Structural Forms and Transitions for the Complex of Mercury(II) with Poly(dG-dC)

Abstract

Infrared spectroscopy was used to study hydrated double-helical poly(dG-dC) complexed with varying amounts of mercury (II). For one Hg(II) per ten nucleotide residues (r = 0.1), the B structure was stabilized and the B* structure was absent at high hydration. The Z structure did not form as hydration was reduced. For r = 0.2, the B and Z structures coexisted at high hydration and the transition to total Z structure was broad as hydration was reduced. Hg(II) was bound exclusively to the guanine residues probably at N 3 orN7forr < 0.25. The cytosine residue did not protonate (at N3) as Hg(II) was bound to guanine. The addition of NaCl together with Hg(II) reduced the binding of Hg(II), stabilized the B structure at the highest hydration and caused a sharp transition between the B and Z structures as hydration was lowered. Hydration with D,0 stabilized the Z structure for poly(dG-dC) complexed with HgCl₂.     

Structural forms and transitions of poly(dG-dC) with Cd(II), Ag(I) and NaNO3

Infrared spectroscopy was used to study the structures and transitions in hydrated gels of double-helical poly(dG-dC) complexed with the metal carcinogens Cd(II) and Ag(I). For one Cd(II) per ten nucleotides (r = 0.1), the B structure was stable at high and moderate hydrations with D2O and the B and Z structures coexisted at low hydrations. For poly(dG-dC) with Cd(II) at r = 0.2 to 0.35, the Z structure was stable at high hydrations (94% r.h. for r = 0.2). At a given value of hydration, H2O gave a higher content of Z structure than D2O. Cd(II) most likely binds to guanine residues at N7 in both the B and Z forms of poly(dG-dC) but binding to guanine N3 can not be excluded. It is unlikely that Cd(II) binds to cytosine residues at the r values studied and the cytosine residues did not protonate at N3 as Cd(II) bound to guanine residues. Poly(dG-dC) with Ag(I) at r = 0.2 to 0.36, existed in a B-family structure which is different from the B-family structure of the type I complex of Ag(I) and calf-thymus DNA. Poly(dG-dC) with Ag(I) did not assume the Z structure at lower hydrations even though NO3- was present in the sample. Ag(I) differs from other soft-metal acids which promote the Z structure. Ag(I) most likely binds to the guanine N7 or N3 and not to cytosine residues. Cytosine residues did not protonate at N3 as Ag(I) was bound to guanine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural forms, stabilities and transitions in double-helical poly(dG-dC) as a function of hydration and NaCl content. An infrared spectroscopic study.

The poly(dG-dC) helical duplex forms a modified, B-family structure (B*) at very high hydration and a normal B structure at slightly lower hydration. The B* structure is slightly different in sugar-phosphate and base-stacking conformations than the B structure. Increasing the hydration or decreasing the NaCl content stabilizes B* with respect to B. Poly(dG-dC) forms the Z structure at low NaCl contents when the hydration is sufficiently reduced. At moderate NaCl content, the B to Z transition is sharp and cooperative for hydration with D2O. Hydration with H2O broadens the transition which occurs at lower hydration. This suggests that hydrogen bonding is stronger in the Z structure and helps stabilize Z over B. IR spectra may be used to quantitatively estimate the fractions of B and Z structures present in a sample. Some new indicator bands are described.     

The B goes to Z transition of poly(dG-dC) . poly(dG-dC) modified by some platinum derivatives.

Poly(dG-dC) . poly(dG-dC) was modified by chlorodiethylenetriamino platinum (II) chloride, cis-dichlorodiammine platinum (II) and trans-dichlorodiammine platinum (II), respectively. The conformation of these modified poly(dG-dC) . poly(dG-dC) was studied by circular dichroism. In 4 M Na+, the circular dichroism spectra of poly(dG-dC)dien-Pt (0 less than or equal to rb less than or equal to 0.2) are similar (rb is the amount of bound platinum per base). It is concluded that the conformation of these polymers belongs to the Z-family. Dien-Pt complexes stabilize the Z-form. The midpoint of the Z goes to B transition of poly(dG-dC)dien-Pt(0.12) is at 0.2 M NaCl. Moreover another B goes to Z transition is observed at lower salt concentration (midpoint at 6 mM NaCl). In 1 mM phosphate buffer, the stability of Z-poly(dG-dC)dien-Pt(0.12) is greatly affected by the presence of small amounts of EDTA. Poly(dG-dC) . poly(dG-dC) modified by cis-Pt and trans-Pt complexes do not adopt the Z-form even in high salt concentration.     

