DNA interaction with the antitumor agent thiophosphamide

DNA interaction with an alkylating antitumor drug N,N',N"-triethylenethiophosphoramide (thiotepa) in water-salt solutions at 37 degrees C has been studied by UV-spectroscopy, heat denaturation and electron microscopy methods. Changes of the DNA melting curve parameters provide information on the kinetics of alkylation. The dependence of the alkylation rate on DNA and thiotepa concentrations shows that the alkylation reaction is biomolecular. The increase of sodium chloride concentration from 10(-3) to 10(-1) M is accompanied by a drastic decrease of the alkylation rate. Thiotepa binding results in destabilization of the DNA secondary structure and formation of cross-links. An increased amount of bounded thiotepa results in DNA denaturation; prolonged alkylation causes breaks in the sugar-phosphate backbone. The results of the work are discussed in connection with the literature data on DNA interaction with thiotepa in vivo.     

Uranyl photofootprinting of triple helical DNA.

Two triple helix structures (15-mers containing only T.A-T triplets or containing mixed T.A-T and C.G-C triplets) have been studied by uranyl mediated DNA photocleavage to probe the accessibility of the phosphates of the DNA backbone. Whereas the phosphates of the pyrimidine strand are at least as accessible as in double stranded DNA, in the phosphates of the purine strand are partly shielded and more so at the 5'-end of the strand. With the homo A/T target increased cleavage is observed towards the 3'-end on the pyrimidine strand. These results show that the third strand is asymmetrically positioned along the groove with the tightest triple strand double strand interactions at the 5'-end of the third strand. The results also indicate that homo-A versus mixed A/G 'Hoogsteen-triple helices' have different structures.     

DNA determinants important in sequence recognition by Eco RI endonuclease

Alkylation interference and protection methods (Siebenlist, U., and Gilbert, W., (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 122-126) have been utilized to deduce potential DNA contacts involved in specific complex formation between Eco RI endonuclease and its recognition sequence. The endonuclease protected the N7 position (major groove) of the dG and the N3 position (minor groove) of both dA residues within the Eco RI sequence against alkylation by dimethylsulfate, d(GpApApTpTpC), suggesting the presence of poly-peptide in both grooves in the vicinity of affected nitrogens. Results of methylation interference analysis suggest that the N7 of the Eco RI site dG and the N3 of the central dA, d(GpApApTpTpC), are utilized as contacts by the enzyme. The failure to observe interference upon methylation of the 5'-penultimate dA within the sequence implies that the endonuclease does not bond to the N3 of this residue, despite the fact that it is protected against alkylation by the protein. Ethylation interference patterns suggest four major phosphate contacts between endonuclease and each DNA strand. Two of these phosphates are 5'-external to the Eco RI sequence, d(pNpGpApApTpTpC), suggesting involvement of outside phosphates in electrostatic interactions. Moreover, alkylation protection and interference effects on the two DNA strands display perfect 2-fold symmetry. Thus, the endonuclease interacts with a minimum of 10 nucleotide pairs to yield a DNA-protein complex characterized by elements of symmetry. In contrast, specific alkylation effects were not observed in comparable experiments with the endonuclease and a DNA which had been previously methylated by the Eco RI modification enzyme.     

Concerted bis-alkylating reactivity of clerocidin towards unpaired cytosine residues in DNA

Clerocidin (CL) is a topoisomerase II poison, which cleaves DNA irreversibly at guanines (G) and reversibly at cytosines (C). Furthermore, the drug can induce enzyme-independent strand breaks at the G and C level. It has been previously shown that G-damage is induced by alkylation of the guanine N7, followed by spontaneous depurination and nucleic acid cleavage, whereas scission at C is obtained only after treatment with hot alkali, and no information is available to explain the nature of this damage. We present here a systematic study on the reactivity of CL towards C both in the DNA environment and in solution. Selected synthetic derivatives were employed to evaluate the role of each chemical group of the drug. The structure of CL–dC adduct was then characterized by tandem mass spectrometry and NMR: the adduct is a stable condensed ring system resulting from a concerted electrophilic attack of the adjacent carbonyl and epoxide groups of CL towards the exposed NH₂ and N3, respectively. This reaction mechanism, shown here for the first time, is characterized by faster kinetic rates than alkylation at G, due to the fact that the rate-determining step, alkylation at the epoxide, is an intramolecular process, provided a Schiff base linking CL and C can rapidly form, whereas the corresponding reaction of G N7 is intermolecular. These results provide helpful hints to explain the reversible/irreversible nature of topoisomerase II mediated DNA damage produced by CL at C/G steps.     

