Fluorescence decay studies of poly(riboadenylic acid) containing 1-N6-ethenoadenosine.

The fluorescence properties of the 1-N6-etheno derivatives of poly(riboadenylic acid) (poly(rA, epsilon rA)) have been examined. The fluorescence quantum yield of poly(rA, epsilon rA) decreases with an increase in the degree of the epsilon A substitution and is much smaller than that for epsilon AMP even for low degrees of epsilon A substitution. The nearest-neighbor interactions such as epsilon-adenine-adenine and epsilon-adenine-epsilon-adenine may be responsible for this behavior. It is found that the fluorescence decay kinetics obeys a three-exponential decay law for poly(rA, epsilon rA), suggesting that there exist at least three different stacked conformational states.

Interaction of N6-substituted-9-methyladenines to poly-5-bromouridylic acid.

Interaction of N6-methyl-9-methyladenine (m6m9A) to poly-5-bromouridylic acid (poly(BU] was investigated. The stoichiometry of interaction was determined to be 1 m6A:2 BU by equilibrium dialysis. Structural information was obtained from circular dichroism and absorption spectra and a similarity of the structure to the corresponding polymer complex was suggested. Thermodynamic parameters of the interaction was calculated from dependence of TmS on the monomer concentration and compared to those from calorimetric measurements. N6-(delta 2-Isopentenyl) - and N6-allyl-9-methyladenine were also examined of the binding to poly(BU).

Synthesis and physicochemical properties of two analogs of poly(dA): poly(2-aminopurine-9-beta-D-deoxyribonucleotide) and poly 2-amino-deoxyadenylic acid.

Polymerization of chemically synthesized dn2h6ATP and dn2ATP by deoxynucleotidyl transferase from calf thymus furnished poly(dn2h6A) and poly(dn2A) respectively. The synthetic polynucleotides were characterized by spectroscopic, ultracentrifugation and enzymatic methods. In polynucleotide-polynucleotide interaction, poly(dn2h6A) and poly(dn2A) behaved like analogs of poly(dnA).

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.

Polynucleotides. XL. Synthesis and properties of poly 2'-azido-2'-deoxyadenylic acid.

Poly 2'-azido-2'-deoxyadenylic acid (Poly Az) was synthesized from 2'-azido-2'-deoxyadenosine diphosphate by polynucleotide phosphorylase. Poly (Az) has U.V. absorption properties similar to poly (A) and hypochromicity of 40% at 0.1 M Na+ and neutrality. CD curve also resembled to that of poly (A), but has smaller ellipticity. Titration of poly (Az) with HCl gave a transition at pH 5.5, but exact structure of the acid-form complex was not elucidated. Upon mixing with poly (U), poly (Az) forms a 1:1 and 1:2 complexes having Tm's somewhat higher than that of poly (A)- poly (U) complex in the same condition.

Conformational analysis of polynucleotides. I. The favorable left-handed helical model for the poly(8,2'-S-cycloadenylic acid) with high anti conformation.

1) Energy calculations have shown that poly (8,2'-S-cycloadenylic aicd) can form left-handed helices owing to the high anti conformation. 2) Two favorable left-handed helices are characterized by axial translation per residue (Z=4.3 and 3.6A) and by rotations per residue (theta= 40 degrees and -25 degrees). 3) The proposed helical models might be stable in aqueous solution and is well explicable of the optical property of this compound.

Poly(2-aminoadenylic acid): interaction with poly(uridylic acid).

