Methylation of cytosine in the 5-position alters the structural and energetic properties of the supercoil-induced Z-helix and of B-Z junctions

The structural and energetic consequences of cytosine methylation in the 5-position on the supercoil-dependent B-Z equilibrium in alternating dC-dG sequences cloned into recombinant plasmids were investigated. The helical parameters determined with the band shift method for right-handed [10.7 base pairs (bp)/turn] and left-handed (12.8 bp/turn) 5MedC-dG inserts were different from the helical repeat values for unmethylated dC-dG inserts (10.5 bp/turn in the right-handed and 11.5 bp/turn in the left-handed form). We analyzed the thermodynamic parameters delta GBZ (free energy difference per base pair between right-handed and left-handed helix structure), delta Gjx (free energy for formation of one B-Z junction), and b (helix unwinding at a junction region) for varying lengths of dC-dG inserts by two-dimensional gel electrophoresis and application of a statistical mechanics model. A comparison of plasmids fully methylated in vitro with HhaI methylase and their unmethylated counterparts revealed that delta Gjx is not significantly changed by cytosine methylation. However, this base modification results in an approximate 3-fold decrease of delta GBZ and an approximate 2-fold decrease of the unwinding b at B-Z junction regions. Analysis of a pair of related plasmids, each containing two dC-dG blocks, revealed qualitatively different transition behaviors. When the two dC-dG blocks were separated by 95 bp of a mixed sequence, they underwent independent B to Z transitions with separate nucleation events and junction formations. When the two blocks were separated by only a 4 bp GATC sequence, only one nucleation event was necessary, and the Z-helix spread across the nonalternating GATC region.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytosine methylation enhances Z-DNA formation in vivo.

The influence of cytosine methylation on the supercoil-stabilized B-Z equilibrium in Escherichia coli was analyzed by two independent assays. Both the M.EcoRI inhibition assay and the linking-number assay have been used previously to establish that dC-dG segments of sufficient lengths can exist as left-handed helices in vivo. A series of dC-dG plasmid inserts with Z-form potential, ranging in length from 14 to 74 base pairs, was investigated. Complete methylation of cytosine at all HhaI sites, including the inserts, was obtained by coexpression of the HhaI methyltransferase (M.HhaI) in cells also carrying a dC-dG-containing plasmid. Both assays showed that for all lengths of dC-dG inserts, the relative amounts of B and Z helices were shifted to more Z-DNA in the presence of M.HhaI than in the absence of M.HhaI. These results indicate that cytosine methylation enhances the formation of Z-DNA helices at the superhelix density present in E. coli. The B-Z equilibrium, in combination with site-specific base methylation, may constitute a concerted mechanism for the modulation of DNA topology and DNA-protein interactions.     

Recognition of the structural distortions at the junctions between B and Z segments in negatively supercoiled DNA by osmium tetroxide

It has been shown for the first time that conformational junction between contiguous right-handed B and left-handed Z segments can be recognized by a chemical probe. Plasmid pRW751 containing (dC-dG)13 and (dC-dG)16 blocks was treated with osmium tetroxide, pyridine (a reagent known to be single-strand selective) at physiological ionic conditions (0.1 and 0.2 M NaCl) and neutral pH. Mapping of the osmium binding sites by restriction enzyme digestion followed by nuclease S1 cleavage has revealed selective binding of osmium at, or near to, the end of the (dC-dG)n segments proximal to the 95 bp lac sequence. The junction of the shorter (dC-dG)13 segment was modified to a substantially greater extent than that of the longer segment. Partial inhibition of DNA cleavage by BamHI was observed at the restriction sites neighbouring to the both (dC-dG)n segments as a result of DNA modification by osmium tetroxide. The site-selective modification occurred only in supercoiled and not in relaxed molecules. Differences in the sensitivity of the B/Z junctions in pRW751 to the osmium tetroxide were explained by different structural features of these junctions.     

Inhibition of restriction endonuclease cleavage due to site-specific chemical modification of the B-Z junction in supercoiled DNA

Structural distortions on the boundary between right-handed B and left-handed Z DNA segments in plasmid pRW751 (a derivative of pBR322 containing (dC-dG)13 and (dC-dG)16 segments) were studied by means of chemical probes. Samples of supercoiled DNA were treated with the respective chemical probe, linearized with EcoRI and inhibition of BamHI (whose recognition sequence GGATCC lies on the boundary between the (dC-dG)n segments and the pBR322 nucleotide sequence) cleavage was tested. Treatment with osmium tetroxide in the presence of pyridine or 2,2'-bipyridine, respectively, resulted in a strong inhibition of the BamHI cleavage at both restriction sites, provided the (dC-dG)n segments were in the left-handed form. In the presence of 2,2'-bipyridine submillimolar concentrations of OsO4 (at 26 degrees C) were sufficient to induce the inhibition of BamHI. Chloroacetaldehyde was used as a probe reacting selectively with atoms involved in the Watson-Crick hydrogen bonding. Similarly as in the case of osmium tetroxide treatment of pRW751 with this agent resulted in the inhibition of BamHI cleavage. It was concluded that the B-Z junction regions in pRW751 contain few solitary bases with disturbed hydrogen bonding or non-Watson-Crick base pairs.     

