Evidence for Z-form RNA by vacuum UV circular dichroism.

Circular dichroism (CD) spectra in the vacuum UV region for different conformations of poly d(G-C) X poly d(G-C) and poly r(G-C) X poly r(G-C) are very characteristic. The CD of the RNA in the A-form (6 M NaClO4 and 22 degrees C) is very similar to that of the DNA in 80% alcohol where it is believed to be in the A-form. With the exception of the longest wavelength transition, the CD of the RNA in 6 M NaClO4 at 46 degrees C is similar to the CD of the DNA under conditions where it is believed to be in the Z-form (2 M NaClO4). This substantiates that poly r(G-C) X poly r(G-C) assumes a left-handed Z-conformation in 6 M NaClO4 above 35 degrees C. CD spectra for the left-handed Z-forms of both the RNA and DNA are characterized by an intense negative peak at 190-195 nm, a crossover at about 184 nm, and an intense positive peak below 180 nm. The right-handed A- and B-forms of RNA and DNA all have an intense positive peak in their CD spectra near 186 nm. The large difference in CD in the range 185-195 nm for right- and left-handed conformations of nucleic acids can be used to identify the sense of helix winding.     

Synthesis and characterization of six sequential polypeptides containing tyrosine, glutamic acid, alanine, and glycine by circular dichroism and difference spectroscopy

Six sequential polytetrapeptides containing equimolar amounts of tyrosine, glutamic acid, alanine, and glycine were characterized by CD and difference spectroscopy over a wide range of pH. As the pH was lowered from physiological values, each of the polymers underwent pH-sensitive transitions. The CD spectra indicated that two polymers, poly(Tyr-Glu-Ala-Gly) and poly(Tyr-Ala-Glu-Gly), had some α-helical conformation at pH 7.0 and approached maximum helicity around pH 6.0; two others, poly(Ala-Tyr-Glu-Gly) and poly(Glu-Ala-Tyr-Gly), had no α-helical conformation at pH 7.0 and about one-third of the ellipticities of the above two polymers at pH 5.5; and the remaining two, poly(Ala-Glu-Tyr-Gly) and poly(Glu-Tyr-Ala-Gly) had little or no α-helix, even at pH 5.5. Difference spectroscopy at 286 nm yielded results quite different. The molar extinction coefficients for poly(Tyr-Glu-Ala-Gly) and poly(Tyr-Ala-Glu-Gly) continued to change, even below pH 5.5, and the total changes in absorbance between pH 8.0 and 4.5 were of intermediate magnitudes among the six polymers. Poly(Ala-Tyr-Glu-Gly) and poly(Glu-Ala-Tyr-Gly), which had similar CD spectra, had the lowest and highest pH-related changes in the molar extinction coefficients. It thus appears that amino acid composition alone cannot account for the apparent differences in conformation among the polytetrapeptides. Other factors, such as amno acid sequence, must play a major role in the determination of conformation. The intrinsic viscosity of poly(Tyr-Glu-Ala-Gly) increased markedly between pH 6.0 and 5.5, which was below the pH of the CD transition but above the pH at which the largest absorption perturbation change, at 286 nm, took place. The model that can best account for the relatively low pH at which the absorption transition of tyrosine occurred is a progressive immobilization of side chains in the α-helix as the pH decreases.     

Spectroscopic and equilibrium dialysis studies of poly(α-L-glutamic acid)–Cu(II) complexes in the pH range 4–7

The formation of complex between the Cu²⁺ ion and poly(α-L -glutamic acid) [poly(Glu)] in 150 mM NaCl solutions was studied by uv–visible absorption and equilibrium dialysis methods at the mixing ratios of Glu residues to Cu²⁺, R, of 32, 16, and 8 and in the pH range 4–7. The results showed that more than 90% of Cu²⁺ ions bind to the poly(Glu) at pH > 4.9, but the bound Cu(II) begins to dissociate with a decrease in pH. The absorption spectra of bound Cu(II) varied with pH and R in a complicated manner. Three different component spectra were disclosed from the analysis of the pH dependence of the bound spectra. We concluded that poly(Glu)–Cu(II) complexes fall into three classes in the pH range 4–7, with the proportions of these complexes varying with both pH and R. The three complexes predominate either in the helix or extended-coil region, in the helix–coil transition region, or in the helix-aggregate region. The stability constant and binding mode of each Cu(II)–Glu complex were estimated from the dialysis data. With these results, the possible structure of each complex is discussed.     

