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.     

Length-Dependent Cruciform Extrusion in d(GTAC)n Sequences

Abstract

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.     

Conformational isomerization of the Holliday junction associated with a cruciform during branch migration in supercoiled plasmid DNA

The variable positions of a branch-migrating cruciform junction in supercoiled plasmid DNA were mapped following cleavage of the DNA with bacteriophage T7 endonuclease I. T7 endonuclease I specifically cleaved, and thereby resolved, the Holliday junction existing at the base of the cruciform in the circular bacterial plasmid pSA1B.56A. Cruciform extrusion of cloned sequences in pSA1B.56A (containing a 322 base-pair inverted repeat insert composed of poxvirus telomeric sequences) topologically relaxed the plasmid substrate in vitro. Thus, numerous crossover positions were identified within the region of cloned sequences, reflecting the range of superhelical densities in the native plasmid preparation. Endonuclease I-sensitive crossover positions, mapped to both strands of the viral insert following the T7 endonuclease I digestion of either plasmid preparations or individual topoisomers, were regularly separated by approximately ten nucleotides. The appearance of sensitive crossovers every ten nucleotides corresponds to a change in linking difference (delta Lk) of +/- 2 in the circular core domain of the plasmid during branch point migration. In contrast, individual topoisomers of a plasmid preparation differ in linking number in increments of +/- 1. Thus, the observed linearization of each individual topoisomer following enzyme treatment, as a result of resolution of the crossovers associated with each topoisomer, showed that branch point migration to sensitive crossover positions must have occurred facilely. T7 endonuclease I randomly resolved across either axis of the cruciform, though some discrimination (related to the sequence specificity of the enzyme) was observed. The ten-nucleotide spacing between sensitive crossover positions is accounted for by an isomerization of the cruciform junction on branch point migration. An hypothesis is that this isomerization was imposed upon the cruciform junction by the change in helix twist (delta Tw) in the two branches that compose the topologically closed, circular domain of the plasmid. T7 endonuclease I may discriminate between the various isomeric forms and cleave a sensitive conformation that appears with every turn of branch migration which leads to the extrusion, or absorption, of two turns of helix from the circular core.     

Efficient resolution of replicated poxvirus telomeres to native hairpin structures requires two inverted symmetrical copies of a core target DNA sequence.

The terminal hairpin sequences of the linear double-stranded DNA genome of the leporipoxvirus Shope fibroma virus (SFV) has been cloned in Saccharomyces cerevisiae and in recombination-deficient Escherichia coli as a palindromic insert within circular plasmid vectors. This sequence configuration is equivalent to the inverted repeat structure detected as a telomeric replicative intermediate during poxvirus replication in vivo. Previously, it has been shown that when circular plasmids containing this palindromic insert were transfected into SFV-infected cells, efficient replication and resolution generated linear minichromosomes with bona fide viral hairpin termini (A. M. DeLange, M. Reddy, D. Scraba, C. Upton, and G. McFadden, J. Virol. 59:249-259, 1986). To localize the minimal target DNA sequence required for efficient resolution, a series of staggered unidirectional deletions were constructed at both ends of the inverted repeat. Analyses of the resolution efficiencies of the various clones indicate that up to 240 base pairs (bp) centered at the symmetry axis were required for maximal resolution to minichromosomes. To investigate the role of the AT-rich central axis sequences, which in SFV include 8 nonpalindromic bp, a unique AflII site at the symmetry axis was exploited. Bidirectional deletions extending from this AflII site and insertions of synthetic oligonucleotides into one of the deletion derivatives were constructed and tested in vivo. The efficiency with which these plasmids resolved to linear minichromosomes with hairpin termini has enabled us to define the minimal target DNA sequence as two inverted copies of an identical DNA sequence between 58 and 76 bp in length. The nonpalindromic nucleotides, which, after resolution, constitute the extrahelical residues characteristic of native poxviral telomeres, were not required for resolution. The close resemblance of the SFV core target sequence to the analogous region from the orthopoxvirus vaccinia virus is consistent with a conserved mechanism for poxviral telomere resolution.     

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.     

