Synthesis and properties of PNA oligomers containing orotic acid derivatives

We have investigated the incorporation of C6-derivatives of uracil into polypyrimidine peptide nucleic acid oligomers (PNA). Starting with orotic acid (uracil-6-carboxylic acid) we have prepared a PNA monomer containing the methyl orotate nucleobase which is compatible with Fmoc-based synthesis. Treatment of the resin-bound oligomers with hydroxide or amines cleanly converted the ester to an orotic acid or orotamide-containing PNA. Alternatively, the methyl orotate-containing PNA was liberated from the resin by standard acidolysis. PNA bearing a modified nucleobase was found to hybridize to both poly(rA) and poly(dA). Complexes with poly(rA) were more stable than those with poly(dA) but both were destabilized relative to an unmodified PNA. Modification of a terminal residue was tolerated better than modification of an internal position. The type of charge provided by the modification affected the complex stability. In the worst case, an internal modification was nearly as detrimental as a base mismatch.     

Oligothymidylates covalently linked to an acridine derivative and with modified phosphodiester backbone: circular dichroism studies of their interactions with complementary sequences.

Oligothymidylates involving alternating alkyl phosphotriester-phosphodiester or methylphosphonate-phosphodiester backbones and covalently linked to an acridine derivative have been studied using circular dichroism. Two isomers with the same diastereoisomeric configuration for all the phosphotriesters (ethyl triester and neopentyl triester) or the methylphosphonate linkages were studied. These six compounds were compared to the parent oligonucleotide with unmodified phosphodiester bonds. Intramolecular interactions between the acridine and the bases of the oligonucleotides were revealed by the induced circular dichroism of the acridine dye. Binding to poly(rA) and poly(dA) induced large changes in the circular dichroism signal. All oligothymidylates formed double-stranded complexes with poly(rA). Substitution of phosphotriesters and methylphosphonates to phosphates allowed both double- and triple-stranded structures to be formed with with poly(dA). The double-stranded structures formed with poly(rA) and poly(dA) were characterized by different environments of the acridine dye. The circular dichroism spectra of the complexes with poly(dA) and the thermal stabilities of the complexes formed with both poly(rA) and poly(dA) were drastically dependent of the diastereoisomeric configuration of the phosphate modification. For the complexes formed with the pseudoequatorial stereoisomer the modification of the phosphate groups increased the stability of the complexes as compared with the oligothymidylate containing only phosphodiester linkages whereas it decreased it for pseudoaxial modifications.     

The binding of poly (rA) and poly (rU) to denatured DNA. II. Studies with natural DNAs.

We have studied the interaction of poly(rA) and poly(rU) with natural DNAs containing (dA.dT)n sequences. The results indicate that hybridization of poly(rA) to denatured DNA can be used to estimate the size and frequency of large (dA.dT)n tracts, whereas hybridization with poly(rU) does not give reliable information on these points. In 6.6 M CsCl, poly(rU) can form stable complexes with denatured DNA containing short (dA)n tracts (n less than or equal to 6), whereas binding of poly(rA) to denatured DNA under these conditions requires much larger (dT)n tracts (estimated n greater than 13). Moreover, binding of poly(rA) requires pre-hybridization in low salt, because free poly(rA) precipitates in 6.6 M CsCl.     

The binding of poly(rA) and poly(rU) to denatured DNA. I. Model studies with homopolymers.

We have compared the properties of the poly(rA).oligo(dT) complex with those of the poly(rU).oligo(dA)n complex. Three main differences were found. First, poly(rA) and oligo(dT)n do not form a complex in concentrations of CsCl exceeding 2 M because the poly(rA) is insoluble in high salt. If the complex is made in low salt, it is destabilized if the CsCl concentration is raised. Complexes between poly(rU) and oligo(dA)n, on the other hand, can be formed in CsCl concentrations up to 6.6 M. Second, complexes between poly(rA) and oligo(dT)n are more rapidly destabilized with decreasing chain length than complexes between poly(rU) and oligo(dA)n. Third, the density of the complex between poly(rA) and poly(dT) in CsCl is slightly lower than that of poly(dT), whereas the density of the complex between poly(rU) and poly(dA) in CsCl is at least 300 g/cm3 higher than that of poly(dA). These results explain why denatured natural DNAs that bind poly(rU) in a CsCl gradient usually do not bind poly(rA).     