Binding of [(dien)PtCl] Cl to poly(dG-dC)-poly(dG-dC) facilitates the B goes to Z conformational transition.

Chlorodiethylenetriamineplatinum(II) chloride, [(dien)PtCl]Cl, bound to less than or equal to 10% of the nucleotide bases of poly(dG-dC) . poly(dG-dC) reduces the amount of ethanol necessary to bring about the B goes to Z conformational transition in proportion to the amount of platinum complex bound as monitored by CD spectroscopy. The transition may be effected by 25% ethanol with 9.3% of the bases modified polymer an ethanol with 5.4% of the bases modified. With an unmodified polymer an ethanol concentration of 55-60% is necessary to bring about the transition. The assignment of the Z conformation was supported by 31P NMR spectroscopy. This covalent modification of the DNA is reversed by treatment with cyanide ion after which the normal amount of ethanol is necessary to achieve the transition. The platinum complex shows no enhanced binding to DNA in the Z versus the B conformation. Between 20 and 33% (saturation binding) modification, [(dien)PtCl]Cl binds cooperatively to the heterocopolymer as judged by CD spectroscopy. At this high level of modification it is no longer possible to induce the Z DNA structure with ethanol. When [(dien)PtCl]Cl is bound to preformed (with ethanol) Z DNA at saturating levels the CD spectrum is altered but reverts to the spectrum of highly modified DNA upon removal of ethanol. The antitumor drug cis-diaminedichloroplatinum(II), cis-DDP, binds to poly(dG-dC) . poly(dG-dC) and alters the CD spectrum. It does not facilitate the B goes to Z conformational change, however, and actually prevents it from happening even at very high ethanol concentrations.     

Comparison between poly(dG-dC).poly(dG-dC) and DNA modified by cis-diamminedichloroplatinum (II): immunological and spectroscopic studies

The importance of the base composition and of the conformation of nucleic acids in the reaction with the drug cis-diamminedichloroplatinum(II) has been studied by competition experiments between the drug and several double-stranded polydeoxyribonucleotides. Binding to poly(dG).poly(dC) is larger than to poly (dG-dC).poly(dG-dC). There is no preferential binding in the competition between poly(dG-dC).poly(dG-dC), poly(dA-dC).poly(dG-dT) and poly(dA-dG).poly(dC-dT). In the competition between poly(dG-dC).poly (dG-dC) (B conformation) and poly(dG-br5dC).poly(dG-br5dC) (Z conformation), the drug binds equally well to both polynucleotides. In natural DNA, modification of guanine residues in (GC)n.(GC)n sequences by the drug has been revealed by the inhibition of cleavage of these sequences by the restriction enzyme BssHII. By means of antibodies to platinated poly(dG-dC), it is shown that some of the adducts formed in platinated poly(dG-dC) are also formed in platinated pBR322 DNA. The type of adducts recognized the antibodies is not known. Thin layer chromatography of the products after chemical and enzymatic hydrolysis of platinated poly(dG-dC) suggests that interstrand cross-links are formed. Finally, the conformations of poly(dG-dC) modified either by cis-diamminedichloroplatinum(II) or by trans-diamminedichloroplatinum (II) have been compared by circular dichroism. Both the cis-isomer and the trans-isomer stabilize the Z conformation when they bind to poly(dG-m5dC) in the Z conformation. When they bind to poly(dG-m5dC) in the B conformation, the conformations of poly(dG-m5dC) modified by the cis or the trans-isomer are different. Moreover, the cis-isomer facilitates the B form-Z form transition of the unplatinated regions while the trans-isomer makes it more difficult.     

Bromination stabilizes poly(dG-dC) in the Z-DNA form under low-salt conditions

Using circular dichroism studies, Pohl & Jovin (1972) [Pohl, F.M., & Jovin, T.M. (1972) J. Mol. Biol. 67, 375-396] demonstrated that poly(dG-dC) undergoes a salt-dependent conformational change characterized by a spectral inversion. The low-salt form corresponds to the right-handed B form of DNA and the high-salt form to the left-handed Z-DNA helix. Modification of poly(dG-dC) by adding bromine atoms to the C8 position of guanine and the C5 position of cytosine residues stabilized this polymer in the Z-DNA form under low-salt conditions. The guanine residues were found to be twice as reactive as the cytosine residues. With a modification of 38% Br8G and 18% Br5C, the polymers formed a stable Z-DNA helix under physiological conditions. The bromination produced spectroscopic features very similar to poly(dG-dC) in 4 M NaCl. However, bromination did not freeze the Z structure as was shown by ethidium bromide intercalation studies. Addition of the dye favored an intercalated B-DNA form. The conversion of B- to Z-DNA leads to profound conformational changes which were also seen by a reduced insensitivity to various exo- and endonucleases. Comparative studies showed that the brominated polymers have a high affinity to nitrocellulose filters. In 1 M NaCl, there was virtually no binding of B-DNA, but a substantial binding of Z-DNA was found even at rather low levels of bromination.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformational changes induced in DNA by the in vitro reaction with the mutagenic amine: 3-N,N-acetoxyacetylamino-4,6-dimethyldipyrido (1,2-a: 3', 2'-d) imidazole.

