7-Deaza-2′-deoxyinosine: A Stable Nucleoside with the Ambiguous Base Pairing Properties of 2′-Deoxyinosine

Abstract

The base pairing ambiguity of 7-deaza-2′-deoxyinosine (c⁷I_d, 2) was studied and was found to be the same as that of 2′-deoxyinosine. The duplex stability decreases in the order [d(c⁷I-C) > d(c⁷I-A) > d(c⁷I-T) > d(c⁷I-G)]. Modified nucleosides were used to probe the various base pair motifs which were the same for dl and c⁷I_d. The 7-deazapurine nucleoside (2) is extremely stable against acid or base. As oligonucleotides can be prepared using phosphoramidite chemistry and DNA is accessible by enzymic polymerisation of the triphosphate of 2, the latter can be used as an universal nucleoside for the sequencing of DNA by chemical degradation and is otherwise a facile substitute of 2′-deoxyinosine when stability in acidic or alkaline solution is required.     

Database proton NMR chemical shifts for RNA signal assignment and validation

The Biological Magnetic Resonance Data Bank contains NMR chemical shift depositions for 132 RNAs and RNA-containing complexes. We have analyzed the ¹H NMR chemical shifts reported for non-exchangeable protons of residues that reside within A-form helical regions of these RNAs. The analysis focused on the central base pair within a stretch of three adjacent base pairs (BP triplets), and included both Watson–Crick (WC; G:C, A:U) and G:U wobble pairs. Chemical shift values were included for all 4³ possible WC-BP triplets, as well as 137 additional triplets that contain one or more G:U wobbles. Sequence-dependent chemical shift correlations were identified, including correlations involving terminating base pairs within the triplets and canonical and non-canonical structures adjacent to the BP triplets (i.e. bulges, loops, WC and non-WC BPs), despite the fact that the NMR data were obtained under different conditions of pH, buffer, ionic strength, and temperature. A computer program (RNAShifts) was developed that enables convenient comparison of RNA ¹H NMR assignments with database predictions, which should facilitate future signal assignment/validation efforts and enable rapid identification of non-canonical RNA structures and RNA-ligand/protein interaction sites.     

Conformation of N4-acetylcytidine,a modified nucleoside of tRNA,and stereochemistry of codon-anticodon interaction

The crystal structure of N⁴-acetylcytidine (ac⁴C) a modified nucleoside of tRNA, has been determined from three-dimensional x-ray diffractometer data. The N⁴-substituent is proximal to C(5), quite contrary to expectations from solution studies of N⁴-methylcytosine. This orientation of the N⁴-substituent will not block Watson-Crick base pairing for reading the third codon by tRNA_M^Met, and hence the discriminatory function suggested for ac⁴C might arise due to non-standard conformation of the polynucleotide backbone of the anticodon around the Wobble base. A common characteristic of the modified nucleosides that occur at the Wobble position is their inability to shield the Watson-Crick base pairing sites; this is quite consistent with the necessity for reading the third base of the codon. This is in sharp contrast to the modifications of the nucleosides adjacent to the 3′-end of anticodons, all of which prevent Watson-Crick base pairing.     

Direct observation of the temperature-induced melting process of the Salmonella fourU RNA thermometer at base-pair resolution

In prokaryotes, RNA thermometers regulate a number of heat shock and virulence genes. These temperature sensitive RNA elements are usually located in the 5′-untranslated regions of the regulated genes. They repress translation initiation by base pairing to the Shine–Dalgarno sequence at low temperatures. We investigated the thermodynamic stability of the temperature labile hairpin 2 of the Salmonella fourU RNA thermometer over a broad temperature range and determined free energy, enthalpy and entropy values for the base-pair opening of individual nucleobases by measuring the temperature dependence of the imino proton exchange rates via NMR spectroscopy. Exchange rates were analyzed for the wild-type (wt) RNA and the A8C mutant. The wt RNA was found to be stabilized by the extraordinarily stable G14–C25 base pair. The mismatch base pair in the wt RNA thermometer (A8–G31) is responsible for the smaller cooperativity of the unfolding transition in the wt RNA. Enthalpy and entropy values for the base-pair opening events exhibit linear correlation for both RNAs. The slopes of these correlations coincide with the melting points of the RNAs determined by CD spectroscopy. RNA unfolding occurs at a temperature where all nucleobases have equal thermodynamic stabilities. Our results are in agreement with a consecutive zipper-type unfolding mechanism in which the stacking interaction is responsible for the observed cooperativity. Furthermore, remote effects of the A8C mutation affecting the stability of nucleobase G14 could be identified. According to our analysis we deduce that this effect is most probably transduced via the hydration shell of the RNA.     