Sequence-dependant polymorphism of DNA duplex in solutions

Raman spectra of six synthetic polydeoxyribonucleotide duplexes with different base sequences have been examined in aqueous solutions with different salt or nucleotide concentrations. Detailed conformational differences have been indicated between B and Z forms of poly[d(G-C)] X poly[d(G-C)], between B forms of poly[d(G-C)] X poly[d(G-C)] and poly[d(G-m5C)] X poly[d(G-m5C)], between A and B forms of poly(dG) X poly(dC), between B and "CsF" forms of poly[d(A-T)] X poly[d(A-T)], between B forms of poly[d(A-U)] X poly[d(A-U)] and poly[d(A-T)] X poly[d(A-T)], and between low- and high-salt (CsF) forms of poly(dA) X poly(dT). The Raman spectrum of calf-thymus DNA in aqueous solution was also observed and was compared with the Raman spectra of its fibers in A, B, and C forms.     

Deuteration kinetics of deoxyguanosine, deoxycytidine, and their polynucleotides by means of ultraviolet spectrophotometry

The kinetics of the hydrogen-deuterium exchange reactions of deoxyguanosine (dG), deoxycytidine (dC), double-helical poly[d(G-C)] X poly[d(G-C], and double-helical poly(dG) X poly(dC) have been examined at 20 degrees C, pH 7.0, and in low-salt (0.15 M NaCl) medium by stopped-flow ultraviolet spectrophotometry, in the spectral region of 260 to 320 nm. The rate constant was found to be 78.9 s-1 for dG-NH, 2.2 s-1 for dG-NH2, 39.3 s-1 for dC-NH2, 2.4 s-1 (fast) and 0.94 s-1 (slow) for poly[d(G-C)] X poly[d(G-C)], and 2.2 s-1 (fast) and 0.92 s-1 (slow) for poly(dG) X poly(dC). From these values, the probability of base-pair opening of the G X C containing B-form double helix is estimated to be (3 +/- 1) X 10(-3). This is much greater than what is expected from an extrapolation of the van't Hoff plot at the helix-coil transition region, i.e. at about 110 degrees C. The mechanism of these base-pair openings at 20 degrees C (as well as the mechanism of base-pair reformation) is suggested to be totally different from those in the melting temperature range.     

The interaction of ethidium with synthetic double-stranded polynucleotides at low ionic strength.

The interaction of ethidium with synthetic DNA and RNA double-stranded polymers at 0.01 M ionic strength, pH 7.0, has been studied by fluorimetry at low drug to nucleotide ratios. Binding constants have been calculated assuming an excluded-neighbouring site model for the interaction of ethidium with double-stranded polymers. The values obtained are poly d(AT).poly d(AT), 9.5 X 10(6) M-1; poly dA.poly dT, 6.5 X 10(5) M-1; poly d(GC).poly d(GC), 9.9 X 10(6) M-1; poly dG,poly dC, 4.5 X 1-(6) M-1; poly d(AC); poly d(GT), 9.8 X 10(6) M-1; poly d(AG).poly d(CT), 1.3 X 10(6) M-1; poly rA.poly rU, 4.1 X 10(7) M-1. The displacement of ethidium from poly d(AT).poly d(AT) by 9-aminoacridine and an acridine-containing antitumor agent (NSC 156303; 4'-(9-acridinylamino)methanesulphon-m-anisidide) has also been examined.     

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.     

CD of homopolymer DNA-RNA hybrid duplexes and triplexes containing A-T or A-U base pairs.