Replication of poly dA and poly rA by a Drosophila DNA polymerase

The activity of a 7.3S-8.3S Drosophila DNA polymerase was characterized in detail using poly dA.p(dT)[unk] and poly rA.p(dT)[unk]. With poly dA.p(dT)[unk], Mg(2+) ion was the preferred divalent cation, and enzyme activity was inhibited by K(+) ion and by spermidine. With poly rA.p(dT)[unk], Mn(2+) ion was the preferred divalent cation and enzyme activity was stimulated by K(+) ion and by spermidine. The dependence of enzyme activity on the concentration of primer-template and on the ratio of primer to template was the same in both reactions. The two enzyme activities were identically inhibited by N-ethylmaleimide. Poly dA was replicated extensively and poly rA was replicated partially. The activation energy for poly dA replication was twice that for poly rA replication. Enzyme activity with poly dA.p(dT)[unk] was more stable to thermal inactivation than was enzyme activity with poly rA.p(dT)[unk]. These studies suggest that the same enzyme responds to both the deoxy- and the ribohomopolymer template but that the mechanisms of replication may be different.     

Oligodeoxynucleoside phosphoramidates (P-NH2): synthesis and thermal stability of duplexes with DNA and RNA targets.

Syntheses of non ionic oligodeoxynucleoside phosphoramidates (P-NH2) and mixed phosphoramidate- phosphodiester oligomers were accomplished on automated solid supported DNA synthesizer using both H-phosphonate and phosphoramidite chemistries, in combination with t-butylphenoxyacetyl for N-protection of nucleoside bases, an oxalyl anchored solid support and a final treatment with methanolic ammonia. Thermal stabilities of the hybrids formed between these new analogues and their DNA and RNA complementary strands were determined and compared with those of the corresponding unmodified oligonucleotides, as well as of the phosphorothioate and methylphosphonate derivatives. Dodecathymidines containing P-NH2 links form less stable duplexes with DNA targets, d(C2A12C2) (deltaTm/modification -1.4 degrees C) and poly dA (deltaTm/modification -1.1 degrees C) than the corresponding phosphodiester and methylphosphonate analogues, but the hybrids are slightly more stable than the one obtained with phosphorothioate derivative. The destabilization is more pronounced with poly rA as the target (deltaTm/modification -3 degrees C) and could be compared with that found with the dodecathymidine methylphosphonate. The modification is less destabilizing in an heteropolymer-RNA duplex (deltaTm/modification -2 degrees C). As expected, the P-NH2 modifications are highly resistant towards the action of various nucleases. It is also demonstrated that an all P-NH2 oligothymidine does not elicit Escherichia coli RNase H hydrolysis of the poly rA target but that the modification may be exploited in chimeric oligonucleotides combining P-NH2 sections with a central phosphodiester section.     

A Raman scattering study of the helix-destabilizing gene-5 protein with adenine-containing nucleotides.

Raman spectra of gp5 and complexes of gp5 with poly(rA) and poly(dA) have been determined and analysed. From a fit of the amide I-band with model spectra it follows that the secondary structure of gp5 contains 52% beta-sheet, 28% undefined conformation and 19% alpha-helix. The band at 1032 cm-1 due to phenylalanine has an anomalous intensity both in the spectra of the complexes and the free protein. This possibly indicates a stacked structure present in the protein. Binding of gp5 to poly(rA) and poly(dA) influences the intensity of bands near 1338 and 1480 cm-1 which are considered to be marker-bands for the phosphate-sugar-base conformer. A change in conformation of the nucleotides is also reflected by vibrations originating in the phosphate- and sugar-residues of the backbone. In the spectrum of complexed poly(rA) the intensity of the conformation sensitive band at 813 cm-1, which is due to the phosphodiester group, is zero. It seems that gp5 forces poly(rA) and poly(dA) to a similar conformation. A marker band for stacking interaction in poly(rA) indicates that stacking interactions in the complex have increased.     

