Clamping down on weak terminal base pairs: oligonucleotides with molecular caps as fidelity-enhancing elements at the 5'- and 3'-terminal residues

The base-pairing fidelity of oligonucleotides depends on the identity of the nucleobases involved and the position of matched or mismatched base pairs in the duplex. Nucleobases forming weak base pairs, as well as a terminal position favor mispairing. We have searched for 5′-appended acylamido caps that enhance the stability and base-pairing fidelity of oligonucleotides with a 5′-terminal 2′-deoxyadenosine residue using combinatorial synthesis and MALDI-monitored nuclease selections. This provided the residue of 4-(pyren-1-yl)butyric acid as a lead. Lead optimization gave (S)-N-(pyren-1-ylmethyl)pyrrolidine-3-phosphate as a cap that increases duplex stability and base-pairing fidelity. For the duplex of 5′-AGGTTGAC-3′ with its fully complementary target, this cap gives an increase in the UV melting point T_m of +10.9°C. The T_m is 6.3–8.3°C lower when a mismatched nucleobase faces the 5′-terminal dA residue. The optimized cap can be introduced via automated DNA synthesis. It was combined with an anthraquinone carboxylic acid residue as a cap for the 3′-terminal residue. A doubly capped dodecamer thus prepared gives a melting point decrease for double-terminal mismatches that is 5.7–5.9°C greater than that for the unmodified control duplex.     

Thermodynamic stability of base pairs between 2-hydroxyadenine and incoming nucleotides as a determinant of nucleotide incorporation specificity during replication

We investigated the thermodynamic stability of double-stranded DNAs with an oxidative DNA lesion, 2-hydroxyadenine (2-OH-Ade), in two different sequence contexts (5′-GA*C-3′ and 5′-TA*A-3′, A* represents 2-OH-Ade). When an A*–N pair (N, any nucleotide base) was located in the center of a duplex, the thermodynamic stabilities of the duplexes were similar for all the natural bases except A (N = T, C and G). On the other hand, for the duplexes with the A*–N pair at the end, which mimic the nucleotide incorporation step, the stabilities of the duplexes were dependent on their sequence. The order of stability is T > G > C >> A in the 5′-GA*C-3′ sequences and T > A > C > G in the 5′-TA*A-3′ sequences. Because T/G/C and T/A are nucleotides incorporated opposite to 2-OH-Ade in the 5′-GA*C-3′ and 5′-TA*A-3′ sequences, respectively, these results agree with the tendency of mutagenic misincorporation of the nucleotides opposite to 2-OH-Ade in vitro. Thus, the thermodynamic stability of the A*–N base pair may be an important factor for the mutation spectra of 2-OH-Ade.     

Synthesis and monitored selection of nucleotide surrogates for binding T:A base pairs in homopurine-homopyrimidine DNA triple helices

A total of 16 oligodeoxyribonucleotides of general sequence 5′-TCTTCTZTCTTTCT-3′, where Z denotes an N-acyl-N-(2-hydroxyethyl)glycine residue, were prepared via solid phase synthesis. The ability of these oligonucleotides to form triplexes with the duplex 5′-AGAAGATAGAAAGA-HEG-TCTTTCTATCTTCT-3′, where HEG is a hexaethylene glycol linker, was tested. In these triplexes, an ‘interrupting’ T:A base pair faces the Z residue in the third strand. Among the acyl moieties of Z tested, an anthraquinone carboxylic acid residue linked via a glycinyl group gave the most stable triplex, whose UV melting point was 8.4°C higher than that of the triplex with 5′-TCTTCTGTCTTTCT-3′ as the third strand. The results from exploratory nuclease selection experiments suggest that a combinatorial search for strands capable of recognizing mixed sequences by triple helix formation is feasible.     

