X-ray fiber diffraction and model-building study of polyguanylic acid and polyinosinic acid.

X-ray diffraction patterns of fibers of polyriboguanylic acid and polyriboinosinic acid are shown to be virtually identical. These diffraction patterns are consistent only with three or four-stranded models. Model-building studies on a computer-assisted interactive display system favor the four-stranded model. In addition, the greater thermal stability of poly(rG) relative to poly(rI) can be accounted for by a four-stranded model in which there are two hydrogen bonds per base for poly(rG) versus one for poly(rI).     

A vibrational spectroscopic study of the self-association of polyinosinic acid and polyguanylic acid in aqueous solution

We have studied by Raman and ir spectroscopy the structure of self-associated polyinosinic acid and polyguanylic acid in aqueous solution. The results are consistent with the formation of a four-stranded complex, which melts cooperatively near 60°C in the case of poly (I) in the presence of K⁺ ions. The conformation of the ribose in both systems is mixed C2′-endo/C3′-endo, giving a structure that is intermediate between the extremes proposed previously from x-ray diffraction studies. Characteristic Raman bands for the C2′-endo ribose conformation in polyribonucleotides are identified. The four-stranded structure of poly (I) appears to be very flexible, with ≈15% of the tetrameric segments being disrupted and ≈30% of the ribose units adopting a disordered conformation prior to melting. This disordering process increases to ≈75% above the melting transition, with the remaining ≈25% of the ribose units keeping an ordered C2′-endo or C3′-endo conformation. © 1994 John Wiley & Sons, Inc.     

The conformation of polycytidylic acid, polyguanylic acid, polyinosinic acid, and their helical complexes in aqueous solution from laser Raman scattering

The Raman spectra of the double helical complexes of poly C–poly G and poly I–poly C at neutral p^H are presented and compared with the spectra of the constituent homopolymers. When a completely double-helical structure is formed in solution a strong sharp band at 810–814 cm^?1 appears which has previously been shown to be due to the A-type conformation of the sugar–phosphate backbone chain. By taking the ratio of the intensity of the 810–814 cm^?1 band to the intensity of the 1090–1100 cm^?1 phosphate vibration, one can obtain an estimate of the fraction of the backbone chain in the A-type conformation for both double-stranded helices and self-stacked single chains. This type of information can apparently only be obtained by Raman spectroscopy. In addition, other significant changes in Raman intensities and frequencies have been observed and tabulated: (1) the Raman intensity of certain of the ring vibrations of guanine and hypoxanthine bases decrease as these bases become increasingly stacked (Raman hypochromism), (2) the Raman band at 1464 cm^?1 in poly I is asigned to the amide II band of the cis-amide group of the hypoxanthine base. It shifts in frequency upon base pairing to 1484 cm^?1, thus permitting the determination of the fraction of I–C pairs formed.     

Phonon dispersion in polyinosinic acid

A study of the normal modes of vibration and their dispersion in polyinosinic acid [poly (I)] along the helix axis based on Urey-Bradley force field is reported. It leads to a better interpretation of Raman and FTIR spectra. A comparison of dispersion curves of poly (I) with poly (G) has been made. Characteristic features of dispersion curves, such as regions of high density-of-states, repulsion and character mixing are discussed. Predictive value of heat capacity as a function of temperature is reported.     

Induction of helicity in polyuridylic acid and polyinosinic acid by silver ions

Silver ions binding to poly(U) and poly(I) produce highly ordered multistranded helices under conditions which would otherwise lead to random coils. Evidence for helicity comes from the hypochromicity and high ellipticity generated in the polymers by Ag⁺ binding, as well as from x-ray studies and from the cooperativity of the Ag⁺ complexing reaction. Continuous variation studies show that both polymers form 1:1 and 2:1 polymer–Ag⁺ complexes. Low pH favors the 1:1 complex with poly(U) and the 2:1 complex with poly(I); the reverse is true at high pH. Ag⁺ binding and proton-release experiments make it clear that at low pH, unprotonated electron-donor groups are complexed preferentially, but that at high pH, Ag⁺ readily displaces H⁺ from protonated groups. In poly(I) the unprotonated donor is N(7), leading at low pH to a 2:1 complex containing N(7)-Ag-N(7) bonds; at high pH, proton release from N(1) leads to a 1:1 complex containing N(1)-Ag-O bonds. In poly(U) there is no unprotonated donor; the low-pH 1:1 complex involves deprotonation of only one N(3) per bound Ag⁺, leading to N₃-Ag-O bonding, while high pH causes deprotonation of two N(3) per Ag⁺ and a 2:1 N(3)-Ag-N(3) complex. Thus silver ions react with the nucleotide bases in chemically predictable ways, and the formation of different Ag–nucleotide bonds leads to different multiple-helix structures.     

A calorimetric study of polyguanylic acid at neutral pH.

The structure of polyguanylic acid (poly G) at neutral pH has been studied by optical and calorimetrical methods. It can be shown that diverging from earlier findings Poly G reversibly undergoes a cooperative thermal transition. Thermal denaturation curves are recorded at 253 nm as a function of the sodium ion concentration. The denaturation enthalpy of poly G in dilute aqueous solution is determined to 2.2 kcal/mole g. It is concluded, that the part of the ordered poly G structure, which gives rise to a temperature dependent cooperative transition, arises from stacking interactions of adjacent bases in the single strand.     