Poly(2-aminoadenylic acid) forms both double and triple helices with poly(uridylic acid) [poly(U)]. The 2-amino group forms a third hydrogen bond, elevating the 2 leads to 1 transition temperature by 33 degrees C. The third strand, however, has about the same stability as poly(A)-2poly(U), as measured by Tm 3 leads to 2. This selective stabilization of the two-stranded helix results in a much greater resolution of the differnt thermal transitions than that observed in analogous polynucleotide systems. In contrast to other A, U systems 3 leads to 1 and 2 leads to 3 transitions are not observed under any conditions, and the triple helix always undergoes a 3 leads to 2 transition even at very high ionic strength. A 1:1 mixture of poly(2NH2A) and poly(U) exhibits no transient formation of 1:2 complex, unlike similar mixtures of poly(A) with poly(U) and poly(T). This difference is evidently due to a more rapid displacement reaction: [poly(2NH2A) + poly(2NH2A)-2poly(U) leads to 2 poly(2NH2A)-poly(U)] With poly(2NH2A) than with poly(A). We describe a method for establishing the combining ratios of polynucleotide complexes which used a computer to calculate the angles of intersection of mixing curves as explicit and continuous functions of the wavelength. The wavelength dispersions of the angles of intersection determine optimum wavelengths for establishing stoichiometry and can also provide reliable negative evidence that presumably plausible complexes are not formed. Analogous computer procedures have been developed to determine wavelengths which are selective for the formation of both 1:1 and 1:2 complexes. Infrared spectra of the 1:1 and 1:2 complexes resemble those of other A, U homoribopolynucleotide helices in having two and three strong bands, respectively, in the region of carbonyl stretching vibrations. CD spectra of the two complexes are unusual in having negative first extrema of moderate intensity. We attribute these extrema to intrastrand interactions of strong, well-resolved transitions at 278 nm (B2u) of the 2-aminoadenine residues. The CD spectra are correlated with those of other polynucleotide helices.

Preparation and properties of an analogue of poly(A) and poly(G): poly(isoguanylic acid).

Isoguanosine-5'-pyrosphosphate, in the presence of an oligonucleotide primer, was polymerized by Escherichia coli polynucleotide phosphorylase under conditions analogous to those required for polymerization of 5'-GMP. The resulting poly(isoguanylic acid), poly(isoG), was a multistranded helix with a stability considerably higher than that of poly(G), and fully resistant to various nucleolytic enzymes. The polymer exhibited a two-step temperature transition profile in moderately alkaline propylene glycol. Alkaline titration in aqueous medium, by ultraviolet and circular dichroism spectroscopy, showed two clearly defined transitions, the second of which was fully cooperative. The accompanying changes in sedimentation constants were consistent with a structure for poly(isoG) of a fourstranded helix, like neutral poly(G). In acid medium, spectral and potentiometric titrations demonstrated the existence of more than one transition in the pH range 6-12, with accompanying protonation of the isoguanosine residues. In neutral medium the polymer formed no complexes with other potentially complementary homopolymers. In acid medium, on the other hand, the protonated form of poly(isoG) did form a triple-stranded complex with poly(I), viz. 2poly(I) . poly(isoG)+. Possible structures are formulated for the neural and protonated forms of poly(isoG) which account for the two-step thermal transition in alkaline propylene glycol and on alkaline titration in aqueous medium. The nature of the protonated form, and its complex with poly(I) is also discussed.

Modified nucleotide polymers as inhibitors of DNA polymerases.

We have compared the relative inhibitory activity of poly (A) with its analogues poly N6-isopentenyl adenylic acid (poly(i6 A)) and poly N6-benzyl adenylic acid (poly(bzl6A)), and of poly (U) with its analogue poly 2'-fluoro-2'-deoxyuridylic acid (poly(dUfl)), against DNA polymerase, alpha, beta and gamma and terminal deoxynucleotidyl transferase from human cells and two oncorna virus DNA polymerases. Although poly (A) and its analogues were equally inhibitory against endogenous RNA-directed DNA polymerases of murine and feline leukemia viruses, the analogues in contrast to poly (A) were strongly inhibitory against all four cellular enzymes. Poly (dUfl), on the other hand, was up to 100-fold more potent than poly (U) against both viral and cellular enzymes. Since poly (U) at 100 mug/ml and poly (dUfl) at 1 mug/ml had no effect on terminal deoxynucleotidyl transferase while inhibiting other enzymes by 80--100 per cent these polymers could be useful in the characterization and assay of terminal deoxynucleotidyl transferase. In addition, the polymers such as poly (igA) and poly (bzl5A) which were strongly inhibitory to all cellular enzymes, could be useful in cancer chemotherapy if taken up preferentially by the malignant calls due to their high pinocytic activity. The results also demonstrate potential for large variation in inhibitory activity of polyribonucleotides as related to their chemical composition.