Kinetics and thermodynamics of BI-BII interconversion altered by T:G mismatches in DNA

T:G mismatches in DNA result in humans primarily from deamination of methylated CpG sites. They are repaired by redundant systems, such as thymine DNA glycosylase (TDG) and methyl-binding domain enzyme (MBD4), and maintenance of these sites has been implicated in epigenetic processes. The process by which these enzymes identify a canonical DNA base in the incorrect basepairing context remains a mystery. However, the conserved contacts of the repair enzymes with the DNA backbone suggests a role for protein-phosphate interaction in the recognition and repair processes. We have used ³¹P NMR to investigate the energetics of DNA backbone BI-BII interconversion, and for this work have focused on alterations to the activation barriers to interconversion and the effect of a mismatch compared with canonical DNA. We have found that alterations to the ΔG of interconversion for T:G basepairs are remarkably similar to U:G basepairs in the form of stepwise differences in ΔG of 1–2 kcal/mol greater than equivalent steps in unmodified DNA, suggesting a universality of this result for TDG substrates. Likewise, we see perturbations to the free energy (～1 kcal/mol) and enthalpy (2–5 kcal/mol) of activation for the BI-BII interconversion localized to the phosphates flanking the mismatch. Overall our results strongly suggest that the perturbed backbone energetics in T:G basepairs play a significant role in the recognition process of DNA repair enzymes.     

Computer aided study of the interaction of thyroid hormone receptor with DNA.

Interaction of the first zinc finger from human thyroid hormone receptor (finger) with hexanucleotide duplex d(AGGTCA).d(TGACCT) from thyroid regulatory element has been studied by molecular mechanics simulation technique. The structure of the finger as well as its complex with DNA is optimized using constrain of tetrahedral coordination of the zinc ion to Cys sulphurs. The finger is stabilized by series of H--bonds (5 in backbone, 2 in side chains and 2 between backbone and side chains). The complex is stabilized by H-bonds between side chains of Tyr 11, His 12, Tyr 13 and Arg 14 with G2, G3 and G8. DNA is in B form. H--bonding network within DNA is preserved. Opposite strand P-P and Cl'-Cl' distances are changed slightly. There is a systematic change in the backbone torsional angles and sugar pucker. Also, there is an evidence of protein-induced conformational change in DNA.     

31P NMR study of daunorubicin-d(CGTACG) complex in solution. Evidence of the intercalation sites

The interaction of daunorubicin with the self-complementary DNA fragment d(CGTACG) was studied by 31P NMR spectroscopy. The individual phosphates have been assigned for the nucleotide and the complex and signals from bound and free species in slow exchange at 19 degrees C were detected. In solution, the hexanucleotide binds two molecules of daunorubicin, which intercalate in the d(CG) sequence at both ends of the helix. Evidence for local deformations of the backbone at the sites of C5pG6, C1pG2 and G2pT3 phosphates is given. The binding constants for the stepwise equilibrium and the rate of dissociation of the intercalated duplex were also determined.     

Alkylation of nucleic acid components with ethylenimine and its derivatives. IV. Alkylation of homopolynucleotides and DNA]

Alkylation of homopolynucleotides and DNA by thio TEPA and monoaziridine diethyl phosphate was studied. The modification affected nucleic bases and terminal phosphate groups but not internucleotide phosphate groups. It was shown that the main center of modification in poly(A) was the N1 atom, whereas the products of N6- and N3-alkylations were formed in smaller amounts. In poly(G), the alkylation proceeded predominantly at the N7 and, insignificantly, at the N1 atom of guanine; the pyrimidine N3 atom is alkylated poorly in poly(C) and even worse in poly(U). In the case of DNA, the major alkylated sites are the guanine N7 and the adenine N3; this results in DNA denaturation and the subsequent formation of products modified at N1 and N6 of adenine, N1 of guanine, and N3 of cytosine. An increase in the pH and ionic strength of the solution as well as the DNA denaturation decrease the reaction rate, whereas ultrasonic fragmentation enhances it. Upon alkylation, melting temperatures decrease, CD and UV spectra change, and DNA luminescence appears. To separate the reaction mixtures and identify the DNA alkylation products, chemical hydrolysis, ion-exchange and reverse-phase HPLC, and UV spectroscopy were used.     

