Structure and Stability of Z* DNA

Abstract

The structure and stability of the left handed Z* DNA aggregate was examined by spectroscopic methods and by electron microscopy. Poly(dGdC), upon heating in the presence of Mn⁺⁺, forms a large aggregate which may be sedimented at 12,000 X g, with a circular dichroism spectrum characteristic of left handed DNA Aggregation gives rise to turbidity changes at visible wavelengths, providing a convenient means of monitoring the transition in solution. The wavelength dependence of turbidity is consistent with the scattering behavior of a long thin rod. Electron microscopy shows that Z* DNA is a large fibrous structure of indeterminant length, with a uniform diameter of approximately 20 nm. The results obtained in solution and under the requisite conditions for electron microscopy are mutually consistent Poly(dGdC) preparations with average lengths of 60,240,500, and 2000 base pairs all form Z* DNA Poly(dGm⁵dC) forms Z* DNA in the presence of Mn⁺⁺ without heating, but poly(dAdC)-poly(dGdT) and calf thymus DNA cannot be induced to the Z* form under any conditions tried. Kinetic studies, monitored by turbidity changes, provide evidence that the formation of Z* DNA proceeds by a nucleated condensation mechanism. Dissolution of the Z* aggregate results from the chelation of Mn⁺⁺ or by the addition of the intercalator ethidium bromide. The allosteric conversion of Z* DNA to an intercalated, right handed form by ethidium is demonstrated by kinetic studies, equilibrium binding studies and circular dichroism spectroscopy. Electron microscopy provides a striking visualization of the dissolution of the Z* aggregate by ethidium.     

Methylation and restriction endonuclease cleavage of linear Z-DNA in the presence of hexamminecobalt (III) ions.

These studies employed the synthetic linear DNA, poly dGdC, in the B and cobalt hexammine chloride (Co)-induced Z form to determine the effect of conformation on protein-DNA interactions. The rate of the reaction of the restriction endonucleases, Hha I and Cfo I, are reduced with Z DNA as compared to B DNA. The ability of both restriction endonucleases to react with an aggregate form of Z DNA (Z* DNA) is found to depend upon how the Z* DNA is formed. When Z* DNA is induced by low concentrations of Co (50 microM), the endonucleases remain active. In the presence of 100 microM Co, which causes increased aggregation, the endonucleases are inactive. The Hha I DNA methyltransferase reacts at equal rates with the B, Z and low cobalt Z* forms and at a greatly reduced rate with the high cobalt Z* form. These results are significantly different than those observed with Z form dGdC tracts inserted into circular DNA molecules.     

Inhibition of the B to Z transition in poly(dGdC).poly(dGdC) by covalent attachment of ethidium: equilibrium studies

The effects of covalent modification of poly(dGdC).poly(dGdC) and poly(dGm5dC).poly(dGm5dC) by ethidium monoazide (a photoreactive analogue of ethidium) on the salt-induced B to Z transition are examined. Earlier studies have shown ethidium monoazide to bind DNA (in the absence of light) in a manner identical to that of the parent ethidium bromide. Photolysis of the ethidium monoazide-DNA complex with visible light results in the covalent attachment of the photoreactive analogue to the DNA. This ability to form a covalent adduct was utilized to probe the effects of an intercalating irreversibly bound adduct on the salt-induced B to Z transition of the poly(dGdC).poly(dGdC) and poly(dGm5dC).poly(dGm5dC) polynucleotides. In the absence of drug, the salt-induced transition from the B to Z structure occurs in a highly cooperative manner. In contrast, this cooperativity is diminished as the concentration of covalently attached drug is increased. The degree of inhibition of the B to Z transition is quantitated as a function of the concentration of covalently attached drug. At a concentration of one drug bound per four base pairs for poly(dGdC).poly(dGdC) and seven base pairs for poly(dGm5dC).poly(dGm5dC), total inhibition of this transition is achieved. Lower concentrations of bound drug were effective in the partial inhibition of this transition. The effects of the covalently bound intercalator on the energetics of the B to Z transition were determined and demonstrated that the adduct is effective in locking the alternating copolymer in a right-handed conformation under high salt conditions.     

Mn2+ and other transition metals at low concentration induce the right-to-left helical transformation of poly[d(G-C)].

