Novel Hoogsteen-like bases for configurational recognition of the T-A base pair by DNA triplex formation

Effective sequence-specific recognition of duplex DNA is possible by triplex formation with natural oligonucleotides via Hoogsteen H-bonding. However, triplex formation is in practice limited to pyrimidine oligonucleotides binding duplex A-T or G-C base-pair DNA sequences specifically at homopurine sites in the major groove as T·A-T and C⁺·G-C triplets. Here we report the successful modeling of novel unnatural nucleosides that recognize the T-A DNA base pair by Hoogsteen interaction. Since the DNA triplex can be considered to assume an A-type or B-type conformation, these novel Hoogsteen nucleotides are tested within model A-type and B-type conformation triplex structures. A triplet consisting of the T-A base pair and one of the novel Hoogsteen nucleotides replaces the central T·A-T triplet in the triplex using the same deoxyribose-phosphodiester and base-deoxyribose dihedral angle configuration. The entire triplex is energy minimized and the presence of any structural or energetic perturbations due to the central triplet is assessed with respect to the unmodified energy-minimized (T·A-T)₁₁ proposed starting structures. Incorporation of these novel triplets into both A-type and B-type natural triplex structures provokes minimal change in the configuration of the central and adjacent triplets. The plan is to produce a series of Hoogsteen-like bases that preferentially bind the T-A major groove in either an A-type or B-type conformation. Selective recognition of the T-A major groove with respect to the G-C major groove, which presents similar keto and amine placement, is also assessed with configurational preference. Evaluation of the triplex solution structure by using these unnatural bases as binding conformational probes is a prerequisite to the further design of triplet forming bases. © 1996 John Wiley & Sons, Inc.     

1H NMR and optical spectroscopic investigation of the sequence-dependent dimerization of a symmetrical cyanine dye in the DNA minor groove

A symmetrical cyanine dye was previously shown to bind as a cofacial dimer to alternating A-T sequences of duplex DNA. Indirect evidence suggested that dimerization of the dye occurred in the minor groove. 1H NMR experiments reported here verify this model based on broadening and shifting of signals due to protons on carbon 2 of adenine and imino protons at the central five A-T pairs of the 11 base pair duplex: 5'-GCGTATATGCG-3'/3'-CGCATATACGC-5'. This binding mode is similar to that of distamycin A, even though the dye lacks the hydrogen-bonding groups used by distamycin for sequence-specific recognition. Surprisingly, the third base pair (G-C) was also implicated in the binding site. UV-vis experiments were used to compare the extent of dimerization of the dye for 11 different sequence variants. These experiments verified the importance of a G-C pair at the third position: replacing this pair with A-T suppressed dimerization. These results indicate that the dye binding site spans six base pairs: 5'-GTATAT-3'. The initial G-C pair seems to be important for widening the minor groove rather than for making important contacts with the dye molecules since inverting its orientation to C-G or replacing it with I-C still led to favorable dimerization of the dye.     

Triplex formation by oligonucleotides containing novel deoxycytidine derivatives.

Homopurine sequences of duplex DNA are binding sites for triplex-forming oligodeoxyribopyrimidines. The interactions of synthetic duplex DNA targets with an oligodeoxyribopyrimidine containing N4-(6-amino-2-pyridinyl)deoxycytidine (1), a nucleoside designed to interact with a single C-G base pair interruption of the purine target tract, was studied by UV melting, circular dichroism spectroscopy and dimethylsulfate alkylation experiments. Nucleoside 1 supports stable triplex formation at pH 7.0 with formation of a 1-Y-Z triad, where Y-Z is a base pair in the homopurine tract of the target. Selective interaction was observed when Y-Z was C-G, although A-T and, to a lesser extent, T-A and G-C base pairs were also recognized. The circular dichroism spectra of the triplex having a 1-C-G triad were similar to those of a triplex having a C(+)-G-C triad, suggesting that the overall structures of the two triplexes are quite similar. Removal of the 6-amino group from 1 essentially eliminated triplex formation. Reaction of a triplex having the 1-C-G triad with dimethylsulfate resulted in a 50% reduction of methylation of the G residue of this triad. In contrast, the G of a similar triplex containing a U-C-G triad was not protected from methylation by dimethylsulfate. These results are consistent with a binding mode in which the 6-amino-2-pyridinyl group of 1 spans the major groove of the target duplex at the 1-C-G binding site and forms a hydrogen bond with the O6 of G. An additional stabilizing hydrogen bond could form between the N4 of the imino tautomer of 1 and the N4 amino group of C.     

