C5-functionalized DNA, LNA, and α-L-LNA: positional control of polarity-sensitive fluorophores leads to improved SNP-typing

Single nucleotide polymorphisms (SNPs) are important markers in disease genetics and pharmacogenomic studies. Oligodeoxyribonucleotides (ONs) modified with 5-[3-(1-pyrenecarboxamido)propynyl]-2'-deoxyuridine monomer X enable detection of SNPs at non-stringent conditions due to differential fluorescence emission of matched versus mismatched nucleic acid duplexes. Herein, the thermal denaturation and optical spectroscopic characteristics of monomer X are compared to the corresponding locked nucleic acid (LNA) and α-L-LNA monomers Y and Z. ONs modified with monomers Y or Z result in a) larger increases in fluorescence intensity upon hybridization to complementary DNA, b) formation of more brightly fluorescent duplexes due to markedly larger fluorescence emission quantum yields (Φ(F)=0.44-0.80) and pyrene extinction coefficients, and c) improved optical discrimination of SNPs in DNA targets. Optical spectroscopy studies suggest that the nucleobase moieties of monomers X-Z adopt anti and syn conformations upon hybridization with matched and mismatched targets, respectively. The polarity-sensitive 1-pyrenecarboxamido fluorophore is, thereby, either positioned in the polar major groove or in the hydrophobic duplex core close to quenching nucleobases. Calculations suggest that the bicyclic skeletons of LNA and α-L-LNA monomers Y and Z influence the glycosidic torsional angle profile leading to altered positional control and photophysical properties of the C5-fluorophore.     

3'-C-Branched LNA-type nucleosides locked in an N-type furanose ring conformation: synthesis, incorporation into oligodeoxynucleotides, and hybridization studies

Three protected 3'-C-branched LNA-type phosphoramidite building blocks 17, 27, and 38, containing furanose rings locked in an N-type conformation, were synthesized from a known 3-C-allyl allofuranose derivative using strategies relying on the introduction of the branching alkyl chain before condensation with the nucleobase. Synthesis of 3'-C-hydroxypropyl derivatives proved superior to synthesis of the 3'-C-hydroxyethyl derivatives, and the former was converted into the corresponding 3'-C-aminopropyl derivatives. Phosphoramidites 27 and 38 were subsequently applied on an automated DNA synthesizer leading to the introduction of three novel 3'-C-branched LNA-type monomers X, Y, and Z into oligodeoxynucleotides and studies of their effect on the hybridization properties. A duplex-stabilizing effect of introducing 3'-C-aminopropyl-LNA monomer Y, relative to 3'-C-hydroxypropyl-LNA monomer X, was observed, especially at low salt conditions. This indicates that the primary amino group of monomer Y is protonated under the hybridization conditions applied and that positioning of this positively charged group in the major groove has a significant duplex stabilizing effect. Monomer Y was by an on-column conjugation method further functionalized by a glycyl unit to give monomer Z that showed a less stabilizing effect than monomer Y.     

Influence of the Type of Junction in DNA-3′-Peptide Nucleic Acid (PNA) Chimeras on Their Binding Affinity to DNA and RNA

The automated on-line synthesis of DNA-3′-PNA (PNA=Polyamide Nucleic Acids) chimeras 1 – 3 is described, in which the 3′-terminal part of the oligonucleotide is linked to the aminoterminal part of the PNA either via a N-(2-mercaptoethyl)- (X=S), a N-(2-hydroxyethyl)- (X=O), or a N-(2-aminoethyl)- (X=NH) N-[(thymin-1-yl)acetyl]glycine unit. Furthermore, the DNA-3′-PNA chimera 4 without a nucleobase at the linking unit was prepared. The binding affinities of all chimeras were directly compared by determining their T_m values in the duplex with complementary DNA, RNA, or DNA containing a mismatch or abasic site opposite to the linker unit. We found that all investigated chimeras with a nucleobase at the junction form more stable duplexes with complementary DNA and RNA than the corresponding unmodified DNA. The influence of X on duplex stabilization was determined to be in the order O>S≈NH, rendering the phosphodiester bridge the most favored linkage at the DNA/PNA junction. The observed strong duplex-destabilizing effects, when base mismatches or non-basic sites were introduced opposite to the nucleobase at the DNA/PNA junction, suggest that the base at the linking unit contributes significantly to duplex stabilization.     

