Polynucleotides. XLIV. Synthesis and properties of poly (2-azaadenylic acid) and poly(2-azainosinic acid).

Chemically synthesized 2-azaadenosine 5'-diphosphate (n2ADP) and 2-azainosine 5'-diphosphate (n2IDP) were polymerized to yield poly(2-azaadenylic acid), poly(n2A), and poly(2-azainosinic acid), poly(n2I), using Escherichia coli polynucleotide phosphorylase. In neutral solution, poly(n2A) and poly(n2I) had hypochromicities of 32 and 5.5%, respectively. Poly(n2A) formed an ordered structure, which had a melting temperature (Rm) of 20 degrees C at 0.15 M salt concentration. Upon mixing with poly(U), poly(n2A) formed a 1 : 2 complex with Tm of 41 degrees C at 0.15 M salt concentration. Poly(n2A) and poly(n2I) formed three-stranded complexes with poly(I), and poly(A), respectively. Poly(n2A) . 2poly(I), poly(A) . 2poly(n2I), and poly(n2A) . 2poly(n2I) complexes had Tm values of 23, 48, and 31 degrees C at 0.15 M salt concentration, respectively. Poly(n2I) formed a double-stranded complex with poly(C), but its Tm was very low.     

Interferon induction by poly(inosinic acid).poly(cytidylic acid) segmented by spin-labels

Poly(inosinic acid).poly(cytidylic acid) [(I)n.(C)n] duplexes of which the (C)n strand was modified to various degrees chemically or enzymatically with nitroxide radicals (spin-labels) were evaluated for interferon-inducing activity. Upon annealing of the chemically modified (C)n, (1C,Cx)n (X = 1000 or 16), with (I)n, the interferon-inducing activity was similar to that of (I)n.(C)n in PRK cell cultures. However, to overcome hydrolysis of the spin-label linkage in (1C,Cx)n, and enzymatic approach was taken to synthesize (1S(4)U,Cx)n copolymers with x = 100, 38, 16, and 8. The (1s(4)U,Cx)n copolymers were chemically stable, and upon annealing with (I)n the correlation time of the nitroxide moiety in (I)n. (1s(4)U,Cx)n was determined. A comparison of this correlation time with that measured for (RUGT,U100)n.(A)n, which contains the nitroxide moiety in position 5 of the U moiety, suggests that the 1s(4)U residue is in a nonintrahelical conformation and partitions the duplex into double-helical segments of varying size. The interferon-inducing activity of (I)n. (1s(4)U,Cx)n was evaluated in primary rabbit kidney, human skin fibroblast (strain VGS), and mouse L-929 cell cultures as well as in rabbits. The 1s(4)U residue did not cause a significant change in the interferon induction as compared to (I)n.(C)n in most systems tested unless x less than 16. These findings indicate that double-helical segments of approximately 16 base pairs partitioned by nonintrahelical 1s(4)U residues suffice to trigger the interferon response in all systems studied.     

Interactions of 2-methyladenines and poly(m2A) with poly(br5U)

Mixing curve experiments and melting curve analyses have shown that poly(m2A) forms complexes with poly(br5U) with stoichiometries of either 1:1 or 1:2 in high ionic strengths. CD spectra of poly(m2A).poly(br5U) and poly(m2A).2 poly(br5U) both resemble quite well to those of poly(A). poly(br5U) and poly(A).2poly(br5U), respectively. This suggests that the corresponding complexes are closely related in the structural details. Significant similarities of the CD spectra were observed for poly(m2A).2poly(br5U) and complexes between 2,9-dimethyladenine or 2-methyladenosine and poly(br5U) in the presence of spermine, indicating also the 1:2 stoichiometry. Thus, a methyl group at the position 2 of adenine ring is not necessarily hindering a formation of the Watson-Crick type base pairings.     

Structural requirements of polynucleotides for the activation of (2'' - 5'')An polymerase and protein kinase.