A-tract DNA disfavours triplex formation.

Optimisation of DNA triplex stability is of fundamental importance in the anti-gene strategy. In the present work, thermal denaturation studies by UV-spectrophotometry and structural and dynamical characterizations by NMR spectroscopy have been used systematically to investigate the effects on triplex stability of isolated insertions of different base triplets into an otherwise homogeneous 15-mer dT x dA-dT oligo-triplex. It is found that insertion of a single central C(+) x G-C or T x D-T triplet (D=2,6-diaminopurine) leads to a pronounced stabilization (up to 20 deg. C if the cytosine base is C5 methylated) at acidic as well as neutral pH. To a smaller degree, this is the case also for a C(+) x I-C triplet insertion.Using imino proton exchange measurements, it is shown that insertion of a DT base-pair in the underlying duplex perturbs the intrinsic A-tract structure in the same way as has been shown for a GC insert. We propose that the intrinsic properties of A-tract duplex DNA (e. g. high propeller twist and rigidity) are unfavourable for triplex formation and that GC- or DT-inserts stabilize the triplex by interfering with the A-tract features of the underlying duplex. The C(+) x I-C triplet without the N2 amino group in the minor groove is readily accommodated within the typical, highly propeller-twisted A-tract structure. This might be related to its smaller effect on the stability of the corresponding triplex.These results may be valuable for understanding DNA triplex formation in vivo as well as for the design of efficient triplex-forming oligonucleotides and in choosing suitable target sequences in the anti-gene strategy.     

New insights into DNA triplexes: residual twist and radial difference as measures of base triplet non-isomorphism and their implication to sequence-dependent non-uniform DNA triplex

DNA triplexes are formed by both isomorphic (structurally alike) and non-isomorphic (structurally dissimilar) base triplets. It is espoused here that (i) the base triplet non-isomorphism may be articulated in structural terms by a residual twist (Δt°), the angle formed by line joining the C1′…C1′ atoms of the adjacent Hoogsteen or reverse Hoogsteen (RH) base pairs and the difference in base triplet radius (Δr Å), and (ii) their influence on DNA triplex is largely mechanistic, leading to the prediction of a high (t + Δt)° and low (t − Δt)° twist at the successive steps of Hoogsteen or RH duplex of a parallel or antiparallel triplex. Efficacy of this concept is corroborated by molecular dynamics (MD) simulation of an antiparallel DNA triplex comprising alternating non-isomorphic G*GC and T*AT triplets. Conformational changes necessitated by base triplet non-isomorphism are found to induce an alternating (i) high anti and anti glycosyl and (ii) BII and an unusual BIII conformation resulting in a zigzag backbone for the RH strand. Thus, base triplet non-isomorphism causes DNA triplexes into exhibiting sequence-dependent non-uniform conformation. Such structural variations may be relevant in deciphering the specificity of interaction with DNA triplex binding proteins. Seemingly then, residual twist (Δt°) and radial difference (Δr Å) suffice as indices to define and monitor the effect of base triplet non-isomorphism in nucleic acid triplexes.     

Selective Preference of Parallel DNA Triplexes Is Due to the Disruption of Hoogsteen Hydrogen Bonds Caused by the Severe Nonisostericity between the G*GC and T*AT Triplets