The conformation of synthetic or natural DNAs modified in vitro by covalent binding of N-AcO-A-Glu-P-3 was investigated by fluorescence and circular dichroism. In all cases, substitution occurs mainly on the C8 of guanine residues. In modified poly(dG-dC).poly(dG-dC) or poly(dA-dC).poly(dG-dT) in B conformation, A-Glu-P-3 residues interact strongly with the bases whereas in Z conformation these residues are largely exposed to the solvent and interact weakly with the bases. A-Glu-P-3 and N-acetyl-2-aminofluorene (AAF) residues are equally efficient to induce the B-Z transition of poly(dG-dC).poly(dG-dC) and of poly(dA-dC).poly(dG-dT). Modifications of poly(dG).poly(dC) and calf thymus DNA indicate strong interactions between A-Glu-P-3 and the bases.     

Electron microscopic measurement of chain flexibility of poly(dG-dC).poly(dG-dC) modified by cis-diamminedichloroplatinum(II).

The antitumor drug cis-diamminedichloroplatinum (II) (cis-Pt) forms bidentate adducts with guanine residues of poly(dG-dC).poly(dG-dC). The secondary structure of the polymer is altered. In this work, high resolution pictures of naked molecules, obtained by dark field electron microscopy reveal DNA chain distortions with radii as small as 30 A. The extent of distortion increases with the drug/nucleotide ratio (rb). These alterations of the secondary structure are responsible for the apparent shortening of the molecules. Measurements of the persistence lengths of the polymer as well as the end-to-end distances of elementary segments of various lengths, are obtained from digitized electron micrographs. The measurements are used to monitor and quantify the observed modifications of polymer structure upon cis-Pt binding at various rb or incubation times. Poly(dG-m5dC).poly(dG-m5dC) in the B and Z forms have different persistence lengths. In the B form, this polymer is more altered by cis-Pt than in the Z one.     

Existence of the C Structure in Poly(dA-dC) · Poly(dG-dT)

Abstract

We show that the lithium salt of calf-thymus DNA can assume the C structure in nonoriented, hydrated gels. The transitions between the B and C structures showed little hysteresis and none of the metastable structural states which occur in oriented gels. Therefore crystal-lattice forces are not needed to stabilize the C structure.

The occurrence of the alternative structures of the Li, Na and K salts of poly(dA-dC) · poly(dG-dT) was measured as a function of hydration for nonoriented gels. Poly(dA-dC) · poly(dG-dT) · Li exists in the B structure at high hydrations and in the C structure at moderate hydrations with no A or Z structure at any hydration tested. The Na salt of poly(dA-dC) · poly(dG-dT) exists in the B structure at high hydration, as mixtures of B and C at moderate hydrations and in the A structure at lower hydrations. The potassium salt behaves similarly except that mixtures of the C and A structures exist at lower hydrations.

ZnCl₂ and NaNO₃, which promote the Z structure in duplex poly(dG-dC), promote the C structure in poly(dA-dC) · poly(dG-dT). Information contained in the sequence of base pairs and not specific ionic interactions appear to determine the stability of the alternative structures of polynucleotides as hydration is changed.     

