Reaction of nucleic acids with cis-diamminedichloroplatinum(II): interstrand cross-links

In the reaction of cis-diamminedichloroplatinum(II) (cis-DDP) with double-helical (dC-dG)4.(dC-dG)4 or (dC-dG)5.(dC-dG)5, intrastrand and interstrand cross-links between two guanine residues are formed. This is shown by gel electrophoresis in denaturing conditions of the reaction products and by high-performance liquid chromatography (HPLC) analysis of the products digested with nuclease P1. In the reaction of cis-DDP and poly(dG-dC).poly(dG-dC), at relatively low levels of platination, it is mainly interstrand cross-links between two guanine residues that are formed. This is shown by HPLC analysis of the nuclease P1 digest and by gel electrophoresis in denaturing and nondenaturing conditions of the platinated polymer after cleavage with the restriction enzyme HhaI. Moreover, the antibodies to platinated poly(dG-dC).poly(dG-dC) cross-react with the interstrand cross-linked (dC-dG)4 or (dC-dG)5 but not with the intrastrand cross-linked (dC-dG)4 or (dC-dG)5. These antibodies cross-react with platinated natural DNA. The amount of interstrand cross-links deduced from radioimmunoassays (0.5% of the total bound platinum) is lower than that (2%) deduced by gel electrophoresis in denaturing conditions of a platinated DNA restriction fragment. By gel electrophoresis, it is also shown that in vitro the isomer trans-DDP is more efficient in forming interstrand cross-links than cis-DDP.     

The formation of acetylaminofluorene adducts in poly(dC-dG) and poly(dA-dT) on reaction with N-acetoxy-2-acetylaminofluorene and the effect of such modification upon the polymers as templates for DNA polymerases

N-Acetoxy-2-acetylaminofluorene (AcO-AAF) reacts with the alternating DNA-like polynucleotides poly(dC-dG) and poly(dA-dT) in vitro to give adducts of the guanine and adenine bases similar to those reported to be formed in DNA. A previously unobserved guanine adduct was detected in the poly(dC-dG). Using a double-labelled [U-14C-dG, 8-3H-G]-poly(dC-dG) we show that this adduct does not involve the 7- or 8-positions of the guanine. Similarly a thymine adduct of unknown structure was observed in poly(dA-dT). Modification of the polymers with AcO-AAF inhibits their capacity to act as templates for Escherichia coli DNA polymerase I and mammalian DNA polymerase alpha although the binding of the polymerases to the polynucleotides is unaffected. Such modification also leads to an increase in the levels of non-complementary nucleotides incorporated into newly synthesised DNA.     

Amino acids as catalysts of the binding reaction of formaldehyde with adenine residue in polyadenylic acid

Binding of formaldehyde and amino acids (Gly, Lys and Leu) with poly(A), poly(G), and poly(C) has been investigated in comparison with treatment with formaldehyde alone. It was found that in the case of poly(A) amino acids were found to catalyze the N-hydroxymethylation reaction on exocyclic amino groups of adenine. For example, at 20 degrees C and pH 6.0 the rate of this reaction increased about 10 fold in the presence of glycine.     

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.     

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.     

