Linear Duplex DNA Research Articles

DNase protection by recA protein during strand exchange. Asymmetric protection of the Holliday structure.

When recA protein pairs linear duplex DNA with a homologous duplex molecule that has a single-stranded tail, it produces a recombination intermediate called the Holliday structure and causes reciprocal or symmetric strand exchange, whereas the pairing of a linear duplex molecule with fully single-stranded DNA leads to an asymmetric exchange. To study the location of recA protein on DNA molecules undergoing symmetric exchange, we labeled individually each end of the four strands involved and looked for protection against DNase I or restriction endonucleases. As expected, because of its preferred binding to single-stranded DNA, recA protein protected the single-stranded tails of either substrates, or products. In addition however, strong protection extended into the newly formed heteroduplex DNA along the strand to which recA protein was initially bound. Experiments with uniformly labeled DNA showed a corresponding homology-dependent asymmetry in the protection of the tailed substrate versus its fully duplex partner. Restriction experiments showed that protection extended 50-75 base pairs beyond the point where strand exchange was blocked by a long region of heterology. When compared with earlier observations (Chow, S. A., Honigberg, S. M., Bainton, R. J., and Radding, C. M. (1986) J. Biol. Chem. 261, 6961-6971), the present experiments reveal a pattern of association of recA protein with DNA that suggests a common mechanism of asymmetric and symmetric strand exchange.

The role of suramin as an antiviral reagent : W. S. Mason, D. J. Petcu, L. Coates, C. Aldrich and J. M. Taylor, Fox Chase Cancer Center, Philadelphia, PA 19111, U.S.A.

For hepadnaviruses, the RNA primer for plus-strand DNA synthesis is generated by the final RNase H cleavage of the pregenomic RNA at an 11 nt sequence called DR1 during the synthesis of minus-strand DNA. This RNA primer initiates synthesis at one of two distinct sites on the minus-strand DNA template, resulting in two different end products; duplex linear DNA or relaxed circular DNA. Duplex linear DNA is made when initiation of synthesis occurs at DR1. Relaxed circular DNA, the major product, is made when the RNA primer translocates to the sequence complementary to DR1, called DR2 before initiation of DNA synthesis. We studied the mechanism that determines the site of the final RNase H cleavage in hepatitis B virus (HBV). We showed that the sites of the final RNase H cleavage are always a fixed number of nucleotides from the 5′ end of the pregenomic RNA. This finding is similar to what was found previously for duck hepatitis B virus (DHBV), and suggests that all hepadnaviruses use a similar mechanism. Also, we studied the role of complementarity between the RNA primer and the acceptor site at DR2 in HBV. By increasing the complementarity, we were able to increase the level of priming at DR2 over that seen in the wild-type virus. This finding suggests that the level of initiation of plus-strand DNA synthesis at DR2 is sub-maximal for wild-type HBV. Finally, we studied the role of the sequence at the 5′ end of the RNA primer that is outside of the DR sequence. We found that substitutions or insertions in this region affected the level of priming at DR1 and DR2.

Specific binding of cruciform DNA structures by a protein from human extracts.

A gel electrophoresis binding assay has been used to probe extracts from cultured human lymphoblasts for proteins that bind cruciform structures in duplex DNA. Proteins have been detected that form complexes with synthetic X- and Y-junctions. Several lines of evidence suggest that binding is specific for DNA structure rather than sequence: (1) X- and Y-structures were bound whereas linear duplexes containing identical DNA sequences were not, (2) Binding occurred with equal efficiency to two X-junctions that were constructed from DNA strands of different sequence, (3) One X-junction successfully competed with another for binding whereas linear duplex DNA did not; and (4) protein-DNA complexes were observed at probe:non-specific competitor DNA ratios of 1:10,000.

Reversibility of strand invasion promoted by recA protein and its inhibition by Escherichia coli single-stranded DNA-binding protein or phage T4 gene 32 protein.