Two enzymatic pathways are involved in the inhibitory effects of double-stranded (ds)RNA on protein synthesis in cell extracts derived from interferon-treated human fibroblasts or HeLa cells, an oligonucleotide polymerase that synthesizes (2'-5')An from ATP and a protein kinase that phosphorylates the alpha subunit of initiation factor eIF-2 as well as a polypeptide of Mr = 72,000. We have now evaluated the activation of both the (2'-5')An polymerase and protein kinase by a large variety of polynucleotides, triple-stranded and synthetic dsRNAs, homopolymers, alternating copolymers, triple-stranded polymers, purine-purine duplexes and purine-pyrimidine duplexes with modifications at either the pyrimidine or ribose moieties. All these polynucleotides have been the subject of previous interferon induction studies. Some polynucleotides, i.e. (I)n.(C)n and mycophage dsRNA, which have been recognized as excellent interferon inducers, were also potent activators of both (2'-5')An polymerase and protein kinase, whereas non-inducers such as (A)n. (X)n and (A)n. (br5U)n did not activate either the kinase or the polymerase. However, some polymers like (I)n.(br5C)n, (difl)n(C)n and (dIcl)n (C)n, while potent interferon inducers and kinase activators, behaved poorly as activators of the (2'-5')An polymerase. Other polymers, i.e. (dAfl)n (U)n and (A)n.(U)nl (I)n, that do not induce interferon, activated the kinase but not the polymerase. Finally, (I)n (s2c)n, a relatively potent interferon inducer, did not activate either kinase or polymerase. These findings indicate that there is no simple relationship between the interferon-inducing ability of dsRNAs and their stimulating effects on (2'-5')An polymerase and protein kinase activity.     

Interferon induction by mismatched analogues of polyinosinic acid . polycytidylic acid [(Ix,U)n.(C)n].

Interruption of the (I)n strand of (I)n.(C)n by unpaired bases [(U)] yielded mismatched analogues, (Ix,U)n.(C)n which were still effective as inducers of interferon, provided the I:U ratio (x) was equal or greater than 10. In highly sensitive interferon-induction systems such as primary rabbit kidney cells and human skin fibroblasts superinduced with cycloheximide and actinomycin D, (I10,U)n.(C)n and (I50,U)n.(C)n proved nearly as active as (I)n.(C)n. By virtue of their increased susceptibility to degradation by nucleases, (Ix,U)n.(C)n complexes with 10 less than or equal to x less than or equal to 50 may be expected not to persist as long in biological fluids as (I)n.(C)n, hence to induce fewer side effects.     

Synthesis and biological activity of polyriboadenylic acid: polyribo-5-dimethylaminouridylic acid hybrid (poly(A): poly(Me2N5U))

Poly-5-dimethylaminouridylic acid, (poly(Me2N5U)) has been synthesized by the conversion of 5-bromouridine-5'-monophosphate to 5-dimethylaminouridine-5'-monophosphate which was later made into the 5'-diphosphate and subsequently polymerized by PNPase. The polymer formed a 1:1 hybrid with poly(A) with the ability to induce the production of interferon in chick embryoes as certain doses of the hybrid protected chick embryoes against wesselsbron virus (H 10964).     

8-Azido double-stranded RNA photoaffinity probes. Enzymatic synthesis, characterization, and biological properties of poly(I,8-azidoI).poly(C) and poly(I,8-azidoI).poly(C12U) with 2',5'-oligoadenylate synthetase and protein kinase

The technique of photoaffinity labeling has been applied to the double-stranded RNA (dsRNA)-dependent enzyme 2',5'-oligoadenylate (2-5A) synthetase to provide a means for the examination of RNA-protein interaction(s) in the dsRNA allosteric binding domain of this enzyme. The synthesis, characterization, and biological properties of the photoaffinity probe poly[( 32P]I,8-azidoI).poly(C) and its mismatched analog poly[( 32P]I,8-azidoI).poly(C12U), which mimic the parent molecules poly(I).poly(C) and poly(I).poly(C12U), are described. The efficacy of poly[( 32P]I,8-azidoI).poly(C) and poly[( 32P]I,8-azidoI).poly(C12U) as allosteric site-directed activators is demonstrated using highly purified 2-5A synthetase from rabbit reticulocyte lysates and from extracts of interferon-treated HeLa cells. The dsRNA photoprobes activate these two 2-5A synthetases. Saturation of 2-5A synthetase is observed at 6 x 10(-4) g/ml poly[( 32P]I,8-azidoI).poly(C) following photolysis for 20 s at 0 degrees C. The photoincorporation of poly[( 32P]I,8-azidoI).poly(C) is specific, as demonstrated by the prevention of photoincorporation by native poly(I).poly(C). DNA, poly(I), and poly(C) are not competitors of poly[( 32P]I,8-azidoI).poly(C). Following UV irradiation of 2-5A synthetase with poly[( 32P]I,8-azidoI).poly(C), the reaction mixture is treated with micrococcal nuclease to hydrolyze azido dsRNA that is not cross-linked to the enzyme. A radioactive band of 110 kDa (the same as that reported for native rabbit reticulocyte lysate 2-5A synthetase) is observed following sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. The specific photolabeling of the 2-5A synthetase suggests that the azido dsRNA is intrinsic to the allosteric binding domain. The utility of poly[( 32P]I,8-azidoI).poly(C) for the detection of dsRNA-dependent binding proteins and the isolation of peptides at or near the allosteric binding site is discussed.     