Site-directed mutagenesis of residues involved in G Strand DNA binding by Escherichia coli DNA topoisomerase I

Crystal structures of complexes between type IA DNA topoisomerases and single-stranded DNA suggest that the residues Ser-192, Arg-195, and Gln-197 in a conserved region of Escherichia coli topoisomerase I may be important for direct interactions with phosphates on the G strand of DNA, which is the substrate for DNA cleavage and religation (Changela A., DiGate, R. J., and Mondragón, A. (2001) Nature 411, 1077-1081; Perry, K., and Mondragón, A. (2003) Structure 11, 1349-1358). Site-directed mutagenesis experiments altering these residues to alanines and other amino acids were carried out to probe the relevance of these interactions in the catalytic activities of the enzyme. The results show that the side chains of Arg-195 and Gln-197 are required for DNA cleavage by the enzyme and are likely to be important for positioning of the G strand of DNA at the active site prior to DNA cleavage. Mutation of Ser-192 did not affect DNA binding and cleavage but nevertheless decreased the overall rate of relaxation of supercoiled DNA probably because of its participation in a later step of the reaction pathway.     

Sequence-specific DNA cleavage by dipeptides disubstituted with chlorambucil and 2,6-dimethoxyhydroquinone-3-mercaptoacetic acid.

Two dipeptides, each containing a lysyl residue, were disubstituted with chlorambucil (CLB) and 2,6-dimethoxyhydroquinone-3-mercaptoacetic acid (DMQ-MA): DMQ-MA-Lys(CLB)-Gly-NH2 (DM-KCG) and DMQ-MA-beta-Ala-Lys(CLB)-NH2 (DM-BKC). These peptide-drug conjugates were designed to investigate sequence-specificity of DNA cleavage directed by the proximity effect of the DNA cleavage chromophore (DMQ-MA) situated close to the alkylating agent (CLB) inside a dipeptide moiety. Agarose electrophoresis studies showed that DM-KCG and DM-BKC possess significant DNA nicking activity toward supercoiled DNA whereas CLB and its dipeptide conjugate Boc-Lys(CLB)-Gly-NH2 display little DNA nicking activity. ESR studies of DMQ-MA and DM-KCG both showed five hyperfine signals centered at g = 2.0052 and are assigned to four radical forms at equilibrium, which may give rise to a semiquinone radical responsible for DNA cleavage. Thermal cleavage studies at 90 degrees C on a 265-mer test DNA fragment showed that besides alkylation and cleavage at G residues, reactions with DM-KCG and DM-BKC show a preference for A residues with the sequence pattern: 5'-G-(A)n-Pur-3' > 5'-Pyr-(A)n-Pyr-3' (where n = 2-4). By contrast, DNA alkylation and cleavage by CLB occurs at most G and A residues with less sequence selectivity than seen with DM-KCG and DM-BKC. Thermal cleavage studies using N7-deazaG and N7-deazaA-substituted DNA showed that strong alkylation and cleavage at A residues by DM-KCG and DM-BKC is usually flanked on the 3' side by a G residue whereas strong cleavage at G residues is flanked by at least one purine residue on either the 5' or 3' side. At 65 degrees C, it is notable that the preferred DNA cleavage by DM-KCG and DM-BKC at A residues is significantly more marked than for G residues in the 265-mer DNA; the strongest sites of A-specific reaction occur within the sequences 5'-Pyr-(A)n-Pyr-3'; 5'-Pur-(A)n-G-3' and 5'-Pyr-(A)n-G-3'. In pG4 DNA, cleavage by DM-KCG and DM-BKC is much greater than that by CLB at room temperature and at 65 degrees C. It was also observed that DM-KCG and DM-BKC cleaved at certain pyrimidine residues: C40, T66, C32, T34, and C36. These cleavages were also sequence selective since the susceptible pyrimidine residues were flanked by two purine residues on both the 5' and 3' sides or by a guanine residue on the 5' side. These findings strongly support the proposal that once the drug molecule is positioned so as to permit alkylation by the CLB moiety, the DMQ-MA moiety is held close to the alkylation site, resulting in markedly enhanced sequence-specific cleavage.     

