Circular dichroism of films of polynucleotides

Ammonium Gemini Surfactants Form Complexes with Model Oligomers of siRNA and dsDNA

Dimeric cationic surfactants (gemini-type) are a group of amphiphilic compounds with potential use in gene therapy as effective carriers for nucleic acid transfection (i.e., siRNA, DNA, and plasmid DNA). Our studies have shown the formation of lipoplexes composed of alkanediyl-α,ω-bis[(oxymethyl)dimethyldodecylammonium] chlorides and selected 21-base-pair nucleic acid (dsDNA and siRNA) oligomers. To examine the structure and physicochemical properties of these systems, optical microscopy, circular dichroism spectroscopy (CD), small-angle X-ray scattering of synchrotron radiation (SR-SAXS), and agarose gel electrophoresis (AGE) were used. The lengths of spacer groups of the studied surfactants had a significant influence on the surfactants’ complexing properties. The lowest charge ratio (p/n) at which stable lipoplexes were observed was 1.5 and the most frequently occurring microstructure of these lipoplexes were cubic and micellar phases for dsDNA and siRNA, respectively. The cytotoxicity tests on HeLa cells indicated the non-toxic concentration of surfactants to be at approximately 10 µM. The dicationic gemini surfactants studied form complexes with siRNA and dsDNA oligomers; however, the complexation process is more effective towards siRNA. Therefore these systems could be applied as transfection systems for therapeutic nucleic acids.

Structural characterization of transfection nanosystems based on tricationic surfactants and short double stranded oligonucleotides

For several years cationic surfactants have been the subjects of extensive studies as potential transgene carriers to be used in gene therapy. We report the formation of stable complexes between 21 base pairs oligonucleotides - siRNA, enhancing DMPK gene, and dsDNA and two tricationic surfactants (1,2,3-propanetri[oxymethyl-3-(1-dodecylimidazolium)]chloride and 1,2,3-propanetri[(oxymethyl)dimethyldodecylammonium]chloride. Structural studies by SAXS and TEM have shown that the dominant structure of the obtained lipoplexes is based on hexagonal, lamellar and cubic phases, packed in highly ordered aggregates. It has been established that tricationic surfactants can be used as siRNA carriers in gene therapy.

Liquid-Crystalline Dispersions of Double-Stranded DNA

In this review, we compare the circular dichroism (CD) spectra of liquid-crystalline dispersion (LCD) particles formed in PEG-containing aqueous-salt solutions with the purpose of determining the packing of ds DNA molecules in these particles. Depending on the osmotic pressure of the solution, the phase exclusion of ds DNA molecules at room temperature results in the formation of LCD particles with the cholesteric or the hexagonal packing of molecules. The heating of dispersion particles with the hexagonal packing of the ds DNA molecules results in a new phase transition, accompanied by an appearance of a new optically active phase of ds DNA molecules. Our results are rationalized by way of a concept of orientationally ordered “quasinematic” layers formed by ds DNA molecules, with a parallel alignment in the hexagonal structure. These layers can adopt a twisted configuration with a temperature increase; and as a result of this process, a new, helicoidal structure of dispersion particle is formed (termed as the “re-entrant” cholesteric phase). To prove the cholesteric pattern of ds DNA molecules in this phase, the “liquid-like” state of the dispersion particles was transformed into its “rigid” counterpart.

The study of complexation between dicationic surfactants and the DNA duplex using structural and spectroscopic methods

Dicationic (also known as gemini or dimeric) bis-alkylimidazolium surfactants belong to a group of non-viral transfection systems proposed for the successful introduction of different types of nucleic acids (i.e., siRNA, DNA oligomers, and plasmid DNA) into living cells.

Vibrational CD (VCD) and atomic force microscopy (AFM) study of DNA interaction with Cr3+ ions: VCD and AFM evidence of DNA condensation

