The circular dichroism of complexes of 2,7-di-tertiary-butyl proflavine with DNA

The binding isotherm of 2, 7-di-tert-butyl proflavine on calf thymus DNA has been measured by dialysis equilibrium. The CD spectra of complexes of the dye and DNA have been measured, and the variation of the induced circular dichroism of the dye with the amount of dye bound (r) has been found. The results show that di-tert-butyl proflavine binds to DNA in a completely different manner from proflavine itself, since both the visible and ultraviolet CD spectra of complexes of the two dyes with DNA differ markedly. The conformation of the nucleic acid is not affected by the binding of di-tert-butyl proflavine. It is possible that these results may allow determination, by using CD spectroscopy, of whether molecules intercalate into DNA.     

The circular dichroism in the ultraviolet of aminoacridines and ethidium bromide bound to DNA

The circular dicrosim (CD) spectra of complexes of DNA with ethidiun bromnide, profiavine, 9-aminoacridine and 4-etliyl-9-amino-acridine have been determined between 220 and 450 nm, the range lieing extended to 600 nm for ethidiufm bromide. The variation of the magnitude of the visible and near—ultraviolet CD spectra of ethidium bromide—DNA complexes with the amount of ligand bound (r) suggests a common binding position with profiavine. On the other hand, 4-ethyl-9-aminoacndine complexed to DNA shows CD spectra not distinguishable from those of 9-aminnoacnidmc in both the visible and ultraviolet. The interpretation of these results with respect to the stereochemistry of the DNA-ligand complexes is discussed.     

Interaction of ethidium bromide with DNA. Optical and electrooptical study

The binding of ethidium bromide to DNA has been studied by various optical methods. From fluorescence polarization studies, and film, electric linear dichroism, and circular dichroism spectra, we propose assignments of the absorption bands of the dye, which are discussed in connection with wave-mechanical calculations recently reported. The optical activity induced in the dye absorption bands upon binding to DNA was attributed to various origins depending on the electronic transition considered. The visible absorption band displayed a circular dichroism due to the asymmetry of the binding site and independent of the amount of binding. The transition identified at 378 nm from the circular dichroism and electric dichroism observations was thought to be due to a magnetic-dipole transition. It remained constant with increasing amounts of dye bound. The main ultraviolet band showed circular dichroism characteristics corresponding to exciton interactions between dye molecules bound to neighboring sites. The electric dichroism observed for the strongly bound dye molecules indicated that the phenanthridinium ring of ethidium bromide was probably not perfectly parallel to the DNA base planes. When the amount of dye bound to DNA exceeded the maximum amount compatible with the exclusion of adjacent binding sites, the electric dichroism decreased owing to the appearance of externally bound dye molecules with no contribution to the dichroism. Sonicated DNA was used to study the lengthening of the DNA molecule upon complexation. Although the viscosity of the complexes increased with the amount of binding, the rotational diffusion coefficient measured by the electric birefringence relaxation was not detectably affected. The absence of variation in the electric birefringence with the binding indicated that the DNA base stacking remained unaltered.     

Differences in circular dichroism and fluorescence between the DNA complexes formed with 3-amino- and 3,8- diaminophenanthridinium derivatives

The conformation of DNA complexes formed with various 3-amino- and 3,8-diamino-phenanthridinium derivatives were examined by CD and fluorescence methods. The CD of these complexes is characterized by major bands in the 300–350-nm and the 400–550-nm regions. The CD properties of the complexes formed with diaminophenanthridinium derivatives suggest that the structure of such complexes is well represented by the intercalation complex formed between DNA and ethidium bromide. The substantial and regular increases in ellipticities near 308 nm that occur with increasing DNA-bound diaminophenanthridinium to DNA phosphate ratios (r) may result from direct interactions between molecules intercalated in neighbouring binding sites. In contrast, the changes in the shape of the CD of DNA complexes of monoaminophenanthridinium derivatives with r and the much lower maximum ellipticities attained suggest that near-neighbor interactions among intercalated monoaminophenanthridinium derivatives occur much less efficiently than in the corresponding diamino complexes, if at all. Although alternative explanations for the differences in the optical properties between the mono- and diaminophenanthridinium complexes of DNA may be offered, such results seem to indicate that complexes formed with monoaminophenanthridinium derivatives are characterized by a conformation which is quite distinct and different from that of the DNA–diaminophenanthridinium complexes. This conclusion is further supported by the considerable increase in fluorescence that accompanies the binding of the diaminophenanthridinium derivatives to DNA as compared to the minor increases, which occur upon the binding of the monoaminophenanthridinium compounds. The importance of conformation as a factor influencing template, function, especially with respect to the RNA polymerase-catalyzed synthesis of RNA, is now well appreciated. Therefore, methods which could provide information readily about changes in the conformation of a template, i.e., as a result of dye intercalation, are expected to facilitate our understanding of the effects of conformational change on the function and activity of templates.     

