasmid molecules. These observations suggest a model for multiple recombination events in which an initial exchange occurs between the damaged DNA and homologous sequences on an undamaged molecule. Linked sequences on the undamaged molecule up to 870 base pairs distant from the break site participate in subsequent exchanges with other intact DNA molecules. These events result in recombinants produced by reciprocal exchange between three or more DNA molecules.     

Analysis of mouse Rad54 expression and its implications for homologous recombination

Homologous recombination is one of the major pathways for repair of DNA double-strand breaks (DSBs). Important proteins in this pathway are Rad51 and Rad54. Rad51 forms a nucleoprotein filament on single-stranded DNA (ssDNA) that mediates pairing with and strand invasion of homologous duplex DNA with the assist of Rad54. We estimated that the nucleus of a mouse embryonic stem (ES) cells contains on average 4.7x10(5) Rad51 and 2.4x10(5) Rad54 molecules. Furthermore, we showed that the amount of Rad54 was subject to cell cycle regulation. We discuss our results with respect to two models that describe how Rad54 stimulates Rad51-mediated DNA strand invasion. The models differ in whether Rad54 functions locally or globally. In the first model, Rad54 acts in cis relative to the site of strand invasion. Rad54 coats the Rad51 nucleoprotein filament in stoichiometric amounts and binds to the target duplex DNA at the site that is homologous to the ssDNA in the Rad51 nucleoprotein filament. Subsequently, it promotes duplex DNA unwinding. In the second model, Rad54 acts in trans relative to the site of strand invasion. Rad54 binds duplex DNA distant from the site that will be unwound. Translocation of Rad54 along the duplex DNA increases superhelical stress thereby promoting duplex DNA unwinding.