Implications of DNA, RNA and RNA.DNA hybrid triplexes in diverse biological functions, diseases and therapeutic applications call for a thorough understanding of their structure-function relationships. Despite exhaustive studies mechanistic rationale for the discriminatory preference of parallel DNA triplexes with G_*GC & T_*AT triplets still remains elusive. Here, we show that the highest nonisostericity between the G_*GC & T_*AT triplets imposes extensive stereochemical rearrangements contributing to context dependent triplex destabilisation through selective disruption of Hoogsteen scheme of hydrogen bonds. MD simulations of nineteen DNA triplexes with an assortment of sequence milieu reveal for the first time fresh insights into the nature and extent of destabilization from a single (non-overlapping), double (overlapping) and multiple pairs of nonisosteric base triplets (NIBTs). It is found that a solitary pair of NIBTs, feasible either at a G_*GC/T_*AT or T_*AT/G_*GC triplex junction, does not impinge significantly on triplex stability. But two overlapping pairs of NIBTs resulting from either a T_*AT or a G_*GC interruption disrupt Hoogsteen pair to a noncanonical mismatch destabilizing the triplex by ~10 to 14 kcal/mol, implying that their frequent incidence in multiples, especially, in short sequences could even hinder triplex formation. The results provide (i) an unambiguous and generalised mechanistic rationale for the discriminatory trait of parallel triplexes, including those studied experimentally (ii) clarity for the prevalence of antiparallel triplexes and (iii) comprehensive perspectives on the sequence dependent influence of nonisosteric base triplets useful in the rational design of TFO’s against potential triplex target sites.     

Strong, specific, monodentate G-C base pair recognition by N7-inosine derivatives in the pyrimidine.purine-pyrimidine triple-helical binding motif.

The nucleoside analogs 7-(2'-deoxy-alpha-D-ribofuranosyl)hypoxanthine (alpha7H,1), 7-(2'-deoxy-beta-D-ribofuranosyl)hypoxanthine (beta7H,2) and 7-7-(2'-O-methyl-beta-D- ribofuranosyl)hypoxanthine (beta7HOMe,3) were prepared and incorporated into triplex forming oligodeoxynucleotides, designed to bind to DNA in the parallel (pyrimidine.purine-pyrimidine) motif. By DNase I footprinting techniques and UV-melting curve analysis it was found that, at pH 7. 0, the 15mer oligonucleotides d(TTTTTMeCTXTMeCTMeCTMeCT) (MeC = 5-methyl-deoxycytidine, X =beta7H,beta7HOMe) bind to a DNA target duplex forming a H.G-C base triple with equal to slightly increased (10-fold) stability compared to a control oligodeoxynucleotide in which the hypoxanthine residue is replaced by MeC. Remarkably, triple-helix formation is specific to G-C base pairs and up to 40 microM third strand concentration, no stable triplex exhibiting H.A-T, H.T-A or H.C-G base arrangements could be found (target duplex concentration approximately 0.1 nM). Multiply substituted sequences containing beta7H residues either in an isolated [d(TTTTTbeta7HTbeta7HTbeta7HTbeta7HTbeta7HT)] or in a contiguous [d(TTTbeta7Hbeta7Hbeta7Hbeta7HTTTTbeta7HTTT)] manner still form triplexes with their targets of comparable stability as the control (MeC-containing) sequences at pH 7.0 and high salt or spermine containing buffers. General considerations lead to a structural model in which the recognition of the G-C base pair by hypoxanthine takes place via only one H-bond of the N-H of hypoxanthine to N7 of guanine. This model is supported by a molecular dynamics simulation. A general comparison of the triplex forming properties of oligonucleotides containing beta7H with those containing MeC or N7-2'-deoxyguanosine (N7G) reveals that monodentate recognition in the former case can energetically compete with bidentate recognition in the latter two cases.     

Triple helical DNA in a duplex context and base pair opening

It is fundamental to explore in atomic detail the behavior of DNA triple helices as a means to understand the role they might play in vivo and to better engineer their use in genetic technologies, such as antigene therapy. To this aim we have performed atomistic simulations of a purine-rich antiparallel triple helix stretch of 10 base triplets flanked by canonical Watson–Crick double helices. At the same time we have explored the thermodynamic behavior of a flipping Watson–Crick base pair in the context of the triple and double helix. The third strand can be accommodated in a B-like duplex conformation. Upon binding, the double helix changes shape, and becomes more rigid. The triple-helical region increases its major groove width mainly by oversliding in the negative direction. The resulting conformations are somewhere between the A and B conformations with base pairs remaining almost perpendicular to the helical axis. The neighboring duplex regions maintain a B DNA conformation. Base pair opening in the duplex regions is more probable than in the triplex and binding of the Hoogsteen strand does not influence base pair breathing in the neighboring duplex region.     

