Length-dependent cruciform extrusion in d(GTAC)n sequences

pBR322-derived plasmids have been constructed carrying d(GTAC)n.d(GTAC)n inserts of different lengths, in order to investigate the effect of insert size on cruciform extrusion and/or the B-Z transition. Plasmids with n ranging from 4 to 12 are hypersensitive to cleavage by the single-strand specific nucleases, S1 nuclease and Bal31 nuclease. Hypersensitive sites associated with the smaller alternating purine-pyrimidine tracts, however, coexist with the major pBR322 sites. Site-selective cleavage of these plasmids with the resolvase, T7 endonuclease I, demonstrates that all the inserts form cruciform structures when stably integrated into negatively supercoiled plasmids. An increase in the negative superhelical density of the DNA's induces cruciform formation within the insert region, resulting in a reduction in torsional stress consistent with the size of the insert. Moreover, as n decreases, the superhelical density required to stabilise the cruciform state increases. Therefore, the cruciform geometry is the favoured conformation of these d(GTAC)n.d(GTAC)n sequences under torsional stress. The stability of these cruciforms increases as n increases, with cruciformation occurring at lower superhelical densities and to the exclusion of the other pBR322 cruciforms.     

A Structural Transition in d(AT) n ·d(AT) n Inserts within Superhelical DNA

Abstract

We have constructed plasmids carrying d(AT)_n·d(AT)_n inserts of different lengths. Two- dimensional gel electrophoresis patterns show that an increase in the negative superhelicity of these DNAs brings about a structural transition within the inserts, resulting in a reduction of the superhelical stress. However, this reduction corresponds to the expected values neither for cruciform nor for the Z form. Those DNA topoisomers in which the structural transition had occurred proved to be specifically recognizable by single-strand-specific endonuclease SI, with the cleavage site situated at the centre of the insert. These data, as well as kinetic studies, suggest that the cloned d(AT)_n·d(AT) _n sequences adopt a cruciform rather than the Z-form structure. We discuss plausible reasons of the discrepancy between the observed superhelical stress release and that expected for the transition of the insert to the cruciform state.     

Stress-induced cruciform formation in a cloned d(CATG)10 sequence.

The synthetic alternating purine-pyrimidine sequence, d(CATG)10.d(CATG)10, has been cloned into a 2.079-kb pBR322-derived plasmid (pLN1) and its conformation studied under torsional stress. The resultant plasmid, pLNc40, is hypersensitive to cleavage by the single strand-specific nucleases, S1 nuclease and Bal31 nuclease, and to modification by the single strand-selective reagent, osmium tetroxide. The S1-hypersensitive site of this plasmid predominates over those previously mapped in pBR322. Site-specific cleavage of pLNc40 with the resolvase T4 endonuclease VII demonstrates that this alternating purine-pyrimidine tract selectively forms a cruciform structure when stably integrated into a negatively supercoiled plasmid. Quantitative measurements of the twist change (-4.3 +/- 0.2) and free energy of formation (16.2 +/- 0.5 kcal/mol) of this cruciform have been made from two-dimensional gel electrophoresis experiments, and correspond well with the predicted values of cruciform formation for this sequence. We conclude that cruciform extrusion versus the B-Z transition is the favoured conformation of this insert under torsional stress.     

A structural transition in d(AT)n.d(AT)n inserts within superhelical DNA

We have constructed plasmids carrying d(AT)n.d(AT)n inserts of different lengths. Two-dimensional gel electrophoresis patterns show that an increase in the negative superhelicity of these DNAs brings about a structural transition within the inserts, resulting in a reduction of the superhelical stress. However, this reduction corresponds to the expected values neither for cruciform nor the Z form. Those DNA topoisomers in which the structural transition had occurred proved to be specifically recognizable by single-strand-specific endonuclease S1, with the cleavage site situated at the centre of the insert. These data, as well as kinetic studies, suggest that the cloned d(AT)n.d(AT)n sequences adopt a cruciform rather than the Z-form structure. We discuss plausible reasons of the discrepancy between the observed superhelical stress release and that expected for the transition of the insert to the cruciform state.     