CD spectra and difference-CD spectra of (a) two DNA X RNA hybrid duplexes (poly[r(A) X d(U)] and poly[r(A) X d(T)]) and (b) three hybrid triplexes (poly-[d(T) X r(A) X d(T)], poly[r(U) X d(A) X r(U)], and poly[r(T) X d(A) X r(T)]) were obtained and compared with CD spectra of six A X U- and A X T-containing duplex and triplex RNAs and DNAs. We found that the CD spectra of the homopolymer duplexes above 260 nm were correlated with the type of base pair present (A-U or A-T) and could be interpreted as the sum of the CD contributions of the single strands plus a contribution due to base pairing. The spectra of the duplexes below 235 nm were related to the polypurine strands present (poly-[r(A)] or poly[d(A)]). We interpret the CD intensity in the intermediate 255-235 nm region of these spectra to be mainly due to stacking of the constituent polypurine strands. Three of the five hybrids (poly[r(A) X d(U)], poly[r(A) X d(T)], and poly[d(T) X r(A) X d(T)]) were found to have heteronomous conformations, while poly[r(U) X d(A) X r(U)] was found to be the most A-like and poly[r(T) X d(A) X r(T)], the least A-like.     

A polycationic amine that induces unique conformational changes in poly(dA-dT) in low salt

Circular dichroism was used to examine alterations in the secondary structure of poly(dA-dT) X poly(dA-dT) upon binding polymer X, a polycationic CD probe for aspects of DNA structure. Stable complex formation is evidenced by increasing Tm and the appearance of large extrinsic bands in the greater than 300 nm, region which increase proportionally with r (ratio of polymer charge to DNa phosphate), in the range 0.0 to 0.32. At relatively low values of r (less than .32), CD spectra of the poly(dA-dT) X poly(dA-dT)-polymer X complex show a gradual non-cooperative inversion in the long wavelength portion (275 nm) of the intrinsic band in low salt solutions suggesting structural and conformational flexibility in poly(dA-dT) X poly(dA-dT) and further implicating polymer X as a potential probe for variations in DNA secondary structure. The dinucleotide repeat configuration of poly(dA-dT) X poly(dA-dT) is presumed to play a role in the observed intrinsic CD changes. NMR data support an "alternating B" conformation for the complex.     

Immobilization of polyribonucleotides in agarose gels at high ionic strength

Purine polyribonucleotides poly(A), poly(G), and poly(I) associate reversibly with agarose gels at high NaCl molarities over the pH range 6–10, at 20°?40°C. Pyrimidine polyribonucleotides poly (C) and poly(U) could not be immobilized in agarose gels under the above conditions. However, poly(C) could be immobilized in agarose without precipitation between pH 3.2 and 4.0. Association of poly(G) and poly(I) with agarose appears to decrease progressively with deprotonation of their purine residues, and both polymers interact with the gel very weakly above pH 10 regardless of NaCl concentration. The binding to agarose of these polymers at pH 7.5 is also strongly influenced by temperature in the range 20°?40°C. The association of single-stranded poly(A) is only shifted toward higher NaCl molarities by increased pH; its binding is also little affected by temperature in the above range. At NaCl molarities effecting the saturating retention in agarose and at neutral pH, the immobilization of several polynucleotides could be prevented by urea in a concentration-dependent manner. The corresponding profiles of urea molarity appear to disclose a number of hydrophobic interactions between polynucleotides and agarose, some of which could be relatively strong, especially in the case of poly(A).     

Interaction of metal ions with polynucleotides and related compounds. X. Studies on the reaction of silver (I) with the nucleosides and polynucleotides, and the effect of silver(I) on the zinc(II) degradation of polynucleotides

Potentiometric titration curves of the silver(I) complexes of cytidine, adenosine, and uridine show little uptake of base below pH 7, unlike the curve for silver(I)-guanosine, which shows extensive base uptake at neutral pH. This observation is correlated with spectrophotometric data showing little difference between the silver complex spectra of adenosine, cytidine, and uridine and the spectra of uncomplexed nucleosides, except at high pH, but showing a great difference between the silver complex spectra of guanosine and inosine and the corresponding uncomplexed nucleosides even at pH 6. Similar comparisons of the silver complexes of poly A, poly C, poly I, and poly U, both by potentiometric titration and by spectrophotometry, show that poly I behaves like guanosine and inosine as expected, differing from poly A and poly C. However, poly U behaves like poly I and thus does not resemble uridine in its complexing behavior. There is thus a dichotomy between poly A and poly C on the one hand in silver complexing phenomena, compared with poly U and poly I on the other. When silver(I) is added to systems containing zinc(II) and various polynucleotides, the same dichotomy is noted. Silver(I) inhibits the degradation by zinc(II) of all four polynucleotides, but the degradation of poly I and poly U is prevented virtually completely. Silver(I) alone has no degradative effect on RNA and inhibits, the zinc(II) degradation of RNA. Polynucleotide complexes in which silver(I) and zinc(II) are simultaneously bound to different positions on the macromolecules are postulated as intermediates in the inhibited degradation reactions.     