Alternative conformations of DNA modified by N-2-acetylaminofluorene

Modification of DNA by the carcinogen N-acetoxy-N-2-acetylaminofluorene gives two adducts, a major one at the C-8 position of guanine and a minor one at the N-2 position with differing conformations. Binding at the C-8 position results in a large distortion of the DNA helix referred to as the “base displacement model” with the carcinogen inserted into the DNA helix and the guanosine displaced to the outside. The result is increased susceptibility to nuclease S, digestion due to the presence of large, single-stranded regions in the modified DNA. In contrast, the N-2 adduct results in much less distortion of the helix and is less susceptible to nuclease S₁ digestion. A third and predominant adduct is formed in vivo, the deacetylated C-8 guanine adduct. The conformation of this adduct has been investigated using the dimer dApdG as a model for DNA. The attachment of aminofluorene (AF) residues introduced smaller changes in the circular dichroism (CD) spectra of dApdG than binding of acetylaminofluorene (AAF) residues. Similarly, binding of AF residues caused lower upfield shifts for the H-2 and H-8 protons of adenine than the AAF residues. These results suggest that AF residues are less stacked with neighboring bases than AAF and induce less distortion in conformation of the modified regions than AAF. An alternative conformation of AAF-modified deoxyguanosine has been suggested based on studies of poly(dG-dC)·poly(dG-dC). Modification of this copolymer with AAF to an extent of 28% showed a CD spectrum that had the characteristics of the left-handed Z conformation seen in unmodified poly-(dG-dC)·poly(dG-dC) at high ethanol or salt concentrations. Poly(dG)·poly(dC), which docs not undergo the B to Z transition at high ethanol concentrations, did not show this type of conformational change with high AAF modification. Differences in conformation were suggested by single-strand specific nuclease S₁ digestion and reactivity with anticytidine antibodies. Highly modified poly(dG-dC)·poly(dG-dC) was almost completely resistant to nuclease S₁ hydrolysis, while, modified DNA and poly(dG)·poly(dC) are highly susceptible to digestion. Two possible conformations for deoxyguanosine modified at the C-8 position by AAF are compared depending on whether its position is in alternating purine-pyrimidine sequences or random sequence DNA.     

Base and conformational specificity of an amine modification of DNA

We have investigated the site and conformational preference of the reaction of a formaldehyde/amine reagent with DNA. Previous investigations of this laboratory have established that this reagent will react with native DNA, placing a positively charged amine moiety on the duplex that will survive exhaustive dialysis. The resulting adduct is duplex and base stacked in character, possessing B backbone geometry with a higher average winding angle and exhibiting remarkable stability with respect to the A-form, Z-form, or the single-strand denaturated species. In this current investigation, we have found that the stability of the adduct is dramatically reduced if the DNA is converted to mononucleotides, thus obviating the usual approach of nuclease digestion and chromatography for the identification of the modified nucleotides. Using indirect approaches, we have established that the reactive site that survives removal of the equilibrium concentrations of CH2O and amine is the exocyclic amino group of the guanine bases. This conclusion is based on (1) the positive correlation between GC content and the extent of adduct formation under standard reaction conditions (27 degrees C, 0.63M CH2O, 0.007M n-butylamine, pH 7); (2) decreases in the level of substitution of amine in DNA, which has this site blocked by trinitrobenzene modification; and (3) failure of poly(dI-dC) to retain amine upon dialysis. Raman spectra of the derivatized poly(dG-dC) show enhanced 2'-endo B character, with no marked shifts in the position of any of the lines, indicating the absence of any ring structures involving the N7 and the 06 of G. In standard reaction mixtures, other sites may react but this phenomenon appears to be minimal under conditions that do not favor fluctuational opening of base pairs. In the latter case, excess loading of amine on high GC content polymers produces a CD spectrum that is similar to one produced by poly(dA-dT) in the "X"-form [M. Vorlickova, E. Minyat, and J. Kypr (1984) Biopolymers 23, 1-4]. This conformation is lost, however, upon removal of excess reagents by dialysis and cannot be reestablished, in the absence of unbound amine and formaldehyde. The reaction is specific for the B-form of polynucleotides as demonstrated by the failure of poly(dG-m5dC) in the stable Z-form to exhibit substantial reaction. The B-form of this polymer will react readily with the retention of 0.23 moles amine/mole nucleotide under our standard reaction conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Modification of deoxyribonucleic acid by a diol epoxide of benzo[a]pyrene. Relation to deoxyribonucleic acid structure and conformation and effects on transfectional activity.