Hybridization of polymers of antibiotic C-nucleoside phosphates, poly(formycin phosphate) and poly(laurusin phosphate)

The ability of complex formation of poly-(formycin phosphate), poly(F), and poly(laurusin phosphate), poly(L), with the polymers of natural polynucleotides was examined mainly by mixing experiments in 0.1 M NaCl-0.05 M sodium cascodylate buffer (pH 7.0) at 2 degrees. Poly(F) formed complexes with poly(U) and poly(I) in the ratio of 1:1 and 1:2, respectively. Poly(L) formed complexes with poly(A) in 2:1 ration and poly(C) in 1:2 and 2:1 ratios in addition to a self-complex. Poly(F) and poly(L) also formed a 1:2 complex between them. Some of these complexes were assumed to contain novel types of base pairings using the 7-NH group. Thus it was concluded that poly(L) could form complexes with both, the oligomer of cycloadenylic acid (?cn-120 degrees) and polymers of natural nucleotides (?cn0degrees), showing flexibility of the torsion angle of the laurusin residue.     

Physical and coding properties of poly(5-methoxyuridylic) acid.

The synthesis of poly(mo5U) requires a high concentration (2.7 mg/ml) of polynucleotide phosphorylase as well as a long reaction time (48 h). The resulting polynucleotide has a chain length of approximately 100 nucleotides. It shows no indication of a stable secondary structure. When poly(mo5U) is mixed with poly(A), a triple-stranded complex poly(A) . 2poly(mo5U) is formed. This complex has a melting temperature of 68.5 +/- 0.5 degrees C at 150 mMNa+ and exhibits a hysteresis loop between melting and reformation of the complex having a delta Tm of 11.5 degrees C. Poly-5-methoxyuridylic acid stimulates the binding of Phe-tRNA to 70-S ribosomes but is inactive in directing poly(Phe) synthesis.     

Cooperative binding of a platinum metallointercalation reagent to poly(A).poly(U).

The cationic complex (2-hydroxyethanethiolato)(2,2',2'-terpyridine)platinum(II), [(terpy)Pt(HET)]+, binds cooperatively to poly(A).poly(U) by intercalation. The melting temperature of poly(A).poly(U) in low-salt buffer is increased by 6 degrees C in the presence of [(terpy)Pt(HET)]+, indicating stabilization of the duplex structure by the bound platinum reagent. Viscosity measurements provide evidence for comparable lengthening of the polynucleotide in the presence of [(terpy)Pt(HET)]+ and the intercalating dye, ethidium bromide. Scatchard plots of the binding of [(terpy)Pt(HET)]+ to poly(A).poly(U) and poly(I).poly(C), determined through ultracentrifugation pelleting methods, show large positive curvature, reflecting the strong cooperativity associated with the platinum complex-RNA interaction. The characteristics of the binding isotherms are interpreted in terms of a model where cooperative pair units of [(terpy)Pt(HET)]+ intercalate into the double-stranded polymer. At saturation, two platinum molecules are bound for every three base pairs. This stoichiometry may be compared with the nearest-neighbor-exclusion binding observed previously in the interaction of [(terpy)Pt(HET)]+ and the ethidium cation with DNA, in which one intercalator occupies every other interbase-pair site at saturation. The striking differences observed in the interaction of [(terpy)Pt(HET)]+ with DNA and RNA suggest that drug recognition is sensitive to the constraints imposed by nucleic acid secondary structure.     