B-Z DNA junctions contain few, if any, nonpaired bases at physiological superhelical densities

The reactions of bromoacetaldehyde (BAA) with recombinant plasmids that contain sequences which can adopt left-handed Z structures or, at other locations, cruciforms were studied as a function of supercoil density. The sequence in pRW756 that undergoes a supercoil induced transition from a right to left-handed helix was (dC-dG)16 and regions near the replication origin of the pBR322 vector were converted from linearforms to cruciforms. The locations of the most nonpaired structural features were mapped by S1 nuclease cleavage of the "wedged open" duplexes after linearization of the DNAs. Three cruciforms in the pBR322 portions of the plasmids were specifically detected by BAA reaction at physiological supercoil densities (sigma = -0.067). However, the B-Z junctions did not react with BAA under these conditions although the junctions were present since the (dC-dG)16 was shown to be left-handed. Thus, the B-Z junctions have less single-stranded character than the pBR322 cruciforms (3-6 nonpaired bases) and may be fully paired. At much higher superhelical densities (sigma = -0.11-0.12), the B-Z junctions as well as the cruciforms react with BAA indicating a change in the nature of the junctions. Studies were also performed with pRW777 which harbors the mouse kappa immunoglobin sequence (dT-dG)32 . (dC-dA)32 that adopts a left-handed helix under appropriate conditions; the results were similar to those found with pRW756.     

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.     

Intermediate range effects in DNA. I: Low pH/stress induced conformational changes in the vicinity of an extruded d(AT)n.d(AT) in cruciform.

A family of plasmids which contain d(AT)n cruciforms are sensitive to "single strand specific" (SS) endonucleases and a variety of chemical probes in a "random sequence" region centered 10-30 residues away from the cruciform junction. The SS nuclease sensitive structures are dependent on the presence of the extruded cruciform and exhibit a degree of sequence independence. Their appearance depends upon the combined effects of slightly lower than neutral pH and superhelical coiling above the minimum required to drive the extrusion of the d(AT)n cruciform arms. The nuclease sensitive structure is therefore underwound with respect to the B conformation and contains protonated bases.     

Rh(DIP)3(3+): a shape-selective metal complex which targets cruciforms.

The coordination complex tris(4,7-diphenylphenanthroline)rhodium(III), Rh(DIP)3(3+), binds to and, upon photoactivation, cleaves both DNA strands near the base of a DNA cruciform. Sites of photoinduced double-stranded DNA cleavage by the rhodium complex map to regions containing cruciforms on closed circular pBR322, pColE1 and phi X174 (replicative form) DNAs. Neither cleavage nor binding by the metal complex, assayed using S1 nuclease, is found on the linear plasmid which lacks the extruded cruciform. High resolution mapping experiments reveal that Rh(DIP)3(3+) cleaves at a specific AT-rich site neighboring the stem of the minor cruciform on pBR322. The primary site of cleavage is found at position 3238 on the 3'-strand and 3250 on the 5'-strand and is remarkably specific. The pattern of cleavage, to one side only of the cruciform stem, indicates an asymmetry in the cruciform structure recognized by the complex. These results suggest that Rh(DIP)3(3+) may provide a useful reagent to probe cruciform sites. In addition, the high degree of specificity found in targeting the cruciform structure with this simple metal complex underscores the utility of shape-selection for the recognition of specific sites on a DNA strand.     

B-Z Junctions in Supercoiled pRW751 DNA Contain Unpaired Bases or Non-Watson-Crick Base Pairs

Abstract

Structural distortions on the boundary between right-handed and left-handed DNA segments in negatively supercoiled plasmid pRW751 (a derivative of pBR322 containing (dC-dG)₁₃ and (dC-dG)₁₆ segments) were studied by means of osmium tetroxide, pyridine and glyoxal. These two probes react preferentially with single-stranded DNA but only the latter requires non-paired bases for the reaction. Nuclease SI and testing of the inhibition of BamHI cleavage (whose recognition sequences GGATCC lie on the “outer” boundaries between the (dC-dG)_n and the pBR322 nucleotide sequence) were used to detect the site-specific chemical modification in pRW751.

As a result of glyoxal treatment BamHI cleavage was strongly inhibited in topoisomeric samples whose superhelical density was sufficiently negative to stabilize the (dC-dG)_n segments in the left-handed form. Osmium tetroxide, pyridine modification resulted in a similar inhibition of BamHI cleavage and in a formation of nuclease SI sensitive sites. The results suggest that the “outer” B-Z junctions in pRW751 contain one or few non-paired bases or non-Watson- Crick base pairs.     

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.     