Thermodynamic parameters are sequence-dependent for the supercoil-induced B to Z transition in recombinant plasmids

The entropy and enthalpy changes which contribute to the thermodynamics of the B to Z transition were determined for three recombinant plasmids containing a (dC-dG)16 tract and for a plasmid containing a pair of (dT-dG)20 regions. For each base pair which adopts a left-handed conformation in the plasmids with (dC-dG)16 sequences, the delta HBZ and delta SBZ are -2.1 kcal/mol bp and -8.8 cal/K-mol bp, respectively. In the plasmid containing the (dT-dG)20 tracts, however, the delta HBZ and delta SBZ values are 0.58 kcal/mol bp and -0.76 cal/K-mol bp, respectively. Also, these determinations show that for each B-Z junction that forms in the plasmids containing the (dC-dG), the enthalpy and entropy changes are 24 kcal/mol junction and 65 cal/K-mol junction, whereas for the (dT-dG) plasmid, the enthalpy and entropy changes are -1.8 kcal/mol junction and -22 cal/K-mol junction, respectively. Those values for the enthalpy and entropy changes for the formation of a BZ junction in (dC-dG) and (dT-dG) plasmids suggest that the properties and possibly the structures of the junctions are different. Calculations using the enthalpy and entropy changes determined in this study reveal that the B to Z transition in plasmids containing (dC-dG) blocks are more temperature-dependent than the transitions in plasmids with (dT-dG) blocks. Surprisingly, at temperatures above 60 degrees C, calculations indicate that the B to Z transitions in (dT-dG) plasmids should be energetically favored over that transition in (dC-dG) plasmids.     

Osmium tetroxide recognized structural distortions at junctions between right- and left-handed DNA in a bacterial cell

It was shown for the first time that the structural distortions at the junctions between contiguous right-handed and left-handed Z-DNA segments can be recognized in bacterial cells. E. coli containing recombinant plasmid pPK1 (a derivative of pUC19 containing (dC-dG)13 and (dC-dG)16 blocks) were treated with osmium tetroxide, 2.2'-bipyridine (Os,bipy); after this treatment pPK1 DNA was isolated by the boiling method. pPK1 DNA was then cleaved with BglI, and inhibition of BamHI (with its recognition sequence GGATCC lying on the boundary between the (dC-dG)n segments and the pUC19 nucleotide sequence) cleavage was tested. Treatment of cells with 2 mmol/l Os,bipy resulted in a strong inhibition of BamHI cleavage at both restriction sites showing a site-specific osmium modification at the B--Z junction. About the same inhibition of BamHI cleavage was observed after treatment of isolated pPK1 DNA with 0.2 mmol/l Os,bipy.     

B-Z junctions in supercoiled pRW751 DNA contain unpaired bases or non-Watson-Crick base pairs

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 S1 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 S1 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.     

Recognition of the Structural Distortions at the Junctions Between B and Z Segments in Negatively Supercoiled DNA by Osmium Tetroxide

Abstract

It has been shown for the first time that conformational junction between contiguous right- handed B and left-handed Z segments can be recognized by a chemical probe. Plasmid pRW751 containing (dC-dG)₁₃ and (dC-dG)₁₆ blocks was treated with osmium tetroxide, pyridine (a reagent known to be single-strand selective) at physiological ionic conditions (0.1 and 0.2 M NaCl) and neutral pH. Mapping of the osmium binding sites by restriction enzyme digestion followed by nuclease SI cleavage has revealed selective binding of osmium at, or near to, the end of the (dC-dG)_n segments proximal to the 95 bp lac sequence. The junction of the shorter (dC-dG)₁₃ segment was modified to a substantially greater extent than that of the longer segment. Partial inhibition of DNA cleavage by BamHI was observed at the restriction sites neighbouring to the both (dC-dG)_n segments as a result of DNA modification by osmium tetroxide. The site-selective modification occurred only in supercoiled and not in relaxed molecules. Differences in the sensitivity of the B/Z junctions in pRW751 to the osmium tetroxide were explained by different structural features of these junctions.     