The effects of the first-row transition metal ions on the right(B)- to left(Z)-handed helical transition of poly[d(G-C)] have been determined. The Z conformation is induced by MnCl2 at submillimolar concentrations. The forward reaction has a very large activation energy (440 kJ/mol) so that a facile conversion occurs only at temperatures above 45 degrees C. However, the left-handed form remains stable upon cooling. The addition of ethanol (20% v/v) eliminates the requirement for elevated temperature. The transition is highly co-operative and is accompanied by spectral changes (absorption, circular dichroism) characteristic for the B----Z conformational transition. NiCl2 and CoCl2 also induce the B----Z transition in poly[d(G-C)] but the activation energies and thus the temperature requirements for the forward reaction are lower than those observed with MnCl2. The left-handed DNA formed in the presence of Mn2+ is similar to 'Z DNA' previously described in Mg2+-EtOH (van de Sande and Jovin , 1982): (a) it readily sediments out of solution at low speed as a consequence of intermolecular association which, however, is not accompanied by turbidity; and (b) it supports the binding of ethidium bromide although this drug interacts preferentially with the B form of DNA. With Ni2+, the B----Z isomerization step can be separated from the subsequent specific Z----Z* association. Mn2+, Ni2+, and Co2+ also promote the B----Z transition of poly[d(G-m5C)] at substoichiometric concentrations with respect to DNA nucleotide.     

Stabilization of the Z'' form of poly(dGdC):poly(dGdC) in solution by multivalent ions relates to the ZII form in crystals.

Both multivalent ions and 85% ethanol are required to produce the original Z' form of poly(dGdC):poly(dGdC) in solution. When multivalent impurities are removed by dialysis against 0.5 M NaCl and 1 mM EDTA, the circular dichroism retains features of the standard Z form. Addition of Ca+2 nearly reverses this effect. Analysis by singular value decomposition of near-ultraviolet circular dichroism spectra collected during titrations of polynucleotide in 60% ethanol with multivalent ions reveal that, at concentrations below .5 per nucleotide, they stabilize Z'-like forms in a two-state equilibrium with the Z form. Differences among the Z' spectra produced by the different ions suggest that at least three families of Z' structures exist. Furthermore, comparison with crystal data indicates that the Z' form in solution is related to the ZII form in crystals.     

Inhibition of the B to Z transition in poly(dGdC).poly(dGdC) by covalent attachment of ethidium: kinetic studies

The photoaffinity analogue ethidium monoazide was used to prepare samples of poly(dGdC).poly(dGdC) containing covalently attached ethidium. The effects of both noncovalently and covalently bound ethidium on the kinetics of the NaCl-induced B to Z transition in poly(dGdC).poly(dGdC) was examined using absorbance and fluorescence spectroscopy to monitor the reaction. Covalently and noncovalently attached ethidium were equal in the extent to which they reduce the rate of the B to Z transition. By using fluorescence to selectively monitor the fate of noncovalently bound ethidium over the course of the transition, we found that ethidium completely dissociates as the reaction proceeds, but at a rate that lags behind the conversion of the polymer to the Z form. These experiments provide evidence for the redistribution of noncovalently bound ethidium over the course of the B to Z transition, leading to the development of biphasic reaction kinetics. The observed kinetics suggest that the primary effect of both covalently and noncovalently bound ethidium is on the nucleation step of the B to Z transition. The reduction in the rate of the B to Z transition by noncovalently or covalently bound ethidium may be quantitatively explained as resulting from the reduced probability of finding a drug-free length of helix long enough for nucleation to occur. As necessary ancillary experiments, the defined length deoxyoligonucleotides (dGdC)4, (dGdC)5, and (dGdC)6 were synthesized and used in kinetic experiments designed to determine the nucleation length of the B to Z transition, which was found to be 6 bp. The activation energy of the B to Z transition was demonstrated to be independent of the amount of covalently bound ethidium and was found to be 21.2 +/- 1.1 kcal mol-1. Covalent attachment of ethidium was observed to increase the rate of the reverse Z to B transition, presumably by locking regions of the polymer into a right-handed conformation and thereby providing nucleation sites from which the Z to B conversion may propagate.     

Stabilization of (dG-dC)n.(dG-dC)n in the Z conformation by a crosslinking reaction

(dG-dC)n.(dG-dC) was converted to the Z conformer by heating in the presence of Mn++n. Reaction of this preparation with the crosslinking reagent, DL-diepoxybutane (DEB), stabilized this conformer so that it retained its structure even when returned to conditions that favored reversion to the B conformation. Treatment of the crosslinked Z conformer with periodate caused scission of the crosslink, allowing reversion to the B conformer. Reaction of (dG-dC)n.(dG-dC)n in the B conformation with DEB did not prevent conversion to the Z conformer in 4M NaC1; dialysis of the high salt solution against low ionic strength buffer allowed return to the B conformer. The Z in equilibrium B transitions were followed by circular dichroism studies and immunochemical procedures. The results suggest the feasibility of stabilizing Z sequences of DNA in chromatin by crosslinking, so that they could then be identified after DNA isolation.     

