T4 endonuclease VII resolves cruciform DNA with nick and counter-nick and its activity is directed by local nucleotide sequence.

Endonuclease VII of phage T4 resolves Holliday structures in vitro by nicking pairs of strands across the junction. We report here analyses of this reaction between endonuclease VII and a Holliday structure analogue, made in vitro from synthetic oligonucleotides. The enzyme cleaves the structure in a non-concerted way and nicks each strand independently. Combinations of nicks with counter-nicks in strands across the junction resolve the construct. The specificity of the enzyme for DNA secondary structures was tested with a series of branched molecules made from oligonucleotides with the same nucleotide sequence in one strand. Results show that the number, location and relative cleavage efficiencies depend largely on the local nucleotide sequence, rather than on the branch type. In particular, endonuclease VII cleaves a complete four-armed cruciform as efficiently as a three-armed Y-junction or its derivatives, a semi-Y, a fork with two single-strand overhangs, a single-strand overhang, and a nicked DNA. However, exchange or addition of one or more nucleotides within the cleavage area flanking the structural signal for endonuclease VII strongly affects the cleavage pattern as well as their relative efficiency of usage. Examples with a single-stranded overhang are presented and show in summary that the enzyme has a fivefold preference for pyrimidines rather than purines.     

Action of RecBCD enzyme on cruciform DNA

We tested the hypothesis that RecBCD enzyme of Escherichia coli resolves pre-existing Holliday recombination intermediates by examining the action of the purified enzyme on an open-ended DNA cruciform with limited ability to branch migrate. The enzyme cleaved two strands of the cruciform near its base to produce "recombinant" products, with a marked bias in the direction of cleavage. The two nicks necessary to cleave the cruciform were made separately. Cruciforms whose four termini were blocked by synthetic hairpin-shaped oligonucleotides were not detectably nicked by the enzyme. With one terminus open the enzyme made a nick at the base of the cruciform but not a double-strand cut. With two or more termini open the enzyme made double-strand cuts. We infer that RecBCD enzyme molecules must enter the termini of duplex DNA and approach the cruciform from more than one direction in order to cleave it into recombinant products. Previous results on RecBCD-mediated recombination between phage lambda and lambda dv imply that intracellular RecBCD enzyme can approach pre-existing Holliday junctions from only one direction. We infer that intracellular RecBCD enzyme cannot cleave pre-existing Holliday junctions into recombinants and suggest that the enzyme may cleave Holliday junctions in whose formation it participates.     

Underwound loops in self-renatured DNA can be diagnostic of inverted duplications and translocated sequences

DNA that contains inverted duplications separated by non-inverted sequences often can form characteristic “underwound loops” when it is denatured and reannealed. An underwound loop is a partially double-stranded, partially denatured segment between the inverted duplications and is produced as follows. During the early stages of the reannealing, intrastrand stem-loop structures form with first-order kinetics when the inverted duplications pair. In a slower second-order reaction, complementary strands (each with a stem-loop) reanneal. The stem-loop structures produce a cruciform in the hybrid. Because of the unpaired sequences in the loop, the cruciform is unstable. It can isomerize to a linear duplex by double-strand exchange of complementary sequences in the stems. This process requires co-ordinated axial rotation of the stems and the flanking duplexes as well as rotation of the loops. If, however, complementary sequences in the loops start to pair, axial rotation is prevented and the stem-loop structures are trapped in a metastable state. The strands of separate, closed rings cannot interwind when they pair. Consequently, the loops observed by electron microscopy have variable patterns of single-stranded denaturation bubbles and duplex segments with both right-handed and left-handed winding.We have used underwound loops to identify a short inverted duplication flanking the γδ recombination sequence of Escherichia coli F factor (isolated on φ80 d₃ilv⁺ transducing phage) and to study DNA from phages Mu and P1 in which the G segments are flanked by inverted duplications. When deproteinized adenovirus-2 DNA was denatured and reannealed, some underwound circles the length of the entire chromosome were observed by electron microscopy. These resulted from the restricted interaction of complementary single-stranded rings generated when pairing of the short inverted terminal duplications closed the ends of single strands. Another type of underwound loop was seen in heteroduplexes containing complementary insertion loops located at different positions in the hybridized strands, such as occurs with P1 cam DNAs. All these underwound structures are similar in appearance to the hybrids formed when topologically separate, complementary single-stranded circles of Colicin E₁ DNA were allowed to anneal.     