DNA-binding small-ligand-immobilized surface plasmon resonance biosensor for detecting thymine-related single-nucleotide polymorphisms

A surface plasmon resonance (SPR) biosensor that carries DNA-binding small ligands has been developed for the detection of single-nucleotide polymorphisms (SNPs). 3,5-Diaminopyrazine derivatives, with a hydrogen-bonding profile fully complementary to the thymine base, were utilized as recognition elements on the sensor surface, and a target single-stranded DNA sequence was hybridized with a DNA probe containing an abasic site to place this site opposite a nucleobase to be detected. In a continuous flow of sample solutions buffered to pH 6.4 (0.25 M NaCl), the 3,5-diaminopyrazine-based SPR sensor can detect an orphan nucleobase in the duplex with a clear selectivity for thymine over cytosine, guanine, and adenine (5'-GTT GGA GCT GXG GGC GTA GGC-3'/3'-CAA CCT CGA CNC CCG CAT CCG-5'; X=abasic site, N=target nucleobase G, C, A, or T). The SPR response was linear in the concentration range 10-100 nM. Allele discrimination is possible based on the combination of different binding surfaces in a flow cell of the SPR system, which is demonstrated for the analysis of the thymine/cytosine mutation present in 63-meric polymerase chain reaction (PCR) amplification products (Ha-ras gene, codon 12, antisense strand). Comparison with a bulk assay based on 3,5-diaminopyrazine/DNA binding shows that the immobilization of 3,5-diaminopyrazine derivatives on the SPR sensor allows more sensitive detection of the target DNA sequence, and binding selectivity can be tuned by controlling the salt concentration of sample solutions. These features of the DNA-binding small-molecule-immobilized SPR sensor are discussed as a basis for the design of SPR biosensors for SNP genotyping.     

Locked nucleic acid (LNA) recognition of RNA: NMR solution structures of LNA:RNA hybrids

Locked nucleic acids (LNAs) containing one or more 2'-O,4'-C-methylene-linked bicyclic ribonucleoside monomers possess a number of the prerequisites of an effective antisense oligonucleotide, e.g. unprecedented helical thermostability when hybridized with cognate RNA and DNA. To acquire a detailed understanding of the structural features of LNA giving rise to its remarkable properties, we have conducted structural studies by use of NMR spectroscopy and now report high-resolution structures of two LNA:RNA hybrids, the LNA strands being d(5'-CTGAT(L)ATGC-3') and d(5'-CT(L)GAT(L)AT(L)GC-3'), respectively, T(L) denoting a modified LNA monomer with a thymine base, along with the unmodified DNA:RNA hybrid. In the structures, the LNA nucleotides are positioned as to partake in base stacking and Watson-Crick base pairing, and with the inclusion of LNA nucleotides, we observe a progressive change in duplex geometry toward an A-like duplex structure. As such, with the inclusion of three LNA nucleotides, the hybrid adopts an almost canonical A-type duplex geometry, and thus it appears that the number of modifications has reached a saturation level with respect to structural changes, and that further incorporations would furnish only minute changes in the duplex structure. We attempt to rationalize the conformational steering induced by the LNA nucleotides by suggesting that the change in electronic density at the brim of the minor groove, introduced by the LNA modification, is causing an alteration of the pseudorotational profile of the 3'-flanking nucleotide, thus shifting this sugar equilibrium toward N-type conformation.     

Fluorescence and electrochemical detection of pyrimidine/purine transversion by a ferrocenyl aminonaphthyridine derivative

A novel hydrogen bond-forming ligand for pyrimidine/purine transversion, which contains both a fluorescent naphthyridine moiety and a ferrocenyl group as an electrochemical indicator, is described. Hydrogen bond-mediated recognition for a target nucleobase at an abasic site in a DNA duplex is confirmed by both fluorescence and electrochemical measurements. The analysis by fluorescence titration reveals that the ligand shows significant fluorescent quenching upon formation of a 1 : 1 complex with the target nucleobase opposite the abasic site, and the selectivity is in the order of cytosine > thymine > adenine, guanine, reflecting the stability of the hydrogen bond formation.     