Cloning of the vaccinia virus telomere in a yeast plasmid vector

The vaccinia virus DNA telomere, which contains a covalently closed hairpin structure, has been cloned in a yeast plasmid vector. Restriction mapping indicates that the cloned vaccinia telomere is maintained in yeast not in its native hairpin configuration but as an inverted repeat structure, within a circular plasmid, with the sequences of the viral hairpin now at the axis of symmetry of an imperfect palindrome. As such, the cloned telomere resembles the telomeric replicative intermediate observed during vaccinia virus DNA replication. Small deletions and duplications in the viral inverted repeats of different clones suggest a model in which the observed circular plasmids were generated in yeast by the replication of hybrid linear DNA molecules consisting of the linearized yeast vector flanked by two hairpin-containing vaccinia termini.     

Flanking AT-rich sequences may lower the activation energy of cruciform extrusion in supercoiled DNA

In the absence of flanking AT-rich segments, cruciform transition energies of DNA palindromic sequences of random base composition are high and mainly dependent upon the base-stacking and -pairing parameters of the palindromic segment. When AT-rich sequences adjoin palindromes, the transition energy of cruciform extrusion is significantly lowered. An inverse relationship exists between the length of the AT-rich stretch and the cruciform transition energy. Long stretches lower the transition energies more than short stretches. At physiological salt and temperature conditions, equilibrium between cruciform extrusion and absorption for the inverted repeat sequences IRS-B and IRS-C of pBR322 derived plasmids is reached in less than five minutes.     

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.     

Molecular cloning and sequence of the concatemer junction from vaccinia virus replicative DNA. Viral nuclease cleavage sites in cruciform structures

The concatemer junction from replicative forms of vaccinia virus DNA was cloned into plasmid vectors and shown to be a precise duplex copy of the viral terminal hairpin structure, with each strand corresponding to one of the alternative sequence isomers. The plasmids were relaxed circles with extruded cruciforms representing two copies of the vaccinia telomere hairpin structure. Head-to-head dimers containing two copies of the vaccinia virus concatemer junction were observed to contain only one set of stem-loop structures per molecule, suggesting that the initial formation of a small cruciform, and not branch migration, was the rate-limiting step in cruciform formation. The plasmids containing the concatemer junction were converted into nicked circular, linear and cross-linked linear molecules by a nuclease isolated from vaccinia virions. The region-specific cleavage near the border of the hairpin loop and the formation of DNA cross-links in some of the molecules is consistent with the nuclease acting as a nicking-closing enzyme that participates in the resolution of mature termini from replicative concatemer intermediates.     

Long-range structural effects in supercoiled DNA: statistical thermodynamics reveals a correlation between calculated cooperative melting and contextual influence on cruciform extrusion

We have previously described [K. M. Sullivan and D. M. J. Lilley (1986) Cell 47, 817-827] a set of sequences, called C-type inducing sequences, which cause cruciform extrusion by adjacent inverted repeats to occur by an abnormal kinetic pathway involving a large denatured region of DNA. In this paper we apply statistical thermodynamic DNA helix melting theory to these sequences. We find a marked correlation between the ability of sequences to confer C-type cruciform character experimentally and their calculated propensity to undergo cooperative melting, and no exceptions have been found. The correlations are both qualitative and quantitative. Thus the ColE1 flanking sequences behave as single melting units, while the DNA of the S-type plasmid pIRbke8 exhibits no propensity to melt in the region of the bke cruciform. The results of the calculations are also fully consistent with the following experimental observations: 1. the ability of the isolated colL and colR fragments of the ColE1 flanking sequences, as well as the short sequence col30, to confer C-type character; 2. C-type induction by an A + T rich Drosophila sequence; 3. low-temperature cruciform extrusion by an (AT)34 sequence; 4. the effect of changing sequences at a site 90 base pairs (bp) removed from the inverted repeat; 5. the effects of systematic deletion of the colL sequence; and 6. the effects of insertion of various sequences in between the colL sequence and the xke inverted repeat. These studies show that telestability effects on thermal denaturation as predicted from equilibrium helix melting theory of linear DNA molecules may explain all the features that are revealed by studying the extrusion of cruciforms in circular DNA molecules subjected to superhelical stress.     