Electron microscopic study of equine herpesvirus type 1 DNA.

Electron microscopic studies of equine herpesvirus DNA revealed that single strands that were allowed to reanneal formed single-stranded loops with double-stranded stems only at one end of the molecule. These observations support restriction enzyme analyses which indicate that the 92-megadalton DNA molecule exists as a long region of unique sequences covalently linked to a short region. The short region is comprised of an internal unique sequence, which forms the loop during reannealing of single strands, and two terminal inverted repeat sequences that bracket the unique sequence and form the double-stranded stem structure observed upon reannealing of single strands. Measurements of the unique sequence and terminal inverted repeat subgenomic sequences indicate a size of 6.4 megadaltons for each and thus fix the size of the short region at approximately 19.2 megadaltons.     

Specific interaction of plant HMG-like proteins with cruciform DNA

Proteins which, on the basis of their solubility in 0.35% NaCl-2%TCA and of their electrophoretic mobility, correspond to animalHMG 1/2 family were isolated from nuclei of ungerminated peaembryos. These proteins ound with a high degree of specificityto synthetic cruciform DNA produced by annealing chemicallysynthesized oligonucleotides. Hence, specific binding to four-wayjunction DNA, previously reported for animal HMG 1 and 2 proteinsproved also to be a property of plant HMG 1/2 family, in spiteof their low homology to the animal ones. Key words: Pisum sativum, chromosomal proteins, cruciform DNA, high mobility group proteins     

Cruciform-resolvase interactions in supercoiled DNA

T4 endonuclease VII, which cleaves Holliday-like junctions in DNA, specifically cleaves short inverted repeats in supercoiled plasmids. These sequences are subject to site-specific cleavage by single-strand-specific nucleases, and cruciform formation has been suggested as an explanation for this observation. This proposal is greatly strengthened by the present data, since a formal analogy between cruciform structures and Holliday junctions exists. Resolution of a variety of unrelated cruciform sequences demonstrates that the cleavage process results in a linear molecule with hairpin ends and single ligatable nicks at positions corresponding to the stem-base of the cruciform. In two examples mapped in detail, the cleavages are exclusively introduced at two or three nucleotides from the end of the symmetric sequence at the 5' side on each strand. These studies demonstrate the potential of endonuclease VII as a probe of cruciform structure and the utility of short cruciform structures as Holliday junction models.     

Interaction of a protein from rat liver nuclei with cruciform DNA.

We constructed a synthetic cruciform DNA which closely resembles Holliday junctions, a DNA structure formed during recombination or following the transition from interstrand to intrastrand base pairing in palindromic DNA sequences. We identified and partially purified a protein from rat liver that specifically binds to this cruciform DNA molecule and does not bind to single-stranded or double-stranded DNAs of the same sequence. This protein also binds to the cruciform structure formed by a 70 bp palindromic sequence cloned in plasmid pUC18. No detectable nucleolytic activity is associated with the rat liver cruciform-binding protein, in contrast to all cruciform-recognizing proteins known so far.     