The interaction of natural calf thymus DNA with Cr(3+) ions was studied at room temperature by means of vibrational CD (VCD) and infrared absorption (ir) spectroscopy, and atomic force microscopy (AFM). Cr(3+) ion binding mainly to N(7) (G) and to phosphate groups was demonstrated. Psi-type VCD spectra resembling electronic CD (ECD) spectra, which appear during psi-type DNA condensation, were observed. These spectra are characterized mainly by an anomalous, severalfold increase of VCD intensity. Such anomalous VCD spectra were assigned to DNA condensation with formation of large and dense particles of a size comparable to the wavelength of the probing ir beam and possessing large-scale helicity. Atomic force microscopy confirmed DNA condensation by Cr(3+) ions and the formation of tight DNA particles responsible for the psi-type VCD spectra. Upon increasing the Cr(3+) ion concentration the shape of the condensates changed from loose flower-like structures to highly packed dense spheres. No DNA denaturation was seen even at the highest concentration of Cr(3+) ions studied. The secondary structure of DNA remained in a B-form before and after the condensation. VCD and ir as well as AFM proved to be an effective combination for investigating DNA condensation. In addition to the ability of VCD to determine DNA condensation, VCD and ir can in the same experiment provide unambiguous information about the secondary structure of DNA contained in the condensed particles.

A-DNA accommodates adducts derived from diol epoxides of polycyclic aromatic hydrocarbons bound in a "side-stacking" mode

The minor groove of undistorted A-DNA provides a good binding site for planar, hydrophobic moieties such as unmetabolized polycyclic aromatic hydrocarbons (PAHs), and the base pairs at the ends of short oligodeoxynucleotide helices. It also accommodates the chief adduct derived from the metabolically activated form of the carcinogen benzo[a]pyrene. B-DNA lacks such a site. Computerized models have been generated for the major (N2-guanine-linked) adducts formed at this site by both + and - enantiomers of anti-benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide (anti-BPDE) with poly(dG).poly(dC) in the A-DNA conformation. The BPDE adducts lie in the shallow, relatively hydrophobic minor groove of the A-DNA after empirical potential energy minimization using the program AMBER. We term this binding mode "side-stacking." The side-stacked + anti-BPDE may constitute the chief carcinogenic lesion derived from benzo[a]pyrene.

Condensed form of (dG-dC)n X (dG-dC)n as an intermediate between the B- and Z-type conformations induced by sodium acetate

Circular dichroism and laser Raman spectroscopy reveal that the synthetic DNA polymer (dG-dC)n X (dG-dC)n undergoes a cooperative transition induced by sodium acetate from a right-handed B-form to a left-handed Z-type conformation with a midpoint at 2.05 M. However, at concentrations only slightly higher than the end point of this transition (above approximately 2.2 M) and up to approximately 2.65 M, the Z-form is not stable in solution but aggregates to form highly condensed DNA. A manyfold increase of positive ellipticity in the range 340-250 nm is observed which is indicative of a psi (+)-type structure. At even higher concentrations (greater than or equal to 2.7 M), the Z-form is stable without condensation, and there is no change in the inverted CD spectrum. All structural transitions are reversible except that it is not possible to redissolve the highly condensed psi (+)-form by further increasing the salt concentration to greater than or equal to 2.7 M. The very high cooperativity of these transitions enables the DNA polymer to adopt three distinctly different structures (B-, Z-, and psi-forms) within a narrow range of sodium acetate concentration (approximately 200 mM). The Raman spectra of the condensed form and the Z-form in very concentrated sodium acetate show that the psi (+)-type state forms without substantial changes of the secondary conformation of the DNA. This indicates that the left-handed Z-helix of (dG-dC)n X (dG-dC)n can form psi-type aggregates with an ordered superstructure similar to those observed for natural right-handed DNA helices.

Study of DNA films by the CD, X-ray and polarization microscopy techniques

DNA films with psi +/- CD spectra have been investigated. X-ray analysis has shown the sign of the psi spectra to be independent of the secondary structure of DNA. The appearance of the psi spectra is attended by the formation of a characteristic polygonal texture of the cholesteric type in the DNA film.

A 300 MHz and 600 MHz proton NMR study of a 12 base pair restriction fragment: investigation of structure by relaxation measurements

The 1H NMR spectrum of a 12 base pair DNA restriction fragment has been measured at 300 and 600 MHz and resonances from over 70 protons are individually resolved. Relaxation rate measurements have been carried out at 300 MHz and compared with the theoretical predictions obtained using an isotropic rigid rotor model with coordinates derived from a Dreiding model of DNA. The model gives results that are in excellent agreement with experiment for most protons when a 7 nsec rotational correlation time is used, although agreement is improved for certain base protons by using a shorter correlation time for the sugar group, or by increasing the sugar-base interproton distances. A comparison of non-selective and selective spin-lattice relaxation rates for carbon bound protons indicates that there is extensive spin diffusion even in this short DNA fragment. Examination of the spin-spin relaxation rates for the same type of proton on different base pairs reveals little sequence effect on conformation.

