Conformational Preferences of Modified Nucleoside N(4)-Acetylcytidine, ac4C Occur at “Wobble” 34th Position in the Anticodon Loop of tRNA

Conformational preferences of modified nucleoside, N(4)-acetylcytidine, ac⁴C have been investigated using quantum chemical semi-empirical RM1 method. Automated geometry optimization using PM3 method along with ab initio methods HF SCF (6-31G**), and density functional theory (DFT; B3LYP/6-31G**) have also been made to compare the salient features. The most stable conformation of N(4)-acetyl group of ac⁴C prefers “proximal” orientation. This conformation is stabilized by intramolecular hydrogen bonding between O(7)···HC(5), O(2)···HC2′, and O4′···HC(6). The “proximal” conformation of N(4)-acetyl group has also been observed in another conformational study of anticodon loop of E. coli elongator tRNA^Met. The solvent accessible surface area (SASA) calculations revealed the role of ac⁴C in anticodon loop. The explicit molecular dynamics simulation study also shows the “proximal” orientation of N(4)-acetyl group. The predicted “proximal” conformation would allow ac⁴C to interact with third base of codon AUG/AUA whereas the ‘distal’ orientation of N(4)-acetyl cytidine side-chain prevents such interactions. Single point energy calculation studies of various models of anticodon–codon bases revealed that the models ac⁴C₍₃₄₎(Proximal):G₃, and ac⁴C₍₃₄₎(Proximal):A₃ are energetically more stable as compared to models ac⁴C₍₃₄₎(Distal):G₃, and ac⁴C₍₃₄₎(Distal):A₃, respectively. MEPs calculations showed the unique potential tunnels between the hydrogen bond donor–acceptor atoms of ac⁴C₍₃₄₎(Proximal):G₃/A₃ base pairs suggesting role of ac⁴C in recognition of third letter of codons AUG/AUA. The “distal” conformation of ac⁴C might prevent misreading of AUA codon. Hence, this study could be useful to understand the role of ac⁴C in the tertiary structure folding of tRNA as well as in the proper recognition of codons during protein biosynthesis process.     

Conformation and possible role of hypermodified nucleosides adjacent to 3'-end of anticodon in tRNA: N-(purin-6-ylcarbamoyl)-L-threonine riboside

The crystal structure of N-(purin-6-ylcarbamoyl)-L-threonine riboside was determined from three-dimensional x-ray diffraction data. The N⁶-substituent is distal ($\text{trans}$) to the imidazole ring, leading to a bifurcated hydrogen interaction involving two intramolecular contacts with the hydrogen on N(threonine): a hydrogen bond to N(1) of adenine and a close contact to the hydroxyl oxygen of threonine. The conformation of the molecule and the internal hydrogen bond completely block the two sites N⁶-H and N¹ of adenine from taking part in the Watson-Crick base pairing. This inability to base pair according to the Watson-Crick scheme appears as a common structural feature in all modified bases adjacent to the 3′-end of anticodons. These results, along with Crick's hypothesis for codon recognition, suggest that the hypermodified bases adjacent to the anticodons may be important in (i) preventing the misreading of the codons by bases adjacent to anticodons and (ii) promoting a single stranded conformation for the anticodon loops.     

Conformation of N-(purin-6ylcarbamoyl) glycine, a hypermodified base in tRNA

The crystal structure of the potassium salt of N-(purin-6ylcarbamoyl) glycine was determined from three-dimensional X-ray diffraction data. The N⁶-substituent is distal ($\text{trans}$) to the imidazole ring, forming an intramolecular hydrogen bond N(glycine) -H---N(1)adenine. This conformation of the N⁶-substituent is typical of ureidopurines, and blocks the two sites N⁶-H and N¹ of adenine that are normally utilized for complementary base-pairing in the double helical regions of nucleic acids; the internal hydrogen bonding further enhances the shielding of N¹. This blocking of N⁶-H and N¹ may be important in enhancing the single stranded conformation of the anticodon loop of tRNA and in preventing the modified adenosine adjacent to the anticodon from taking part directly in codon-anticodon interaction through the complementary base pairing.     