Polynucleotide sequences in eukaryotic DNA and RNA that form ribonuclease-resistant complexes with polyuridylic acid

When annealed with synthetic polynucleotides and treated with ribonuclease under appropriate conditions, poly(U) forms the ribonuclease-resistant complexes poly(rA) · poly(U) (1:1), poly(dA) · 2poly(U) (1:2) and poly · (dA)poly(dT) · poly(U) (1:1:1). This forms the basis of a quantitative assay of poly(rA), poly(dA) and poly(dA) · poly(dT) sequences in unlabelled nucleic acids. Using this assay, duck haemoglobin messenger RNA is shown to contain a poly(rA) sequence approximately 100 nucleotides long.Eukaryotic DNAs contain small amounts of sequences that react with poly(U). In the case of duck DNA, these sequences are considerably shorter than the mRNA-associated sequences and are interspersed widely with other sequences. It is concluded that if duck DNA does contain poly(dA) sequences corresponding to mRNA-associated poly(rA) sequences, there are fewer than 8000 of these per haploid genome.     

Triple helical polynucleotidic structures: sugar conformations determined by FTIR spectroscopy.

Fourier Transform Infrared Spectra of triple stranded polynucleotides containing homopurine dA or rA and homopyrimidine dT or rU strands have been obtained in H2O and D2O solutions as well as in hydrated films at various relative humidities. The spectra are interpreted by comparison with those of double stranded helixes with identical base and sugar composition. The study of the spectral domain corresponding to in-plane double bond stretching vibrations of the bases shows that whatever the initial duplex characterized by a different IR spectrum (A family form poly rA.poly rU, heternomous form poly rA.poly dT, B family form poly dA.poly dT), the triplexes present a similar IR spectrum reflecting similar base interactions. A particular attention is devoted to the 950-800 cm-1 region which contains marker bands of the sugar conformation in the nucleic acids. In solution the existence of only N (C3'endo-A family form) type of sugar pucker is detected in poly rU.poly rA.poly rU and poly dt.poly rA.poly rU. On the contrary absorption bands characteristic of both N (C3'endo-A family form) and S (C2'endo-B family form) type sugars are detected for poly rU.poly rA.poly dT, poly rU.poly dA.poly dT and poly dT.poly rA.poly dT. Finally mainly S (C2'endo-B family form) type sugars are observed in poly dT.poly dA.poly dT.     

Construction of peptide conjugates with peptide nucleic acids containing an anthracene probe and their interactions with DNA

We designed and synthesized the peptide nucleic acid (PNA)-peptide conjugates having anthracene chromophores and investigated their interactions with calf thymus DNA, [d(AT)(10)](2), [d(GC)(10)](2), and [d(AT)(10)dA(6)](2). Considering the synthesis compatibility and expecting that a novel DNA analogue, PNA, can improve DNA binding properties of alpha-helix peptides, we attempted to attach thymine PNA oligomers at the C-terminus of a 14 amino acid alpha-helix peptide that contained a pair of artificial intercalators, anthracene, as a probe, and to examine their interactions with DNA using anthracene UV, fluorescence and circular dichroism properties. The results observed in this study showed that the designed peptide folded in an alpha-helix structure in the presence of calf thymus DNA, [d(AT)(10)](2), and [d(AT)(10)dA(6)](2) with the chromophores at the side-chain being fixed with a left-handed chiral-sense orientation. The alpha-helix and the anthracene signals were not observed for [d(GC)(10)](2). Incorporation of thymine PNA oligomers into the designed alpha-helix peptide increased the DNA binding ability to [d(AT)(10)dA(6)](2) with increasing the length of the PNA without changing the conformations of the peptide backbone and the anthracene side-chains.     

Three forms of DNA polymerase from Drosophila melanogaster embryos. Purification and properties.

