Formation of (dA-dT)n cruciforms in Escherichia coli cells under different environmental conditions.

We have detected cruciform formation of (dA-dT)n inserts in Escherichia coli cells by analyzing the superhelical density of isolated plasmid DNA samples and by probing intracellular DNA with chloroacetaldehyde. The plasmids we used were pUC19 containing inserts of (dA-dT)n. The cruciforms appeared after cells underwent different stresses: inhibition of protein synthesis, anaerbiosis, and osmotic shock. At the same time, all these stimuli led to an increase in superhelical density of the control pUC19 plasmid DNA. Therefore, we suggest that the increase in plasmid superhelicity in response to different environmental stimuli entails the appearance of cruciform structures. The use of the (dA-dT)n units of various lengths made it possible to estimate the superhelical density of the plasmid DNA in vivo.     

Reduced 4,5',8-trimethylpsoralen cross-linking of left-handed Z-DNA stabilized by DNA supercoiling

Z-DNA-forming sequences, (GT)21, (GT)12ATGT, and (CG)6TA(CG)6, were cloned into plasmids. These sequences formed left-handed Z-DNA conformations under torsional tension from negative supercoiling of DNA. 4,5',8-Trimethylpsoralen, on absorption of 360-nm light, forms monoadducts and interstrand cross-links in DNA that exists in the B-helical conformation. Trimethylpsoralen cross-links were introduced into the potential Z-DNA-forming sequences in relaxed DNA when these sequences existed as B-form DNA. In supercoiled DNA when these sequences existed in the Z conformation, the rate of cross-linking was greatly reduced, and trimethylpsoralen did not form monoadducts appreciably to Z-DNA. As an internal control in these experiments, the rates of cross-linking of the Z-DNA-forming sequences were measured relative to that of an adjacent, cloned sequence that could not adopt a Z conformation. The initial relative rates of cross-linking to Z-DNA-forming sequences were dependent on the superhelical density of the DNA, and the rates were ultimately reduced by factors of 10-15 for Z-DNA in highly supercoiled plasmids. This differential rate of cross-linking provides a novel assay for Z-DNA. Initial application of this assay in vivo suggests that a substantial fraction of (CG)6TA(CG)6, which existed as Z-DNA in plasmid molecules purified from cells, existed in the B conformation in vivo.     

On the Deletion of Inverted Repeated DNA in Escherichia Coli: Effects of Length, Thermal Stability, and Cruciform Formation in Vivo

We have studied the deletion of inverted repeats cloned into the EcoRI site within the CAT gene of plasmid pBR325. A cloned inverted repeat constitutes a palindrome that includes both EcoRI sites flanking the insert. In addition, the two EcoRI sites represent direct repeats flanking a region of palindromic symmetry. A current model for deletion between direct repeats involves the formation of DNA secondary structure which may stabilize the misalignment between the direct repeats during DNA replication. Our results are consistent with this model. We have analyzed deletion frequencies for several series of inverted repeats, ranging from 42 to 106 bp, that were designed to form cruciforms at low temperatures and at low superhelical densities. We demonstrate that length, thermal stability of base pairing in the hairpin stem, and ease of cruciform formation affect the frequency of deletion. In general, longer palindromes are less stable than shorter ones. The deletion frequency may be dependent on the thermal stability of base pairing involving approximately 16-20 bp from the base of the hairpin stem. The formation of cruciforms in vivo leads to a significant increase in the deletion frequency. A kinetic model is presented to describe the relationship between the physical-chemical properties of DNA structure and the deletion of inverted repeats in living cells.     

Effect of DNA supercoiling on the geometry of holliday junctions

Unusual DNA conformations including cruciforms play an important role in gene regulation and various DNA transactions. Cruciforms are also the models for Holliday junctions, the transient DNA conformations critically involved in DNA homologous and site-specific recombination, repair, and replication. Although the conformations of immobile Holliday junctions in linear DNA molecules have been analyzed with the use of various techniques, the role of DNA supercoiling has not been studied systematically. We utilized atomic force microscopy (AFM) to visualize cruciform geometry in plasmid DNA with different superhelical densities at various ionic conditions. Both folded and unfolded conformations of the cruciform were identified, and the data showed that DNA supercoiling shifts the equilibrium between folded and unfolded conformations of the cruciform toward the folded one. In topoisomers with low superhelical density, the population of the folded conformation is 50-80%, depending upon the ionic strength of the buffer and a type of cation added, whereas in the sample with high superhelical density, this population is as high as 98-100%. The time-lapse studies in aqueous solutions allowed us to observe the conformational transition of the cruciform directly. The time-dependent dynamics of the cruciform correlates with the structural changes revealed by the ensemble-averaged analysis of dry samples. Altogether, the data obtained show directly that DNA supercoiling is the major factor determining the Holliday junction conformation.     