[Hg(9-methyl-1-deazapurine)2](NO3)2 · H2O: a complex with a distorted hexagonal bipyramidal metal ion coordination sphere

Reaction of 9-methyl-1-deazapurine (9-MeDP) with Hg(CF₃COO)₂ in the presence of NaNO₃ yields the title compound [Hg(9-MeDP)₂](NO₃)₂ · H₂O with the two 9-MeDP ligands bound to the metal ion via their N7 positions. The X-ray structure is reported: monoclinic, P2₁/c (no. 14), a = 5.4015(11), b = 20.467(4), c = 17.775(4) Å, β = 97.00(3)°, V = 1950.4(7) ų, Z = 4. Hg is eight-coordinate with two trans-oriented Hg-N bonds (2.073(3) and 2.075(3) Å) and three nearly coplanar, bidentate nitrate moieties (Hg-O: 2.716(3)-2.985(4) Å), leading to a distorted hexagonal bipyramidal environment of the metal ion. Within this structure, the nitrate ions form a honeycomb-like chain structure with Hg^II being positioned inside the combs. This work represents the first report of such geometry for a transition metal ion surrounded by symmetrically bidentate nitrate ions. The corresponding nucleoside, 1-deazapurine 2′-deoxyribonucleoside, also forms a stable 2:1 complex with Hg^II, as was shown by ¹H NMR spectroscopy, making it a potential candidate for incorporation into nucleic acids based on metal-mediated base pairs.     

Nucleotide sequence of nuclear 5S RNA of mouse cells

The nucleotide sequence of nuclear 5S RNA of mouse cells was determined. The 5S RNA is 117 nucleotides long with one mole each of m₃^2,2,7G, Gm, Am and Cm, two moles of Um, and three moles of ψ as modified nucleosides, and it is rich in uridylate residues (about 36 %). The 5′-terminal hexanucleotide-containing cap structure, m₃^2,2,7GpppAm-Um-A-C-U-, is identical with that of U1 RNA. This RNA contains sequences complementary to the terminal sequences of the introns of heterogeneous nuclear RNAs.     

Detection of N-H...N hydrogen bonding in RNA via scalar couplings in the absence of observable imino proton resonances

Hydrogen bond networks stabilize RNA secondary and tertiary structure and are thus essentially important for protein recognition. During structure refinements using either NMR or X-ray techniques, hydrogen bonds were usually inferred indirectly from the proximity of donor and acceptor functional groups. Recently, quantitative heteronuclear J(N,N)-HNN COSY NMR experiments were introduced that allowed the direct identification of donor and acceptor nitrogen atoms involved in hydrogen bonds. However, protons involved in base pairing interactions in nucleic acids are often not observable due to exchange processes. The application of a modified quantitative J(N,N)-HNN COSY pulse scheme permits observation of ^2hJ(N,N) couplings via non-exchangeable protons. This approach allowed the unambiguous identification of the A27·U23 reverse Hoogsteen base pair involved in a U-A·U base triple in the HIV-2 transactivation response element–argininamide complex. Despite a wealth of NOE information, direct evidence for this interaction was lacking due to the rapid exchange of the U23 imino proton. The ability to directly observe hydrogen bonds, even in D₂O and in the presence of rapid exchange, should facilitate structural studies of RNA.     

Hfq-bridged ternary complex is important for translation activation of rpoS by DsrA

The rpoS mRNA, which encodes the master regulator σ^S of general stress response, requires Hfq-facilitated base pairing with DsrA small RNA for efficient translation at low temperatures. It has recently been proposed that one mechanism underlying Hfq action is to bridge a transient ternary complex by simultaneously binding to rpoS and DsrA. However, no structural evidence of Hfq simultaneously bound to different RNAs has been reported. We detected simultaneous binding of Hfq to rpoS and DsrA fragments. Crystal structures of AU6A•Hfq•A7 and Hfq•A7 complexes were resolved using 1.8- and 1.9-Å resolution, respectively. Ternary complex has been further verified in solution by NMR. In vivo, activation of rpoS translation requires intact Hfq, which is capable of bridging rpoS and DsrA simultaneously into ternary complex. This ternary complex possibly corresponds to a meta-stable transition state in Hfq-facilitated small RNA–mRNA annealing process.     