The absence of non-local conformational changes in OR3 operator DNA on complexing with the cro repressor

The Interaction of the cro protein of lambda phage with a synthetic OR3 operator having 17 base pairs in length and with its 9 bp fragment has been studied using the circular dichroism (CD) method. In both cases, a considerable change in the CD of the samples was found in the region 260-300 nm upon the addition of the cro protein. The stoichiometry obtained by the CD titration was identical for OR3 and its 9 bp fragment: one duplex per dimeric cro. NaCl addition makes the complexes dissociate so that the 9 bp fragment becomes free at [NaCl] greater than 0.2 M while the whole OR3 becomes free at [NaCl] greater than 0.5 M. The CD spectra of both the free duplexes show a typical B-form conservative pattern with a positive CD band (270 nm) and a negative one (250 nm). The specific complexing of both the duplexes results in a substantial CD depression in the positive band. The most pronounced effect occurs at 280 nm. This spectral change is quite distinct from those in the B to A transition and in the non-cooperative winding of the DNA within the B-family of forms. The interaction of the cro protein with the non-operator DNAs, calf thymus DNA and a synthetic 10 bp duplex, reveals no visible CD changes at all. An inference is drawn that the CD change in the specific complexes is mainly due to the induced CD in tyr-26 upon its interaction with a specific base pair in the operator or its fragment, the operator DNA conformation being conserved in a B-like form as a whole.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformation and properties of DNA–(Lys33, Leu67)100–(Orn)20 complex: A nucleohistone model

The synthesis and characterization of the block copolypeptide (Leu⁶⁷, Lys³³)₁₀₀Orn₂₀, a synthetic model of histone, are reported. In neutral aqueous solutions, 80% of the etheropolypeptide block assumes an α-helical conformation, whereas the polyornithine block is in a random-coil conformation. In the association complexes with DNA, melting and titration experiments, as well as CD results, indicate that the polyornithine block interacts with DNA, whereas at least 2/3 of the lysine residues of the (Leu, Lys) moiety are excluded from the direct binding with DNA. CD spectra of the association complexes reveal significant differences from those obtained with DNA–polyornithine and DNA–polylysine complexes but substantial similarities with CD spectra of native and reconstituted nucleohistones. In contrast to DNA–polyornithine complexes, the CD spectra of the ternary complexes, copolypeptide–DNA–ethidium bromide, indicate a strong reduction of the dye intercalation. The low-angle x-ray diffraction pattern, reminiscent of that of chromatin, reveals the presence of a superstructure in these complexes. The results obtained are discussed in connection with the expected structural features of the model.     

Interaction of ethidium bromide with DNA: effect of LiCl and ethylene glycol.

The interaction of the intercalating dye ethidium bromide with several native and synthetic polydeoxyribonucleic acids has been studied by means of circular dichroic spectra. The CD of DNA-ethidium bromide complexes in the 290-360 nm region is characterized, especially at high salt and at high ethylene glycol content, by positive and negative bands near 308 nm and 295 nm, respectively. These dye associated CD bands are unaffected by the addition of LiCl or ethylene glycol, suggesting that the relative conformation of dye and neighboring base pairs does not change when the conformation of the rest of the DNA changes.     