The binding of Mg(II) and Ni(II) to synthetic polynucleotides

Equilibria and kinetics of the interactions of Mg2+ and Ni2+ with poly(U), poly(C) and poly(I) have been investigated at 25 degrees C, an ionic strength of 0.1 M, and pH 7.0 or 6.0. Analogous studies involving poly(A) were reported earlier. All binding equilibria were studied by means of the (usually small) absorbance changes in the ultraviolet range. This technique yields apparent binding constants which are fairly large for the interaction of Ni2+ with poly(A) (K = 0.9 X 10(4) M-1) and poly(I) (K approximately equal to 2 X 10(4) M-1) but considerably lower for the corresponding Mg2+ systems, Mg2+-poly(A) (K = 2 X 10(3) M-1) and Mg2+-poly(I) (K = 280 M-1). Each of the two pyrimidine nucleotides binds both metal ions with about the same strength (K approximately equal to 65 M-1 for poly(U) and K near 600 M-1 for poly(C]. In the case of poly(C) the spectral changes deviate from those expected for a simple binding equilibrium. In addition, the binding of Ni2+ to the four polynucleotides was measured by using murexide as an indicator of the concentration of free Ni2+. The results obtained by this technique agree or are at least consistent with those derived from the ultraviolet spectra. Complications are encountered in the binding studies involving poly(I), particularly at higher metal ion concentrations, obviously due to the formation of aggregated poly(I) species. Kinetic studies of the binding processes were carried out by the temperature-jump relaxation technique. Measurable relaxation effects of time constants greater than 5 microseconds were observed only in the systems Ni2+-poly(A) and Ni2+-poly(I). Such not-too-fast reaction effects are expected for processes which include inner-sphere substitution steps at Mg2+ or Ni2+. The relaxation process in Ni2+-poly(I) is characterized by (at least) four time constants. Obviously, the complicated kinetics again include reactions of aggregated poly(I). The absence of detectable relaxation effects in all other systems (except Mg2+-poly(I), the kinetics of which was not investigated) indicates that inner-sphere coordination of the metal ions to specific sites of the polynucleotides (site binding) does not occur to a significant extent. Rather, the metal ions are bound in these systems mainly by electrostatic forces, forming a mobile cloud. The differences in binding strength which are nevertheless observed are attributed to differences in the conformation of the polynucleotides which result in different charge densities.     

Demonstration of three protonated forms of poly(A): potentiometric and conductometric study of isoionic solutions

It is shown that there are three parts on the potentiometric titration curves of isoionic solutions of poly(A) ascribed to the three protonated structures. Double-helical protonated structures are especially stable in isoionic solution. These parts on potentiometric curves are attributed to the single-stranded poly(A), to the completely protonated double-stranded poly(A+).poly(A+), and to the semiprotonated poly(A+).poly(A) structures: D, A, B forms of poly(A), respectively. pK0 values of these forms are calculated. The D form portion is found to be about 18% in isoionic solution, 40% in KCl solution (from 0.01 to 1.0 M), 40% in solution, containing 1.2 X 10(-3) M MgCl2 and 70% in 8 X 10(-4) M MgCl2 solution. The increase of MgCl2 concentration up to 8 X 10(-4) M leads to complete degradation of the double-helical structure. Only single-stranded D form exists in 5 X 10(-3) M MgCl2 solution. About 5-7% of all protons become inaccessible for titration in all solutions containing KCl and in the presence of small amounts of MgCl2. This phenomenon can not be explained by aggregation of poly(A), because all protons become accessible for titration in more concentrated MgCl2 solution when aggregation of poly(A) is significant and accompanied by the precipitation of sediment insoluble in NaOH. The supposition is made, that unprotonated double-stranded poly(A) can exist in salt-free solution at neutral pH. It is this form that is protonated with decrease of pH.     