Structural studies of LNA:RNA duplexes by NMR: conformations and implications for RNase H activity

We have used NMR and CD spectroscopy to study the conformations of modified oligonucleotides (locked nucleic acid, LNA) containing a conformationally restricted nucleotide (T(L)) with a 2'-O,4'-C-methylene bridge. We have investigated two LNA:RNA duplexes, d(CTGAT(L)ATGC):r(GCAUAUCAG) and d(CT(L)GAT(L)AT(L)GC):r(GCAUAUCAG), along with the unmodified DNA:RNA reference duplex. Increases in the melting temperatures of +9.6 degrees C and +8.1 degrees C per modification relative to the unmodified duplex were observed for these two LNA:RNA sequences. The three duplexes all adopt right-handed helix conformations and form normal Watson-Crick base pairs with all the bases in the anti conformation. Sugar conformations were determined from measurements of scalar coupling constants in the sugar rings and distance information derived from 1H-1H NOE measurements; all the sugars in the RNA strands of the three duplexes adopt an N-type conformation (A-type structure), whereas the sugars in the DNA strands change from an equilibrium between S- and N-type conformations in the unmodified duplex towards more of the N-type conformation when modified nucleotides are introduced. The presence of three modified T(L) nucleotides induces drastic conformational shifts of the remaining unmodified nucleotides of the DNA strand, changing all the sugar conformations except those of the terminal sugars to the N type. The CD spectra of the three duplexes confirm the structural changes described above. On the basis of the results reported herein, we suggest that the observed conformational changes can be used to tune LNA:RNA duplexes into substrates for RNase H: Partly modified LNA:RNA duplexes may adopt a duplex structure between the standard A and B types, thereby making the RNA strand amenable to RNase H-mediated degradation.     

C2'-pyrene-functionalized triazole-linked DNA: universal DNA/RNA hybridization probes

Development of universal hybridization probes, that is, oligonucleotides displaying identical affinity toward matched and mismatched DNA/RNA targets, has been a longstanding goal due to potential applications as degenerate PCR primers and microarray probes. The classic approach toward this end has been the use of "universal bases" that either are based on hydrogen-bonding purine derivatives or aromatic base analogues without hydrogen-bonding capabilities. However, development of probes that result in truly universal hybridization without compromising duplex thermostability has proven challenging. Here we have used the "click reaction" to synthesize four C2'-pyrene-functionalized triazole-linked 2'-deoxyuridine phosphoramidites. We demonstrate that oligodeoxyribonucleotides modified with the corresponding monomers display (a) minimally decreased thermal affinity toward DNA/RNA complements relative to reference strands, (b) highly robust universal hybridization characteristics (average differences in thermal denaturation temperatures of matched vs mismatched duplexes involving monomer W are <1.7 °C), and (c) exceptional affinity toward DNA targets containing abasic sites opposite of the modification site (ΔT(m) up to +25 °C). The latter observation, along with results from absorption and fluorescence spectroscopy, suggests that the pyrene moiety is intercalating into the duplex whereby the opposing nucleotide is pushed into an extrahelical position. These properties render C2'-pyrene-functionalized triazole-linked DNA as promising universal hybridization probes for applications in nucleic acid chemistry and biotechnology.     

Conformationally controlled high-affinity targeting of RNA or DNA by novel 2'-amino-DNA/LNA mixmers and pyrenyl-functionalized 2'-amino-DNA

9-Mer DNA sequences containing 2'-N-methyl-2'-N-(pyren-1-ylmethyl)-2'-amino-DNA monomers display significantly increased affinity towards DNA complements whereas the corresponding 2'-amino-DNA monomer has a detrimental effect on duplex stability. These effects are efficiently reversed by incorporation of four LNA nucleotides inducing a B-DNA to A-DNA conformational change.     