The physical chemistry of cruciform structures in supercoiled DNA molecules

Inverted repeat DNA sequences extrude cruciform structures when present in negatively supercoiled molecules, stabilised by the release of torsional stress brought about by the negative twist change. We have revealed the presence of cruciform structures by means of enzyme and chemical probing experiments and topological band shift methods. The geometry of cruciform structures has been studied from two points of view. The unpairing of bases in the loop region has been investigated using bisulphite modification, with the result that the central four nucleotides have single-stranded character, and the next pair have only partially single-stranded nature. Gel electrophoretic studies of a pseudo-cruciform structure indicate that the cruciform junction introduces a pronounced bend into the molecule. The dependence of the formation of the ColE1 cruciform upon DNA supercoiling shows that it has a free energy of formation of 18.4 +/- 0.5 kcal mole-1. The kinetics of the extrusion process are complex. Most sequences extrude slowly with considerable temperature coefficients, but the detailed properties are strongly sequence-dependent. One synthetic inverted repeat sequence which we have studied in detail has an Arrhenius activation energy of 42.4 +/- 3.2 kcal mole-1. We discuss possible mechanistic pathways for the extrusion process.     

Does cruciform DNA provide a recognition signal for DNA-topoisomerase II?

Topoisomerase II displays higher affinity for supercoiled DNA compared to the same relaxed DNA. Moreover, cruciform structures are formed in topologically constrained DNA. Here we report that, using S1 nuclease experiments on supercoiled DNA, hairpin structures are located close to numerous topoisomerase II cleavage sites on the BPV I genome. Therefore, DNA secondary structure may play a role in the recognition mechanism of DNA by topoisomerase II.     

Persistence of cruciform structure and preferential location of nucleosomes on some regions of pBR322 and ColE 1 DNAs

Inverted repeats of pBR322 and ColE 1 DNAs have been analyzed for the presence of cruciform structures upon formation of nucleosomes, using S1, P1 and restriction enzyme analysis. In both cases the fraction of molecules showing nuclease-sensitive sites is unaffected by the DNA relaxation, owing to the formation of nucleosomes. A kinetic mechanism, based on the freezing of cruciform structures on the nucleosome surface or nearby, is proposed. This hypothesis is supported by a preferential location of nucleosomes at the DNA sequences containing the nuclease-sensitive sites, as indicated by restriction enzyme analysis and electron microscopy visualization after psoralen cross-linking.     

Measurement of steady-state kinetic parameters for DNA unwinding by the bacteriophage T4 Dda helicase: use of peptide nucleic acids to trap single-stranded DNA products of helicase reactions

Measurement of steady-state rates of unwinding of double-stranded oligonucleotides by helicases is hampered due to rapid reannealing of the single-stranded DNA products. Including an oligonucleotide in the reaction mixture which can hybridize with one of the single strands can prevent reannealing. However, helicases bind to single-stranded DNA, therefore the additional oligonucleotide can sequester the enzyme, leading to slower observed rates for unwinding. To circumvent this problem, the oligonucleotide that serves as a trap was replaced with a strand of peptide nucleic acid (PNA). Fluorescence polarization was used to determine that a 15mer PNA strand does not bind to the bacteriophage T4 Dda helicase. Steady-state kinetic parameters of unwinding catalyzed by Dda were determined by using PNA as a trapping strand. The substrate consisted of a partial duplex with 15 nt of single-stranded DNA and 15 bp. In the presence of 250 nM substrate and 1 nM Dda, the rate of unwinding in the presence of the DNA trapping strand was 0.30 nM s^–1 whereas the rate was 1.34 nM s^–1 in the presence of the PNA trapping strand. PNA prevents reannealing of single-stranded DNA products, but does not sequester the helicase. This assay will prove useful in defining the complete kinetic mechanism for unwinding of oligonucleotide substrates by this helicase.     

Effect of magnesium on cruciform extrusion in supercoiled DNA.