The effects of secondary structure on DNA modification by (+/-)-7 beta, 9 alpha-dihydroxy-9 alpha, 10 alpha-epoxy-7,8,9,10-tetrahydrobenzol[a]pyrene [(+/-)BPDE I] were investigated. No differences in the total extent of (+/-) BPDE I binding to double- and single-stranded calf thymus DNA were found. High-performance liquid chromatography (LC) of the nucleoside adducts obtained from hydrolysates of native and denatured calf thymus, as well as from superhelical and linear plasmid DNA, indicated that in all cases the major adduct (60--80% of total adducts) was formed by reaction of the (+) enantiomer of BPDE I with the N-2 position of dG residues in the DNA. A minor adduct formed from the reaction of the (-) enantiomer with dG residues was also detected and was present in greater amounts in denautred DNA than in native DNA. Small amounts of BPDE I--dA and BPDE I--dC adducts were also detected in both the single- and double-stranded DNAs. Restriction enzyme analysis of BPDE I modified SV40 and phage lambda DNA provided evidence that the modification of DNA by this carcinogen is fairly random with respect to nucleotide sequence. Partial hydrolysis of modified plasmid DNA by the single-strand-specific S1 nuclease and LC analysis of the nucleoside adducts in the digested and undigested fractions of the DNA revealed no preferential excision by the S1 nuclease of the different BPDE I--deoxynucleoside adducts. Functional changes in BPDE I modified DNA were demonstrated. With increasing extents of modification, there was a decrease in the ability of plasmid DNA to transfect a receptive Escherichia coli strain to antibiotic resistance.     

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.     

DNA binding mediated by the wheat HMGa protein: a novel instance of selectivity against alternating GC sequence

The high-mobility-group (HMG) chromosomal protein wheat HMGa was purified to homogeneity and tested for its binding characteristics to double-stranded DNA. Wheat HMGa was able to bind to P268, an A/T-rich fragment derived from the pea plastocyanin gene promoter, producing a small mobility shift in gel retardation assays where the bound complex was sensitive to addition of proteinase K but resistant to heat treatment of the protein, consistent with the identity of wheat HMGa as a putative HMG-I/Y protein. Gel retardation assays and southwestern hybridization analysis revealed that wheat HMGa could selectively interact with the DNA polynucleotides poly(dA).poly(dT), poly(dAdT).poly(dAdT), and poly(dG).poly(dC), but not with poly(dGdC).poly(dGdC). Surface plasmon resonance analysis determined the kinetic and affinity constants of sensor chip-immobilized wheat HMGa for double-stranded DNA 10-mers, revealing a good affinity of the protein for various dinucleotide combinations, except that of alternating GC sequence. Thus contrary to prior reports of a selectivity of wheat HMGa for A/T-rich DNA, the protein appears to be able to interact with sequences containing guanine and cytosine residues as well, except where G/C residues alternate directly in the primary sequence.     

Substrate specificity and mode of action of the zinc-metallo nuclease from Physarum polycephalum

The alkaline zinc-metallo nuclease of Physarum polycephalum is an endonuclease with a high specificity for single-stranded nucleic acids. Single-stranded DNA was cleaved at least 6,000 times faster than double-stranded DNA under identical conditions. In the supercoil-induced single-stranded region of Form I PM2 DNA only a single nick was made. The nuclease showed nucleotide specificity. Poly(A), poly(I), and poly(dT) were preferentially hydrolyzed. Product analysis showed that it acted by an endonucleolytic mechanism: long polynucleotides were fragmented via intermediate length products to oligo- and mono-nucleotides with the phosphate group at the 5'-terminal position. Extensive similarities exist with the single-strand-specific nuclease S1 from Aspergillus. The zinc-metallo endonuclease from Physarum could be used as a similar probe for single-stranded nucleic acids at neutral or alkaline pH conditions.     