When recA protein promotes homologous pairing and strand exchange involving circular single strands and linear duplex DNA, the protein first polymerizes on the single-stranded DNA to form a nucleoprotein filament which then binds naked duplex DNA to form nucleoprotein networks, the existence of which is independent of homology, but requires the continued presence of recA protein (Tsang, S. S., Chow, S. A., and Radding, C. M. (1985) Biochemistry 24, 3226-3232). Further experiments revealed that within a few minutes after the beginning of homologous pairing and strand exchange, these networks began to be replaced by a distinct set of networks with inverse properties: their formation depended upon homology, but they survived removal of recA protein by a variety of treatments. Formation of this second kind of network required that homology be present specifically at the end of the linear duplex molecule from which strand exchange begins. Escherichia coli single-stranded DNA-binding protein or phage T4 gene 32 protein largely suppressed the formation of this second population of networks by inactivating the newly formed heteroduplex DNA, which, however, could be reactivated when recA protein was dissociated by incubation at 0 degrees C. We interpret these observations as evidence of reinitiation of strand invasion when recA protein acts in the absence of auxiliary helix-destabilizing proteins. These observations indicate that the nature of the nucleoprotein products of strand exchange determines whether pairing and strand exchange are reversible or not, and they further suggest a new explanation for the way in which E. coli single-stranded DNA-binding protein and gene 32 protein accelerate the apparent forward rate of strand exchange promoted by recA protein, namely by suppressing initiation of the reverse reaction.

Evidence for a gapped linear duplex DNA intermediate in the replicative cycle of human and simian spumaviruses.

Two forms of linear DNAs have been found in simian (SFV1) and human (HSRV) spumaviruses: a linear duplex unsensitive to nuclease S1 and a sensitive structure with a single-stranded gap. Two nuclease S1 sensitive sites, mapping at the same position for both viruses, have been identified in the gapped structure. Using different molecular subgenomic clones of HSRV as probes in Southern blot analysis, one S1 site was localized in the 3'LTR and the other near the middle of the molecule at about 6.5 kbp from the 5' end of the viral genome. The latter site was shown to correspond to a single stranded region within the linear duplex DNA. Nucleotide sequence analysis revealed that the polypurine tract (PPT) usually found at the 5' boundary of the 3'LTR of retroviruses, is duplicated in HSRV at the 3' end of the pol gene, near the gap. This suggests that the synthesis of plus strand DNA is discontinuous, generating the gap.

Microscopic energy absorption of the DNA molecules from auger electrons of iodine-125

The microscopic energy distribution along the DNA duplex due to local absorption of Auger electrons of iodine-125 incorporated into the DNA molecule, has been theoretically calculated. Our calculation method [Ünak T. Nucl. Instrum. Methods A255, 274 (1987); Ünak T. Ibid. A255, 281 (1987)] (12,13) recently presented for spatial energy distribution from low-energy electrons in different chemical systems, has also been used for these calculations. As a result, it has been determined that the maximum range of the highest energy 125I Auger electrons in a linear DNA duplex is about 38 μm, and the total energy absorbed by DNA molecule per decay is about 10.3 keV, which is approximately half of the total energy released by electrons (19.8 keV per decay). This absorbed energy is not uniformly distributed along the DNA duplex. Consequently, it has also been determined that the microscopic energy absorption per DNA base or sugar-phosphate group rapidly decreased with the distance from the 125I nuclide, and reached about 5 eV per DNA base or sugar-phosphate group at a distance of about 2 nm. On the other hand, the results also demonstrated that the local absorption of 125I Auger electrons is able to produce alone at least one double strand break (DSB) on the DNA duplex without the support of the neutralization effects of highly charged tellurium ions.

Identification of homologous pairing and strand-exchange activity from a human tumor cell line based on Z-DNA affinity chromatography.

An enzymatic activity that catalyzes ATP-dependent homologous pairing and strand exchange of duplex linear DNA and single-stranded circular DNA has been purified several thousand-fold from a human leukemic T-lymphoblast cell line. The activity was identified after chromatography of nuclear proteins on a Z-DNA column matrix. The reaction was shown to transfer the complementary single strand from a donor duplex linear substrate to a viral circular single-stranded acceptor beginning at the 5' end and proceeding in the 3' direction (5'----3'). Products of the strand-transfer reaction were characterized by electron microscopy. A 74-kDa protein was identified as the major ATP-binding peptide in active strand transferase fractions. The protein preparation described in this report binds more strongly to Z-DNA than to B-DNA.