Artificially expanded genetic information system: a new base pair with an alternative hydrogen bonding pattern

To support efforts to develop a ‘synthetic biology’ based on an artificially expanded genetic information system (AEGIS), we have developed a route to two components of a non-standard nucleobase pair, the pyrimidine analog 6-amino-5-nitro-3-(1′-β-D-2′-deoxyribofuranosyl)-2(1H)-pyridone (dZ) and its Watson–Crick complement, the purine analog 2-amino-8-(1′-β-D-2′-deoxyribofuranosyl)-imidazo[1,2-a]-1,3,5-triazin-4(8H)-one (dP). These implement the pyDDA:puAAD hydrogen bonding pattern (where ‘py’ indicates a pyrimidine analog and ‘pu’ indicates a purine analog, while A and D indicate the hydrogen bonding patterns of acceptor and donor groups presented to the complementary nucleobases, from the major to the minor groove). Also described is the synthesis of the triphosphates and protected phosphoramidites of these two nucleosides. We also describe the use of the protected phosphoramidites to synthesize DNA oligonucleotides containing these AEGIS components, verify the absence of epimerization of dZ in those oligonucleotides, and report some hybridization properties of the dZ:dP nucleobase pair, which is rather strong, and the ability of each to effectively discriminate against mismatches in short duplex DNA.     

Aminonucleosides and their derivatives. IVI Synthesis of the 3′-amino-3′-deoxynucleoside 5′-phosphates

A new procedure has been developed for the synthesis of 3′-amino-3′-deoxyribonucleosides of adenine, cytosine and uracil by condensing the trimethylsilylated bases with peracylated 3-azido-3-deoxyribose derivative. The azido group could subsequently be reduced to amino. The 5′-phosphates of these nucleosides have been prepared and the analogues have been tested for their ability to stimulate the ribosome-catalyzed reaction of 3′(2′)-O-(N-formylmethionyl)adenosine 5′-phosphate with phenylalanyl-tRNA.     

The 3′–5′ proofreading exonuclease of archaeal family-B DNA polymerase hinders the copying of template strand deaminated bases

Archaeal family B polymerases bind tightly to the deaminated bases uracil and hypoxanthine in single-stranded DNA, stalling replication on encountering these pro-mutagenic deoxynucleosides four steps ahead of the primer–template junction. When uracil is specifically bound, the polymerase–DNA complex exists in the editing rather than the polymerization conformation, despite the duplex region of the primer-template being perfectly base-paired. In this article, the interplay between the 3′–5′ proofreading exonuclease activity and binding of uracil/hypoxanthine is addressed, using the family-B DNA polymerase from Pyrococcus furiosus. When uracil/hypoxanthine is bound four bases ahead of the primer–template junction (+4 position), both the polymerase and the exonuclease are inhibited, profoundly for the polymerase activity. However, if the polymerase approaches closer to the deaminated bases, locating it at +3, +2, +1 or even 0 (paired with the extreme 3′ base in the primer), the exonuclease activity is strongly stimulated. In these situations, the exonuclease activity is actually stronger than that seen with mismatched primer-templates, even though the deaminated base-containing primer-templates are correctly base-paired. The resulting exonucleolytic degradation of the primer serves to move the uracil/hypoxanthine away from the primer–template junction, restoring the stalling position to +4. Thus the 3′–5′ proofreading exonuclease contributes to the inability of the polymerase to replicate beyond deaminated bases.     

DNA strand transfer catalyzed by vaccinia topoisomerase: ligation of DNAs containing a 3' mononucleotide overhang

The specificity of vaccinia topoisomerase for transesterification to DNA at the sequence 5′-CCCTT and its versatility in strand transfer have illuminated the recombinogenic properties of type IB topoisomerases and spawned topoisomerase-based strategies for DNA cloning. Here we characterize a pathway of topoisomerase-mediated DNA ligation in which enzyme bound covalently to a CCCTT end with an unpaired +1T nucleotide rapidly and efficiently joins the CCCTT strand to a duplex DNA containing a 3′ A overhang. The joining reaction occurs with high efficiency, albeit slowly, to duplex DNAs containing 3′ G, T or C overhangs. Strand transfer can be restricted to the correctly paired 3′ A overhang by including 0.5 M NaCl in the ligation reaction mixture. The effects of base mismatches and increased ionic strength on the rates of 3′ overhang ligation provide a quantitative picture of the relative contributions of +1 T:A base pairing and electrostatic interactions downstream of the scissile phosphate to the productive binding of an unlinked acceptor DNA to the active site. The results clarify the biochemistry underlying topoisomerase-cloning of PCR products with non-templated 3′ overhangs.     