Interaction of 4,5-dibromo-2,7-di-(acetatomercuri)-fluorescein with DNAs of different base composition.

The changes in absorption spectra in the visible region observed on adding different naturally occurring and synthetic DNA duplexes to solutions of 4,5-dibromo-2,7-di-(acetatomercuri)-fluorescein indicate that the mercurial reacts with polynucleotides of this type. The reaction is reversible as proved by adding excess of KCN which restores the original spectra of the free dye. The interaction is characterised also by quenching of the fluorescence of the dye and the induction of optical activity in it. The extent of these spectral effects depends strongly on the (A+T) content of the complexed DNA and decreased in the order: poly [d(A-T)], Clostridium perfringens DAN, Escherichia coli DNA, Micrococcus luteus DNA and poly(dC). From equilibrium-dialysis experiments the same order in affinity is obtained when these poly-nucleotides are at equilibrium with the same concentration of 4,5-dibromo-2,7-di-(acetatomercuri)-fluorescein. From the changes produced by different mercurials in the ORD spectra and viscosity of a DNA solution it has been concluded that 4,5-dibromo-2,7-di(acetatomercuri)-fluorescein does not cause any drastic alteration of the secondary structure of DNA.     

Interaction of lysozyme with dyes. II. Binding of bromophenol blue

The binding of lysozyme with bromophenol blue (BPB) at various dye concentrations and pH was carried out at 25 degrees C by equilibrium dialysis, ultraviolet (UV) difference and circular dichroism (CD) spectral techniques. Binding isotherms at pH 5.0 show non-cooperative binding at low dye concentrations, which change over to cooperative binding at higher concentrations indicating biphasic nature. However, binding isotherms at pH 7.0 and 9.0 show cooperative binding only, at all concentrations of the dye. The number of available binding sites decreases with the increase of pH. Gibbs free energy change, calculated on the basis of Wyman's binding potential concept, decreases with the increase of pH. Binding isotherms at pH 5.0 obtained at a lower temperature of 8 degrees C, also indicate the biphasic nature similar to those observed at 25 degrees C, but with a slight decreased strength of binding. The UV difference spectra of the complex do not show any distinct peaks in the 285 to 297 nm region eliminating any possible interaction of BPB with tryptophan and tyrosine residues of the lysozyme molecule. The CD spectra of lysozyme-BPB complex show a decrease in ellipticities with reference to native lysozyme in the near UV and far UV regions. This indicates that the lysozyme-BPB complex has a lower helical content probably due to the conformational changes induced into the native enzyme. The appearance of new positive peaks at 315 nm in the near UV region and at 592 nm in the visible region of the CD spectra may be due to the induced asymmetry into the BPB molecule as a result of its binding to a cationic residue (probably a lysine residue) of lysozyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylated protamines. II. Circular dichroism of complexes with DNA, dependency on ionic strength.

The influence of protamine phosphorylation upon the conformation of nucleoprotamine complexes was studied at different ionic strengths using circular dichroism. The sharp onset of CD spectral changes upon decreasing the NaC1 concentrationwas correlated with the beginning of complex formation and can be used to determine apparent binding affinities in terms of a critical ionic strength. It is show that phosphorylation strongly reduces the binding strength of protamines towards DNA. Directly mixed and reconstituted complexes reveal differences in their CD spectra, which decrease with increasing ionic strength. Spectra of complexes between threefold phosphorylated clupeine Z and DNA obtained by reconstitution or direct mixing at higher ionic strength resemble the phi-type spectra of DNA and are unique for the phosphorylated species. The implications of protamine phosphorylation for chromatin or DNA condensation havebeen discussed.     

The Absence of Non-Local Conformational Changes in OR3 Operator DNA on Complexing with the Cro Repressor

Abstract

The Interaction of the cro protein of λ phage with a synthetic OR3 operator having 17 base pairs in length and with its 9 bp fragment has been studied using the circular dichroism (CD) method. In both cases, a considerable change in the CD of the samples was found in the region 260-300 nm upon the addition of the cro protein. The stoichiometry obtained by the CD titration was identical for OR3 and its 9 bp fragment: one duplex per dimeric cro.