Synthesis and properties of 5-cyano-substituted nucleoside analog with a donor-donor-acceptor hydrogen-bonding pattern

6-Aminopyridin-2-ones form Watson-Crick pairs with complementary purine analogues to add a third nucleobase pair to DNA and RNA, if an electron-withdrawing group at position 5 slows oxidation and epimerization. In previous work with a nucleoside analogue trivially named dZ, the electron withdrawing unit was a nitro group. Here, we describe an analogue of dZ (cyano-dZ) having a cyano group instead of a nitro group, including its synthesis, pK(a), rates of acid-catalyzed epimerization, and enzymatic incorporation.     

Nucleic acid structural engineering using pyrene-functionalized 2'-amino-alpha-L-LNA monomers and abasic sites

Oligonucleotides (ONs) modified with a 2'-N-(pyren-1-yl)acetyl-2'-amino-alpha-L-LNA thymine monomer Y flanked on the 3'-side by an abasic site Phi (i.e., YPhi-unit) exhibit unprecedented increases in thermal affinity (DeltaT(m) values) toward target strands containing abasic sites (DeltaT(m) per YPhi unit >+33.0 degrees C in 9-mer duplexes relative to unmodified ONs). Biophysical studies along with force field calculations suggest that the conformationally locked 2-oxo-5-azabicyclo[2.2.1]heptane skeleton of monomer Y, in concert with the short rigid acetyl linker, efficiently forces the thymine and pyrene moieties to adopt an interplanar distance of approximately 3.4 A. This precisely positions the pyrene moiety in the duplex core void formed by abasic sites (Phi:Phi pair) for optimal pi-pi overlap. Duplexes with multiple YPhi: APhi units separated by one base pair are tolerated extraordinarily well, as exemplified by a 13-mer duplex containing four separated YPhi: APhi units (8 abasic sites distributed over 13 "base pairs"), which exhibit a thermal denaturation temperature of 60.5 degrees C. The YPhi probes display up to 16-fold increases in fluorescence intensity at 380 nm upon hybridization with abasic target strands, whereby self-assembly of these complex architectures can be easily monitored. This study underlines the potential of N2'-functionalized 2'-amino-alpha-L-LNA as building blocks in nucleic acid based diagnostics and nanomaterial engineering.     

Efficient Discrimination of Single Nucleotide Polymorphisms (SNPs) Using Oligonucleotides Modified with C5‐Pyrene‐Functionalized DNA and Flanking Locked Nucleic Acid (LNA) Monomers

Oligodeoxyribonucleotides modified with 5‐[3‐(1‐pyrenecarboxamido)propynyl]‐2′‐deoxyuridine monomer X and proximal LNA monomers display higher affinity for complementary DNA, more pronounced increases in fluorescence emission upon DNA binding, and improved discrimination of SNPs at non‐stringent conditions, relative to the corresponding LNA‐free probes across a range of sequence contexts. The results reported herein suggest that the introduction of LNA monomers influences the position of nearby fluorophores via indirect conformational restriction, a characteristic that can be utilized to develop optimized fluorophore‐labeled probes for SNP‐discrimination studies.     

DNA-duplexes containing abasic sites: correlation between thermostability and acoustic wave properties

Aldehydic apurinic or apyrimidinic sites that lack a nucleobase moiety are one of the most common forms of toxic lesions in DNA. In the present study, a close structural analog of such a site, the 2-(hydroxymethyl) tetrahydrofuranyl residue, was synthesized in order to act as a model for damaged nucleic acid probes. Prepared oligodeoxyribonucleotides containing one, two or three abasic sites were hybridized to complementary sequences immobilized on a gold surface using the neutravidin-biotin interaction for study by thickness shear mode acoustic wave detector. Measurement of the complex electrical impedance of an AT-cut quartz device with immobilized biotinylated nucleotide allowed the detection of changes of series resonance frequency, Deltafs, and motional resistance, Rm, associated with duplex formation. The changes as detected by the acoustic wave method correlated well with the thermostability of DNA duplexes in solution. With respect to the latter, UV-monitored melting curves indicate that both the number of sites and their localization in the double-stranded structure influence the amount by which a 19 b.p. duplex is destabilized. The presence of 3 abasic sites completely destabilized the DNA duplex.     