Propynyl groups in duplex DNA: stability of base pairs incorporating 7-substituted 8-aza-7-deazapurines or 5-substituted pyrimidines

Oligonucleotides incorporating the 7-propynyl derivatives of 8-aza-7-deaza-2′-deoxyguanosine (3b) and 8-aza-7-deaza-2′-deoxyadenosine (4b) were synthesized and their duplex stability was compared with those containing the 5-propynyl derivatives of 2′-deoxycytidine (1) and 2′-deoxyuridine (2). For this purpose phosphoramidites of the 8-aza- 7-deazapurine (pyrazolo[3,4-d]pyrimidine) nucleosides were prepared and employed in solid-phase synthesis. All propynyl nucleosides exert a positive effect on the DNA duplex stability because of the increased polarizability of the nucleobase and the hydrophobic character of the propynyl group. The propynyl residues introduced into the 7-position of the 8-aza-7-deazapurines are generally more stabilizing than those at the 5-position of the pyrimidine bases. The duplex stabilization of the propynyl derivative 4b was higher than for the bromo nucleoside 4c. The extraordinary stability of duplexes containing the 7-propynyl derivative of 8-aza-7- deazapurin-2,6-diamine (5b) is attributed to the formation of a third hydrogen bond, which is apparently not present in the base pair of the purin-2,6-diamine 2′-deoxyribonucleoside with dT.     

Effects of Defined Mutations in the 5′ Nontranslated Region of Rubella Virus Genomic RNA on Virus Viability and Macromolecule Synthesis

The 5′ end of the genomic RNA of rubella virus (RUB) contains a 14-nucleotide (nt) single-stranded leader (ss-leader) followed by a stem-and-loop structure [5′(+)SL] (nt 15 to 65), the complement of which at the 3′ end of the minus-strand RNA [3′(−)SL] has been proposed to function as a promoter for synthesis of genomic plus strands. A second intriguing feature of the 5′ end of the RUB genomic RNA is the presence of a short (17 codons) open reading frame (ORF) located between nt 3 and 54; the ORF encoding the viral nonstructural proteins (NSPs) initiates at nt 41 in an alternate translational frame. To address the functional significance of these features, we compared the 5′-terminal sequences of six different strains of RUB, with the result that the short ORF is preserved (although the coding sequence is not conserved) as is the stem part of both the 5′(+)SL and 3′(−)SL, while the upper loop part of both structures varies. Next, using Robo302, an infectious cDNA clone of RUB, we introduced 31 different mutations into the 5′-terminal noncoding region, and their effects on virus replication and macromolecular synthesis were examined. This mutagenesis revealed that the short ORF is not essential for virus replication. The AA dinucleotide at nt 2 and 3 is of critical importance since point mutations and deletions that altered or removed both of these nucleotides were lethal. None of the other mutations within either the ss-leader or the 5′(+)SL [and accordingly within the 3′(−)SL], including deletions of up to 15 nt from the 5′(+)SL and three different multiple-point mutations that lead to destabilization of the 5′(+)SL, were lethal. Some of the mutations within both ss-leader and the 5′(+)SL resulted in viruses that grew to lower titers than the wild-type virus and formed opaque and/or small plaques; in general mutations within the stem had a more profound effect on viral phenotype than did mutations in either the ss-leader or upper loop. Mutations in the 5′(+)SL, but not in the ss-leader, resulted in a significant reduction in NSP synthesis, indicating that this structure is important for efficient translation of the NSP ORF. In contrast, viral plus-strand RNA synthesis was unaffected by the 5′(+)SL mutations as well as the ss-leader mutations, which argues against the proposed function of the 3′(−)SL as a promoter for initiation of the genomic plus-strand RNA.     

The Methanothermobacter thermautotrophicus ExoIII homologue Mth212 is a DNA uridine endonuclease

The genome of Methanothermobacter thermautotrophicus, as a hitherto unique case, is apparently devoid of genes coding for general uracil DNA glycosylases, the universal mediators of base excision repair following hydrolytic deamination of DNA cytosine residues. We have now identified protein Mth212, a member of the ExoIII family of nucleases, as a possible initiator of DNA uracil repair in this organism. This enzyme, in addition to bearing all the enzymological hallmarks of an ExoIII homologue, is a DNA uridine endonuclease (U-endo) that nicks double-stranded DNA at the 5′-side of a 2′-d-uridine residue, irrespective of the nature of the opposing nucleotide. This type of activity has not been described before; it is absent from the ExoIII homologues of Escherichia coli, Homo sapiens and Methanosarcina mazei, all of which are equipped with uracil DNA repair glycosylases. The U-endo activity of Mth212 is served by the same catalytic center as its AP-endo activity.     