X-ray crystallographic study of several 2'-deoxy-beta-D-ribonucleosides with 1-deazapurine-derived aglycones

The 2'-deoxy-beta-D-ribonucleosides of 1,3-deazapurine (benzimidazole (1)), 1-deazapurine (both 1H-imidazo[4,5-b]pyridine (2) and 3H-imidazo[4,5-b]pyridine (3)), and 6-benzoylamino-1-deazapurine (7-benzoylamino-3H-imidazo[4,5-b]pyridine (4)) have been prepared and structurally characterized by X-ray crystallography. Especially compounds 1-3 can serve as artificial nucleosides that may substitute 2'-deoxy adenosine because they lack the exocyclic amino group and one or two of the endocyclic nitrogen atoms and hence have a much smaller potential to engage in hydrogen bonds. In the latter respect, they are candidates for nucleosides in metal-ion mediated base pairs. The unit cell of compound 3 contains two crystallographically independent molecules. Compound 4 was crystallized from methanol and water, respectively, giving rise to two different solvates. Despite the closely related aglycones, the sugar conformations in 1-4 are found to be highly variable (1: (2)T(1); 2: (3)T(2); 3: (3)E and E(4); 4: (2)E and (2)T(3)). The structures reported here confirm that there is no simple correlation between the sugar conformation and the character of the nucleoside, and they will hopefully contribute to a better understanding of the complex interplay of different effects that are in control of the conformational equilibrium.     

Synthesis and characterization of oligodeoxynucleotides containing a novel tetraazabenzo[cd]azulene:naphthyridine base pair

The synthesis and thermal stability of oligodeoxynucleotides (ODNs) containing 4-amino-2,3,5,6-tetraazabenzo[cd]azulen-7-one nucleosides 5 (BaO^N) with the aim of developing new base pairing motif is described. The tricyclic nucleoside 5 was prepared starting with the 7-deaza-7-iodopurine derivative 1 via a palladium catalyzed cross-coupling reaction with methyl acrylate, followed by an intramolecular cyclization. The resulting nucleoside was incorporated into ODNs, and the base pairing property of the BaO^N:NaN^O (2-amino-7-hydroxy-1,8-naphthyridine nucleoside) pair in the duplex was evaluated by a thermal denaturation study. The melting temperature (T_m) of the duplex containing the BaO^N:NaN^O pair showed a higher value than that of the duplexes containing the adenine:thymine (A:T) and the guanine:cytosine (G:C) pairs, however it was lower than that of the ImO^N:NaN^O (ImO^N = 7-amino-imidazo[5′,4′:4,5]pyrido[2,3-d]pyrimidin-4(5H)-one nucleoside) pair. A temperature-dependent ¹H NMR study revealed that the H-bonding ability of BaO^N was lower than that of ImO^N, which would explain why the BaO^N:NaN^O pair was less thermally stable than the ImO^N:NaN^O pair.     

Synthesis of Modified RNA-Oligonucleotides for Structural Investigations

Abstract

RNA exhibits a higher structural diversity than DNA and is an important molecule in biology of life. It shows a number of secondary structures such as duplexes, hairpin loops, bulges, internal loops etc. However, in natural RNA, bases are limited to the four predominant structures U, C, A, and G and so the number of compounds that can be used for investigation of parameters of base stacking, base pairing and hydrogen bond, is limited. We synthesized different fluoromodifications of RNA building blocks: 1′-deoxy-1′-(2,4,6-trifluorophenyl)-ß-D-ribofuranose (F), 1′-deoxy-1′-(2,4,5-trifluorophenyl)-ß-D-ribofuranose (M) and 1′-deoxy-1′-(5-trifluoromethyl-1H-benzimidazol-1-yl)-ß-D-ribofuranose (D). Those amidites were incorporated and tested in a defined A, U- rich RNA sequence (12-mer, 5′-CUU UUC XUU CUU-3′ paired with 3′-GAA AAG YAA GAA-5’) (Schweitzer, B.A.; Kool, E.T. Aromatic nonpolar nucleosides as hydrophobic isosters of pyrimidine and purine nucleosides. J. Org. Chem. 1994, 59, 7238 pp.). Only one position was modified, marked as X and Y respectively. UV melting profiles of those oligonucleotides were measured.     

8-Aza-7-deazapurine DNA: Synthesis and Duplex Stability of Oligonucleotides Containing 7-Substituted Bases

Abstract

The 7-substituted 8-aza-7-deazapurine phosphoramidites 1a – 3c as well as the phosphoramidite 4a were synthesized. In comparison to the parent purine oligonucleotide duplexes, the 7-substituted 8-aza-7-deazapurine residues lead to a significant duplex stabilization.     