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.     

Structural Properties of Hybrid Triplex of Polycation Deoxyribonucleic S-methylthiourea (DNmt) Strands with a Complementary DNA Strand,Probed by Nanosecond Molecular Dynamics

Abstract

The replacement of phosphodiester linkages of the polyanion DNA with S-methylthiourea linkers provides the polycation deoxyribonucleic S-methylthiourea (DNmt). Molecular dynamics studies to 1,220 ps of the hybrid triplex formed from octameric DNmt strands d(Tmt)₈ with a complementary DNA oligomer strand d(Ap)₈ have been carried out with explicit water solvent and Na counterions under periodic boundary conditions using the CHARMM force field and the Ewald summation method. The Watson-Crick and Hoogsteen hydrogen-bonding patterns of the A/T tracts remained intact without any structural restraints for triplex structures throughout the simulation. The duplex portion of the triplex structure equilibrated at a B-DNA conformation in terms of the helical rise and other helical parameters. The dynamic structures of the DNmt·DNA·DNmt triplex were determined by examining histograms from the last 800 ps of the dynamics run. These included the hydrogen-bonding pattern (sequence recognition), three-centered bifurcating occurrences, minor groove width variations, and bending of tracts for the hybrid triplex structures. Together with the Watson-Crick hydrogen-bondings, the strong Hoogsteen hydrogen-bondings, the partially maintained three-centered bifurcatings in the Watson-Crick pair, and the medium-strength three-centered bifurcatings in the Hoogsteen pair suggest that the hybrid triplex is energetically favorable as compared to a duplex with similar base stacking, van der Waals interactions, and helical parameters. This is in agreement with our previously reported thermody- namic study, in which only triplex structures were observed in solution. The bending angle measured between the local axis vectors of the first and last helical axis segments is about 20° for the Watson-Crick portion of the averaged structure. Propeller twist (associated with three-centered hydrogen-bonding) up to ?30°, native to DNA AT base pairing, was also observed for the triplex structure. The sugar pseudorotation phase angles and the ring rotation angles for the DNA strand are within the C3′-endo domain and C2′-endo domain for the DNmt strand. Water spines are observed in both minor and major grooves throughout the dynamics run. The molecular dynamics simulations of the structural properties of DNmt·DNA·DNmt hybrid triplex is compared to the DNG·DNA·DNG hybrid triplex (In DNG the -O-(PO₂-)-O- linkers in DNA is replaced by -NH-C(=N₂)-NH-).     

Single-Stranded DNA and RNA Targeted Triplex-Formation: UV,CD and Molecular Modeling Studies of Foldback Triplexes Containing Different RNA, 2′-OMe-RNA and DNA Strand Combinations

Abstract

We studied the influence of different 2′-OMe-RNA and DNA strand combinations on single strand targeted foldback triplex formation in the Py.Pu:Py motif using ultraviolet (UV) and circular dichroism (CD) spectroscopy, and molecular modeling. The study of eight combinations of triplexes (D D:D, R* D:D, D D:R*, R* D:R*, D R:D, R* R:D, DR:R*, and R*-R:R*; where the first, middle, and last letters stand for the Hoogsteen Pyrimidine, Watson-Crick [WC] purine and WC pyrimidine strands, respectively, and D, R and R* stand for DNA, RNA and 2′-OMe-RNA strands, respectively) indicate more stable foldback triplex formation with a DNA purine strand than with an RNA purine strand. Of the four possible WC duplexes with RNA/DNA combinations, the duplex with a DNA purine strand and a 2′-O-Me-RNA pyrimidine strand forms the most thermally stable triplex, although its thermal stability is the lowest of all four duplexes. Irrespective of the duplex combination, a 2′-OMe-RNA Hoogsteen pyrimidine strand forms a stable foldback triplex over a DNA Hoogsteen pyrimidine strand confirming the earlier reports with conventional and circular triplexes. The CD studies suggest a B-type conformation for an all DNA homo-foldback triplex (D.D.D), while hetero-foldback triplex spectra suggest intermediate conformation to both Atype and B-type structures. A novel molecular modeling study has been carried out to understand the stereochemical feasibility of all the combinations of foldback triplexes using a geometric approach. The new approach allows use of different combinations of chain geometries depending on the nature of the chain (RNA vs. DNA).     