Electron attachment to DNA single strands: gas phase and aqueous solution

The 2′-deoxyguanosine-3′,5′-diphosphate, 2′-deoxyadenosine-3′,5′-diphosphate, 2′-deoxycytidine-3′,5′-diphosphate and 2′-deoxythymidine-3′,5′-diphosphate systems are the smallest units of a DNA single strand. Exploring these comprehensive subunits with reliable density functional methods enables one to approach reasonable predictions of the properties of DNA single strands. With these models, DNA single strands are found to have a strong tendency to capture low-energy electrons. The vertical attachment energies (VEAs) predicted for 3′,5′-dTDP (0.17 eV) and 3′,5′-dGDP (0.14 eV) indicate that both the thymine-rich and the guanine-rich DNA single strands have the ability to capture electrons. The adiabatic electron affinities (AEAs) of the nucleotides considered here range from 0.22 to 0.52 eV and follow the order 3′,5′-dTDP > 3′,5′-dCDP > 3′,5′-dGDP > 3′,5′-dADP. A substantial increase in the AEA is observed compared to that of the corresponding nucleic acid bases and the corresponding nucleosides. Furthermore, aqueous solution simulations dramatically increase the electron attracting properties of the DNA single strands. The present investigation illustrates that in the gas phase, the excess electron is situated both on the nucleobase and on the phosphate moiety for DNA single strands. However, the distribution of the extra negative charge is uneven. The attached electron favors the base moiety for the pyrimidine, while it prefers the 3′-phosphate subunit for the purine DNA single strands. In contrast, the attached electron is tightly bound to the base fragment for the cytidine, thymidine and adenosine nucleotides, while it almost exclusively resides in the vicinity of the 3′-phosphate group for the guanosine nucleotides due to the solvent effects. The comparatively low vertical detachment energies (VDEs) predicted for 3′,5′-dADP⁻ (0.26 eV) and 3′,5′-dGDP⁻ (0.32 eV) indicate that electron detachment might compete with reactions having high activation barriers such as glycosidic bond breakage. However, the radical anions of the pyrimidine nucleotides with high VDE are expected to be electronically stable. Thus the base-centered radical anions of the pyrimidine nucleotides might be the possible intermediates for DNA single-strand breakage.     

Locating the uracil-5-yl radical formed upon photoirradiation of 5-bromouracil-substituted DNA

In a previous study, we found that 2-deoxyribonolactone is effectively generated in the specific 5-bromouracil (^BrU)-substituted sequence 5′-(G/C)[A]_{n = 1,2}^BrU^BrU-3′ and proposed that a formed uracil-5-yl radical mainly abstracts the C1′ hydrogen from the 5′-side of ^BrU^BrU under 302-nm irradiation condition. In the present work, we performed photoirradiation of ^BrU-substituted DNA in the presence of a hydrogen donor, tetrahydrofuran, to quench the uracil-5-yl radical to uracil and then subjected the sample to uracil DNA glycosylase digestion. Slab gel sequence analysis indicated that uracil residues were formed at the hot-spot sequence of 5′-(G/C)[A]_{n = 1,2}^BrU^BrU-3′ in 302-nm irradiation of ^BrU-substituted DNA. Furthermore, we found that the uracil residue was also formed at the reverse sequence 5′-^BrU^BrU[A]_{n = 1,2}(G/C)-3′, which suggests that both 5′-(G/C)[A]_{n = 1,2}^BrU^BrU-3′ and 5′-^BrU^BrU[A]_{n = 1,2}(G/C)-3′ are hot-spot sequences for the formation of the uracil-5-yl radical.     