Determination of affinity constants of locked nucleic acid (LNA) and DNA duplex formation using label free sensor technology

Locked nucleic acid (LNA) is a nucleic acid analogue containing 2'-O,4'-C-methylene-beta-D-ribofuranosyl nucleotides, which have a bicyclic furanose unit locked in a RNA mimicking sugar conformation. Oligonucleotides containing LNA monomers show an enhanced thermal stability and robustness against nuclease mediated cleavage. Therefore special tailored LNA is a versatile tool for gene array analysis and single nucleotide polymorphism (SNP) analysis. The higher melting temperatures result from a higher affinity between the LNA and its complementary base. This was verified by the determination of the affinity constants of the duplex formation of 3 oligonucleotides: DNA, L-DNA, in which all thymidines are substituted by LNA, and a fully modified LNA, to their complementary DNA strand. Affinity constants were calculated to be 1.5 x 10(9), 4.0 x 10(9) and >10(12) L mol(-1). This was done using the label free and time resolved sensing technology reflectometric interference spectroscopy (RIfS), in an assay format similar to a titration called binding inhibition assay.     

Synthesis and properties of trans-3',4'-bridged nucleic acids having typical S-type sugar conformation

The synthesis of nucleoside analogues with a conformationally restricted sugar moiety is of great interest. The present research describes the synthesis of BNA (bridged nucleic acid) monomers 1 and 2 bearing a 4,7-dioxabicyclo[4.3.0]nonane skeleton and a methoxy group at the C2' position. Conformational analysis showed that the sugar moiety of these monomers is restricted in a typical S-type conformation. It was difficult to synthesize the phosphoramidite derivative of the ribo-type monomer 1, while the phosphoramidite of the arabino-type monomer 2 was successfully prepared and incorporated into oligodeoxynucleotides (ODNs). The hybridization ability of the obtained ODN derivatives containing 2 with complementary strands was evaluated by melting temperature (T(m)) measurements. As a result, the ODN derivatives hybridized with DNA and RNA complements in a sequence-selective manner, though the stability of the duplexes was lower than that of the corresponding natural DNA/DNA or DNA/RNA duplex.     

Highly Stable Duplex Formation by Artificial Nucleic Acids Acyclic Threoninol Nucleic Acid (aTNA) and Serinol Nucleic Acid (SNA) with Acyclic Scaffolds

The stabilities of duplexes formed by strands of novel artificial nucleic acids composed of acyclic threoninol nucleic acid (aTNA) and serinol nucleic acid (SNA) building blocks were compared with duplexes formed by the acyclic glycol nucleic acid (GNA), peptide nucleic acid (PNA), and native DNA and RNA. All acyclic nucleic acid homoduplexes examined in this study had significantly higher thermal stability than DNA and RNA duplexes. Melting temperatures of homoduplexes were in the order of aTNA>PNA≈GNA≥SNA?RNA>DNA. Thermodynamic analyses revealed that high stabilities of duplexes formed by aTNA and SNA were due to large enthalpy changes upon formation of duplexes compared with DNA and RNA duplexes. The higher stability of the aTNA homoduplex than the SNA duplex was attributed to the less flexible backbone due to the methyl group of D ‐threoninol on aTNA, which induced clockwise winding. Unlike aTNA, the more flexible SNA was able to cross‐hybridize with RNA and DNA. Similarly, the SNA/PNA heteroduplex was more stable than the aTNA/PNA duplex. A 15‐mer SNA/RNA was more stable than an RNA/DNA duplex of the same sequence.     

Bipyridyl- and biphenyl-DNA: a recognition motif based on interstrand aromatic stacking

The synthesis and incorporation into oligonucleotides of C-nucleosides containing the two aromatic, non-hydrogen-bonding nucleobase substitutes biphenyl (I) and bipyridyl (Y) are described. Their homo- and hetero-recognition properties in different sequential arrangements were then investigated via UV-melting curve analysis, gel mobility assays, CD- and NMR spectroscopy. An NMR analysis of a dodecamer duplex containing one biphenyl pair in the center, as well as CD data on duplexes with multiple insertions provide further evidence for the zipper-like interstrand stacking motif that we proposed earlier based on molecular modeling. UV-thermal melting experiments with duplexes containing one to up to seven I- or Y base pairs revealed a constant increase in T(m) in the case of I and a constant decrease for Y. Mixed I/Y base pairs lead to stabilities in between the homoseries. Insertion of alternating I/abasic site- or Y/abasic site pairs strongly decreases the thermal stability of duplexes. Asymmetric distribution of I- or Y residues on either strand of the duplex were also investigated in this context. Duplexes with three natural base pairs at both ends and 50 % of I pairs in the center are still readily formed, while duplexes with blunt ended I pairs tend to aggregate unspecifically. Duplexes with one natural overhang at the end of a I-I base pair tract can both aggregate or form ordered duplexes, depending on the nature of the natural bases in the overhang.     