DNA sequence selectivity of guanine-N7 alkylation by nitrogen mustards.

Nitrogen mustards alkylate DNA primarily at the N7 position of guanine. Using an approach analogous to that of the Maxam-Gilbert procedure for DNA sequence analysis, we have examined the relative frequencies of alkylation for a number of nitrogen mustards at different guanine-N7 sites on a DNA fragment of known sequence. Most nitrogen mustards were found to have similar patterns of alkylation, with the sites of greatest alkylation being runs of contiguous guanines, and relatively weak alkylation at isolated guanines. Uracil mustard and quinacrine mustard, however, were found to have uniquely enhanced reaction with at least some 5'-PyGCC-3' and 5'-GT-3' sequences, respectively. In addition, quinacrine mustard showed a greater reaction at runs of contiguous guanines than did other nitrogen mustards, whereas uracil mustard showed little preference for these sequences. A comparison of the sequence-dependent variations of molecular electrostatic potential at the N7-position of guanine with the sequence dependent variations of alkylation intensity for mechlorethamine and L-phenylalanine mustard showed a good correlation in some regions of the DNA, but not others. It is concluded that electrostatic interactions may contribute strongly to the reaction rates of cationic compounds such as the reactive aziridinium species of nitrogen mustards, but that other sequence selectivities can be introduced in different nitrogen mustard derivatives.     

Photo-induced hole transfer from base to sugar in DNA: relationship to primary radiation damage

This work presents the hypothesis that photo-excitation of G.+ in DNA and model systems results in the same electronic states expected from direct ionization of the sugar phosphate backbone and that these states lead to specific sugar radicals on the DNA sugar phosphate backbone. As evidence we show that visible photo-excitation of guanine cation radicals (G.+) in the dinucleoside phosphate TpdG results in high yields (about 85%) of deoxyribose sugar radicals at the C1' and C3' sites. Further, we have calculated transition energies of hole transfer from G.+ in TpdG using time-dependent density functional theory (TD-DFT) at the B3LYP/6-31G(d) level in gas phase as well as in a solvated environment. These calculations clearly predict that visible excitation of G.+ in TpdG causes transitions from only inner-shell filled molecular orbitals (MOs) to the singly occupied molecular orbital (SOMO) that effectively result in hole transfer from guanine either to the sugar phosphate backbone or to the adjacent base, thymine. The hole transfer is followed by rapid deprotonation from the sugar to form C1' and C3' radicals. These experimental and theoretical results are in agreement with our previously published experimental and theoretical results that photo-excitation of G.+ results in high yields of deoxyribose sugar radicals in DNA, guanine deoxyribonucleosides and deoxyribonucleotides. Photo-excitation of G.+ therefore provides a convenient method to produce and study sugar radicals that are expected to be formed in gamma-irradiated DNA systems unencumbered by the many other pathways involved in direct ionization.     

Conserved structural motifs governing the stoichiometric repair of alkylated DNA by O(6)-alkylguanine-DNA alkyltransferase

O(6)-alkylguanine-DNA alkyltransferase (AGT) directly repairs alkylation damage at the O(6)-position of guanine in a unique, stoichiometric reaction. Crystal structures of AGT homologs from the three kingdoms of life reveal that despite their extremely low primary sequence homology, the topology and overall structure of AGT has been remarkably conserved. The C-terminal domain of the two-domain, alpha/beta fold bears a helix-turn-helix (HTH) motif that has been implicated in DNA-binding by structural and mutagenic studies. In the second helix of the HTH, the recognition helix, lies a conserved RAV[A/G] motif, whose "arginine finger" promotes flipping of the target nucleotide from the base stack. Recognition of the extrahelical guanine is likely predominantly through interactions with the protein backbone, while hydrophobic sidechains line the alkyl-binding pocket, as defined by product complexes of human AGT. The irreversible dealkylation reaction is accomplished by an active-site cysteine that participates in a hydrogen bond network with invariant histidine and glutamic acid residues, reminiscent of the serine protease catalytic triad. Structural and biochemical results suggest that cysteine alkylation opens the domain-interfacing "Asn-hinge", which couples the active-site to the recognition helix, providing both a mechanism for release of repaired DNA and a signal for the observed degradation of alkylated AGT.     