Mechanistic decoupling of exonuclease III multifunctionality into AP endonuclease and exonuclease activities at the single-residue level

Bacterial exonuclease III (ExoIII) is a multifunctional enzyme that uses a single active site to perform two conspicuous activities: (i) apurinic/apyrimidinic (AP)-endonuclease and (ii) 3′→5′ exonuclease activities. The AP endonuclease activity results in AP site incision, while the exonuclease activity results in the continuous excision of 3′ terminal nucleobases to generate a partial duplex for recruiting the downstream DNA polymerase during the base excision repair process (BER). The key determinants of functional selection between the two activities are poorly understood. Here, we use a series of mutational analyses and single-molecule imaging to unravel the pivotal rules governing these endo- and exonuclease activities at the single amino acid level. An aromatic residue, either W212 or F213, recognizes AP sites to allow for the AP endonuclease activity, and the F213 residue also participates in the stabilization of the melted state of the 3′ terminal nucleobases, leading to the catalytically competent state that activates the 3′→5′ exonuclease activity. During exonucleolytic cleavage, the DNA substrate must be maintained as a B-form helix through a series of phosphate-stabilizing residues (R90, Y109, K121 and N153). Our work decouples the AP endonuclease and exonuclease activities of ExoIII and provides insights into how this multifunctional enzyme controls each function at the amino acid level.     

Synthesis and polymerase incorporation of 5'-amino-2',5'-dideoxy-5'-N-triphosphate nucleotides

Owing to the markedly increased reactivity of amino functional groups versus hydroxyls, the 5′-amino-5′-deoxy nucleoside and nucleotide analogs have proven widely useful in biological, pharmaceutical and genomic applications. However, synthetic procedures leading to these analogs have not been fully explored, which may possibly have limited the scope of their utility. Here we describe the synthesis of the 5′-amino-2′,5′-dideoxy analogs of adenosine, cytidine, guanosine, inosine and uridine from their respective naturally occurring nucleosides via the reduction of 5′-azido-2′,5′-dideoxy intermediates using the Staudinger reaction, and the high yield conversion of these modified nucleosides and 5′-amino-5′-deoxythymidine to the corresponding 5′-N-triphosphates through reaction with trisodium trimetaphosphate in the presence of tris(hydroxymethyl)aminomethane (Tris). We also show that each of these nucleotide analogs can be efficiently incorporated into DNA by the Klenow fragment of Escherichia coli DNA polymerase I when individually substituted for its naturally occurring counterpart. Mild acid treatment of the resulting DNA generates polynucleotide fragments that arise from specific cleavage at each modified nucleotide, providing a sequence ladder for each base. Because the ladders are generated after the extension, the corresponding products may be manipulated by enzymatic and/or purification processes. The potential utility of this extension–cleavage procedure in genomic sequence analysis is discussed.     

Enzymatic processing of replication and recombination intermediates by the vaccinia virus DNA polymerase

Poxvirus DNA polymerases play a critical role in promoting virus recombination. To test if vaccinia polymerase (E9L) could mediate this effect by catalyzing the post-synaptic processing of recombinant joint molecules, we prepared substrates bearing a nick, a 3′-unpaired overhang, a 5′ overhang, or both 3′ and 5′ overhangs. The sequence of the 5′ overhang was also modified to permit or preclude branch migration across the joint site. These substrates were incubated with E9L, and the fate of the primer strand characterized under steady-state reaction conditions. E9L rapidly excises a mispaired 3′ strand from a DNA duplex, producing a meta-stable nicked molecule that is a substrate for ligase. The reaction was not greatly affected by adding an unpaired 5′ strand, but since such molecules cannot be processed into nicked intermediates, the 3′-ended strand continued to be subjected to exonucleolytic attack. Incorporating homology into the 5′ overhang prevented this and permitted some strand assimilation, but such substrates also promoted strand-displacement DNA synthesis of a type predicted by the 1981 Moyer and Graves model for poxvirus replication. Single-strand annealing reactions are used by poxviruses to produce recombinant viruses and these data show that virus DNA polymerases can process DNA in such a manner as to both generate single-stranded substrates for such reactions and to facilitate the final processing of the reaction products.     

Crystal structure of trioxacarcin A covalently bound to DNA

We report a crystal structure that shows an antibiotic that extracts a nucleobase from a DNA molecule ‘caught in the act’ after forming a covalent bond but before departing with the base. The structure of trioxacarcin A covalently bound to double-stranded d(AACCGGTT) was determined to 1.78 Å resolution by MAD phasing employing brominated oligonucleotides. The DNA–drug complex has a unique structure that combines alkylation (at the N7 position of a guanine), intercalation (on the 3′-side of the alkylated guanine), and base flip-out. An antibiotic-induced flipping-out of a single, nonterminal nucleobase from a DNA duplex was observed for the first time in a crystal structure.     