Screening of Minimalist Noncanonical Sites in Duplex DNA and RNA Reveals Context and Motif-Selective Binding by Fluorogenic Base Probes

We hypothesize that programmable hybridization to noncanonical nucleic acid motifs may be achieved by macromolecular display of binders to individual noncanonical pairs (NCPs). As each recognition element may individually have weak binding to an NCP, we developed a semi-rational approach to detect low affinity interactions between selected nitrogenous bases and noncanonical sites in duplex DNA and RNA. A set of fluorogenic probes was synthesized by coupling abiotic (triazines, pyrimidines) and native RNA bases to thiazole orange (TO) dye. This probe library was screened against duplex nucleic acid substrates bearing single abasic, single NCP, and tandem NCP sites. Probe engagement with NCP sites was reported by 100–1000× fluorescence enhancement over background. Binding is strongly context-dependent, reflective of both molecular recognition and stability: less stable motifs are more likely to bind a synthetic probe. Further, DNA and RNA substrates exhibit entirely different abasic and single NCP binding profiles. While probe binding in the abasic and single NCP screens was monotonous, much richer binding profiles were observed with the screen of tandem NCP sites in RNA, in part due to increased steric accessibility. In addition to known binding interactions between the triazine melamine (M) and T/U sites, the NCP screens identified new targeting elements for pyrimidine-rich motifs in single NCPs and 2×2 internal bulges. We anticipate that semi-rational approaches of this type will lead to programmable noncanonical hybridization strategies at the macromolecular level.     

Evaluating the contributions of desolvation and base-stacking during translesion DNA synthesis

DNA polymerases catalyze the insertion of a nucleoside triphosphate into the growing polymer chain using the template strand as a guide. Numerous factors such as hydrogen bonding interactions, base-stacking contributions, and desolvation play important roles in controlling the efficiency and fidelity of this process. We previously demonstrated that 5-nitro-indolyl-2'-deoxyriboside triphosphate, a non-natural nucleobase with enhanced base-stacking properties, was more efficiently inserted opposite a non-templating DNA lesion compared to natural templating nucleobases (E. Z. Reineks and A. J. Berdis, Biochemistry, 2004, 43, 393-404). The catalytic enhancement was proposed to reflect increased base-stacking interactions of the non-natural nucleobase with the polymerase and DNA. However, the effects of desolvation could not be unambiguously refuted. To further address the contributions of base stacking and desolvation during translesion DNA replication, we synthesized indolyl-2'-deoxyriboside triphosphate, a nucleobase devoid of nitro groups, and measured its efficiency of enzymatic insertion into modified and unmodified DNA. Removal of the nitro group reduces the catalytic efficiency for insertion opposite an abasic site by 3600-fold. This results from a large decrease in the rate of polymerization (similar 450-fold) coupled with a modest decrease in binding affinity (similar 8-fold). Since both non-natural nucleobases show the same degree of hydrophobicity, we attribute this reduction to the loss of base-stacking contributions rather than desolvation capabilities. Indolyl-2'-deoxyriboside triphosphate can also be inserted opposite natural nucleobases. Surprisingly, the catalytic efficiency for insertion is nearly identical to that measured for insertion opposite an abasic site. These data are discussed within the context of pi-electron interactions of the incoming nucleobase with the polymerase:DNA complex. Despite this lack of insertion selectivity, the polymerase is unable to extend beyond the non-natural nucleobase. This result indicates that indolyl-2'-deoxyriboside triphosphate acts as an indiscriminate chain terminator of DNA synthesis that may have unique therapeutic applications.