Site-specific chemical modification of B-Z junctions in supercoiled DNA as detected by nuclease S1 digestion, inhibition of restriction cleavage and nucleotide sequencing

Structural distortions on the boundary between right-handed and left-handed segments in the superhelical plasmid pPK2 (a derivative of pUC19 containing (dC-dG)n segments cloned into polylinker) were studied by means of chemical probes. Strong osmium tetroxide, pyridine (Os,py) modification of DNA at native superhelical density (sigma) was found in four thymines surrounding the (dC-dG)13 segment. These results correlated with restriction cleavage inhibition (due to modification): BamHI cleavage was strongly inhibited, unlike the neighbouring XbaI and SalI (weak or no inhibition). In the (dC-dG)8 segment considerably weaker modification of the B-Z junctions was observed, accompanied by weak inhibition of BamHI cleavage, while the neighbouring SmaI and KpnI were not affected. Os,py modification of DNA at native sigma was not detected by nuclease S1 cleavage at and (dC-dG)n segment. However, this enzyme recognized and cleaved at the B-Z junction, osmium modified at more negative sigma. The results obtained with the glyoxal and diethyl pyrocarbonate modification support the idea of very narrow B-Z junctions at native sigma.     

Specific limited cleavage of bihelical deoxyribonucleic acid by wheat seedling nuclease.

Wheat seedling nuclease catalyzes the hydrolysis of intact, bihelical viral DNA or high molecular weight, native Escherichia coli DNA to produce limit polymers which are resistant to further hydrolysis by additional enzyme. These limit products are double-stranded polymers free of single strand interruptions and are terminated at their 5' ends with equal amounts of either deoxycytidylate or deoxyguanylate residues. The average size of the duplex limit products, as determined by (a) alkaline and neutral sucrose gradient sedimentation, (b) viscometric determination of molecular weight, and (c) 5'-end labeling, varies from 2 to 4 times 10-6 depending on the source of the DNA. The involvement of regions rich in adenine-thymine base pairs at the sites of cleavage of the DNA molecule is suggested by the following experimental results: (a) the copolymeric duplex, poly(dA-dt) is hydrolyzed at a rate comparable to that found for denatured calf thymus DNA, a rate which is several orders of magnitude faster than that at which native calf thymus DNA is hydrolyzed; (b) lambda DNA, which contains an adenine-thymine-rich region near its center, is rapidly cleaved to yield two fragments of similar size; (c) the rate of hydrolysis of native DNA is increased approximately 14-fold by increasing the reaction temperature from 20 degrees to 30 degrees.     

Effect of alkylation with N-methyl-N-nitrosourea and N-ethyl-N-nitrosourea on the secondary structure of DNA

We have earlier reported that alkylation of DNA by the chemical carcinogen dimethyl sulphate, which mainly alkylates N-7 of guanine and N-3 of adenine, causes the formation of partially denatured regions in double-stranded DNA (Rizvi RY, Alvi NK & Hadi SM, Biosci. Rep. 2, 315-322, 1982). It is known that the major site of alkylation in DNA by N-ethyl-N-nitrosourea (EtNu) are the phosphate groups. N-methyl-N-nitrosourea (MeNu), on the other hand, causes the alkylation of mainly guanine residues. We have therefore studied the effect of these two alkylating carcinogens on the secondary structure of DNA. DNA alkylated with increasing concentrations of EtNu and MeNu was subjected to alkaline and S1 nuclease hydrolysis. Thermal melting profiles of alkylated DNA were also determined using S1 nuclease. The results indicated that alkylation by the two alkylating agents had a differential effect on the secondary structure of DNA. EtNu-alkylated DNA was found to be more thermostable than native DNA at neutral pH. It was however more alkali-labile than MeNu-alkylated DNA. The greater stability of EtNu-alkylated DNA was considered to be due to abolition of negative charges on phosphate alkylation.     