CRYSTAL STRUCTURE OF 1,3,5-TRIMETHYL-N4-HYDROXYCYTOSINE,AND ITS RELEVANCE TO THE MECHANISM OF HYDROXYLAMINE MUTAGENESIS

Abstract

1,3,5-Trimethyl-N⁴-hydroxycytosine, an analogue of the promutagenic N⁴-hydroxycytosine and 5-methyl-N⁴-hydroxycytosine nucleosides, crystallizes in the monoclinic space group P 2₁/n with cell dimensions at ?147°C: a = 7.1481(7), b = 9.2565(5), c = 13.3086(12) Å, β = 97.90(2)°, V = 872.24(13) ų, ρ_c = 1.426 Mg m^?3, Z = 4, F(000) = 401.39, μ = 0.91 mm^?1, λ(Cu) = 1.54056 Å, 20(max) = 139.3°. The crystal structure has been solved by X-ray difraction and refined to R = 3.7 % for 1457 reflections. Notwithstandin the steric hindrance imposed by methyl groups at both N(3) and C(5), the exocyclic N⁴-OH group is located essentially in the plane of the ring, giving rise to an “overcrowded” molecule, like that of 1,5,N⁴,N⁴-tetramethylcytosine. The conformational parameters have also been compared with those of a number of related and previously reported N(1)-substituted cytosines. In the present compound the N⁴-OH rotamer is in the anti conformation relative to the ring N(3), hence similar to that of one of the rotamers in N(1)-substituted N⁴-hydroxycytosine, which permits normal Watson-Crick base pairing of the latter, relevant to the mechanism of hydroxylamine mutagenesis.     

Synthesis and triplex-forming properties of oligonucleotides capable of recognizing corresponding DNA duplexes containing four base pairs

A triplex-forming oligonucleotide (TFO) could be a useful molecular tool for gene therapy and specific gene modification. However, unmodified TFOs have two serious drawbacks: low binding affinities and high sequence-dependencies. In this paper, we propose a new strategy that uses a new set of modified nucleobases for four-base recognition of TFOs, and thereby overcome these two drawbacks. TFOs containing a 2’-deoxy-4N-(2-guanidoethyl)-5-methylcytidine (d^gC) residue for a C-G base pair have higher binding and base recognition abilities than those containing 2’-OMe-4N-(2-guanidoethyl)-5-methylcytidine (_2’-OMe^gC), 2’-OMe-4N-(2-guanidoethyl)-5-methyl-2-thiocytidine (_2’-OMe^gC_s), d^gC and 4S-(2-guanidoethyl)-4-thiothymidine (^gsT). Further, we observed that N-acetyl-2,7-diamino-1,8-naphtyridine (^DAN_ac) has a higher binding and base recognition abilities for a T-A base pair compared with that of dG and the other DNA derivatives. On the basis of this knowledge, we successfully synthesized a fully modified TFO containing ^DAN_ac, d^gC, 2’-OMe-2-thiothymidine (_2’-OMe^sT) and 2’-OMe-8-thioxoadenosine (_2’-OMe^sA) with high binding and base recognition abilities. To the best of our knowledge, this is the first report in which a fully modified TFO accurately recognizes a complementary DNA duplex having a mixed sequence under neutral conditions.     