Hydrixyl radical generation by the tetracycline antibiotics with free radical damage to DNA, lipids and carbohydrate in the presence of iron and copper salts

Tetracycline antibiotics caused the degradation of carbohydrate in the presence of a ferric salt at pH 7.4. This degradation appeared to involve hydroxyl radicals since the damage was substantially reduced by the presence of catalase, superoxide dismutase, scavengers of the hydroxyl radical and metal chelators. Similarly, the tetracycline antibiotics in the presence of a ferric salt greatly stimulated the peroxidation of liposomal membranes. This damage, which did not implicate the hydroxyl radical, was significantly reduced by the addition of chain-breaking antioxidants and metal chelators. Only copper salts in the presence of tetracycline antibiotics, however, caused substantial damage to linear duplex DNA. Studies with inhibitors suggested that damage to DNA did involve hydroxyl radicals.

Circular intermediates with missing nucleotides in the conversion of supercoiled or nicked circular to linear duplex DNA catalyzed by two species of BAL 31 nuclease

The extracellular nucleases from Alteromonas espejiana BAL 31 can catalyze the endonucleolytic and/or exonucleolytic hydrolysis of duplex DNA in response to a variety of alterations, either covalent or noncovalent, in DNA structure. The nuclease can exist as at least two kinetically and molecularly distinct protein species. The two species that have been studied, called the ‘fast’ ( F) and ‘slow’ ( S) nucleases, both readily convert negatively supercoiled DNAs to linear duplex molecules and accomplish this conversion through the formation of a circular duplex intermediate containing usually a single interruption in one strand. It is further shown that most of these intermediates contain gaps arising from the removal in a processive manner of one or more nucleotide residues after the introduction of the initial strand break (nick). Considering only the intermediates with gaps, the average number of missing residues is 6.3 ± 0.5 and 2.8 ± 0.3, respectively, for DNA acted upon by the F and S enzymes independently of the extent of conversion of supercoiled DNA. The nicks and gaps are bounded by 3′-hydroxyl and 5′-phosphoryl termini. When singly nicked circular DNA is used as the substrate, conversion to the linear duplex form occurs predominantly through a gapped circular intermediate with the same average numbers, within experimental error, of missing nucleotides for the respective nuclease species as found when supercoiled DNA is the substrate. The conversion to linear duplex DNA is much slower when nicked circular DNA is the substrate compared to that found when supercoiled DNA is the starting material.

Oxygen radical damage to DNA by rifamycin SV and copper ions

The hydroquinone moiety of the antibiotic rifamycin SV reacts with molecular oxygen to form reduced oxygen intermediates such as superoxide (O − 2) and hydrogen peroxide (H 2O 2). The antibiotic semiquinone is also formed. Rifamycin SV in the presence of iron and copper salts can lead to the formation of the highly reactive hydroxyl radical (OH) which degrades the sugar deoxyribose. This damage is substantially inhibited by the enzyme catalase and scavengers of the hydroxyl radical such as formate, mannitol and thiourea. When linear duplex DNA is substituted for deoxyribose only rifamycin SV and copper ions substantially degrade DNA with release from the DNA molecule of thiobarbituric acid-reactive products. Damage to DNA by rifamycin and copper ions is significantly inhibited by catalase but poorly inhibited by scavengers of the hydroxyl radical consistent with a site-specific radical reaction of the DNA molecule. Several biological properties of rifamycin SV are known to resemble those of the metal chelating agent 1,10-phenanthroline. Here, we show that similarities extend to an unusual chemical property whereby thiobarbituric acid-reactive material is released from DNA in the presence of a copper salt.

Homology-dependent changes in adenosine 5'-triphosphate hydrolysis during recA protein promoted DNA strand exchange: evidence for long paranemic complexes.