Interaction of metal ions with polynucleotides and related compounds. IX. Unwinding and rewinding of poly(A + U) and poly(I + C) by copper(II) ions

It is demonstrated that, poly(A + U) and poly(I + C) are both formed under low ionic strength conditions. Continuous variation studies indicate the formation of copper(II) complexes of poly A, poly C, and poly I, but not of poly U. Copper(II) in a 1:1 ratio to polynucleotide prevents the formation of poly(A + U) and brings about the dissociation of the poly (A + U) complex produced in the absence of the metal. Poly (I + C) is similarly dissociated by copper(II) ions. The addition of sufficient electrolyte reverses the copper(II) induced dissociation of poly(I + C). The effect of copper(II) on ordered synthetic polynucleotides is thus very similar to its effect on DNA.     

Polynucleotides XLVII. Synthesis and properties of poly(2-methylthio- and 2-ethylthioadenylic acid). Formation of non-Watson-Crick type complexes.

Poly(2-methyl- and 2-ethylthioadenylic acid) were prepared by polymerization of corresponding diphosphates with Escherichia coli polynucleotide phosphorylase. These polynucleotides have relatively large hypochromicity of 30-35%. Acid titration of these polymers showed abrupt transition at pH 5.34-5.4, which may indicate that the introduction of alkylthio group at 2-position of adenine bases reduced their basicity. Thermal melting of these polymers showed no clear transition points at neutral pH, but in acidic media they have Tm values of 57 and 56 degrees C, somewhat lower than that of poly(A). Upon complex formation with poly(U), these poly(A) analogs showed only one poly(rs2A) . poly(U) type double-strand complexes, similar to that found in the case of poly(m2A) . poly(U).     

Antiviral activity of polynucleotides: copolymers of inosinic acid and N2-dimethylguanylic of 2-methylthioinosinic acid.

Complexes of poly(C) with copolymers of inosinic acid containing various amounts of mismatched bases (see journal for formula) have been examined for direct resistance to virus infection, interferon induction and toxicity in two different cell cultures (primary rabbit kidney cells and mouse L-929 cells). Complexes in which 20% of the hypoxanthine bases were replaced by (see journal for formula) or ms-2I were partially active whereas complexes in which 40% or more of the hypoxanthine bases were replaced by the odd bases were entirely inactive. The decrease in biological activity observed upon intrusion of (see journal for formula) or ms-2I in the poly(I) strand of poly(I) with poly(C) closely paralleled the amount of odd bases introduced irrespective of the system employed to assess the biological activity (resistance to virus infection, interferon induction or toxicity).     

Recognition of polynucleotides by antibodies to poly(I), poly(C).

The binding of anti poly(I). poly (C) Fab fragments to double or triple stranded polynucletides has been studied by fluorescence. Association constants were deduced from competition experiments. The comparison of the association constants leads to the conclusion that several atoms of the base residues do not interact with the amino acid residues of the binding site of Fab fragment while the hydroxyl groups of furanose rings interact. These results suggest that the Fab fragments do not bind to the major groove of the double stranded polynucleotides. An interaction between the C(2)O group of pyrimidine residues and Fab fragments cannot be excluded. Circular dichroism of poly(I). poly(C) or poly(I). poly(br5C)-Fab fragments complexes are very different from the circular dichroism of free polynucleotides which suggests a deformation of the polynucleotides bound to the Fab fragments.     

Synthesis,structural characterization and in vitro cytotoxicity of organotin(IV) derivatives of heterocyclic thioamides, 2-mercaptobenzothiazole, 5-chloro-2-mercaptobenzothiazole, 3-methyl-2-mercaptobenzothiazole and 2-mercaptonicotinic acid