Identification and codon reading properties of 5-cyanomethyl uridine,a new modified nucleoside found in the anticodon wobble position of mutant haloarchaeal isoleucine tRNAs

Most archaea and bacteria use a modified C in the anticodon wobble position of isoleucine tRNA to base pair with A but not with G of the mRNA. This allows the tRNA to read the isoleucine codon AUA without also reading the methionine codon AUG. To understand why a modified C, and not U or modified U, is used to base pair with A, we mutated the C34 in the anticodon of Haloarcula marismortui isoleucine tRNA (tRNA₂^Ile) to U, expressed the mutant tRNA in Haloferax volcanii, and purified and analyzed the tRNA. Ribosome binding experiments show that although the wild-type tRNA₂^Ile binds exclusively to the isoleucine codon AUA, the mutant tRNA binds not only to AUA but also to AUU, another isoleucine codon, and to AUG, a methionine codon. The G34 to U mutant in the anticodon of another H. marismortui isoleucine tRNA species showed similar codon binding properties. Binding of the mutant tRNA to AUG could lead to misreading of the AUG codon and insertion of isoleucine in place of methionine. This result would explain why most archaea and bacteria do not normally use U or a modified U in the anticodon wobble position of isoleucine tRNA for reading the codon AUA. Biochemical and mass spectrometric analyses of the mutant tRNAs have led to the discovery of a new modified nucleoside, 5-cyanomethyl U in the anticodon wobble position of the mutant tRNAs. 5-Cyanomethyl U is present in total tRNAs from euryarchaea but not in crenarchaea, eubacteria, or eukaryotes.     

'Protected DNA Probes' capable of strong hybridization without removal of base protecting groups

We propose a new strategy called the ‘Protected DNA Probes (PDP) method’ in which appropriately protected bases selectively bind to the complementary bases without the removal of their base protecting groups. Previously, we reported that 4-N-acetylcytosine oligonucleotides (ac⁴C) exhibited a higher hybridization affinity for ssDNA than the unmodified oligonucleotides. For the PDP strategy, we created a modified adenine base and synthesized an N-acylated deoxyadenosine mimic having 6-N-acetyl-8-aza-7-deazaadenine (ac⁶az⁸c⁷A). It was found that PDP containing ac⁴C and ac⁶az⁸c⁷A exhibited higher affinity for the complementary ssDNA than the corresponding unmodified DNA probes and showed similar base recognition ability. Moreover, it should be noted that this PDP strategy could guarantee highly efficient synthesis of DNA probes on controlled pore glass (CPG) with high purity and thereby could eliminate the time-consuming procedures for isolating DNA probes. This strategy could also avoid undesired base-mediated elimination of DNA probes from CPG under basic conditions such as concentrated ammonia solution prescribed for removal of base protecting groups in the previous standard approach. Here, several successful applications of this strategy to single nucleotide polymorphism detection are also described in detail using PDPs immobilized on glass plates and those prepared on CPG plates, suggesting its potential usefulness.     

Decoding the genome: a modified view

Transfer RNA’s role in decoding the genome is critical to the accuracy and efficiency of protein synthesis. Though modified nucleosides were identified in RNA 50 years ago, only recently has their importance to tRNA’s ability to decode cognate and wobble codons become apparent. RNA modifications are ubiquitous. To date, some 100 different posttranslational modifications have been identified. Modifications of tRNA are the most extensively investigated; however, many other RNAs have modified nucleosides. The modifications that occur at the first, or wobble position, of tRNA’s anticodon and those 3′-adjacent to the anticodon are of particular interest. The tRNAs most affected by individual and combinations of modifications respond to codons in mixed codon boxes where distinction of the third codon base is important for discriminating between the correct cognate or wobble codons and the incorrect near-cognate codons (e.g. AAA/G for lysine versus AAU/C asparagine). In contrast, other modifications expand wobble codon recognition, such as U·U base pairing, for tRNAs that respond to multiple codons of a 4-fold degenerate codon box (e.g. GUU/A/C/G for valine). Whether restricting codon recognition, expanding wobble, enabling translocation, or maintaining the messenger RNA, reading frame modifications appear to reduce anticodon loop dynamics to that accepted by the ribosome. Therefore, we suggest that anticodon stem and loop domain nucleoside modifications allow a limited number of tRNAs to accurately and efficiently decode the 61 amino acid codons by selectively restricting some anticodon–codon interactions and expanding others.     