Solution structure of a modified 2',5'-linked RNA hairpin involved in an equilibrium with duplex

The isomerization of phosphodiester functionality of nucleic acids from 3′,5′- to a less common 2′,5′-linkage influences the complex interplay of stereoelectronic effects that drive pseudorotational equilibrium of sugar rings and thus affect the conformational propensities for compact or more extended structures. The present study highlights the subtle balance of non-covalent forces at play in structural equilibrium of 2′,5′-linked RNA analogue, 3′-O-(2-methoxyethyl) substituted dodecamer *CG*CGAA*U*U*CG*CG, 3′-MOE-2′,5′-RNA, where all cytosines and uracils are methylated at C5. The NMR and UV spectroscopic studies have shown that 3′-MOE-2′,5′-RNA adopts both hairpin and duplex secondary structures, which are involved in a dynamic exchange that is slow on the NMR timescale and exhibits strand and salt concentration as well as pH dependence. Unusual effect of pH over a narrow physiological range is observed for imino proton resonances with exchange broadening observed at lower pH and relatively sharp lines observed at higher pH. The solution structure of 3′-MOE-2′,5′-RNA hairpin displays a unique and well-defined loop, which is stabilized by Watson–Crick A5·*U8 base pair and by n → π* stacking interactions of O4′ lone-pair electrons of A6 and *U8 with aromatic rings of A5 and *U7, respectively. In contrast, the stem region of 3′-MOE-2′,5′-RNA hairpin is more flexible. Our data highlight the important feature of backbone modifications that can have pronounced effects on interstrand association of nucleic acids.     

Genome-wide prediction of stop codon readthrough during translation in the yeast Saccharomyces cerevisiae

In-frame stop codons normally signal termination during mRNA translation, but they can be read as ‘sense’ (readthrough) depending on their context, comprising the 6 nt preceding and following the stop codon. To identify novel contexts directing readthrough, under-represented 5′ and 3′ stop codon contexts from Saccharomyces cerevisiae were identified by genome-wide survey in silico. In contrast with the nucleotide bias 3′ of the stop codon, codon bias in the two codon positions 5′ of the termination codon showed no correlation with known effects on stop codon readthrough. However, individually, poor 5′ and 3′ context elements were equally as effective in promoting stop codon readthrough in vivo, readthrough which in both cases responded identically to changes in release factor concentration. A novel method analysing specific nucleotide combinations in the 3′ context region revealed positions +1,2,3,5 and +1,2,3,6 after the stop codon were most predictive of termination efficiency. Downstream of yeast open reading frames (ORFs), further in-frame stop codons were significantly over-represented at the +1, +2 and +3 codon positions after the ORF, acting to limit readthrough. Thus selection against stop codon readthrough is a dominant force acting on 3′, but not on 5′, nucleotides, with detectable selection on nucleotides as far downstream as +6 nucleotides. The approaches described can be employed to define potential readthrough contexts for any genome.     

Solution structure of the apical stem-loop of the human hepatitis B virus encapsidation signal

Hepatitis B virus (HBV) replication is initiated by HBV RT binding to the highly conserved encapsidation signal, epsilon, at the 5′ end of the RNA pregenome. Epsilon contains an apical stem–loop, whose residues are either totally conserved or show rare non-disruptive mutations. Here we present the structure of the apical stem–loop based on NOE, RDC and ¹H chemical shift NMR data. The ¹H chemical shifts proved to be crucial to define the loop conformation. The loop sequence 5′-CUGUGC-3′ folds into a UGU triloop with a CG closing base pair and a bulged out C and hence forms a pseudo-triloop, a proposed protein recognition motif. In the UGU loop conformations most consistent with experimental data, the guanine nucleobase is located on the minor groove face and the two uracil bases on the major groove face. The underlying helix is disrupted by a conserved non-paired U bulge. This U bulge adopts multiple conformations, with the nucleobase being located either in the major groove or partially intercalated in the helix from the minor groove side, and bends the helical stem. The pseudo-triloop motif, together with the U bulge, may represent important anchor points for the initial recognition of epsilon by the viral RT.