Kinetics of cruciform formation and stability of cruciform structure in superhelical DNA

This is a study of the kinetics of formation of a cruciform structure from the longest palindromic sequence in plasmid pAO3 DNA. DNA was prepared so as to be free of cruciforms even in topoisomers whose negative superhelicity was great enough to induce cruciform formation. Samples of such DNA were incubated at various temperatures, the incubation time varying over a wide range. Then the state was frozen by chilling. Two-dimensional electrophoretic analysis made it possible to estimate the fraction of molecules that got the cruciform structure during incubation. Precautions were taken for electrophoresis conditions to rule out any spontaneous conformational changes within the palindromic region. The relaxation time at the midpoint of the transition ranged from 30 min at 30 C to 50 hrs at 20 C, both in 0.1SSC. An increase in the negative superhelical density by 0.01 led to a 500-fold reduction of the relaxation time at 30 C but had little effect at 20 C. The probability of cruciform formation has been examined as a function of temperature. It has been shown that the cruciform state is no longer the predominant one at elevated temperatures: the cruciformation probability drops to an insignificant value for all of the topoisomers involved. Data have been obtained suggesting that the cruciform formation at the major palindromic site is not the only structural transition possible in pAO3 DNA.     

Left-handed Z form in superhelical DNA: a theoretical study

This is a comprehensive statistical mechanical treatment of the Z form formation in purinepyrimidine 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 delta FBZ = 0.5-7.0 kcal.mol-1 under standard salt conditions. Calculations show that the B-Z transition in short purinepyrimidine inserts may be seriously affected by cruciform formation in the carrier DNA.     

Kinetics of Cruciform Formation and Stability of Cruciform Structure in Superhelical DNA

Abstract

This is a study of the kinetics of formation of a cruciform structure from the longest palindromic sequence in plasmid pA03 DNA. DNA was prepared so as to be free of cruciforms even in topoisomers whose negative superhelicity was great enough to induce cruciform formation. Samples of such DNA were incubated at various temperatures, the incubation time varying over a wide range. Then the state was frozen by chilling. Two-dimensional electrophoretic analysis made it possible to estimate the fraction of molecules that got the cruciform structure during incubation. Precautions were taken for electrophoresis conditions to rule out any spontaneous conformational changes within the palindromic region. The relaxation time at the midpoint of the transition ranged from 30 min at 30 C to 50 hrs at 20 C, both in 0.1SSC. An increase in the negative superhelical density by 0.01 led to a 500-fold reduction of the relaxation time at 30 C but had little effect at 20 C. The probability of cruciform formation has been examined as a function of temperature. It has been shown that the cruciform state is no longer the predominant one at elevated temperatures: the cruciformation probability drops to an insignificant value for all of the topoisomers involved. Data have been obtained suggesting that the cruciform formation at the major palindromic site is not the only structural transition possible in pA03 DNA.     

Cruciform transitions in DNA

The rates of transition between the cruciform and linear conformations of a perfectly inverted repeated lac operator DNA sequence have been measured using a trimethylpsoralen intrastrand cross-linking assay. The rate and extent of the linear to cruciform transition were dependent on temperature and on the superhelical density of the DNA. Apparent half-lives for this transition were between 4-9 min at 37 degrees C for supercoiled DNAs as isolated from cells. The half-life for the cruciform to linear transition in relaxed DNA was about 30 s at 37 degrees C. Mg2+ stabilized both conformations but stabilized the linear form to a greater degree than the cruciform. The rates of transition were temperature dependent suggesting enthalpies of activation of 26.3 kcal mol-1 for the cruciform to linear transition and 33.4 kcal mol-1 for the linear to cruciform transition. The rate of the linear to cruciform transition was slower at 50 than 37 degrees C. Heating above 70 degrees C resulted in the loss of the cruciform structure.     

Transition of a cloned d(AT)n-d(AT)n tract to a cruciform in vivo.

A 34 base pair tract of the simple repeating dinucleotide d(AT)n-d(AT)n cloned into a 2.4 kb polylinker plasmid vector undergoes a structural transition in response to negative superhelical coiling. The transition has been characterized by 2 dimensional gel electrophoresis, mapping of S1, P1 and T7 endonuclease 1 sensitive sites, and mapping of sites that are sensitive to modification by bromoacetaldehyde. After S1 nuclease treatment it is possible to trap supercoiled species that are nicked on one or both strands near the center of the palindrome. These data show that the alternate state adopted by the d(AT)n-dAT)n insert is a cruciform rather than a Z conformation. Unlike other B-cruciform transitions the transition in d(AT)n-d(AT)n has a low activation energy and the transition is facilitated by the presence of magnesium ions. Evidence from in-vivo topoisomer distributions is presented which shows that under conditions of blocked protein synthesis the d(AT)n-d(AT)n insert will spontaneously adopt the cruciform state in-vivo in E. coli.