Binding of ethidium and bis(methidium)spermine to Z DNA by intercalation

The interaction of ethidium bromide, a DNA intercalating drug, and bis( methidium )spermine, a DNA bis-intercalating compound, with the left-handed Z form of poly(dG-dC) has been studied in 4.4 M NaCl. Spectrophotometric analysis using absorption, fluorescence and circular dichroism indicates that the complex formed between ethidium and Z DNA resembles very closely that formed with B DNA. This suggests that ethidium binds to Z DNA by intercalation. 31P NMR spectra are presented showing both the conversion of the Z form to the B form with increasing amounts of drug and the typical Z form spectrum at low binding densities. Data are also presented which show that the bifunctional intercalator bis( methidium )spermine binds to Z DNA in a manner similar to its binding to B DNA, i.e., by bis-intercalation. These results are important for our understanding the behavior of Z DNA and its biological significance.     

Synthesis of analogues of a flexible thiopyrylium photosensitizer for purging blood-borne pathogens and binding mode and affinity studies of their complexes with DNA

A series of thio- and selenopyrylium analogues of 2,4-di(4-dimethylaminophen-yl)-6-methylthiopyrylium iodide were prepared in five steps from 4-dimethylaminophenyl-propargyl aldehyde and the corresponding lithium acetylide. When bound to DNA, all of the dyes absorb at wavelengths >600nm, which avoids the hemoglobin band I maximum at 575nm. The binding of the series of dyes to double-stranded DNA was examined spectrophotometrically and by isothermal titration calorimetry to determine binding constants, by a topoisomerase I DNA unwinding assay, by competition dialysis with [poly(dGdC)](2) and [poly(dAdT)](2), and by ethidium bromide displacement studies to examine propensities for intercalation, and by circular dichroism studies. The dyes were found to show mixed binding modes.     

Stabilization of Z-DNA by polyarginine near physiological ionic strength.

The identification of left handed or Z-DNA in solutions of poly d(GC) in high salt suggests that left handed DNA may exist in biological systems if stabilized at lower ionic strength. In the present study we show that binding of polyarginine to the Z form of poly d(GC) results in a protein-Z-DNA complex stable near physiological ionic strength. The percentage of Z-DNA in the low salt polyarginine-poly d(GC) complex was measured from the DNA circular dichroism spectrum. The ratio of Z to B-DNA is a linear function of polyarginine concentration and is sensitive to proteolytic digestion by trypsin. These results suggest that arginine-rich proteins may stabilize Z-DNA in vivo.     

Fluorescence-detected circular dichroism of ethidium bound to poly(dG-dC) and poly(dG-m5dC) under B- and Z-form conditions

The equilibrium binding of ethidium to poly(dG-dC) and poly(dG-m5dC) under conditions favoring B and Z forms was investigated with fluorescence-detected circular dichroism (FDCD) and optical titration methods. FDCD spectra indicate a similar geometry for the intercalated ethidium under both B- and Z-form conditions, even at low levels of bound ethidium. The magnitude of the 310-330-nm FDCD band as a function of the bound drug to base pair ratio (r) indicates ethidium binds to poly(dG-dC) in 4.4 M NaCl and to poly(dG-m5dC) in 25 mM MgCl2 by clustering. Under these conditions, circular dichroism spectra indicate the polymer is largely Z form. Thus, it appears ethidium clusters into regions it has induced into a right-handed form. For all conditions studied, the FDCD spectra provided no evidence for a left-handed binding site. Under B-form conditions, binding is random.     

Z* DNA, the left-handed helical form of poly[d(G-C)] in MgCl2-ethanol, is biologically active.