DNA polymerase was purified from Drosophila melanogaster embryos by a combination of phosphocellulose adsorption, Sepharose 6B gel filtration, and DEAE-cellulose chromatography. Three enzyme forms, designated enzymes I, II, and III, were separated by differential elution from DEAE-cellulose and were further purified by glycerol gradient centrifugation. Purification was monitored with two synthetic primer-templates, poly(dA) . (dT)-16 and poly(rA) . (dT)-16. At the final step of purification, enzymes I, II, and III were purified approximately 1700-fold, 2000-fold and 1000-fold, respectively, on the basis of their activities with poly(dA) . (dT)-16. The DNA polymerase eluted heterogeneously as anomalously high-molecular-weight molecules from Sepharose 6B gel filtration columns. On DEAE-cellulose chromatography enzymes I and II eluted as distinct peaks and enzyme III eluted heterogeneously. On glycerol velocity gradients enzyme I sedimented at 5.5-7.3 S, enzyme II sedimented at 7.3-8.3 S, and enzyme III sedimented at 7.3-9.0 S. All enzymes were active with both synthetic primer-templates, except the 9.0 S component of enzyme III, which was inactive with poly(rA) . (dT)-16. Non-denaturing polyacrylamide gel electrophoresis did not separate poly(dA) . (dT)-16 activity from poly(rA) . (dT)-16 activity. The DNA polymerase preferred poly(dA) . (dT)-16 (with Mg2+) as a primer-template, although it was also active with poly(rA) . (dT)-16 (with Mn2+), and it preferred activated calf thymus DNA to native or heat-denatured calf thymus DNA. All three primer-template activities were inhibited by N-ethylmaleimide. Enzyme activity with activated DNA and poly(dA) . (dT)-16 was inhibited by K+ and activity with poly(rA) . (dT)-16 was stimulated by K+ and by spermidine. The optimum pH for enzyme activity with the synthetic primer-templates was 8.5. The DNA polymerases did not exhibit deoxyribonuclease or ATPase activities. The results of this study suggest that the forms of DNA polymerase from Drosophila embryos have physical properties similar to those of DNA polymerase-alpha and enzymatic properties similar to those of all three vertebrate DNA polymerases.     

The poly dA strand of poly dA.poly dT adopts an A-form in solution: a UV resonance Raman study.

The study by resonance Raman spectroscopy with a 257 nm excitation wave-length of adenine in two single-stranded polynucleotides, poly rA and poly dA, and in three double-stranded polynucleotides, poly dA.poly dT, poly(dA-dT).poly(dA-dT) and poly rA.poly rU, allows one to characterize the A-genus conformation of polynucleotides containing adenine and thymine bases. The characteristic spectrum of the A-form of the adenine strand is observed, except small differences, for poly rA, poly rA.poly rU and poly dA.poly dT. Our results prove that it is the adenine strand which adopts the A-family conformation in poly dA.poly dT.     

A Polydeoxythymidylic acid-specific deoxyribonuclease from rat ascites hepatoma cells.

A deoxyribonuclease has been purified 950-fold from rat ascites hepatoma cells and has been separated from another deoxyribonuclease that appears to have DNase III type activity. The enzyme preferentially degrades single stranded poly(dT), requires Mg²⁺ for maximum activity and has a pH optimum at 8.5 in Tris-HCl buffer. Poly(dA), poly(dC), poly(rA), and poly(rU) are not effective substrates. The hydrolysis of poly(dT) is strongly inhibited when poly(dA) or poly(rA) is annealed with poly(dT). Poly(dT) is degraded ultimately into 5′-deoxythymidylic acid via the formation of oligodeoxythymidylate intermediates.     