Recently, it was reported that Mg2+greatly facilitates cruciform extrusion in the short palindromes of supercoiled DNA, thereby allowing the formation of cruciform structures in vivo. Because of the potential biological importance of this phenomenon, we undertook a broader study of the effect of Mg2+on a cruciform extrusion in supercoiled DNA. The method of two-dimensional gel electrophoresis was used to detect the cruciform extrusion both in the absence and in the presence of these ions. Our results show that Mg2+shifts the cruciform extrusion in the d(CCC(AT)16GGG) palindrome to a higher, rather than to a lower level of supercoiling. In order to study possible sequence-specific properties of the short palindromes for which the unusual cruciform extrusion in the presence Mg2+was reported, we constructed a plasmid with a longer palindromic region. This region bears the same sequences in the hairpin loops and four-arm junction as the short palindrome, except that the short stems of the hairpins are extended. The extension allowed us to overcome the limitation of our experimental approach which cannot be used for very short palindromes. Our results show that Mg2+also shifts the cruciform extrusion in this palindrome to a higher level of supercoiling. These data suggest that cruciform extrusion in the short palindromes at low supercoiling is highly improbable. We performed a thermodynamic analysis of the effect of Mg2+on cruciform extrusion. The treatment accounted for the effect of Mg2+on both free energy of supercoiling and the free energy of cruciform structure per se. Our analysis showed that although the level of supercoiling required for the cruciform extrusion is not reduced by Mg2+, the ions reduce the free energy of the cruciform structure.     

Guanine-rich telomeric sequences stimulate DNA polymerase activity in vitro

Guanine-rich oligonucleotides and short telomeric DNA sequences can self-associate into G-quartet stabilized complexes. We discovered that this self-association can occur in sequencing reactions and that higher-order structures stimulate DNA polymerase to synthesize extended DNA strands. Base analogues were used to identify Hoogsteen base pairings as stabilizing forces in these stimulatory DNA structures. Scanning force microscopy confirmed that quartet-DNA was formed from these oligomers and that these extended, four-stranded structures could be bound by DNA polymerase. Since guanine quartet-stabilized structures are proposed to exist in vivo, such structures may stimulate DNA polymerization in vivo.     

The DNA primase of Sulfolobus solfataricus is activated by substrates containing a thymine-rich bubble and has a 3'-terminal nucleotidyl-transferase activity

DNA primases are responsible for the synthesis of the short RNA primers that are used by the replicative DNA polymerases to initiate DNA synthesis on the leading- and lagging-strand at the replication fork. In this study, we report the purification and biochemical characterization of a DNA primase (Sso DNA primase) from the thermoacidophilic crenarchaeon Sulfolobus solfataricus. The Sso DNA primase is a heterodimer composed of two subunits of 36 kDa (small subunit) and 38 kDa (large subunit), which show sequence similarity to the eukaryotic DNA primase p60 and p50 subunits, respectively. The two polypeptides were co-expressed in Escherichia coli and purified as a heterodimeric complex, with a Stokes radius of about 39.2 Å and a 1:1 stoichiometric ratio among its subunits. The Sso DNA primase utilizes poly-pyrimidine single-stranded DNA templates with low efficiency for de novo synthesis of RNA primers, whereas its synthetic function is specifically activated by thymine-containing synthetic bubble structures that mimic early replication intermediates. Interestingly, the Sso DNA primase complex is endowed with a terminal nucleotidyl-tranferase activity, being able to incorporate nucleotides at the 3′ end of synthetic oligonucleotides in a non-templated manner.     

Cleavage of single- and double-stranded DNAs containing an abasic residue by Escherichia coli exonuclease III (AP endonuclease VI).

The Escherichia coli exonuclease III (AP endonuclease VI) is a DNA-repair enzyme that hydrolyzes the phosphodiester bond 5' to an abasic site in DNA. To study how the enzyme recognizes the abasic site, we used oligonucleotides containing a synthetic abasic site at any desired position in the sequence. We prepared oligonucleotides containing an abasic residue such as 2'-deoxyribosylformamide, 2'-deoxyribose, 1',2'-dideoxy ribofuranose or propanediol. Duplex oligonucleotides containing an abasic residue used in this study were cleaved on the 5' side of the abasic site by exonuclease III in spite of the varieties of the bases opposite and adjacent to the abasic site. In addition, we observed that the enzyme cleaved single-stranded oligonucleotides containing an abasic site on the 5' side of the abasic site. These findings suggest that the enzyme may principally recognize the DNA-pocket formed at an abasic site. The indole ring of the tryptophan 212 residue of the exonuclease III is probably intercalated to the abasic site. The tryptophan in the vicinity of the catalytic site is conserved in the type II AP endonuclease from various organisms.     