Romanowsky dyes and Romanowsky-Giemsa effect. 2. Eosin Y, erythrosin B, tetrachlorofluorescein, spectroscopic characterization of pure dyes, association of eosin Y

Analytically pure samples of the Romanowsky dyes eosin y, erythrosin b and tetrachlorofluorescein are prepared. DC of the dye samples shows no contaminations. We measured the absorption spectra of the dye dianions in alkaline aqueous solution and of the dye acids in 95% ethanol at very low dye concentrations. The molar extinction coefficients of the long wavelength absorption of the monomeric dye species are determined (Table 1). The extinction coefficients may be used for standardisation of dye samples. The absorption spectra of eosin y in aqueous solution are dependent on concentration. Using a new very sensitive method it was possible to identify two association equilibria from the concentration dependency of the spectra. Dimers are formed even in very dilute solutions, at higher concentrations tetramers. The dissociation constant of the dimers D in monomers M at 293 K, pH = 12, is K21 = 2,9 X 10(-5) M; of the tetramers Q in dimers D K42 = 2,4 X 10(-3) M. From the experimental spectra of eosin solutions at various concentrations, pH = 12, and the equilibrium constants K21, K42 the absorption spectra of the pure monomers, dimers and tetramers are calculated. M has one long wavelength absorption band, VM = 19300 cm-1, epsilon M = 1,03 X 10(5) M-1 cm-1; D also one absorption band, VD = 19300 cm-1, epsilon D = 1,74 X 10(5) M-1 cm-1; Q two absorption bands, VQ1 = 19100, VQ2 = 20200 cm-1, epsilon Q1 = 1,65 X 10(5), epsilon Q2 = 1,96 X 10(5) M-1 cm-1. The absorption spectrum of the dimers is discussed by quantum mechanics.     

CD of six different conformational rearrangements of poly[d(A-G).d(C-T)] induced by low pH.

On the basis of circular dichroism (CD) data, we have now identified six different conformational states (other than the duplex) of poly[d(A-G).d(C-T)] at pH values between 8 and 2.5 (at 0.01M Na+; 20 degrees C). Three of these structural rearrangements were observed as the pH was lowered from 8 to 2.5, and three additional rearrangements were observed as the pH was raised from 2.5 back to neutral pH. The major components of the six conformational states were defined using appropriate combinations of the CD spectra of the duplex, triplex, and denatured forms of this polymer, as well as the CD spectra of the individual single strands and their respective acid-induced self-complexes. Our results show that the acid-induced rearrangements of poly[d(A-G).d(C-T)] include not only the poly[d(C+-T).d(A-G).d(C-T)] triplex, but also include the poly[d(C-T)] loop-out structure and a self-complexed form of the poly[d(A-G)] strand that is pH-dependent.     

A pH-dependent conformational change in the coat protein subunits from potato virus X.

Both the circular dichroism and fluorescence spectra of the dissociated coat protein subunits from potato virus X changed substantially over the pH range 8 to 4, irreversible changes resulted below pH 4, with tyrosyl and tryptophanyl residues affected most. The titration curves show a pKa of about 5.6 and do not require cooperative interactions between the coat protein subunits, thus they are in marked contrast to titrations of tobacco mosaic virus A-protein. The spectra of the intact virus were little changed between pH 8 and 4 and suggested that the coat protein was locked into a conformation similar to that of the subunits in solution at pH 7. It is proposed that the pH induced conformational change is responsible for determining the acidic branch of the pH profile for reconstitution of potato virus X from its dissociated coat protein subunits and RNA.     

Polynucleotides. XLVI. 1 Synthesis and properties of poly (2''-amino-2''-deoxyadenylic acid).

Poly (2'-amino-2'-deoxyadenylic acid) [poly (Aa)] was prepared from chemically synthesized 2'-amino-2'-deoxy-ADP by the catalysis of polynucleotide phosphorylase. Poly (Aa) showed a similar UV absorption spectra to poly (A), but quite different CD spectra at pH 7.0 and 5.7. At the former pH it showed a single negative Cotton band and at the latter a curve with a large splitting of bands. Acid titration of poly (Aa) suggested protonated form below pH 7.0. Temperature absorption profiles and their dependency on sodium ion concentration suggested an ordered structure for poly (Aa) which is stabilized by stacking of bases and intrastrand interaction between 2'-amino and internucleotidic phosphate groups. Poly (Aa) forms a 1:2 complex with poly (U) at neutrality and its Tm was 45 degrees in the presence of 0.15M sodium ion.     