Cruciform extrusion in plasmids bearing the replicative intermediate configuration of a poxvirus telomere

The transition from lineform DNA to cruciform DNA (cruciformation) within the cloned telomere sequences of the Leporipoxvirus Shope fibroma virus (SFV) has been studied. The viral telomere sequences have been cloned in recombination-deficient Escherichia coli as a 322 base-pair, imperfect palindromic insert in pUC13. The inverted repeat configuration is equivalent to the arrangement of the telomere structures observed within viral DNA replicative intermediates. A major cruciform structure in the purified recombinant plasmid has been identified and mapped using, as probes, the enzymes AflII, nuclease S1 and bacteriophage T7 endonuclease I. It was extruded from the central axis of the cloned viral inverted repeat and, by unrestricted branch migration, attained a size commensurate with the superhelical density of the plasmid molecule at native superhelical densities. This major cruciform extrusion event was the only detectable duplex DNA perturbation, induced by negative superhelical torsion, in the insert viral sequences. No significant steady-state pool of extruded cruciform was identified in E. coli. However, the identification of a major deletion variant generated even in the recombination-deficient E. coli strain DB1256 (recA recBC sbcB) suggested that the cruciform may be extruded transiently in vivo. The lineform to cruciform transition has been further characterized in vitro using two-dimensional agarose gel electrophoresis. The transition was marked by a high energy of formation (delta Gf = 44 kcal/mol), and an apparently low activation energy that enabled facile transitions at physiological temperatures provided there was sufficient torsional energy. By comparing cruciformation in a series of related bidirectional central axis deletions of the telomeric insert, it has been concluded that the presence of extrahelical bases in the terminal hairpin structures contributes substantially to the high delta Gf value. Also, viral sequences flanking the extruded cruciform were shown to influence the measured delta Gf value. Several general features of poxvirus telomere structure that would be expected to influence the facility of cruciform extrusion are discussed along with the implications of the observed cruciform transition event on the replicative process of poxviruses in vivo.     

Hyperreactivity of B-Z junctions to 4,5',8-trimethylpsoralen photobinding assayed by an exonuclease III/photoreversal mapping procedure

We have developed an exonuclease III/photoreversal procedure to map, with base-pair resolution, the bases that have photoreacted with 4,5',8-trimethylpsoralen (Me3-psoralen) forming either monoadducts or interstrand crosslinks in DNA. This assay allows quantification of relative rates of Me3-psoralen photobinding to bases in DNA at levels less than one crosslink per 8000 base-pairs. We demonstrate the applicability of the Me3-psoralen mapping procedure on the Z-forming sequence GAATT(CG)6-TA(CG)6AATTC. The results confirm our previous findings that Me3-psoralen forms crosslinks in the 5'TA within the (CG)6TA(CG)6 sequence when it exists in the B conformation but not when it exists in the Z conformation. In addition, with increasing superhelical density we observe at least a hundred-fold increased Me3-psoralen presumably represent B-Z junctions. The two presumed junctions respond differently with increasing negative superhelical tension, however, suggesting that the structures of these negative superhelical tension, however, suggesting that the structures of these junctions differ. This increased Me3-psoralen photoreactivity provides a positive signal for the presence of Z-DNA. The sequence and assay described here provide a "torsionally tuned probe" for determining the effective superhelical density of DNA in vivo.     

Real-time detection of DNA topological changes with a fluorescently labeled cruciform

Topoisomerases are essential cellular enzymes that maintain the appropriate topological status of DNA and are the targets of several antibiotic and chemotherapeutic agents. High-throughput (HT) analysis is desirable to identify new topoisomerase inhibitors, but standard in vitro assays for DNA topology, such as gel electrophoresis, are time-consuming and are not amenable to HT analysis. We have exploited the observation that closed-circular DNA containing an inverted repeat can release the free energy stored in negatively supercoiled DNA by extruding the repeat as a cruciform. We inserted an inverted repeat containing a fluorophore-quencher pair into a plasmid to enable real-time monitoring of plasmid supercoiling by a bacterial topoisomerase, Escherichia coli gyrase. This substrate produces a fluorescent signal caused by the extrusion of the cruciform and separation of the labels as gyrase progressively underwinds the DNA. Subsequent relaxation by a eukaryotic topoisomerase, human topo IIα, causes reintegration of the cruciform and quenching of fluorescence. We used this approach to develop a HT screen for inhibitors of gyrase supercoiling. This work demonstrates that fluorescently labeled cruciforms are useful as general real-time indicators of changes in DNA topology that can be used to monitor the activity of DNA-dependent motor proteins.     