A single nuclease active site of the Escherichia coli RecBCD enzyme catalyzes single-stranded DNA degradation in both directions

The RecBCD enzyme of Escherichia coli is an ATP-dependent DNA exonuclease and a helicase. Its exonuclease activity is subject to regulation by an octameric nucleotide sequence called chi. In this study, site-directed mutations were made in the carboxyl-terminal nuclease domain of the RecB subunit, and their effects on RecBCD's enzymatic activities were investigated. Mutation of two amino acid residues, Asp(1067) and Lys(1082), abolished nuclease activity on both single- and double-stranded DNA. Together with Asp(1080), these residues compose a motif that is similar to one shown to form the active site of several restriction endonucleases. The nuclease reactions catalyzed by the RecBCD enzyme should therefore follow the same mechanism as these restriction endonucleases. Furthermore, the mutant enzymes were unable to produce chi-specific fragments that are thought to result from the 3'-5' and 5'-3' single-stranded exonuclease activities of the enzyme during its reaction with chi-containing double-stranded DNA. The results show that the nuclease active site in the RecB C-terminal 30-kDa domain is the universal nuclease active site of RecBCD that is responsible for DNA degradation in both directions during the reaction with double-stranded DNA. A novel explanation for the observed nuclease polarity switch and RecBCD-DNA interaction is offered.     

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.     

Sequence dependence of conformations of self-complementary duplex tetradeoxynucleotides containing cytosine and guanine

The four self-complementary tetradeoxynucleotides which contain only cytosine and guanine are 5'-d-(CpGpCpG)-3', 5'-d(CpCpGpG)-3', 5'-d(GpCpGpC)-3', and 5'-d(GpGpCpC)-3'. The Raman spectra of aqueous solutions (about 0.05 M in monomer) of these tetranucleotides at pH 7 and 2 degrees C show clearly that these self-complementary tetranucleotides form double-stranded duplex structures of the canonical B type when the NaCl concentration is 0.5 M NaCl. If the temperature is raised to 50 degrees C, the Raman spectra show that in each case the double-helical B form melts in a non-cooperative way to a disordered single-chain form. On the other hand, if the salt concentration is raised to saturation, the Raman spectrum of only one of these four tetranucleotide solutions at 2 degrees C is changed in any substantial way. The Raman spectrum of the tetranucleotide 5'-d(CpGpCpG)-3' at 2.2 degrees C and at 4 M or higher salt concentration strongly resembles that of double-helical Z-form poly(dC-dG) taken under similar conditions. We conclude that the tetramer 5'-d(CpGpCpG)-3' is the only self-complementary double-helical tetranucleotide containing only cytosine and guanine in which the B-Z transition can be induced by increasing the salt concentration. This tetramer has several types of stacking interactions which differ markedly from stacking interactions in the other tetramers and may account for the enhanced stabilization of its Z conformation.     

Incision at nucleotide insertions/deletions and base pair mismatches by the SP nuclease of spinach

Spinach leaves contain a highly active nuclease called SP. The purified enzyme incises single-stranded DNA, RNA, and double-stranded DNA that has been destabilized by A-T-rich regions and DNA lesions [Strickland et al. (1991) Biochemistry 30, 9749-9756]. This broad range of activity has suggested that SP may be similar to a family of nucleases represented by S1, P1, and the mung bean nuclease. However, unlike these single-stranded nucleases that require acidic pH and low ionic strength conditions, SP has a neutral pH optimum and is active over a wide range of salt concentrations. We have extended these findings and showed that an outstanding substrate for SP is a mismatched DNA duplex. For base-substitution mismatches, SP incises at all mismatches except those containing a guanine residue. SP also cuts at insertion/deletions of one or more nucleotides. Where the extrahelical DNA loop contains one nucleotide, the preference of extrahelical nucleotide is A > T approximately C but undetectable at G. The inability of SP to cut at guanine residues and the favoring of A-T-rich regions distinguish SP from the CEL I family of neutral pH mismatch endonucleases recently discovered in celery and other plants [Oleykowski et al. (1998) Nucleic Acids Res. 26, 4597-4602]. SP, like CEL I, does not turn over after incision at a mismatched site in vitro. Similar to CEL I, the presence of a DNA polymerase or a DNA ligase allows SP to turn over and stimulate its activity in vitro by about 20-fold. The possibility that the SP nuclease may be a natural variant of the CEL I family of mismatch endonucleases is discussed.     

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.