The effect of changes in salt concentration and pH on the interaction between glycosaminoglycans and cationic polypeptides.

Circular dichroism (CD) spectroscopy has been used to investigate the effects of changes in salt concentration and pH on the interactions between basic polypeptides and connective tissue glycosaminoglycans in dilute aqueous solution. The polypeptides undergo conformation-directing interactions in the presence of glycosaminoglycans, which are subject to transitions as the ionic strength and pH are varied. For poly(L -lysine), the conformational change due to interaction breaks down as the ionic strength (monovalent ions) is increased. Based on the ionic strength at which disruption occurs, the glycosaminoglycans can be placed in order of increasing strength of interaction: chondroitin 6-sulfate, hyaluronic acid, chondroitin 4-sulfate, heparin, and dermatan sulfate. Prior to the conformational transition, scattering effects are observed, indicating the development of larger aggregates. Each glycosaminoglycan induces α-helicity for poly(L -arginine), which does not break down as the ionic strength is increased, indicating a stronger interaction for this polypeptide. The pH-induced transitions are in the pH range 2.5–3.8 and are probably related to deionization of carboxyl groups. For poly(L -lysine) the conformational effect is disrupted at low pH. For poly(L -arginine), the transitions are not complete, but appear to correspond to an increase in scattering.     

Partially quarternized amino functional poly(methacrylate) terpolymers: versatile drug permeability modifiers

Partially quarternized poly(methacrylate) terpolymers (Q-BBMCs) have been synthesized, based on the basic butylated methacrylate copolymer (BBMC/EUDRAGIT E), an excipient approved by the Food and Drug Administration (FDA) and to date mainly applied for tablet coatings. Via straightforward polymer modification reactions, a series of Q-BBMCs with quarternization degrees of 22%, 42%, and 65% has been prepared. Apical to basolateral transport across Caco-2 cell monolayers was investigated, employing the paracellular transported compounds trospium and mannitol. At pH 6.5 quarternization resulted in increased permeation enhancement up to 2.8-fold compared to BBMC, that is, up to 7.3-fold compared to control. Moreover, measurements of the transepithelial electrical resistance (TEER) revealed a special advantage of the quarternized poly(methacrylate) terpolymers with respect to the pH range, in which the polymers exhibit biological activity as permeation enhancers. Whereas at pH 6.5 TEER dropped within 30 min below 30% of the initial value for all polymers, at pH 7.4 this effect solely occurred for Q-BBMCs, meaning a significant extension of the pH range relevant for drug permeation. In a subsequent period of 6 h, also excellent recovery was observed.     

Segmental flexibility of single-, double-, and triple-stranded polyribonucleotides from the data of spin label method. Formation of the triple-stranded poly(A.A.U) polynucleotide helix

Segmental mobility dynamic peculiarities of poly(U), poly(A) and poly(C) synthetic polymers and their complexes were investigated by spin-label method. Imidazolide spin-label was introduced into 2'-oxi-groups of polymer ribose in correlation: one spin-label on 18-20 bases. Formation of complexes was observed by ESR spectra at two pH: 4.2 and 7.2. Segmental mobility of only single strand spin-labelled polymer segment and in the complex was evaluated by measuring rotational correlation time (tau) determined by dependence of distances between outer wide extrema in ESR spectra from solvent viscosity at different temperatures. It turned out that correlation time tau of single strand structures in a high degree depend on pH and temperature. For three strand structures abrupt increase of tau because of appearance of rigidity was observed. It is possible to evaluate part of triple complexes poly(U.A.A) and poly(U.U.A) existing in dynamic equilibrium depending on pH and temperature by the form of outer wide extrema. Adding of dye to complex of poly(U).poly(A) causes an increase of rigidity of the supermolecular structure. Quantitative characteristics of formed complexes were obtained by simulation of ESR spectra on computer.