Involvement of integration host factor (IHF) in maintenance of plasmid pSC101 in Escherichia coli: mutations in the topA gene allow pSC101 replication in the absence of IHF.

Integration host factor (IHF), encoded by the himA and himD genes, is a histonelike DNA-binding protein that participates in many cellular functions in Escherichia coli, including the maintenance of plasmid pSC101. We have isolated and characterized a chromosomal mutation that compensates for the absence of IHF and allows the maintenance of wild-type pSC101 in him mutants, but does not restore IHF production. The mutation is recessive and was found to affect the gene topA, which encodes topoisomerase I, a protein that relaxes negatively supercoiled DNA and acts in concert with DNA gyrase to regulate levels of DNA supercoiling. A previously characterized topA mutation, topA10, could also compensate for the absence of IHF to allow pSC101 replication. IHF-compensating mutations affecting topA resulted in a large reduction in topoisomerase I activity, and plasmid DNA isolated from such strains was more negatively supercoiled than DNA from wild-type strains. In addition, our experiments show that both pSC101 and pBR322 plasmid DNAs isolated from him mutants were of lower superhelical density than DNA isolated from Him+ strains. A concurrent gyrB gene mutation, which reduces supercoiling, reversed the ability of topA mutations to compensate for a lack of him gene function. Together, these findings indicate that the topological state of the pSC101 plasmid profoundly influences its ability to be maintained in populations of dividing cells and suggest a model to account for the functional interactions of the him, rep, topA, and gyr gene products in pSC101 maintenance.     

Effects of the pSC101 partition (par) locus on in vivo DNA supercoiling near the plasmid replication origin.

Previous work has shown that deletion of the partition (par) locus of plasmid pSC101 results in decreased overall superhelical density of plasmid DNA and concommitant inability of the plasmid to be stably inherited in populations of dividing cells. We report here that the biological effects of par correlate specifically with its ability to generate supercoils in vivo near the origin of pSC101 DNA replication. Using OsO4 reactivity of nucleotides adjoining 20 bp (G-C) tracts introduced into pSC101 DNA to measure local DNA supercoiling, we found that the wild type par locus generates supercoiling near the plasmid's replication origin adequate to convert a (G-C) tract in the region to Z form DNA. A 4 bp deletion that decreases par function, but produces no change in the overall superhelicity of pSC101 DNA as determined by chloroquine/agarose gel analysis, nevertheless reduced (G-C) tract supercoiling sufficiently to eliminate OsO4 reactivity. Mutation of the bacterial topA gene, which results in stabilized inheritance of par-deleted plasmids, restored supercoiling of (G-C) tracts in these plasmids and increased OsO4 reactivity in par+ replicons. Removal of par to a site more distant from the origin decreased supercoiling in a (G-C) tract adjacent to the origin and diminished par function. Collectively, these findings indicate that par activity is dependent on its ability to produce supercoiling at the replication origin rather than on the overall superhelical density of the plasmid DNA.     

Diethyl pyrocarbonate: a chemical probe for DNA cruciforms.

Two palindromic DNA sequences were analyzed with respect to their chemical reactivities with diethyl pyrocarbonate. In negatively supercoiled plasmid templates enhanced N7 carbethoxylation was found with individual purines located in presumptive single-stranded loops of DNA cruciform structures. No enhanced reactivity at these positions was observed in linear, relaxed or low superhelical density plasmids. Hyperreactivity was found over a narrow region only, indicating that stable cruciforms contain loops of minimal size. No enhanced chemical reactivity was found with the four-way junction at the base of cruciforms. Diethyl pyrocarbonate has proved a sensitive structural probe for the analysis, with single nucleotide resolution, of DNA cruciform structures.     

Reaction conditions affect the specificity of bromoacetaldehyde as a probe for DNA cruciforms and B-Z junctions.