Probing of B-Z junctions in recombinant plasmids in vitro and in the cell with different osmium tetroxide complexes

Complexes of OsO4 with 2,2'-bipyridine (Os,2,2'-bipy),4,4'-bipyridine (Os,4,4'-bipy), 1,10-phenanthroline (Os,phe), bathophenanthroline disulfonic acid (Os,bpds) and OsO4, pyridine reagent (Os,py) were used to probe structural distortions at the junctions between right-handed B and left-handed Z DNA in supercoiled plasmids pRW751 and pPK1 (both containing (dC-dG)13 and (dC-dG)16 segments). With all five complexes the site-specific modification at the B-Z junctions was detected in vitro but only Os,2,2'-bipy and Os,bpds produced strong site specific modification at submillimolar concentrations. In addition to the B-Z junctions. Os,phe also reacted at other sites. With the exception of Os,2,2'-bipy no one of the tested OsO4 complexes has proved to be suitable for probing structural distortions at the B-Z junctions in E. coli cells.     

Left-handed Z-DNA helices in polymers, restriction fragments, and recombinant plasmids

Studies on DNA polymers, restriction fragments, and recombinant plasmids have revealed the following: A) A family of left-handed DNA conformations exists for (dC-dG)n.(dC-dG)n. The observation of a particular conformation is dependent on the salt, the salt concentration and dehydrating agent. B) In sodium acetate solutions, (dC-dG)n.(dC-dG)n forms left-handed, psi(+)-condensed structures as detected by Raman spectroscopy and circular dichroism. C) (dT-dG)n.(dC-dA)n undergoes a right-to-left-handed transition only when reacted with AAF and at high salt concentrations. D) Transitions observed for polymer DNAs also are observed for restriction fragments containing both (dC-dG).(dC-dG) and (dT-dG).(dC-dA) sequences, but the transitions in the fragments generally require higher salt concentrations than observed for the polymers. E) Studies with recombinant plasmids containing (dC-dG) sequences from 10 to 58 bp in length demonstrate that left-handed Z-DNA segments can exist contiguous to B-DNA segments. F) Negative supercoil density (sigma less than or equal to -0.072) is sufficient to convert the (dC-dG) regions in those plasmids into left-handed structures under physiological ionic conditions (200 mM NaCl). G) The favorable free energy contribution of methylation in stabilizing the Z form in fragments and plasmids is approximately offset by the unfavorable free energy contributions of the B/Z junctions. H) Sl and BAL 31 nucleases recognize aberrant structural features at the confluence of the B and Z regions. I) Detailed mapping of Sl nuclease cleavage on supercoiled plasmids shows that the nuclease sensitive regions extend over at least five to ten bp. J) Even though the (dT-dG)n.(dC-dA)n polymer requires base modification and high salt conditions to undergo the R----L transition, supercoiling (sigma less than or equal to -0.07) can supply enough energy to allow a plasmid containing the intervening sequence of a human fetal globin gene with (dT-dG).(dC-dA) sequences to undergo a R----L transition.     

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.     

Energetic and structural inter-relationship between DNA supercoiling and the right- to left-handed Z helix transitions in recombinant plasmids

We have evaluated the B to Z conformational transitions in supercoiled recombinant plasmids containing different lengths of (dC-dG) described in the preceding paper. The sodium chloride-induced right- to left-handed transition in a small segment of the plasmids caused a relaxation of (-) supercoils which was monitored by electrophoretic mobility changes of individual topoisomers on agarose gels containing NaCl at concentrations up to 5.0 M. The number of supercoils relaxed was proportional to the length of the (dC-dG) segment in the plasmid in good agreement with theoretical values. A short B/Z junction region (less than 5 base pairs) was inferred. The stability of the Z conformation in (dC-dG) segments of the plasmids had a strong length dependency; shorter lengths were less stable. Ten base pairs of (dC-dG) was insufficient to allow a Z conformation under the conditions studied. Supercoiling imparts a substantial favorable free energy to the Z conformation, reducing the NaCl concentration necessary to cause the transition. The relationship of supercoiling with the NaCl concentration necessary to cause a B leads to Z transition suggests that supercoiling alone is sufficient to stabilize the Z conformation at physiological salt concentrations. These results support the notion that left-handed DNA has an important biological role.     