The Design and Synthesis of N 4-Anthraniloyl-2′-dC,the Improved Syntheses of N 4-Carbamoyl-and N4- Ureidocarbamoyl-2′-dC,Incorporation into Oligonucleotides and Triplex Formation Testing

Abstract

Three modified nucleosides were designed with the aim of achieving triplet formation with the CG base pair of duplex DNA. Direct anthraniloylation of 2′-deoxycytidine, using isatoic anhydride, afforded the novel N ⁴-anthraniloyl-2′-deoxycytidine. Much improved preparations of N ⁴-carbamoyl-2′-deoxycytidine and of N ⁴-ureidocarbonyl-2′-deoxycytidine were accomplished. The modified nucleosides were incorporated into oligonucleotides. Thermal denaturation studies and gel mobility shift analysis suggest that these nucleosides do not form base triplets with any of the four base pairs of DNA.     

New light on tautomerism of purines and pyrimidines and its biological and genetic implications

The tautomerism of the natural 1-substituted pyrimidines and 9-substituted purines found in nucleic acids has been re-examined in the light of new experimental data on various nitrogen heterocycles in solution, in the gas phase and, in part, in low-temperature inert matrices. The results are compared with those obtained by quantum chemical calculations, including improved versions of the latter. Examples are presented of natural nucleosides which exhibit appreciable tautomerism in solution,e.g. formycins A and B, isoguanosine, but are not found in DNA. Illustrations are given of synthetic promutagenic nucleosides with pronounced tautomerism in solution relevant to their role in mutagenesis, such as the N⁴-hydroxy-and N⁴-methoxy cytidines. The amino-imino tautomeric equilibria of the promutagenic N⁶-hydroxy-and N⁶ -methoxy-adenosines are highly dependent on the solvent medium, the proportion of the imino species varying from 10% in CCl₄ to 90% in aqueous medium. The type of base pairing of these is dependent on the conformation of the exocyclic hydroxy or methoxy groups. At the monomer level, addition of a potentially complementary base leads to a shift in the tautomeric equilibrium in favour of the species which pairs with this base. Biological and genetical implications of the foregoing are described.     

An algebraic hypothesis about the primeval genetic code architecture

A plausible architecture of an ancient genetic code is derived from an extended base triplet vector space over the Galois field of the extended base alphabet {D, A, C, G, U}, where symbol D represents one or more hypothetical bases with unspecific pairings. We hypothesized that the high degeneration of a primeval genetic code with five bases and the gradual origin and improvement of a primeval DNA repair system could make possible the transition from ancient to modern genetic codes. Our results suggest that the Watson-Crick base pairing G ≡ C and A = U and the non-specific base pairing of the hypothetical ancestral base D used to define the sum and product operations are enough features to determine the coding constraints of the primeval and the modern genetic code, as well as, the transition from the former to the latter. Geometrical and algebraic properties of this vector space reveal that the present codon assignment of the standard genetic code could be induced from a primeval codon assignment. Besides, the Fourier spectrum of the extended DNA genome sequences derived from the multiple sequence alignment suggests that the called period-3 property of the present coding DNA sequences could also exist in the ancient coding DNA sequences. The phylogenetic analyses achieved with metrics defined in the N-dimensional vector space (B³)^N of DNA sequences and with the new evolutionary model presented here also suggest that an ancient DNA coding sequence with five or more bases does not contradict the expected evolutionary history.     