Selective recognition of a C-G base-pair in the parallel DNA triple-helical binding motif.

Selective recognition of a C-G base-pair within the parallel DNA triple-helical binding motif was achieved by a third strand containing the base 5-methyl pyrimidin-2-one. The third strand affinities (K(D)) for a representative 15-mer duplex sequence containing all four Watson-Crick base pairs (X-Y) in the center are C-G (26 nM) > A-T (270 nM) approximately T-A (350 nM) > G-C (ca 700 nM).     

Single strand targeted triplex formation: targeting purine-pyrimidine mixed sequences using abasic linkers.

Foldback triplex-forming oligonucleotides (FTFOs) that contain an abasic linker, [2-(4-aminobutyr-1-yl)-1,3-propanediol] (APD linker), in the Hoogsteen domain against pyrimidine bases of a C:G and a T:A base pair were studied for their relative stability and sequence specificity of triplex formation. In general, the APD linker has less destabilizing effect against a C:G base pair than a T:A base pair. Incorporation of three APD linker moieties resulted in decreased binding to the target, which was comparable to results observed with three imperfectly matched natural base triplets. The APD linker incorporation did not result in the loss of sequence specificity of FTFOs, unlike in the case of normal triplex-forming oligonucleotides (TFOs). The introduction of a positively charged abasic linker, however, resulted in decreased stability of the triplex, because of loss of hydrogen bonding and stacking interactions in the major groove. The results of a molecular modeling study show that APD linker can be readily incorporated without any change in the conformation of the natural sugar-phosphate backbone conserving overall triple helix geometry. Further, the modeling study suggests a hydrogen bond formation between the amino group of linker and N4 of cytosine mediated by a solvent molecule (water) in the floor of the base triplet in addition to a contribution from the positive charge on the APD linker amino group. Either a direct or water-mediated hydrogen bond between the amino group of the APD linker and the O4 of thymine is unlikely when the linker is placed against a T:A base pair.     

Solution structure of a dsDNA:LNA triplex

We have determined the NMR structure of an intramolecular dsDNA:LNA triplex, where the LNA strand is composed of alternating LNA and DNA nucleotides. The LNA oligonucleotide binds to the dsDNA duplex in the major groove by formation of Hoogsteen hydrogen bonds to the purine strand of the duplex. The structure of the dsDNA duplex is changed to accommodate the LNA strand, and it adopts a geometry intermediate between A- and B-type. There is a substantial propeller twist between base-paired nucleobases. This propeller twist and a concomitant large propeller twist between the purine and LNA strands allows the pyrimidines of the LNA strand to interact with the 5′-flanking duplex pyrimidines. Altogether, the triplex has a regular global geometry as shown by a straight helix axis. This shows that even though the third strand is composed of alternating DNA and LNA monomers with different sugar puckers, it forms a seamless triplex. The thermostability of the triplex is increased by 19°C relative to the unmodified DNA triplex at acidic pH. Using NMR spectroscopy, we show that the dsDNA:LNA triplex is stable at pH 8, and that the triplex structure is identical to the structure determined at pH 5.1.     

Recognition of a G-C base pair by α-N-deoxyinosine within the pyrimidine-purine-pyrimidine DNA triple helical motif

The α-nucleoside 7-(2′-deoxy-α-D-ribofuranosyl)hypoxanthine, incorporated into an otherwise β-configured oligodeoxynucleotide that is designed to bind to a DNA duplex in the parallel motif, recognizes selectively and efficiently a G-C base pair, presumably via monodentate α-H⁷·G-C base-triple formation.     