Circular dichroism calculations for polyinosinic acid in proposed multi-stranded geometries.

Circular dichroism spectra have been calculated for multi-stranded polyinosinic acid using three different right-handed structures proposed from X-ray diffraction studies. Agreement between calculated spectra and spectra measured at high salt concentration is best for a four strand structure in which the bases are tilted with respect to the helix axis, as proposed by Arnott et al. (1974). For structures in which the bases are perpendicular to the helix axis, the characteristic negative circular dichoroism of polyinosinic acid at long wavelength no longer appears in the calculated spectra. It is clear that a negative circular dichroism at long wavelength does not indicate a left-handed polynucleotide helix.     

Fluorescent 2-aza-epsilon-adenosine derivatives of polyadenylic acid, polyuridylic acid, and polyinosinic acid.

A new fluorescent analog of adenosine, 1,N⁶-etheno-2-aza-adenosine, has been incorporated into polynucleotides by polynucleotide phosphorylase polymerization of 1,N⁶-etheno-2-aza-adenosine-5′-diphosphate and adenosine-5′-diphosphate, uridine-5′-diphosphate, or inosine-5′-diphosphate. These new oligonucletides possess high fluorescence when excited at 358 nm and emit at 495 nm. The ratio of the fluorescent and nonfluorescent portions of the copolymer can be controlled by the initial composition of the 2-aza-ε-adenosine-diphosphate and the corresponding nucleoside diphosphate. Fluorescent copolymers with a ratio varying from 1.6 to 35 have thus been synthesized. The physicochemical study of copolymers containing less than 10% of the 1,N⁶-etheno-2-aza-adenosine moiety showed that they are similar to poly(A), poly(U), or poly(I). Therefore, fluorescence and polarization study of the 1,N⁶-etheno-2-aza-adenosine residues that have been incorporated into the copolymer provides a sensitive indicator for the structure of the copolymer. Potentially these new copolymers may provide unique roles in probing the structure of poly(C) and poly(A) in cellular mRNA.     

Protonated polynucleotides. VII. Thermal transitions between different complexes of polyinosinic acid and polycytidylic acid in an acid medium

The interaction between poly (I) and poly (C) in acid medium has been studied by potentiometric titration, mixing curves and thermal denaturation. Phase diagramms as a function of ionic strength, pH, and temperature have been established. From these data it is shown that the acid titration of the complex poly (I) · poly (C) passes through a triple-stranded intermediate poly (I) · poly (C) · poly (C⁺) to yield finally the protonated double-helical complex poly (I) · poly (C⁺). The mixing curves indicate the sole presence of the three-stranded complex in the intermediate zone. On the basis of the pK's the coexistence between the three-stranded complex with the neighboring double-stranded structure is demonstrated in a narrow rang of pH and ionic strength. The geometry of the base arrangements, their conformation and the sense of the strands are discussed in the light of the data presented. A Hoogsteen-type pairing between the bases for poly (I) · poly (C⁺) is favored, although the reverse Hoogsteen pair cannot be excluded.     

Cloned human interferons alpha: differential affinities for polyinosinic acid and relationship between molecular structure and species specificity

The HuIFN-alpha A and HuIFN-alpha D interferons, produced by two independent recombinant bacterial clones, have different affinities for polyinosinic acid (poly I). The monomeric form HuIFN-alpha A (FMM), but not the HuIFN-alpha D, binds to poly (I)-agarose and is protected by poly (I) from thermal inactivation. Other subtypes of HuIFN-alpha A including the monomer SMM and oligomers have no affinity for this polynucleotide. In addition, these interferons show different target cell preferences in agreement with our previous suggestion (23) that the polynucleotide binding domain may be responsible for species specificity. Two significant observations are 1) the fractions of HuIFN-alpha D and HuIFN-alpha A unbound on poly (I)-agarose show higher antiviral inducing activity on heterologous (MDBK) than on homologous (WISH) cells, whereas they induce about the same activity of 2'5' oligoadenylate synthetase in these two cell lines. These fractions are also active on L929 cells. 2) The bound fraction of HuIFN-alpha A induces almost the same antiviral and 2'5' oligoadenylate synthetase activities in MDBK and in WISH cells but neither activity in L929 cells.     

A vibrational spectroscopic study of the metastable form of associated polyinosinic acid

We have studied by Raman and ir spectroscopy the metastable complex formed by the self-association of polyinosinic acid in aqueous solution. The complex is easily prepared by quickly cooling to ca. 0°C a warm solution of the polyribonucleotide to which a small amount of rubidium salt has been added. Upon heating, this metastable form melts cooperatively near 13°C, well below the dissociation temperature of a stable four-stranded complex, which occurs at 47°C in the same conditions. The presence of several components in the stretching-mode region of the carbonyl groups in the vibrational spectra of the metastable complex suggests that it also has a parallel four-stranded structure. The difference in structure between the two forms is believed to be caused by the presence of fewer metal ions in the central channel of the metastable complex, in agreement with conclusions reached in previous investigations. The Raman spectra further show that the ribose units in the metastable form have a C3′-endo conformation, in contrast with the stable form, for which we have previously suggested a mixed C2′-endo/C3′-endo conformation. © 1996 John Wiley & Sons, Inc.