Remote phosphate contacts trigger assembly of the active site of DNA topoisomerase IB

Vaccinia topoisomerase IB forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at its target site 5'-CCCTTp downward arrow in duplex DNA. The contributions of backbone electrostatics and individual phosphate oxygens to the transesterification reaction were probed by introducing 22 single Rp and Sp methylphosphonate diastereomers at 11 positions flanking the cleavage site. Methyl groups at eight positions (four on the scissile strand and four on the nonscissile strand) inhibited the rate of single-turnover cleavage by factors of 50-50,000. Stereospecific interference was observed at several phosphates, thereby distinguishing simple electrostatic contributions from putative specific polar contacts to either the pro-Sp or pro-Rp oxygens. The functionally relevant phosphate oxygens are located on the minor groove face of the helix on which the scissile phosphodiester resides. Our findings, combined with available crystal structures of vaccinia and human topoisomerase IB, show how specific phosphate contacts remote from where chemistry occurs are critical for assembly of the active site.     

A Comparative study of Fe(II) and Fe(III) interactions with DNA duplex: major and minor grooves bindings

The involvement of the Fe cations in autoxidation in cells and tissues is well documented. DNA is a major target in such reaction, and can chelate Fe cation in many ways. The present study was designed to examine the interaction of calf-thymus DNA with Fe(II) and Fe(III), in aqueous solution at pH 6.5 with cation/DNA (P) (P = phosphate) molar ratios (r) of 1:160 to 1:2. Capillary electrophoresis and Fourier transform infrared (FTIR) difference spectroscopic methods were used to determine the cation binding site, the binding constant, helix stability and DNA conformation in Fe-DNA complexes. Structural analysis showed that at low cation concentration (r = 1/80 and 1/40), Fe(II) binds DNA through guanine N-7 and the backbone PO(2) group with specific binding constants of K(G) = 5.40 x 10(4) M(1) and K(P) = 2.40 x 10(4) M(1). At higher cation content, Fe(II) bindings to adenine N-7 and thymine O-2 are included. The Fe(III) cation shows stronger interaction with DNA bases and the backbone phosphate group. At low cation concentration (r = 1:80), Fe(III) binds mainly to the backbone phosphate group, while at higher metal ion content, cation binding to both guanine N-7 atom and the backbone phosphate group is prevailing with specific binding constants of K(G) = 1.36 x 10(5) M(-1) and K(P) = 5.50 x 10(4) M(-1). At r = 1:10, Fe(II) binding causes a minor helix destabilization, whereas Fe(III) induces DNA condensation. No major DNA conformational changes occurred upon iron complexation and DNA remains in the B-family structure.     

Recognition and cleavage at the DNA major groove.

DNA recognition agents based on the indole-based aziridinyl eneimine and the cyclopent[b]indole methide species were designed and evaluated. The recognition process involved either selective alkylation or intercalating interactions in the major groove. DNA cleavage resulted from phosphate backbone alkylation (hydrolytic cleavage) and N(7) -alkylation (piperidine cleavage). The formation and fate of the eneimine was studied using enriched 13C NMR spectra and X-ray crystallography. The aziridinyl eneimine specifically alkylates the N(7) position of DNA resulting in direction of the aziridinyl alkylating center to either the 3'- or 5'-phosphate of the alkylated base. The eneimine species forms dimers and trimers that appear to recognize DNA at up to three base pairs. The cyclopent[b]indole quinone methide recognizes the 3'-GT-5' sequence and alkylates the guanine N(7) and the thymine 6-carbonyl oxygen causing the hydrolytic removal of these bases. In summary, new classes of DNA recognition agents are described and the utility of 13C-enrichment and 13C NMR to study DNA alkylation reactions is illustrated.     