Counterstain-enhanced chromosome banding

Summary Chromosome staining, in which at least one member of a pair or triplet of DNA binding dyes is fluoescent whereas the others act as counterstain, is reviewed. Appropriately chosen combinations of fluorescent dyes and counterstains can be employed to enhance general chromosome banding patterns, or to induce specific regional banding patterns. Some pairs of dyes which exhibit complementary DNA binding specificity, A-T/G-C or G-C/A-T, provide enhanced definition of positive or reverse banding patterns. Dye combinations of the type A-T/A-T, that include two DNA stains with similar specificity but non-identical binding modes, produce a specific pattern of brightly fluorescnet heterochromatic regions (DA-DAPI bands). In man, the method highlights the C bands of chromosomes 1, 9, 15, 16, and the Y. Certain dye triplets of the type G-C/A-T/A-T, which include two spectroscopically separated fluorescent stains with reciprocal DNA base pair binding specificites and a non-fluorescent A-T binding counterstain, can be used to highlight selectively, in the appropriate wavelength ranges, either R bands or DA-DAPI bands.Applications of these techniques in human cytogenetics are described. The potential of the new methodology for detecting and analysing specific chromosome bands is demonstrated. The mechanisms responsible for contrast enhancement and pattern induction are reviewed and their implications for chromosome structure are discussed as they relate to the banding phenomenon and to the DNA composition of chromosomes.     

The influence of intercalator binding on DNA triplex stability: correlation with effects on A-tract duplex structure

The triplex form of DNA is of interest because of a possible biological role as well as the potential therapeutic use of this structure. In this paper the stabilizing effects of two intercalating drugs, ethidium and the quinoxaline derivative 9-OH-B220, on DNA triplexes have been studied by thermal denaturation measurements. The corresponding duplex structures of the DNA triplex systems investigated are either A-tract or normal B-DNA. The largest increases in the triplex melting temperatures caused by the intercalators were found for sequences having A-tract duplex structures. Inserting a single base pair with an N2-amino group in the minor groove, e.g. a G-C pair, breaks up the A-tract duplex structure and also reduces the stabilizing effect of the drugs on the triplex melting temperatures. The large drug-induced increase in triplex melting temperature for complexes having an original duplex A-tract structure is correlated with a low initial melting point of the triplex, not with the triplex being unusually stable in the presence of the drug. Hence, we conclude that the large thermal stabilizing effect exhibited by ethidium and 9-OH-B220 on dTn.dAn-dTn triplexes is partly caused by the intercalators breaking up the intrinsic A-tract structure of the underlying duplex.     

Stability of non-Watson-Crick G-A/A-G base pair in synthetic DNA and RNA oligonucleotides

A non-Watson-Crick G-A/A-G base pair is found in SECIS (selenocysteine-insertion sequence) element in the 3'-untranslated region of Se-protein mRNAs and in the functional site of the hammerhead ribozyme. We studied the stability of G-A/A-G base pair (bold) in 17mer GT(U)GACGGAAACCGGAAC synthetic DNA and RNA oligonucleotides by thermal melting experiments and gel electrophoresis. The measured Tm value of DNA oligonucleotide having G-A/A-G pair showed an intermediate value (58 degrees C) between that of Watson-Crick G-C/C-G base pair (75 degrees C) and that of G-G/A-A of non-base-pair (40 degrees C). Similar thermal melting patterns were obtained with RNA oligonucleotides. This result indicates that the secondary structure of oligonucleotide having G-A/A-G base pair is looser than that of the G-C type Watson-Crick base pair. In the comparison between RNA and DNA having G-A/A-G base pair, the Tm value of the RNA oligonucleotide was 11 degrees C lower than that of DNA, indicating that DNA has a more rigid structure than RNA. The stained pattern of oligonucleotide on polyacrylamide gel clarified that the mobility of the DNA oligonucleotide G-A/A-G base pair changed according to the urea concentration from the rigid state (near the mobility of G-C/C-G oligonucleotide) in the absence of urea to the random state (near the mobility of G-G/A-A oligonucleotide) in 7 M urea. However, the RNA oligonucleotide with G-A/A-G pair moved at an intermediate mobility between that of oligonucleotide with G-C/C-G and of the oligonucleotide with G-G/A-A, and the mobility pattern did not depend on urea concentration. Thus, DNA and RNA oligonucleotides with the G-A/A-G base pair showed a pattern indicating an intermediate structure between the rigid Watson-Crick base pair and the random structure of non-base pair. RNA with G-A/A-G base pair has the intermediate structure not influenced by urea concentration. Finally, this study indicated that the intermediate rigidity imparted by Non-Watson-Crick base pair in SECIS element plays an important role in the selenocysteine expression by UGA codon.