Isolation of antibodies against different protein conformations using immunoaffinity chromatography

Physiological effects of DNA bases other than A, G, C, and T as well as ways of removal of such bases from genomes are studied intensely. Methods for targeted insertion of modified bases into DNA, therefore, are highly demanded in the fields of DNA repair and epigenetics. This article describes efficient procedures for incorporation of modified DNA bases into a plasmid-borne enhanced green fluorescent protein (EGFP) gene. The procedure exploits excision of a stretch of 18 nt from either the transcribed or nontranscribed DNA strand with the help of the sequence-specific nicking endonucleases Nb.Bpu10I and Nt.Bpu10I. The excised single-stranded oligonucleotide is then swapped for a synthetic DNA strand containing a desired base modification. Base modifications that form Watson-Crick-type base pairs were efficiently incorporated into plasmid DNA by a straightforward strand exchange, which was achieved by local melting in the presence of large excesses of the synthetic oligonucleotides and reannealing followed by ligation. Base modifications that cause significant distortions of the normal DNA structure, such as thymine glycol and uracil mispaired with guanine, failed to produce high yields of direct strand exchange but could still be incorporated very efficiently when the excised fragment was depleted in an intermediate step.     

An assay combining high-performance liquid chromatography and mass spectrometry to measure DNA interstrand cross-linking efficiency in oligonucleotides of varying sequences

The main method of evaluating the DNA interstrand cross-linking ability of cancer chemotherapeutic agents in naked DNA currently involves the electrophoresis of relatively long radiolabeled duplex DNA fragments (typically approximately 2000 bp) on neutral gels after incubation with the agent of interest. Denaturation by heating is carried out prior to loading, and a neutral gel allows reannealing of cross-linked DNA. To avoid the use of radioactivity we have developed a new method based on ion pair reversed phase liquid chromatography (RPLC) and mass spectrometry (MS) that allows characterization and quantitation of drug-DNA interstrand cross-links formed within short oligonucleotide duplexes (i.e., 12 bp). Advantages of this assay include rapid throughput, as compared to electrophoretic methods, and the use of readily available short nonradiolabeled oligonucleotides of any sequence, thereby facilitating investigation of sequence selectivity. A further advantage is that all species separated by the chromatographic process can be positively identified by MS. Using this new method, we have investigated the rate of DNA cross-linking and sequence selectivity of the interstrand cross-linking agent SJG-136, a pyrrolobenzodiazepine (PBD) dimer currently in phase I clinical trials. The assay was found to be sufficiently sensitive and selective to allow separation of the unbound and drug-bound oligonucleotide species by high-performance liquid chromatography (HPLC) and to allow positive identification of these individual species by MS. A further benefit, as compared with electrophoretic methods, is that kinetic information can be obtained and compared for different binding sequences.     

Method for one-step preparation of double-stranded DNA template applicable for use with Pyrosequencing technology

A new one-step method for fast and efficient preparation of double-stranded DNA template, suitable for use with Pyrosequencing technology, has been developed. In the new method, two different types of oligonucleotides were used to prevent reannealing of remaining PCR primers to the template: oligonucleotides complementary to the PCR primers and 3'-end modified oligonucleotides with the same sequence as the PCR primers. Advantages with the new strategy are: (i) faster and simpler template preparation procedure (one-step); (ii) no need for exonuclease I treatment; and (iii) less problem with unspecific priming from loop structures and dimers. By careful oligonucleotide design, and/or by addition of single-stranded DNA-binding protein, problems with unspecific sequence signals due to mispriming can be reduced. The new method was used for analysis of genotype variations within the renin-angiotensin-aldosterone system.