The interconversion between the right (R) and left (L) helical forms of poly[d(G-C)] occurs at low concentrations of MgCl2 and EtOH, acting together in a highly synergistic manner. Thus, the cooperative R---L transition is induced by only 0.4 mM and 4 MM MgCl2 in combination with 20% and 10% EtOH, respectively. The L form of poly[d(G-C)] formed under these conditions has the spectroscopic properties (absorption, circular dichroism) previously demonstrated under high salt conditions (Pohl and Jovin, 1972) and thought to correspond to the left-handed Z DNA structures recently established by X-ray crystallography (Wang et al., 1979; Drew et al., 1980). However, L DNA formed in Mg2+-EtOH (which we designate as Z* DNA) has unique properties: a) it can be sedimented readily out of solution at low speed, indicative of condensation and intermolecular aggregation; b) it supports the binding of several intercalating (ethidium bromide, actinomycin D) and non-intercalating (mithramycin) drugs, although these interact preferentially with the R (i.e., B) form of DNA; and c) it functions as a template for Escherichia coli RNA polymerase. B and Z* DNAs can be generated under identical ionic conditions and compared in a number of biochemical systems. Our results suggest that left-handed DNA may form under physiological conditions and serve a biological function.     

Ethidium binding to left-handed (Z) DNAs results in regions of right-handed DNA at the intercalation site

The equilibrium binding of ethidium to the right-handed (B) and left-handed (Z) forms of poly(dG-dC).poly(dG-dC) and poly(dG-m5dC).poly(dG-m5dC) was investigated by optical and phase partition techniques. Ethidium binds to the polynucleotides in a noncooperative manner under B-form conditions, in sharp contrast to highly cooperative binding under Z-form conditions. Correlation of binding isotherms with circular dichroism (CD) data indicates that the cooperative binding of ethidium under Z-form conditions is associated with a sequential conversion of the polymer from a left-handed to a right-handed conformation. Determination of bound drug concentrations by various titration techniques and the measurement of circular dichroism spectra have enabled us to calculate the number of base pairs of left-handed DNA that adopt a right-handed conformation for each bound drug; 3-4 base pairs of left-handed poly(dG-dC).poly(dG-dC) in 4.4 M NaCl switch to the right-handed form for each bound ethidium, while approximately 25 and 7 base pairs switch conformations for each bound ethidium in complexes with poly(dG-dC).poly(dG-dC) in 40 microM [Co(NH3)6]Cl3 and poly(dG-m5dC).poly(dG-m5dC) in 2 mM MgCl2, respectively. The induced ellipticity at 320 nm for the ethidium-poly(dG-dC).poly(dG-dC) complex in 4.4 M NaCl indicates that the right-handed regions are nearly saturated with ethidium even though the overall level of saturation is very low. The circular dichroism data indicate that ethidium intercalates to form a right-handed-bound drug region, even at low r values where the CD spectra show that the majority of the polymer is in a left-handed conformation.     

Thermal denaturation of the DNA-ethidium complex. Redistribution of the intercalated dye during melting.

The temperature dependence of the circular dichroism of the DNA-ethidium bromide complex at elevated temperatures provides evidence that the optical activity of the complex near 307 nm originates from interactions between intercalated dye molecules while the optical activity near 515 nm results from singly intercalated ethidium bromide molecules. The behavior of the circular dichroism of the complex at elevated temperatures also explains the higher ellipticities near 307 nm which characterize complexes formed between ethidium bromide and denaturated DNA. Finally the circular dichroism data indicate that the melting of the complex takes place in a stepwise manner with some DNA regions, probably AT-rich regions, dissociating first. The implications of these findings regarding the inhibiting effect of ethidium bromide on the function of DNA polymerase are examined.     

Electronmicroscopy and circular dichroism of the dynamics of the formation and dissolution of supramolecular forms of Z-DNA

Previous electronmicroscopic studies had shown that N-acetylaminofluorene (AFF)-substituted poly(dG-dC)-poly(dG-dC) in the Z conformation, in 10mM Mg++, condensed into periodically banded, branched structures. We now show that similar structures are seen when poly(dG-dC)-poly(dG-dC) is converted to the Z conformation by heating to 60 degrees C in 1mM Mn++ or to 65 degrees in the presence of 0.5mM Mn++. We demonstrate that these banded structures form in solution, i.e. they are not artifacts of the preparative procedures used for electronmicroscopy, by crosslinking the Z conformers in solution with DL-diepoxybutane (DEB), and then restoring the solution to conditions that favor return to the B conformation. Circular dichroism (CD) and immunochemical studies showed that the Z conformation was maintained and the banded supramolecular structures were still seen by electronmicroscopy. Electronmicroscopy and CID were also used to follow the dissolution of the supramolecular structures by controlled scission of the crosslinks with the eventual return to the short double stranded molecules typical of the B conformers. During this process, supercoiled structures, both toroidal and interwound, were observed. The relationship of the toroids to the banded structure is discussed in the context of two possible structures for the condensed polynucleotide. We conclude that DNA, whether in the B or Z conformation, is extremely flexible in the presence of appropriate counter ions, and we present evidence that earlier estimates of their persistence lengths are too high. The inherent tendency to form condensed, highly organized structures is a property of DNA that could play an important role in its "packaging," and in its functions, and might have been critical for the evolution and replication of early life forms.     