As a first step in DNA strand exchange, recA protein forms a filamentous complex on single-stranded DNA (ssDNA), which contains stoichiometric (one recA monomer per four nucleotides) amounts of recA protein. recA protein monomers within this complex hydrolyze ATP with a turnover number of 25 min-1. Upon introduction of linear homologous duplex DNA to initiate strand exchange, this rate of ATP hydrolysis drops by 33%. The decrease in rate is complete in less than 2 min, and the rate of ATP hydrolysis then remains constant during and subsequent to the strand exchange reaction. This drop is completely dependent upon homology in the duplex DNA. In addition, the magnitude of the drop is linearly dependent upon the length of the homologous region in the linear duplex DNA. Linear DNA substrates in which pairing is topologically restricted to a paranemic joint also follow this relationship. Taken together, these properties imply that all of the available homology in the incoming duplex DNA is detected very early in the DNA strand exchange reaction, with the linear duplex DNA paired paranemically with the homologous ssDNA in the complex throughout its length. The results indicate that paranemic joints can extend over thousands of base pairs. We note elsewhere [Pugh, B. F., & Cox, M. M. (1987b) J. Biol. Chem. 262, 1337-1343] that this duplex acquires resistance to digestion by DNase with a much slower time course (30 min), which parallels the progress of strand exchange. Together these results imply that the duplex DNA is paired with the ssDNA but remains outside the nucleoprotein filament. Finally, the results also support the notion that ATP hydrolysis occurs throughout the recA nucleoprotein filament.

Purification and properties of a nuclease from Saccharomyces cerevisiae that cleaves DNA at cruciform junctions.

An endonuclease specific for cruciform junctions has been purified from yeast cells treated with a DNA-damaging agent. The activity was followed through five chromatographic steps by assaying for the linearization of supercoiled plasmid DNA, which extrudes cruciform structures in vitro. The sites of cleavage on pColIR215 were sequenced, and nicks were located to positions symmetrically opposed across the cruciform junction. The products of cleavage were unit length linear duplexes that contained terminal hairpin loops. In contrast to pColIR215, the cleavage patterns of pXG540 plasmid DNA were found to be complex, and cuts were found up to 40 bases from an (A-T)34 sequence that extrudes into a cruciform. Little or no activity could be detected on single-stranded DNA, linear duplex DNA, or nicked circular duplex DNA. The nuclease was insensitive to RNase but was inactivated by treatment with proteinase K. Mg2+ was required as cofactor and could not be replaced by Mn2+, Ca2+, Co2+, or Cu2+. The native molecular weight of the activity was approximately 200,000 as estimated by gel filtration.

Purification and characterization of a transcription termination factor from vaccinia virions.

A DNA-dependent RNA polymerase that transcribes vaccinia virus early genes was partially purified from virus cores by deoxycholate extraction and DEAE-cellulose column chromatography. Accurately initiated and terminated RNAs were synthesized by this enzyme in the presence of a linear duplex DNA template. Glycerol gradient sedimentation resolved the in vitro transcription system into two components: fraction I, a rapidly sedimenting RNA polymerase that initiated transcription at an early promoter but transcribed beyond the in vivo 3' terminus to yield a run-off transcript, and fraction II, a more slowly sedimenting fraction, itself devoid of RNA polymerase, that restored efficient termination when added back to fraction I. The termination factor was heat-labile, resistant to N-ethylmaleimide, and did not exhibit endonucleolytic activity on run-off transcripts. Factor-dependent termination required specific sequence information upstream of the site of termination. The vaccinia termination factor was purified extensively by column chromatography on DEAE-cellulose, heparin-agarose, phosphocellulose, and DNA-agarose, and by velocity sedimentation in a glycerol gradient. At each step, termination factor copurified with the vaccinia mRNA capping enzyme. The preparation was well over 90% pure with respect to the latter enzyme, suggesting that termination activity was tightly associated with, if not intrinsic to, the capping enzyme. Nonetheless, formation of the 5'-cap structure did not appear to be a prerequisite for termination.

Partial purification of an activity from human cells that promotes homologous pairing and the formation of heteroduplex DNA in the presence of ATP

An activity that can promote homologous pairing and strand transfer between suitable DNA substrates has been partially purified from human skin fibroblasts and from HeLa cells. The strand transfer reaction was investigated with DNA substrates consisting of single-stranded circular and duplex linear phage DNA. It requires ATP, and under optimal conditions yields heteroduplex molecules containing one strand from each parental DNA substrate. The reactions appears to be of the same general nature as those mediated by RecA proteins of Escherichia coli and the Rec1 protein of Ustilago maydis.