Reactivity and binding of benzo(a)pyrene diol epoxide to poly(dG-dC).(dG-dC) and poly(dG-m5dC).(dG-m5dC) in the B and Z forms

The physical and covalent binding of the carcinogen benzo(a)pyrene-7,8-diol-9,10-oxide (BaPDE) to poly(dG-dC).(dG-dC) and poly(dG-m5dC).(dG-m5dC) in the B and Z forms were studied utilizing absorbance, fluorescence and linear dichroism techniques. In the case of poly(dG-dC).(dG-dC) the decrease in the covalent binding of BaPDE with increasing NaCl concentration (0.1-4 M) as the B form is transformed to the Z form is attributed to the effects of high ionic strengths on the reactivity and physical binding of BaPDE to the polynucleotides; these effects tend to obscure differences in reactivities with the B and Z forms of the nucleic acids. In the case of poly(dG-m5dC).(dG-m5dC) the B-to-Z transition is induced at low ionic strength (2 mM NaCl + 10 microM Co(NH3)6Cl3) and the covalent binding is found to be 2-3-times lower to the Z form than to the B form. Physical binding of BaPDE by intercalation, which precedes the covalent binding reaction, is significantly lower in the Z form than in the B form, thus accounting, in part, for the lower covalent binding. The linear dichroism characteristics of BaPDE covalently bound to the Z and B forms of poly(dG-m5dC).(dG-m5dC) are consistent with nonintercalative, probably external conformations of the aromatic pyrenyl residues.     

Facilitation of the conversion from B to Z conformation in poly(dG-dC) modified by anti-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide

The transition from B to Z conformation has been studied in poly(dG-dC) covalently modified with racemic anti- or syn-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE), a strong and a weak carcinogen, respectively. Circular dichroism was used to study the kinetics of the transition after a sudden increase of the ionic strength to 2.7 M NaCl. The results show that the rate of the B to Z transition of poly(dG-dC) in high NaCl concentration is considerably enhanced by bound anti-BPDE and diminished by bound syn-BPDE. The results may be interpreted such that at the binding site of anti-BPDE the base stacking is distorted and made looser, which facilitates the B to Z transition. The partly intercalative nature of the syn-BPDE complexes apparently is effective in reducing the rate of the transition. These properties of the two BPDEs may be relevant to explain their different carcinogenic potencies.     

Covalent attachment of an alkylamine prevents the B to Z transition in poly(dG-dC)

Covalent complexes of n-butylamine and double-stranded poly(dG-dC) were prepared by coupling the amine to exocyclic amino groups of guanine bases with CH2O. Neither the absorption spectrum above 230 nm nor the s020,w of the complexes in low to moderate ionic strength solvents, freed of excess unreacted reagents, differs significantly from that of unreacted poly(dG-dC) or a control which had been exposed only to CH2O. In contrast, the CD spectra are profoundly altered. The minimum at 252 nm becomes more negative, and the rotational strength of the positive band above 260 nm is reduced as a linear function of the extent of amine attachment. At 0.22 mol of amine per mole of nucleotide, the transformation is similar to that observed by others in poly(dG-dC) when complexed to core histones in reconstituted core particles or in concentrated LiCl solvents at temperatures below the B----Z transition. Sedimentation studies reveal that these changes in the circular dichroism (CD) spectra reflect secondary structural effects rather than the formation of aggregates or psi type structures. Raman spectra reveal, however, that these secondary structural changes must occur within the B family as the amine complex retains B backbone geometry. The conformation produced by the attachment of the amine is probably a higher winding angle (overwound) B variant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hexammineruthenium (III) chloride: a highly efficient promoter of the B-DNA to Z-DNA transition of poly-(dG-m5dC).poly(dG-m5dC) and poly(dG-dC).poly(dG-dC)

The effects of Ru(NH3)(3+)6 on the conformation of poly(dG-m5dC).poly(dG-m5dC) and poly(dG-dC).poly(dG-dC) were studied by circular dichroism (CD) spectroscopy. Ru(NH3)(3+)6 at very low concentrations provokes the Z-DNA conformation in both polynucleotides. In the presence of 50 mM NaCl, the concentration of Ru(NH3)(3+)6 at the midpoint of B to Z transition of poly(dG-m5dC).poly(dG-m5dC) is 4 microM compared to 5 microM for Co(NH3)(3+)6. The half-lives of B to Z transition of poly(dG-m5dC).poly(dG-m5dC) in the presence of 10 microM Ru(NH3)(3+)6 and Co(NHG3)(3+)6 are at 23 and 30 min, respectively. The concentration of Ru(NH3)(3+)6 at the midpoint of B to Z transition of poly(dG-dC).poly(dG-dC) is 50 microM. These results demonstrate that Ru(NH3)(3+)6 is a highly efficient trivalent cation for the induction of B to Z transition in poly(dG-m5dC).poly(dG-m5dC) and poly(dG-dC).poly(dG-dC). In contrast, Ru(NH3)(3+)6 has no significant effect on the conformation of calf thymus DNA, poly(dA-dT).poly(dA-dT) and poly(dA-dC).poly(dG-dT).     