Synthesis and coding properties of poly(c 1 A), poly(c 3 A), poly(c 7 A) and poly(h 6 A)

The homopolynucleotides poly(c¹A), poly(c³A), poly(c⁷A) and poly(h⁶A)⁺⁺ were synthesized from their corresponding nucleoside diphosphates using polynucleotide phosphorylase. With the exception of poly(h⁶A), which displayed no hypochromicity, the homopolynucleotides showed melting profiles similar to poly(A). All these polynucleotides, poly(h⁶A), poly(c⁷A), poly(c³A) and poly(c¹A) stimulated the binding of Lys-tRNA to ribosomes; the coding activity of poly(c¹A), however, was very low. Poly(h⁶A) was found to be less specific for Lys-tRNA than poly(A). The data supports the exclusive formation of Watson-Crick type base pairs and contradicts Hoogsteen base pairing in codon-anticodon recognition. Since, however, poly(h⁶A), which can form only one hydrogen bridge per base pair, stimulated the binding of Lys-tRNA comparably to poly(A), the coding activity of the homopolynucleotides tested is discussed in respect to their secondary structure as well as to the pK-values of their 6-amino groups.     

Oligonucleotides Containing Pyrazolo[3,4-d]Pyrimidines: 8-Aza-7-deazaadenines With Bulky Substituents in the 2- or 7-Position

The synthesis of the 2′-deoxyadenosine analogues 1b, 2b, and 3c modified at the 7- and/or 2-position is described. The effect of 7-chloro and 2-methylthio groups on the duplex stability is evaluated. For that, the nucleosides 1b, 2b, and 3c were converted to the corresponding phosphoramidites 15, 19, and 22, which were employed in the solid-phase oligonucleotide synthesis. In oligonucleotide duplexes, compound 1b forms stable base pairs with dT, of which the separated 1b- dT base pairs contribute stronger than that of the consecutive base pairs. Compound 2b shows universal base pairing properties while its N8 isomer 3c forms duplexes with lower stability.     

Coupling of 2,6-Dichloropurine and 2,6-Dichlorodeazapurines with Ribose and Ribose Modified Sugars

Abstract

Substituted purine and deazapurine nucleosides are of great interest in medicinal chemistry. Furthermore, 3′-deoxynucleosides exhibit a number of biological activities. In this research the coupling of 2,6-dichloro-1- or 3-deazapurine with protected 3′-deoxyribose is reported. Depending upon coupling conditions and base structure, different anomeric and isomeric mixtures have been obtained. Extensive studies, utilizing chemical and physical methods, have been performed to assign the correct configuration to the resulting nucleosides.     

An RNA fragment consisting of the P7 and P9.0 stems and the 3'-terminal guanosine of the Tetrahymena group I intron.

On the basis of the nucleotide sequence of Tetrahymena group I intron, we constructed a 31 residue RNA that has the P7 stem and the 3'-terminal guanosine residue (3'-G) with a putative stem-loop structure (P9.0) intervening between them. For this model RNA (P7/P9.0/G), four residues around the guanosine binding site (GBS) in the P7 stem were found to exhibit much lower sensitivities to ribonuclease V1 than those of a variant RNA having adenosine in place of the 3'-G, suggesting that the 3'-G contacts around the GBS. NMR analyses of the imino proton resonances of the P7/P9.0/G RNA indicated that the base pairing in the GBS is retained on the interaction with the 3'-G, and that the two base pairs of the putative P9.0 stem-loop are definitely formed. Comparison of the RNA with its variants with either A (3'-A) or a deletion in place of the 3'-G suggested that the stability of the P9.0 stem-loop is affected by the GBS-3'-G interaction. The melting temperatures of the P9.0 stem-loop were determined from the UV absorbances of these RNAs, which quantitatively indicated that the P9.0 stem-loop is significantly stabilized by the interaction of the GBS with the 3'-G, rather than the 3'-A, and also by direct interaction with divalent cations (Mg2+, Ca2+ or Mn2+). Upon replacement of the G-C base pair by C-G in the GBS of the P7/P9.0/G RNA, the specificity was switched from 3'-G to 3'-A, as in the case of the intact intron.     

Solution Structure of a GAAG Tetraloop in Helix 6 of SRP RNA from Pyrococcus furiosus

The NMR structure of a 12-mer RNA derived from the helix 6 of SRP RNA from Pyrococcus furiosus, whose loop-closing base pair is U:G, was determined, and the structural and thermodynamic properties of the RNA were compared with those of a mutant RNA with the C:G closing base pair. Although the structures of the two RNAs are similar to each other and adopt the GNRR motif, the conformational stabilities are significantly different to each other. It was suggested that weaker stacking interaction of the GAAG loop with the U:G closing base pair in 12-mer RNA causes the lower conformational stability.