BAL 31 nuclease as a probe in concentrated salt for the B-Z DNA junction

The BAL 31 nuclease, an extracellular nuclease from A. espejiana, specifically recognizes and cleaves the salt induced conformational junction between B and Z-DNA. Short segments of (dC-dG) left-handed Z-helix, comprising approximately 1% of the total DNA, are specifically detected within two different recombinant plasmids. The BAL 31 enzyme is highly resistant to inactivation by the presence of high concentrations of a variety of electrolytes that stabilize left-handed helices, is active at physiological pH, and can be used to probe both linear and circular DNAs. Additionally, the nuclease cleaves left-handed (dC-dG)n only very poorly, if at all. Thus, the BAL 31 nuclease can be utilized as a probe for helical junctions and consequently for segments of left-handed DNA that might exist within predominantly right-handed naturally occurring genomes.     

Effects of 5 cytosine methylation on the B-Z transition in DNA restriction fragments and recombinant plasmids

Alternating (dC-dG)n regions in DNA restriction fragments and recombinant plasmids were methylated at the 5 position of the cytosine residues by the HhaI methylase. Methylation lowers the concentration of NaCl or MgCl2 necessary to cause the B-Z conformational transition in these sequences. Ionic strengths higher than physiological conditions are required to form the Z conformation when the methylated (dC-dG)n tract is contiguous with regions that do not form Z structures, in contrast to the results with the DNA polymer poly(m5dC-dG) . poly(m5dC-dG). In supercoiled plasmids containing (dC-dG)n sequences, methylation reduces the number of negative supercoils necessary to stabilize the Z conformation. Calculations of the observed free energy contributions of the B-Z junction and cytosine methylation suggest that two junctions offset the favorable effect of methylation on the Z conformation in (dC-dG)n sequences (about 29 base-pairs in length). Studies with individual methylated topoisomers demonstrate that increasing Na+ concentration up to approximately 0.2 M inhibits the formation of the Z conformation in the (m5dC-dG)n region of supercoiled plasmids. The results suggest that methylation may serve as a triggering mechanism for Z DNA formation in supercoiled DNAs.     

Left-handed Z-DNA Helices in Polymers,Restriction Fragments,and Recombinant Plasmids

Abstract

Studies on DNA polymers, restriction fragments, and recombinant plasmids have revealed the following: A) A family of left-handed DNA conformations exists for (dC-dG)_n·(dC-dG)_n. The observation of a particular conformation is dependent on the salt, the salt concentration and dehydrating agent. B) In sodium acetate solutions, (dC-dG)_n·(dC-dG)_n forms left-handed, ψ(+)-condensed structures as detected by Raman spectroscopy and circular dichroism. C) (dT-dG)_n·(dC-dA)_n undergoes a right-to-left-handed transition only when reacted with AAF and at high salt concentrations. D) Transitions observed for polymer DNAs also are observed for restriction fragments containing both (dC-dG)·(dC-dG) and (dT-dG)·(dC-dA) sequences, but the transitions in the fragments generally require higher salt concentrations than observed for the polymers. E) Studies with recombinant plasmids containing (dC-dG) sequences from 10 to 58 bp in length demonstrate that left-handed Z-DNA segments can exist contiguous to B-DNA segments. F) Negative supercoil density (σ≤ ?0.072) is sufficient to convert the (dC-dG) regions in those plasmids into left-handed structures under physiological ionic conditions (200 mM NaCl). G) The favorable free energy contribution of methyla- tion in stabilizing the Z form in fragments and plasmids is approximately offset by the unfavorable free energy contributions of the B/Z junctions. H) S₁ and BAL 31 nucleases recognize aberrant structural features at the confluence of the B and Z regions. I) Detailed mapping of S₁ nuclease cleavage on supercoiled plasmids shows that the nuclease sensitive regions extend over at least five to ten bp. J) Even though the (dT-dG)_n·(dC-dA)_n polymer requires base modification and high salt conditions to undergo the R?L transition, supercoiling (σ ?0.07) can supply enough energy to allow a plasmid containing the intervening sequence of a human fetal globin gene with (dT-dG)·(dC-dA) sequences to undergo a R?L transition.     

The ultimate carcinogen of 4-nitroquinoline 1-oxide does not react with Z-DNA and hyperreacts with B-Z junctions.