Circular dichroism of poly(dG-dC) modified by the carcinogens N-methyl-4-aminoazobenzene or 4-aminobiphenyl.

Poly(dG-dC) was modified to different extents by the carcinogens 4-aminobiphenyl (ABP) or N-methyl-4-aminoazobenzene (MAB). HPLC analysis of the enzymatically hydrolyzed modified polymers indicates that more than 90% of the ABP and 81% of the MAB modification occurs at the C8 position of guanine. The conformational changes of the unmodified and modified polymers were studied as a function of ethanol and magnesium ion concentrations by the use of circular dichroism (CD). The modified polymers show a CD inversion pattern similar to that of the salt-induced B to Z transition of poly(dG-dC). Both of the modified polymers require less salt or ethanol than the unmodified polymer for the inversion of the spectra. The amount of ethanol or magnesium needed to induce the inverted CD spectrum is inversely proportional to the percentage of bound ABP or MAB. These data indicate that ABP and MAB can enhance conversion from B to Z conformation in alternating purine-pyrimidine sequences.     

Base protonation facilitates B-Z interconversions of poly(dG-dC) X poly(dG-dC)

Comparative studies on the salt titration and the related kinetics for poly(dG-dC) X poly(dG-dC) in pH 7.0 and 3.8 solutions clearly suggest that base protonation facilitates the kinetics of B-Z interconversion although the midpoint for such a transition in acidic solution (2.0-2.1 M NaCl) is only slightly lower than that of neutral pH. The rates for the salt-induced B to Z and the reverse actinomycin D induced Z to B transitions in pH 3.8 solutions are at least 1 order of magnitude faster than the corresponding pH 7.0 counterparts. The lowering of the B-Z transition barrier is most likely the consequence of duplex destabilization due to protonation as indicated by a striking decrease (approximately 40 degrees C) in melting temperature upon H+ binding in low salt. The thermal denaturation curve for poly(dG-dC) X poly(dG-dC) in a pH 3.8, 2.6 M NaCl solution indicates an extremely cooperative melting at 60.5 degrees C for protonated Z DNA, which is immediately followed by aggregate formation and subsequent hydrolysis to nucleotides at higher temperatures. The corresponding protonated B-form poly(dG-dC) X poly(dG-dC) in 1 M NaCl solution exhibits a melting temperature about 15 degrees C higher, suggesting further duplex destabilization upon Z formation.     

Intensity changes of base and backbone Raman modes in the B to Z transition of poly(dG-dm5C)

Raman spectroscopy was employed to investigate the temperature-induced B to Z transition of poly(dG-dm5C). The transition midpoint was about 37 degrees C for a solvent containing 20 mM Mg2+. A 10-fold change in Mg2+ concentration altered the transition midpoint by at least 60 degrees C. Raman spectra of the B and Z forms of poly(dG-dm5C) exhibited characteristics similar to those observed with poly(dG-dC). The 682 cm-1 guanine mode and 835 cm-1 backbone mode were present in the B conformation. In the Z form the intensities of these two bands decrease substantially and new peaks were observed at 621 cm-1, 805 and 819 cm-1. Several bands unique to poly(dG-dm5C) were also observed. Transition profiles of band intensity vs. temperature were determined for fourteen Raman bands. The curves of all of the base vibrations and one backbone mode had the same slope and midpoint. This indicates that conformational changes in the guanine and methycytosine bases occur concurrently.     

Effect of chromium(III) on poly(dG-dC) conformation

The interaction of chromium(III) with poly(dG-dC) inhibits the B to Z transition and results in the condensation of the polymer at high Cr/nucleotide ratios. At low Cr/nucleotide ratios chromium(III) enhanced the ability of ethanol to induce the B to Z transition of poly(dG-dC). The effects of chromium(III) on the conformation of DNA may be related to the carcinogenicity of chromium compounds.     

Modifications of circular DNA by photoalkylation

The effects of photoalkylation on superhelical PM2 DNA were examined. The chief product was 8-(2-hydroxy-2-propyl)guanine, formed exclusively in sequences of alternating purines and pyrimidines. Other purine damages included 8-(2-hydroxy-2-propyl)adenine and smaller quantities of two uncharacterized adenine products. DNA strand breaks were formed with increasing irradiation. A small quantity of thymine-containing photodimers was formed. Photoalkylation of poly(dG-dC):poly(dG-dC) reduced the concentration of salt required to effect inversion of the circular dichroic spectrum. This suggests that photoalkylation induces the transition of poly(dG-dC):poly(dG-dC) from the right-handed B form of DNA to the left-handed Z form.     

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.