Interactions of Hg(II) ions with DNA as revealed by CD measurements

The circular dichroism spectra of Hg(II) complexes with native calf thymus DNA, chemically methylated Streptomyces chrysomallus DNA and with Ag(I)-DNA complexes were measured in the region of 220 - 340 nm. As a main result a conversion of the conservative CD spectrum of DNA to a distinct nonconservative type of CD spectrum for the complexes occurs with increasing Hg(II) concentration. The CD spectra of the Hg(II) complexes as well as some additional arguments strongly support the idea, that DNA in the complex undergoes a structural transition to a more condensed state with 4 -like character.

Nature of conformational changes in poly[d(A-T)-d(A-T)] in the premelting region

The conformation of the synthetic DNA, poly-[d(A-T)-d(A-T)], has been investigated both in the solid state and in dilute aqueous solutions at different temperatures below its melting point. The change of the circular dichroism (CD) spectra of poly[d(A-T)-d(A-T)] solutions with decreasing temperatures from just below the melting point to 0 degrees involves a specific decrease of the intensity of the 262 nm CD band. This conformational change has been assigned to a gradual and partial transition from the B to C form, on the basis of the following results: (i) By the use of infrared dichroism measurements on oriented films we have defined humidity and salt conditions under which B and C forms of poly[d(A-T)-d(A-T](Li+) are stable. In addition, we find that ammonium salts induce the C form of poly[d(A-T)-d(A-T)] even at high relative humidity. (ii) CD studies of the films of the lithium salt of poly[d(A-T)-d(A-T)] under the same conditions have given CD spectra corresponding to the B and C forms of this polynucleotide. In addition, the CD spectrum of the ammonium salt of poly[d(A-T)-d(A-T)] in solution approaches that of the C form in films. (iii) The conformational change of poly[d(A-T)-d(A-T)] as a function of temperature can be entirely explained on the basis of changes in the double-stranded base-paired structure. Our data rule out hydrogen bond breaking and unstacking or "breathing" as an explanation of the premelting changes. Curves of the continuous variation of CD(epsilon at 262 nm) as a function of temperature (from 0 degrees to the melting zone) show similar slopes in the presence of different agents stabilizing the double-stranded structure, such as Mg++, or at different salt concentration (KCl), indicating that the nature of the process is independent of ionic strength. Some specific effects were observed in the influence of certain neutral salts; ammonium induces the C form whereas magnesium favors the B form. CD data give direct evidence that a DNA like poly[d(A-T)-d(A-T)] need not change conformation upon transition from a dilute aqueous solution to a highly hydrated (film/gel) solid state. The change of conformation begins only at a defined partial dehydration.

Basic polypeptides as histone models. Effect of conformation, base composition and methylation of nucleic acids on the interaction with H1 and histone models and on the circular dichroism of complexes

Interaction of histone H 1 and models simulating histone chains was followed by monitoring the melting curves of supernatants after the sedimentation of aggregated complexes. In a mixture of two DNAs the histones reacted selectively with (A+T)-rich and non-methylated DNA, respectively. H 1 and (Ala-Lys-Pro)n also interacted preferentially with DNA in a mixture with double stranded RNA whereas (Lys30,Ala70)n did not show any selectivity. (G+C)-rich DNA in complexes showed CD spectra the intensity of which decreased with increasing DNA methylation to values comparable with these of complexes of (A+T)-rich DNA. In complexed with double stranded RNA only the polymer (Lys30,Ala70) displayed CD pattern similar to spectra of complexes with DNA. It was concluded that formation and structure of complexes depend selectively on the DNA conformation and base composition.