Solution structure of a guanine-N7-linked complex of the mitomycin C metabolite 2,7-diaminomitosene and DNA. Basis of sequence selectivity

2,7-Diaminomitosene (2,7-DAM), the major metabolite of the antitumor antibiotic mitomycin C, forms DNA adducts in tumor cells. 2,7-DAM was reacted with the deoxyoligonucleotide d(GTGGTATACCAC) under reductive alkylation conditions. The resulting DNA adduct was characterized as d(G-T-G-[M]G-T-A-T-A-C-C-A-C) (5), where [M]G stands for a covalently modified guanine, linked at its N7-position to C10 of the mitosene. The adducted oligonucleotide complements with itself, retaining 2-fold symmetry in the 2:1 drug-duplex complex, and provides well-resolved NMR spectra, amenable for structure determination. Adduction at the N7-position of G4 ([M]G, 4) is characterized by a downfield shift of the G4(H8) proton and separate resonances for G4(NH(2)) protons. We assigned the exchangeable and nonexchangeable proton resonances of the mitosene and the deoxyoligonucleotide in adduct duplex 5 and identified intermolecular proton-proton NOEs necessary for structural characterization. Molecular dynamics computations guided by 126 intramolecular and 48 intermolecular distance restraints were performed to define the solution structure of the 2,7-DAM-DNA complex 5. A total of 12 structures were computed which exhibited pairwise rmsd values in the 0.54-1.42 A range. The 2,7-DAM molecule is anchored in the major groove of DNA by its C10 covalently linked to G4(N7) and is oriented 3' to the adducted guanine. The presence of 2,7-DAM in the major groove does not alter the overall B-DNA helical structure. Alignment in the major groove is a novel feature of the complexation of 2,7-DAM with DNA; other known major groove alkylators such as aflatoxin, possessing aromatic structural elements, form intercalated complexes. Thermal stability properties of the 2,7-DAM-DNA complex 5 were characteristic of nonintercalating guanine-N7 alkylating agents. Marked sequence selectivity of the alkylation by 2,7-DAM was observed, using a series of oligonucleotides incorporating variations of the 5'-TGGN sequence as substrates. The selectivity correlated with the sequence specificity of the negative molecular electrostatic potential of the major groove, suggesting that the alkylation selectivity of 2,7-DAM is determined by sequence-specific variation of the reactivity of the DNA. The unusual, major groove-aligned structure of the adduct 5 may account for the low cytotoxicity of 2,7-DAM.     

Sequence-dependent variations in the 31P NMR spectra and backbone torsional angles of wild-type and mutant Lac operator fragments

Assignment of the 31P resonances of a series of six sequenced-related tetradecamer DNA duplexes, d(TGTGAGCGCTCACA)2, d(TATGAGCGCTCATA)2, d(TCTGAGCGCTCAGA)2, d(TGTGTGCGCACACA)2, d(TGTGACGCGTCACA)2 and d(CACAGTATACTGTG)2, related to the lac operator DNA sequence was determined either by site-specific 17O labeling of the phosphoryl groups or by two-dimensional 1H-31P pure absorption phase constant time (PAC) heteronuclear correlation spectroscopy. J(H3'-P) coupling constants for each of the phosphates of the tetradecamers were obtained from 1H-31P J-resolved selective proton flip 2D spectra. By use of a modified Karplus relationship the C4'-C3'-O3'-P torsional angles (epsilon) were obtained. Comparison of the 31P chemical shifts and J(H3'-P) coupling constants of these sequences has allowed greater insight into those various factors responsible for 31P chemical shift variations in oligonucleotides and provided an important probe of the sequence-dependent structural variation of the deoxyribose phosphate backbone of DNA in solution. These sequence-specific variations in the conformation of the DNA sugar phosphate backbone of various lac operator DNA sequences can possibly explain the sequence-specific recognition of DNA by DNA binding proteins, as mediated through direct contacts between the phosphates and the protein.     

Spin-labelling of DNA with hydrazine mustard spin label (HMSL)

1. The hydrazine mustard spin label (HMSL), recently synthesized in our laboratory (Raikova, 1977) was used for spin-labelling of DNA. 2. It alkylates both double- and single-stranded DNAs. 3. The reaction of HMSL with DNA was studied with respect to the kinetics of alkylation, dependence on salt concentration and base specificity. 4. It was found that HMSL is a base-specific reagent, alkylating preferentially guanine. According to their ability to bind HMSL, the four deoxyribonucleotides are ordered in the following way: G greater than A greater than C greater than T. 5. The EPR spectra obtained strongly depended on the secondary structure of the spin-labelled DNA: unlike the immobilized spectra of the double-stranded DNAs (2AZZ = 44.8G), the EPR spectra of single-stranded DNAs were non-immobilized (2AZZ = 32.8 G). 6. When sheared double-stranded DNA was spin-labelled, the parameters of the EPR spectrum depended also on the GC content of DNA.