Thermodynamics of nucleic acid "shape readout" by an aminosugar

Recognition of nucleic acids is important for our understanding of nucleic acid structure as well as for our understanding of nucleic acid-protein interactions. In addition to the direct readout mechanisms of nucleic acids such as H-bonding, shape recognition of nucleic acids is being increasingly recognized as playing an equally important role in DNA recognition. Competition dialysis, UV, flourescent intercalator displacement (FID), computational docking, and calorimetry studies were conducted to study the interaction of neomycin with a variety of nucleic acid conformations (shapes). At pH 5.5, the results suggest the following. (1) Neomycin binds three RNA structures [16S A site rRNA, poly(rA)·poly(rA), and poly(rA)·poly(rU)] with high affinities (K(a) ~ 10(7) M(-1)). (2) The binding of neomycin to A-form GC-rich oligomer d(A(2)G(15)C(15)T(2))(2) has an affinity comparable to those of RNA structures. (3) The binding of neomycin to DNA·RNA hybrids shows a 3-fold variance that can be attributed to their structural differences [for poly(dA)·poly(rU), K(a) = 9.4 × 10(6) M(-1), and for poly(rA)·poly(dT), K(a) = 3.1 × 10(6) M(-1)]. (4) The interaction of neomycin with DNA triplex poly(dA)·2poly(dT) yields a binding affinity (K(a)) of 2.4 × 10(5) M(-1). (5) Poly(dA-dT)(2) shows the lowest association constant for all nucleic acids studied (K(a) < 10(5)). (6) Neomycin binds to G-quadruplexes with K(a) values of ~10(4)-10(5) M(-1). (7) Computational studies show that the decrease in major groove width in the B to A transition correlates with increasing neomycin affinity. Neomycin's affinity for various nucleic acid structures can be ranked as follows: RNAs and GC-rich d(A(2)G(15)C(15)T(2))(2) structures > poly(dA)·poly(rU) > poly(rA)·poly(dT) > T·A-T triplex, G-quadruplex, B-form AT-rich, or GC-rich DNA sequences. The results illustrate the first example of a small molecule-based "shape readout" of different nucleic acid conformations.     

Volume changes correlate with entropies and enthalpies in the formation of nucleic acid homoduplexes: Differential hydration of A and B conformations

We have used a combination of densimetric, calorimetric, and uv absorption techniques to obtain a complete thermodynamic characterization for the formation of nucleic acid homoduplexes of known sequence and conformation. The volume change ΔV accompanying the formation of four duplexes was interpreted to reflect changes in hydration based on the electrostriction phenomenon. In 10 mM sodium phosphate buffer at pH 7, the magnitude of the measured ΔV's ranged from ?2.0 to +7.2 ml/mol base pair and followed the order of poly(rA) · poly(dT) ～ poly(dA) · poly(dT) < poly(rA) · poly(dU) ～ poly(rA) · poly(rU). Inclusion of 100 mM NaCl in the same buffer gave the range of ?17.4 to ?2.3 mL/mol base pair and the following order: poly(dA) · poly(dT) < poly(rA) · poly(dT) < poly(rA) · poly(rU) ～ poly(rA) ～ polyr(dU). Standard thermodynamic profiles of forming these duplexes from their corresponding complementary single strands indicated similar free energies that resulted from the compensation of favorable enthalpies with unfavorable entropies along with a similar counterion uptake at both ionic strengths. The differences in these compensating effects of entropy and enthalpy correlated very well with the volume change measurements in a manner suggesting that the homoduplexes in the B conformation are more hydrated than are those in the A conformation. Moreover, the increased thermal stability of these homoduplexes resulted from an increase in the salt concentration corresponding to larger hydration levels as reflected by the ΔV results. © 1993 John Wiley & Sons, Inc.     