The reaction of bromoacetaldehyde (BAA) was investigated further with recombinant plasmids containing tracts of (CG)16, in pRW756, or (CA)32, in pRW777, which adopt left-handed Z-structures under the influence of negative supercoiling. The cruciform structures adopted by the inverted repeat sequences near the replication origins of the pBR322 vectors served as internal controls for the number of unpaired bases. The extent of reaction with the B-Z junctions and the cruciforms was dependent on the reaction and analysis conditions, the method of preparation of BAA, ionic conditions, and the amount of negative supercoiling. In contrast to the previous results of Kang and Wells, B-Z junctions in addition to cruciforms do react with BAA. However, more forcing conditions are required to detect this reaction since B-Z junctions appear to be less reactive than the single stranded loops of cruciforms. The site of reaction with DNA was readily mapped with high precision at the nucleotide level. Also, a simple method is described for determining the concentration of BAA as well as its intrinsic reactivity in a given ionic medium.     

Inverted repeats,stem-loops,and cruciforms: Significance for initiation of DNA replication

Inverted repeats occur nonrandomly in the DNA of most organisms. Stem-loops and cruciforms can form from inverted repeats. Such structures have been detected in pro- and eukaryotes. They may affect the supercoiling degree of the DNA, the positioning of nucleosomes, the formation of other secondary structures of DNA, or directly interact with proteins. Inverted repeats, stem-loops, and cruciforms are present at the replication origins of phage, plasmids, mitochondria, eukaryotic viruses, and mammalian cells. Experiments with anti-cruciform antibodies suggest that formation and stabilization of cruciforms at particular mammalian origins may be associated with initiation of DNA replication. Many proteins have been shown to interact with cruciforms, recognizing features like DNA crossovers, four-way junctions, and curved/bent DNA of specific angles. A human cruciform binding protein (CBP) displays a novel type of interaction with cruciforms and may be linked to initiation of DNA replication. © 1996 Wiley-Liss, Inc.     

Tetracycline promoter mutations decrease non-B DNA structural transitions, negative linking differences and deletions in recombinant plasmids in Escherichia coli

The ability to clone a variety of sequences with varying capabilities of adopting non-B structures (left-handed Z-DNA, cruciforms or triplexes) into three loci of pBR322 was investigated. In general, the inserts were stable (non-deleted) in the EcoRI site (an untranslated region) of pBR322. However, sequences most likely to adopt left-handed Z-DNA or triplexes in vivo suffered deletions when cloned into the BamHI site, which is located in the tetracycline resistance structural gene (tet). Conversely, when the promoter for the tet gene was altered by filling-in the unique HindIII or ClaI sites, the inserts in the BamHI site were not deleted. Concomitantly, the negative linking differences of the plasmids were reduced. Also, inserts with a high potential to adopt Z-DNA conformations were substantially deleted in the PvuII site of pBR322 (near the replication origin and the copy number control region), but were less deleted if the tet promoter was insertion-mutated. The deletion phenomena are due to the capacity of these sequences to adopt left-handed Z-DNA or triplexes in vivo since shorter inserts, less prone to form non-B DNA structures, or random sequences, did not exhibit this behavior. Sequences with the potential to adopt cruciforms were stable in all sites under all conditions. These results reveal a complex interrelationship between insert deletions (apparently the result of genetic recombination), negative supercoiling, and the formation of non-B DNA structures in living Escherichia coli cells.     

Structural changes in positively and negatively supercoiled DNA

The effect of superhelical constraint on the structure of covalently closed circular DNA (cccDNA; pBR322) with positive and negative writhe (superturn) has been investigated as a function of decreasing and increasing specific linking difference (mean superhelical density sigma). At low and moderate negative superhelical densities sigma, the overall average structure is maintained in an unwound B-form slightly modified. The overwound cccDNAs with positive writhe differ from those with negative writhe by an absence of cruciform structure. At high negative densities of supercoiling different changes involving the reversal of twist handedness are shown to lead to the formation of DNA segments in a conformation identical to the left-handed component of form V DNA.     

Interactions between structure transitions in a torsionally constrained DNA

We used S1 nuclease cleavage in conjunction with gel electrophoresis to evaluate torsion-induced cruciform extrusion at two inverted repeat sequences, IRS-B and IRS-C of plasmid pUC12. These structure transitions affect each other through competition for the available torsional free energy according to their relative energies of activation and the magnitude of DNA duplex unwinding associated with each transition. They can be modulated by the level of DNA negative torsion. Interplays between transition sequences occur over long distances and are independent of relative orientation of transition sites. DNA binding factors that enhance or repress structural transitions of specific sequences may, thus, regulate the structural and functional properties of torsionally coupled, distal sequences.