Flexibility of A · Pairs in Left-Handed DNA Helices

Abstract

We have analysed by various approaches the structure of cloned synthetic sequences in supercoiled plasmids. Individual inserts were formed by d(C-G)_n blocks interrupted by the presence of A · T pairs positioned either in phase or out of phase of pur-pyr alternation. Based on the thermodynamic analysis we obtained results confirming that A · T pairs are easily incorporated into left-handed helices without significant energetic penalty. Sequences GTAC which are known to form cruciform structures in multiple repetition underwent a B-Z transition. In the case of plasmids containing AA/TT code words and substantial discontinuities in purine-pyrimidine alternation our analysis indicates that Z-Z junctions formed by A · T pairs contributed little to the overall energetic demands of the B-Z transition probably thanks to their high conformational flexibility.     

A native cruciform DNA structure probed in bacteria by recombinant T7 endonuclease

T7 endonuclease preferentially cleaves purified supercoiled pBR322 and colE1 plasmids at the single-stranded regions exposed when palindromic sequences assume cruciform structures (Panayotatos, N., and Wells, R.D. (1981) Nature 289, 466-470). In vivo, however, induction of nuclease synthesis off a cloned gene caused complete degradation of the bacterial DNA but not of the plasmid vector; presumably, single-stranded regions (cruciforms?) on the genome effectively complete for the nuclease with similar sites on the plasmid (Panayotatos, N., and Fontaine, A. (1985) J. Biol. Chem. 260, 3173-3177). To overcome this competition, we introduced on the plasmid the naturally occurring colE1 palindrome which forms a more stable cruciform in vitro. In addition, we increased the target size (and the T7 endonuclease gene dosage) by raising the copy number of the plasmid 5-fold. Induction of the endonuclease encoded by this new plasmid (pLAT75) resulted not only in degradation of genomic DNA but also in intracellular nicking and linearization of the plasmid. The cleavage site in vivo was mapped at the colE1 palindrome and coincided with the site cleaved specifically in vitro by either T7 or S1 endonuclease only when this palindrome assumes the cruciform structure. These results indicate that cruciform structures exist intracellularly and demonstrate the usefulness of endonucleases as probes of DNA topology in vivo.     

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.     

Nucleosome “phasing” and cruciform structures in circular supercoiled pBR322 DNA

Cruciform structures have been detected in pBR322 supercoiled DNA, both in its naked state and when complexed with histone octamer, using S1 endonuclease cleavage and EcoRI restriction. An inspection of the DNA sequence shows that the S1-hypersensitive sites are very near to AT-rich regions of pBR322 genome. A nucleosome “phasing” in these regions, as found on AT-rich regions of SV40 DNA (15), has been shown by restriction enzymes analysis. On the basis of these results it can be proposed that cruciform structures protrude on the nucleosome surface. This model explains the reason why these structures, which need high superhelical density, can exist in supercoiled DNA partially relaxed by nucleosome formation.     

Formation of Z-DNA in negatively supercoiled plasmids is sensitive to small changes in salt concentration within the physiological range.

Negative supercoiling of the plasmid pBR322 with or without an insert of (dG-dC)n induces the formation of Z-DNA as measured by the binding of antibodies specific for Z-DNA. Increasing the concentration of Na+ (or K+) is shown to inhibit the B to Z-DNA conversion. This may be due to the effect of the cation on the B-Z junction. Using the data for B to Z-DNA conversion of the (dG-dC)n inserts, we have estimated the free energy change per base pair as well as the energy of the B-Z junction. In pBR322, a 14-bp segment [CACGGGTGCGCATG] is believed to form Z-DNA at bacterial negative superhelical densities under salt conditions which are similar to those found in vivo.     

Left-handed Z Form in Superhelical DNA: A Theoretical Study

Abstract

This is a comprehensive statistical mechanical treatment of the Z form formation in purine- pyrimidine stretches of different length inserted into superhelical DNA. The B-Z transition for short inserts is shown to follow the “all-or-none” principle. Over some critical value of the insert length n, the B-Z transition in the insert proceeds in two stages. The flipping of m base pairs into the Z form is followed by a gradual growth of the Z-form stretch until it occupies the whole insert. By fitting the theoretical transition curves to experimental ones the fundamental thermodynamic parameters of the B-Z transition have been determined: the B-Z junction energy Fj = 4–5kcal?mol^?1 and the free energy change ΔF_B-Z = 0.5–0.7 kcal?mol^?1 under standard salt conditions. Calculations show that the B-Z transition in short purine-pyrimidine inserts may be seriously affected by cruciform formation in the carrier 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.