NaCl addition makes the complexes dissociate so that the 9 bp fragment becomes free at [NaCl]>0.2 M while the whole OR3 becomes free at [NaCl]>0.5 M.

The CD spectra of both the free duplexes show a typical B-form conservative pattern with a positive CD band (270 nm) and a negative one (250 nm). The specific complexing of both the duplexes results in a substantial CD depression in the positive band. The most pronounced effect occurs at 280 nm. This spectral change is quite distinct from those in the B to A transition and in the non-cooperative winding of the DNA within the B-family of forms.

The interaction of the cro protein with the non-operator DNAs, calf thymus DNA and a synthetic 10 bp duplex, reveals no visible CD changes at all.

An inference is drawn that the CD change in the specific complexes is mainly due to the induced CD in tyr-26 upon its interaction with a specific base pair in the operator or its fragment, the operator DNA conformation being conserved in a B-like form as a whole. However, some local distortions such as kinks cannot be ruled out on the basis of the CD data.     

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.     

Induced CD provides evidence for helical solution conformation in cellulosic chains

Evidence for a helical contribution to the conformation of methylcellulose in dilute solution is given by CD measurements. Congo red binds to methylcellulose in dilute aqueous solution and becomes optically active. The shape of the induced CD spectra is as predicted by exciton coupling for a helical arrangement of chromophores. The magnitude of the induced CD changes reversibly with temperature, decreasing upon heating. The dimer analogue of the polymer, prepared by acid methanolysis, does not show this effect. These observations suggest that the induced optical activity reflects the conformational dissymmetry of the polymer. Analogous experiments with the cellulose oligomers (cellotriose through cellohexaose) show that five anhydroglucose units are necessary before asymmetry is induced upon dye binding.     

Conformation and orientation of chlorophyll-proteins in photosystem I by circular dichroism and polarized infrared spectroscopies

The protein conformation and orientation of Photosystem I (PS I) particles have been investigated by a combination of ultraviolet circular dichroism and polarized infrared spectroscopies. These PS I particles have been studied before and after reconstitution in phosphatidylcholine vesicles. The native state of the pigments of PS I was characterized by monitoring the low-temperature fluorescence emission spectra as well as the visible CD and linear dichroism spectra at room temperature. Computed analysis of the ultraviolet CD spectra of PS I complex indicates that the secondary structure of the protein is largely α-helical (52 ± 4%) with a very low amount of β-structure. Polarized infrared difference spectra of oriented PS I show a significant orientation of these α-helical segments with the α-helix axes tilted on the average at approx. 35° from the membrane normal.     

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.     

Structure of DNA complexes with regular polypeptides

The conformation of some regular polypeptides: (Lys-Ala)50, (Lys-Ala2)37, (Lys-Ala2)26, (Lys-Ala3)18, (Lys3-Pro)29, (Orn3-Gly)28 was studied by means of CD. The complexes of these polypeptides with DNA were obtained by the methods of jump-dilution of a two-components mixture from 2 M NaCl to 0.05 M NaCl. The extent of DNA covering by the polypeptides was compared using binding isoterms of ethidium on DNA and DNA-polypeptide complex. The length, L, which polypeptides cover on DNA was estimated by means of energy transfer between the dyes absorbed on the complexes. The CD spectra of the complexes revealed a high sensitivity to changes of the environmental conditions. Small variations in the temperature and ionic strength produces marked changes in the CD spectra of the complexes. It was suggested that observed CD changes are due to both the structural relaxation of the complexes and the existence of liquid-crystal domains in solution.     

Effect of counterions on the conformation of hyaluronic acid.