Molecular states in single-stranded adenylate chains by relaxation analysis

The single-strand helix-coil transition in various oligo- and polyadenylates is characterized by means of an improved cable temperature-jump technique. In all the polymers studied {poly(rA), poly(dA), poly[A(m^2′)] and poly[A(e^2′)]} helix-coil relaxation is observed in the time range from 30 to 1000 nsec. Relaxation-time constants observed at wavelengths λ<280 nm (τ_α) are different from those found at λ >280 nm (τβ), indicating the presence of more than two conformational states. The time constants τ_α increase in the series poly(dA), poly[A(m^2′)], constants τ_β/τ_α is approximately 2.5, except in poly(dA) where τ_β/τ_α ≈ 9. Relaxation measurements with r(A)_n- oligomers show a decrease in conformational mobility with increasing chain length. The relaxation curves also demonstrate that “internal” residues have lower reaction rates than residues at the ends of the oligomer chain. Measurement in D₂O reveal a solvent isotope effect for τ_α of +87% for poly(rA), and of +53% for poly(dA), whereas no isotope effect is found in τ_β. The absence of “slow” relaxation processes in the model compound 9,9′ -trimethylenebisadenine shows that the relatively low rate of the single-strand helix-coil transitions is due to the coupling of base stacking with the folding of the sugar–phosphate chain. The absence of a seprate relaxation process (corresponding to τ_β) in 9,9′-trimethylenebisadenine, as well as in the dinucleotides ApC and CpA, suggests that this relaxation process is dependent upon the presence of both the sugar–phosphate chain and of adjacent adenine bases. The experimental data provide evidence that there is more than one ordered conformation in various single-stranded oligo- and polyadenylates and that the transition between these conformations is influenced by the sugar conformation.     

Polynucleotide recognition by DNA alpha-polymerase.

In a survey of template-primer preference of a mouse myeloma DNA alpha-polymerase, the fastest rate of DNA synthesis was with poly(dT) as template and (rA)24 as primer. Such a preference for poly(dT).oligo(rA) was not observed with other DNA polymerases of mouse origin. DNA synthesis in this system resulted in formation of oligo(dA) chains, not template-length poly(dA); thus, the average enzyme molecule bound to a poly(dT).(rA)24 complex and initiated a new oligo(dA) chain many times during the incubation. Binding experiments revealed that the alpha-polymerase had high affinity for poly(dT). Although the alpha-polymerase did not bind to poly(dl) and failed to replicate it inreactions with a base pair complementary primer, poly(dl) was replicated after a (dT) block had been grafted to its 3'-end and the oligo(rA) primer had been added. In similar experiments, the (dT) block was found to be much more effective than other 3'-terminal blocks in promoting replication of denatured calf thymus DNA. The results indicate that specific base sequences may regulate initiation of DNA syntehsis by this alpha-polymerase.     

Single strand conformation of adenylate chains analysed by a specific photoreaction. Determination of structure by 5'' residue.

The photoreactivity was analysed in various oligo- and polyadenylates: 1) The quantum yields of the specific photoreaction in poly(dA) and dApdA decrease with increasing temperature, whereas the quantum yield of the photodegradation in poly(rA) increases. 2) The photoreactivities of poly(2'MeA) and poly(2'EtA) closely correspond to that of poly(rA). 3) The photodegradation of rApdA is very similar to that of rAprA, whereas dAprA shows the same specific photoreaction as observed for dApdA. These data support the view, that the specific photoreaction observed in oligo(dA) and poly(dA) is dependent upon a specific conformation, which is not accessible to oligo(rA), poly(rA), poly(2'MeA) and poly(2'EtA). The specific conformation is determined by the nucleotide, which carries the internucleotide bond in the 3'-position.     

Novel properties of DNA polymerase beta with poly(rA).oligo(dT) template-primer.

Purified DNA polymerase beta of calf thymus can utilize poly(rA).oligo(dT) as efficiently as poly(dA).oligo(dT) or activated DNA as a template primer. The poly(rA).oligo(dT)-dependent activity of DNA polymerase beta was found to differ markedly from the DNA-dependent activity of the same enzyme (with either activated calf thymus DNA or poly(dA).(dT)10) in the following respects. 1) Poly(rA)-dependent activity was strongly inhibited by natural DNA from various sources or synthetic deoxypolymer duplexes at very low concentrations (less than 0.5 microgram/ml) at which the DNA-dependent activity was affected to a much smaller extent, if at all. 2) Poly(rA)-dependent activity was inhibited by N-ethylmaleimide more strongly than DNA-dependent activity measured at 37 degrees C, while it was resistant to this reagent at 26 degrees C. 3) The curves of the activity versus substrate concentration were sigmoidal in the poly(rA)-dependent reaction but hyperbolic in the activated DNA-dependent reaction. A kinetic study suggested that the association of beta-enzyme protomers may be required to copy the poly(rA) strand.