DNA secondary and tertiary structures are known to affect the reaction between the double helix and several damaging agents. We have previously shown that the tertiary structure of DNA influences the reactivity of 4-acetoxyaminoquinoline 1-oxide (Ac-4-HAQO), the ultimate carcinogen of 4-nitroquinoline 1-oxide (4-NQO), being more reactive with naturally supercoiled DNA than with relaxed DNA. The relative proportion of the three main stable adducts and of an unstable adduct, that resulted in strand scission and/or AP sites, was also affected by the degree of supercoiling of plasmid DNA. In this study we examined the influence of Z-DNA structure on the reactivity of Ac-4-HAQO by mapping the distribution of the two main Ac-4-HAQO adducts, C8-guanine and N2-guanine, along a (dC-dG)16 sequence inserted at the BamHI site of pBR322 plasmid DNA. This insert adopted the left-handed Z and right-handed B structure depending on the superhelical density of the plasmid. Sites of C8-guanine adduct formation were determined by hot piperidine cleavage of Ac-4-HAQO modified DNA, while N2-guanine adducts were mapped by the arrest of the 3'-5' exonuclease activity of T4 DNA polymerase. The results showed that Ac-4-HAQO did not react with guanine residues when the (dC-dG)16 sequence was in Z conformation, while hyperreactivity at the B-Z junction was observed. These results indicate that Ac-4-HAQO can probe the polymorphism of DNA at the nucleotide level.     

DNA methylation diminishes bleomycin-mediated strand scission

Three DNA duplexes differing substantially in sequence were derived from pBR322 plasmid DNA and supercoiled SV40 DNA by digestion with appropriate restriction endonucleases. Following treatment with the restriction methylase HhaI (recognition sequence: GCGC) or HhaI and HpaII (CCGG), the unmethylated and methylated DNAs were compared as substrates for the antitumor agent bleomycin. Bleomycin-mediated strand scission was shown to diminish substantially at a number of sites in proximity to the methylated cytidine moieties, especially where multiple sites had been methylated within a DNA segment of limited size. Detailed analysis of the DNA substrates revealed that both strands of DNA within a methylated region became more refractory to cleavage by bleomycin and that the protective effect could extend as many as 14 base pairs in proximity to the 5-methylcytidine moieties. Among the methylated DNA segments that became more resistant to bleomycin cleavage was a HpaII site of SV40 DNA, methylation of which has previously been shown to diminish the synthesis of the major late viral capsid protein following microinjection into Xenopus laevis oocytes. Study of the cleavage reaction at varying salt levels suggested that diminished bleomycin strand scission may be due, at least in part, to local conformational changes of the DNA to Z form (or other non-B-form structures). The results are generally consistent with the hypothesis that one mechanism for the expression of selective therapeutic action by certain DNA damaging agents could involve the recognition of specific methylation patterns.     

Methylation of either cytosine in the recognition sequence CGCG inhibits ThaI cleavage of DNA.

ThaI (CGCG) sites which overlap HhaI (GCGC) sites in phi X174 and pBR322 DNA were methylated in vitro with HhaI methylase and S-adenosylmethionine to yield CGmCG, mCGCG or mCGmCG (5-methylcytosine, mC). Methylation of either cytosine in the ThaI recognition sequence rendered the DNA resistant to ThaI cleavage. Rat pituitary cell genomic DNA was digested with ThaI or 2 other known methylation-sensitive enzymes, AvaI or XhoI. After electrophoresis and ethidium bromide straining of the DNA, all 3 enzymes showed the infrequent DNA cleavage characteristic of methylation-sensitive enzymes. Comparison of pituitary growth hormone (GH) genes bearing strain-specific degrees of methylation showed the less methylated gene to be more frequently cut by either AvaI or ThaI. ThaI resistant sites in GH genes were cleaved by ThaI after exposing cells to 5-azacytidine, an inhibitor of DNA methylation. We conclude that ThaI is a useful restriction enzyme for the analysis of mC at CGCG sequences in eukaryotic DNA.     

Elsamicin A can convert the Z-form of poly[d(G-C)] and poly[(G-m5C)] back to B-form DNA.

The interaction of poly[(G-C)] and poly[d(G-m5C)] with the antitumor antibiotic elsamicin A, which binds to alternating guanine + cytosine tracts in DNA, has been studied under the B and Z conformations. Both the rate and the extent of the B-to-Z transition are diminished by the antibiotic, as inferred by spectroscopic methods under ionic conditions that otherwise favor the left-handed conformation of the polynucleotides. Moreover, elsamicin converts the Z-form DNA back to the B-form. The circular dichroism data indicate that elsamicin binds to poly[d(G-C)] and poly[d(G-m5C)] to form a right-handed bound elsamicin region(s). The transition can be followed by changes of the molar ellipticity at 250 nm, thus providing a convenient wavelength to monitor the Z-to-B conformational change of the polymers as elsamicin is added. The elsamicin A effect might be explained by a model in which the antibiotic binds preferently to a B-form DNA, playing a role as an allosteric effector on the equilibrium between the B and Z conformations, thus favoring the right-handed one.