The genome of lipid-containing bacteriophage PRD1, which infects gram-negative bacteria, contains long, inverted terminal repeats.

The bacteriophage PRD1 is a lipid-bearing phage that infects a wide variety of gram-negative bacteria, including Escherichia coli and Salmonella typhimurium when they contain the appropriate plasmid. It contains a linear duplex DNA molecule that is covalently bound by its 5' ends to a terminal protein. We report here that the PRD1 genome contains a 111-base-pair terminal inverted repeat which does not bear homology to that of any known linear duplex DNAs with terminal proteins. We further report that its 3' termini are susceptible to enzymatic digestion by exonuclease III.

Relationship of the physical and enzymic properties of Escherichia coli recA protein to its strand exchange activity

We have shown that performing the recA protein catalyzed strand exchange reaction in the presence of acetate anions, rather than chloride which is commonly used, greatly increases the rate of the reaction. The initial rate of the reaction in an acetate-based buffer is approximately 3-4 times higher in the presence of Escherichia coli single-stranded DNA binding protein (SSB protein) and 2 times higher in its absence than the initial rate in chloride. To determine the enzymatic basis for this stimulatory effect of acetate buffer, we investigated the relationship between a number of physical and enzymatic properties of recA protein and the strand exchange reaction. We have found that although the acetate anion has some effect on the aggregation properties and the single-stranded DNA-dependent ATPase activity of recA protein, these effects cannot explain the enhanced strand exchange activity in an acetate-based buffer. We do find, however, that two aspects of recA protein activity closely parallel the ability of this protein to catalyze strand exchange. The first is the ability of recA protein to displace SSB protein from single-stranded DNA, an event critical to presynaptic complex formation. RecA protein is able to resist displacement by SSB protein at a lower magnesium concentration in acetate than in chloride buffer. The magnesium ion concentration dependence of strand exchange coincides exactly with this behavior. The second activity correlated to strand exchange is the duplex DNA-dependent ATPase activity of recA protein. We find that over a wide variety of sodium chloride and sodium acetate concentrations, this duplex DNA-dependent ATPase activity is linearly related to the amount of product formed in the strand exchange reaction. We postulate that this duplex DNA-dependent ATPase activity is important in the denaturation of the duplex DNA during the branch migration step of strand exchange and have also determined that this reaction is quite efficient, with the number of ATP molecules hydrolyzed per base pair exchanged being 0.75 +/- 0.25. In addition, recA protein catalyzed strand exchange between circular single-strand and linear duplex DNA molecules is shown to be irreversible, and a possible explanation for this irreversibility is presented.

Uncoupling of the DNA breaking and rejoining steps of Escherichia coli type I DNA topoisomerase. Demonstration of an active covalent protein-DNA complex.

DNA topoisomerases have been shown to cleave DNA phosphodiester bond and simultaneously become linked to the DNA at the cleavage site via a phosphotyrosine linkage (Tse, Y.-C., Kirkegaard, K., and Wang, J. C. (1980) J. Biol. Chem. 255, 5560-5565). For prokaryotic DNA topoisomerases, this is observed only when denaturant or protease is added to the topoisomerase-DNA incubation mixture. Previous attempts to reform DNA phosphodiester bonds from the covalent protein-DNA complex have been unsuccessful. Using oligonucleotides as substrates, the cleavage reaction of Escherichia coli DNA topoisomerase I occurs spontaneously (Tse-Dinh, Y.-C., McCarron, B. G. H., Arentzen, R., and Chowdhry, V. (1983) Nucleic Acids Res. 11, 8691-8701). Upon reaction with oligo(dA) labeled with 32P using terminal transferase and [alpha-32P]dATP, the enzyme becomes covalently linked to the 32P-labeled oligonucleotide. This 32P label can then be transferred to the 3'-OH end of a linear or nicked duplex DNA molecule subsequently added to the reaction mixture. This phosphodiester bond rejoining reaction can occur at a recessed, blunt, or protruding 3'-end of double-stranded DNA. It requires magnesium ions. These observations suggest that the covalent protein-DNA complex is a true intermediate during topoisomerization. Implications on the structure of prokaryotic type I DNA topoisomerases as compared to their eukaryotic counterparts are discussed.