To study the effect of metal ions on the conformation of hyaluronic acid, circular dichroism (CD) and optical rotatory dispersion (ORD), along with viscosity measurements of the Na, Li, Ca, and Mg salts of the polymer, were carried out. With divalent cations, the results show a decrease in CD minima at 210 nm and an increase in ORD troughs at 220 nm, as compared to monovalent ions. To account for this behavior, the ORD in the visible range corresponding to the observed CD bands was directly calculated from the Moscowitz equation using Kronig-Kramer's transform. The background rotation was found to be more levorotatory in bivalent than in monovalent cations. The ORD spectra of various metal hyaluronates differ significantly from each other in the far ultraviolet region, especially at lower pH values. The values of intrinsic viscosities of these hyaluronates, on the other hand, are almost the same in the pH range of 1–3. These results indicate a local conformation variation rather than any appreciable change in the chain conformation of the molecule in the presence of different counterions.     

Circular dichroism of films of polynucleotides

The CD spectra of films of the lithium salt of E. coli and calf thymus DNA, and alternating d-AT : AT were measured as a function of relative humidity. Films of the ammonium acetate salt of DNA were also measured. The ammonium films yield the previously reported A-form CD spectra. A possible explanation for the small magnitude of the 260-nm band of the A-form film spectra compared to double-stranded RNA spectra is that the film DNA is in a different conformation than RNA within the A family of conformations. At relative humidities of 92% or lower, a negative nonconservative CD spectrum with negative minima near 270 and 210 nm is observed with the lithium films. The magnitude of the minima varies from film to film. In films of DNA the magnitude ranges from a delta epsilon of ?5 to ?35; d-AT : AT films show magnitudes to ?300. CD spectra of this type are designated Ψ spectra. Similar spectra have been reported from reconstituted complexes of DNA and polylysine or f-1 histone. If the origins of the film and protein–DNA complex spectra are similar, the complex spectra are not the result of specific secondary structural changes induced in the DNA by the protein fraction. Theoretical analysis suggests that Ψ spectra are not the result of changes in the secondary or tertiary structure of DNA. Instead, the previously proposed explanation based on liquid crystals is favored. The DNA could form asymmetric structures with long-range periodicity. It is likely that the observed CD spectra of f-1 complexes are artifacts of DNA aggregation. The possibility that some other previously published spectra of protein–DNA complexes also reflect artifacts is suggested.     

Effect of chemical structures of acridine and triphenylmethane dyes on the induced optical activity of DNA-dye complexes

Fifteen symmetrically substituted acridine dyes, all of which are interrelated by their chemical structures, each belonging to a C_2v symmetry, and three triphenylmethane dyes with amino or dimethylamino substituents are utilized to study necessary conditions for the appearance of extrinsic Cotton effects upon their binding to native and heat-denatured deoxyribonucleic acid (DNA). Three different kinds of the DNA–dye complexes, i.e., (1) dye added to native DNA, (2) heat-denatured DNA–dye complex, and (3) dye added to preheated DNA, were examined for each dye at a fixed P/D value of about 4. Optical activity was always observed for the compelexes of type (1) in each absorption band of the dyes in the visible and near-ultraviolet region. Two exceptions are 9-acetamido- and 9-hydroxyacridine, both being nonionic in aqueous solution at a pH range of 6. Acridinium chloride was unable to exhibit any definite extrinsic Cotton effect for complexes (2) and (3). Thus, the monocationic form of a dye due to the protonation or quaternization of the ring nitrogen in acridines or exonuclear amino nitrogen in triphenylmethane dyes is concluded to be an essential factor for extrinsic Cotton effect to appear. Changes in the absorption spectra upon complex formation are also related to the structure of dyes. Hypochromism and bathochromism are associated with the induced optical activity in all cases in the presence of native and denatured DNA.     

Induced optical activity in the complex of poly(L-arginine) with azo dyes

The absorption and CD spectra of the complexes of poly(L -arginine) (PLA) and azo dyes have been measured in aqueous solution. On complexation, Blue-shifted additional absorption bands were observed. In the wide pH 4–11 range, induced CD was observed at the visible wavelengths corresponding to the blue-shifted absorption bands. The induced CD arose from the dimeric dye molecules bound to PLA in the α-helical structure. When a modified analysis of induced CE is made by the excition chirality method, the origin of the induced CD can be assigned to the dipole coupling. The PLA–dye complexes showed the counterlockwise (negative, S) chirality of the transition dipole moments of dyes.