Five new organotin(IV) molecules with the heterocyclic thioamides; 2-mercaptobenzothiazole (Hmbzt), 5-chloro-2-mercaptobenzothiazole (Hcmbzt), 3-methyl-2-mercaptobenzothiazole (mmbzt) and 2-mercaptonicotinic acid (H(2)mna) of formulae [(n-C(4)H(9))(2)Sn(mbzt)(2)] (1), [(C(6)H(5))(2)Sn(mbzt)(2)] (2), [(CH(3))(2)Sn(cmbzt)(2)].1.7(H(2)O)] (3), [(n-C(4)H(9))(2)SnCl(2)(mmbzt)(2).(CH(2)Cl(2))] (4) and [[(C(6)H(5))(3)Sn](2)(mna).[(CH(3))(2)CO]] (5) have been synthesized and characterized by elemental analysis, 1H-, 13C-NMR, FT-IR and M?ssbauer spectroscopic techniques. Crystal structures of molecules 1, 3 and 5 have been determined by X-ray diffraction at 173(1) K (1 and 5) and 293(2) K (3). Compound 1 C(22)H(26)N(2)S(4)Sn, is monoclinic, space group C2/c, a=44.018(2), b=8.8864(5), c=12.8633(7) A, beta=104.195(5) degrees, Z=8. Compound 3 is also monoclinic, space group P2(1)/c and a=17.128(2) A, b=17.919(2) A, c=7.3580(10) A, beta=98.290(10) degrees, Z=4. In both molecules 1 and 3, two carbon atoms from aryl groups, two sulfur and two nitrogen atoms from thione ligands form a distorted octahedral geometry around tin(IV) with trans-C(2), cis-N(2), cis-S(2) configurations. Compound 5 C(45)H(39)NO(3)SSn(2) is monoclinic, space group P2(1)/n, a=9.1148(2) A, b=29.2819(6), c=15.5556(4) A, beta=106.2851(9) degrees, Z=4. Complex 5 contains two [(C(6)H(5))(3)Sn(IV)] moieties linked by a double deprotonated 2-mercaptonicotinic acid (H(2)mna). Both tin(IV) ions are five coordinated. This complex is the an example of a pentacoordinated Ph(3)SnXY system with an axial-equatorial arrangement of the phenyl groups at Sn(1) atom. Compounds 1, 3 and 5 were tested for in vitro cytotoxicity against the cancer cell line of sarcoma cells (mesenchymal tissue) from the Wistar rat, polycyclic aromatic hydrocarbons (benzo[a]pyrene) carcinogenesis. Compound 5 exhibits strong cytotoxic activity, while complexes 1 and 3 show less cytotoxic activity.     

Polynucleotides. XLV Synthesis and properties of poly(2''-azido-2''-deoxyinosinic acid).

Poly (2'-azido-2'-deoxyinosinic acid), [poly (Iz)], was synthesized from 2'-azido-2'-deoxyinosine diphosphate by the action of polynucleotide phosphorylase. Poly (Iz) has UV absorption properties similar to poly (I) and hypochromicity of 11% at 0.15M Na+ and neutrality. In solutions of high Na+ ion concentration, poly (Iz) forms a multi-stranded complex and its Tm at 1.0M Na+ ion concentration was 43 degrees. Upon mixing with poly (C), poly (Iz) forms a 1:1 complex having a Tm lower than that of poly (I)-poly (C) complex in the same conditions. The effect of substitution at the 2'-position of the poly (I) strand was discussed in relation to the interferon-inducing activity.     

Induction of poly(I):poly(C)-binding 50 K protein and 2',5'-oligoadenylate synthetase in interferon-treated mouse L929 cells

A new protein retained by poly(I):poly(C)-Sepharose was induced together with dsRNA-dependent enzymatic activities, a protein kinase and 2',5'-oligoadenylate synthetase (2,5A synthetase), in interferon-treated mouse L929 cells; it had an apparent molecular weight of 50,000 (50 K) and was not phosphorylated by the protein kinase. The kinetics of the induction of the poly(I):poly(C)-binding 50 K protein were similar to those of dsRNA-dependent protein kinase and 2',5'-oligoadenylate synthetase, and their inductions were all dependent on the interferon dose added, though a relatively higher dose was required for the 50 K protein. When the interferon preparation was heated to 100 degrees C in the presence of sodium dodecyl sulfate, its effect on cells of inducing the activity of 2',5'-oligoadenylate synthetase was preserved completely, indicating that the interferon molecule itself is responsible for the induction of the synthetase. Since the induction of the enzymatic activity was inhibited by addition of either actinomycin D or cycloheximide, it may not be an activation of a latent enzyme but a de novo synthesis of the enzyme.