Life without tRNAIle-lysidine synthetase: translation of the isoleucine codon AUA in Bacillus subtilis lacking the canonical tRNA2Ile

Translation of the isoleucine codon AUA in most prokaryotes requires a modified C (lysidine or agmatidine) at the wobble position of tRNA₂^Ile to base pair specifically with the A of the AUA codon but not with the G of AUG. Recently, a Bacillus subtilis strain was isolated in which the essential gene encoding tRNA^Ile-lysidine synthetase was deleted for the first time. In such a strain, C34 at the wobble position of tRNA₂^Ile is expected to remain unmodified and cells depend on a mutant suppressor tRNA derived from tRNA₁^Ile, in which G34 has been changed to U34. An important question, therefore, is how U34 base pairs with A without also base pairing with G. Here, we show (i) that unlike U34 at the wobble position of all B. subtilis tRNAs of known sequence, U34 in the mutant tRNA is not modified, and (ii) that the mutant tRNA binds strongly to the AUA codon on B. subtilis ribosomes but only weakly to AUG. These in vitro data explain why the suppressor strain displays only a low level of misreading AUG codons in vivo and, as shown here, grows at a rate comparable to that of the wild-type strain.     

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.     

Specificity of codon recognition by Escherichia coli tRNALeu isoaccepting species determined by protein synthesis in vitro directed by phage RNA.

Codon-anticodon recognition and transfer RNA utilization for the leucine tRNA isoaccepting species of Escherichia coli have been studied by protein synthesis in vitro directed by sequenced bacteriophage MS2 RNA. We have added radioactive Leu-tRNA^Leu isoaccepting species as tracers, rather than use a tRNA-dependent system, since in the presence of an excess of non-radioactive leucine, there is no transfer of radioactive leucine from one isoaccepting species to another. MS2-specific peptides containing leucine residues encoded by known codons were isolated and identified, and the relative abilities of the Leu-tRNA^Leu isoaccepting species to transfer leucine into these peptides compared. Sequenced tRNA₁^Leu and sequenced tRNA₃^Leu are of roughly equal efficiency in their ability to recognize CUC and CUA codons, while tRNA₃^Leu is highly preferred for the CUU codon; tRNA₄^Leu and tRNA₅^Leu both recognize UUA and UUG codons, with tRNA₄^Leu slightly preferred for the UUA codon. We conclude that: (1) wobble is greater than permitted by the wobble hypothesis; (2) there is still some discrimination in the third code letter, and that the CUX₄ (CUC, CUA, CUU, CUG) portion of the leucine family of six codons is not read by a simple “two out of three” mechanism; (3) a Watson-Crick pair (C · G) between codon and anticodon does not appear to be preferred over an unorthodox pair (C · C) in the wobble position; (4) a standard wobble pair (U · G) between codon and anticodon is preferred over an unorthodox pair (U · C); and (5) the extensive wobble observed in the CUX₄ leucine codon series is not paralleled in the UUX₄ leucine (UUG, UUA) and phenylalanine (UUU, UUC) codon series, where mistranslation would be the consequence of such wobble.     

Selective and stable base pairing by alkynylated nucleosides featuring a spatially-separated recognition interface

Unnatural base pairs (UBPs) which exhibit a selectivity against pairing with canonical nucleobases provide a powerful tool for the development of nucleic acid-based technologies. As an alternative strategy to the conventional UBP designs, which involve utility of different recognition modes at the Watson–Crick interface, we now report that the exclusive base pairing can be achieved through the spatial separation of recognition units. The design concept was demonstrated with the alkynylated purine (^NPu, ^OPu) and pyridazine (^NPz, ^OPz) nucleosides endowed with nucleobase-like 2-aminopyrimidine or 2-pyridone (‘pseudo-nucleobases’) on their major groove side. These alkynylated purines and pyridazines exhibited exclusive and stable pairing properties by the formation of complementary hydrogen bonds between the pseudo-nucleobases in the DNA major groove as revealed by comprehensive T_m measurements, 2D-NMR analyses, and MD simulations. Moreover, the alkynylated purine-pyridazine pairs enabled dramatic stabilization of the DNA duplex upon consecutive incorporation while maintaining a high sequence-specificity. The present study showcases the separation of the recognition interface as a promising strategy for developing new types of UBPs.