Different effects of polylysine and polyarginine on the transition to a condensed state of DNA in polyethyleneglycol/salt solution

Circular dichroism spectroscopy has been used to investigate the influence of polylysine and polyarginine on the transition to a condensed state of DNA brought about by high concentrations of polyethyleneglycol and salt. From the dependence on DNA concentration of the CD signals, the anomalous CD of free DNA in polyethyleneglycol/salt solution was attributed to the intermolecular association of DNA molecules. The CD spectral changes in polyethyleneglycol/salt solution of the DNA - polylysine complex were indistinguishable from those of free DNA while the DNA-polyarginine complex suffered much smaller spectral changes as compared with free DNA, at low DNA concentrations where time-independent CD spectra were observed in polyethyleneglycol/salt solution for both the complexed and free DNA. The repression of the spectral change by the latter complex was more remarkable at higher ratios of polyarginine to DNA. The facts indicate that, whereas polylysine binding has little influence on the intermolecular structural transition of double-stranded DNA into a compact molecular configuration in polyethyleneglycol/salt solution, polyarginine binding has an effect of inhibiting the transition.

Basic polypeptides as histone models: circular dichroism of complexes of model polypeptides with DNA

Circular dichroism (CD) was used to study the complexes of DNA (in 0.15M NaCl) with two polypeptides considered as models of the histone molecules. CD spectra in the region of DNA absorption were studied with respect to the concentration used for annealing and to the molecular weight and composition of the DNA used. The properties of supernatants after centrifugation of aggregated complexes were examined. The effect of selectively bound antibiotics (actinomycin D and netropsin) on CD sprectra of complexes was investigated. The induced CD of proflavine molecules bound to DNA in the various complexes was also studied. It was concluded that changes in the CD spectra of DNA in complexes with the polypeptides are due to the formation of chiral superstructures, even if some conformational changes of DNA molecules themselves may also be decisive in some cases. The superstructure is affected by the composition of DNA, the role of (G + C) rich segments being particularly important.

Interaction of histone f2al fragments with deoxyribonucleic acid. Circular dichroism and thermal denaturation studies

The glycine-arginine-rich histone, f2al (IV) (102 amino acids), from calf thymus was cleaved at residue 84 with cyanogen bromide. Complexes containing homologous DNA and each f2al fragment were reconstituted by means of Gdn-HC1 gradient dialysis. The circular dichroic (CD) spectra of these complexes were all examined in 0.14 M NaC1. The CD spectra of the DNA-f2al fragment complexes did not differ appreciably from that of DNA alone in the wavelength region above 240 nm. However, intact f2al-DNA complexes yield CD spectra which differ significantly (enhanced, blue-shifted, 273-nm band) from that of native DNA (Shih and Fasman, 1971). The small C-terminal fragment (85-102) was bound weakly to DNA under the conditions used. However, the large basic N-terminal fragment (1-83) was bound as well to DNA as was whole f2al, but produced no CD distortion. The conformation of the N-terminal fragment, unlike intact f2al, was not changed upon increasing the ionic strength to 0.14 M NaF. These results complement previous studies on f2al and its N-terminal CNBr fragment (Ziccardi and Schumaker, 1973). Thermal denaturation of the complexes in 2.5 X 10(-4) M EDTA was monitored simultaneously by changes in the absorption and CD spectra. All complexes showed a thermal transition at 45 degrees (Tml), attributable to the melting of free, double-stranded DNA. In addition, f2al-DNA and N fragment-DNA complexes displayed melting phenomena at 88 and 78 degrees (Tm2), respectively, caused by the denaturation of the histone-bound DNA. This difference in Tm2 constitutes further evidence that loss of the 18-amino-acid carboxyl end segment of f2al prohibits the unique type of interaction which occurs between DNA and the intact histone.

Investigation of huge negative circular dichroism spectra of some nucleoproteins

Under certain conditions of preparation, DNA, whether free or complexed with polylysine or histone KAP (I, fl), produce huge negative circular dichroism (CD) spectra with maxima at about 270nm. In order to investigate the cause of these spectra, reconstituted polylysine-DNA complex was used as a model system. It was found that the CD change of DNA in the complex is not a linear function of the fraction of base pairs bound. Such a CD spectrum is not changed despite dilution up to 128 folds for as long as 12 hours. Difference CD spectra taken between free DNA and any of the complexes are qualitatively the same, and are similar to those of free DNA and nucleohistone KAP (Fasman et al., Biochemistry 9, 2814-2822, 1970), free DNA and direct mixed polylysine-DNA complexes, or free DNA in high salt (Chang et al., Biochemistry12, 3028-3032, 1973). The suggestion is made that this CD spectrum might be caused by specific conformational changes in DNA, perhaps belonging to the family of B to C transitions followed by a further structural distortion of DNA due to aggregation of the nucleoprotein molecules.