Replication and resolution of cloned poxvirus telomeres in vivo generates linear minichromosomes with intact viral hairpin termini.

The covalently closed terminal hairpins of the linear duplex-DNA genomes of the orthopoxvirus vaccinia and the leporipoxvirus Shope fibroma virus (SFV) have been cloned as imperfect palindromes within circular plasmids in yeast cells and recombination-deficient Escherichia coli. The viral telomeres inserted within these recombinant plasmids are equivalent to the inverted-repeat structures detected as telomeric replicative intermediates during poxvirus replication in vivo. Although the telomeres of vaccinia and SFV show little sequence homology, the termini from both viral genomes exist as AT-rich terminal hairpins with extrahelical bases and alternate "flip-flop" configurations. Using an in vivo replication assay in which circular plasmid DNA was transfected into poxvirus-infected cells, we demonstrated the efficient replication and resolution of the cloned imperfect palindromes to bona fide hairpin termini. The resulting linear minichromosomes, which were readily purified from transfected cells, were shown by restriction enzyme mapping and by electron microscopy to have intact covalently closed hairpin termini at both ends. In addition, staggered unidirectional deletion derivatives of both the cloned vaccinia and SFV telomeric palindromes localized an approximately 200-base-pair DNA region in which the sequence organization was highly conserved and which was necessary for the resolution event. These data suggest a conserved mechanism of the resolution of poxvirus telomeres.

Bacteriocinlike killing action of a temperate bacteriophage phiBA1 of Bacillus aneurinolyticus.

A new temperate phage, phiBA1, was isolated from Bacillus aneurinolyticus, phiBA1 had an icosahedral head with a diameter of about 70 nm and a tail about 20 nm long and contained a circularly permuted, linear duplex DNA of about 38 x 106 daltons. This phage showed two activities: bacteriocin-like killing activity against five strains of B. aneurinolyticus and normal temperate phage activity against three other strains. phiBA1 killed sensitive cells by a single-hit process. After adsorption of phiBA1 to cells sensitive to killing, the content of intracellular ATP increased for the first 5 min and then gradually decreased. Phage DNA injected into the cell immediately after infection was degraded rapidly. Killing was also caused by heavily UV-irradiated phiBA1. Killing-resistant mutants showed normal adsorption of phiBA1 and normal injection of the DNA with its instantaneous restriction. Our results indicate that the killing action of phiBA1 is different from the phenomenon of abortive infection and suggest that the killing might be caused by a proteinaceous component of phiBA1.

The homologous recombination system of phage lambda. Pairing activities of beta protein.

The red genes of phage lambda specify two proteins, exonuclease and beta protein, which are essential for its general genetic recombination in recA- cells. These proteins seem to occur in vivo as an equimolar complex. In addition, beta protein forms a complex with another polypeptide, probably of phage origin, of Mr 70,000. The 70-kDa protein appears to be neither a precursor nor an aggregated form of either exonuclease or beta protein, since antibodies directed against the latter two proteins failed to react with 70-kDa protein on Ouchterlony double diffusion analysis. beta protein promotes Mg2+-dependent renaturation of complementary strands (Kmiec, E., and Holloman, W. K. (1981) J. Biol. Chem. 256, 12636-12639). To look for other pairing activities of beta protein, we developed methods of purification to free it of associated exonuclease. Exonuclease-free beta protein appeared unable to cause the pairing of a single strand with duplex DNA; however, like Escherichia coli single strand binding protein (SSB), beta protein stimulated formation of joint molecules by recA protein from linear duplex DNA and homologous circular single strands. Like recA protein, but unlike SSB, beta protein promoted the joining of the complementary single-stranded ends of phage lambda DNA. beta protein specifically protected single-stranded DNA from digestion by pancreatic DNase. The half-time for renaturation catalyzed by beta protein was independent of DNA concentration, unlike renaturation promoted by SSB and spontaneous renaturation, which are second order reactions. Thus, beta protein resembles recA protein in its ability to bring single-stranded DNA molecules together and resembles SSB in its ability to reduce secondary structure in single-stranded DNA.