Comparison of base inclination in ribo-GC and deoxybribo-GC polymers,and synthesis of poly(rGrC)-poly(rGrC)

The inclination angle between the base normal and the helix axis, and the axes around which the bases incline, are measured for ribo-GC polymers in buffer by using flow linear dichroism (LD), and compared to measurements for deoxyribo-GC polymers in buffer and under dehydrating conditions. A new method is designed to synthesize poly(rGrC) -poly(rGrC), which is not available commercially, in large quantities. The LD of this RNA reveals inclination angles that are similar to the B-form DNA in buffer, although the axes are different. The CD of poly(dGdC)-poly(dGdC) under the dehydrating conditions is similar to poly(rGrC)-poly(rGrC), indicating it is in the A form, and the LD gives larger inclination angles than either the B form or the corresponding RNA. Poly(dG)-poly(dC) is in the A form in buffer. Comparison among poly(rG)-poly(rC) in buffer, and poly (dG)-poly(dC) in buffer and under dehydrating conditions, reveals similar inclination angles and axes, although the LD shows that the DNA has the largest inclination angles. Except for poly(rGrC)-poly(rGrC), which has a unique reduced dichroism, all the axes for G are similar, as are the axes for C. © 1995 John Wiley & Sons, Inc.     

Glycation induced conformational transitions in cystatin proceed to form biotoxic aggregates: A multidimensional analysis

Hyperglycaemic conditions facilitate the glycation of serum proteins which may have predisposition to aggregation and thus lead to complications. The current study investigates the glycation induced structural and functional modifications of chickpea cystatin (CPC) as well as biological toxicity of the modified protein forms, using CPC-glucose as a model system. Several structural intermediates were formed during the incubation of CPC with glucose (day 4, 8, 12, & 16) as revealed by circular dichroism (CD), altered intrinsic fluorescence, and high ANS binding. Further incubation of CPC with glucose (day 21) formed abundant β structures as revealed by Fourier transform infrared spectroscopy and CD analysis which may be due to the aggregation of protein. High thioflavin T fluorescence intensity and increased Congo red absorbance together with enhanced turbidity and Rayleigh scattering by this modified form confirmed the aggregation. Electron microscopy finally provided the valid physical authentication about the presence of aggregate structures. Functional inactivation of glucose incubated CPC was also observed with time. Single cell electrophoresis of lymphocytes and plasmid nicking assays in the presence of modified CPC showed the DNA damage which confirmed its biological toxicity. Hence, our study suggests that glycation of CPC not only leads to structural and functional alterations in proteins but also to biotoxic AGEs and aggregates.     

Carbon nanotubes selective destabilization of duplex and triplex DNA and inducing B-A transition in solution

Single-walled carbon nanotubes (SWNTs) have been considered as the leading candidate for nanodevice applications ranging from gene therapy and novel drug delivery to membrane separations. The miniaturization of DNA-nanotube devices for biological applications requires fully understanding DNA-nanotube interaction mechanism. We report here, for the first time, that DNA destabilization and conformational transition induced by SWNTs are sequence-dependent. Contrasting changes for SWNTs binding to poly[dGdC]:poly[dGdC] and poly[dAdT]:poly[dAdT] were observed. For GC homopolymer, DNA melting temperature was decreased 40°C by SWNTs but no change for AT-DNA. SWNTs can induce B–A transition for GC-DNA but AT-DNA resisted the transition. Our circular dichroism, competitive binding assay and triplex destabilization studies provide direct evidence that SWNTs induce DNA B–A transition in solution and they bind to the DNA major groove with GC preference.     

A circular dichroism study of DNA-basic peptides associations in the absence or in the presence of Ca++.

The interaction of DNA with basic peptides (Lys methyl ester*, Lys2, (Lys)2methyl ester) has been studied by circular dichroism. The changes of the DNA CD spectra in the presence of peptides are interpreted as a transconformation from the B form to the C form of DNA. The presence of Ca++ in the mixture induces a supplementary transconformation. These observations suggest Ca++-basic peptides-DNA complexes as a structural model for chromatin.