Ligand-induced formation of Hoogsteen-paired parallel DNA

zIntroduction: Based on molecular modeling studies, a model has been proposed for intercalation of triple-helixspecific ligands (benzopyridoindole (BPI) derivatives) into triple helices, in which the intercalating compounds interact mainly with the Hoogsteen-paired strands of the triple helix. We set out to test this model experimentally using DNA duplexes capable of forming parallel Hoogsteen base-paired structures.Results: We have investigated the possible formation of a parallel DNA structure involving Hoogsteen hydrogen bonds by thermal denaturation, FTIR spectroscopy and gel-shift experiments. We show that BPI derivatives bind to Hoogsteen base-paired duplexes and stabilize them. The compounds induce a reorganization from a non-perfectly matched antiparallel Watson-Crick duplex into a perfectly matched parallel Hoogsteen-paired duplex.Conclusions: These results suggest that preferential intercalation of BPI derivatives in triple helices is due to their ability to interact specifically with the Hoogsteen-paired bases. The results are consistent with a model proposed on the basis of molecular modeling studies using energy minimization, and they open a new field of investigations regarding the biological relevance of Hoogsteen base-pairing.     

Theoretical study of a new DNA structure: the antiparallel Hoogsteen duplex

The structure of a new form of duplex DNA, the antiparallel Hoogsteen duplex, is studied in polyd(AT) sequences by means of state-of-the-art molecular dynamics simulations in aqueous solution. The structure, which was found to be stable in all of the simulations, has many similarities with the standard Watson-Crick duplex in terms of general structure, flexibility, and molecular recognition patterns. Accurate MM-PB/SA (and MM-GB/SA) analysis shows that the new structure has an effective energy similar to that of the B-type duplex, while it is slightly disfavored by intramolecular entropic considerations. Overall, MD simulations strongly suggest that the antiparallel Hoogsteen duplex is an accessible structure for a polyd(AT) sequence, which might compete under proper experimental conditions with normal B-DNA. MD simulations also suggest that chimeras containing Watson-Crick duplex and Hoogsteen antiparallel helices might coexist in a common structure, but with the differential characteristics of both type of structures preserved.     

Synthesis and pairing properties of alpha-tricyclo-DNA

We describe the synthesis of the phosphoramidite building blocks of alpha-tricyclo-DNA (alpha-tc-DNA) covering all four natural bases, starting from the already known corresponding alpha-tc-nucleosides. These building blocks were used for the preparation of three alpha-tc-oligonucleotide 10-mers representing a homopurine, a homopyrimidine, and a mixed purine/pyrimidine base sequence. The base-pairing properties with complementary parallel and antiparallel oriented DNA and RNA were studied by UV-melting analysis and CD spectroscopy. We found that alpha-tc-DNA binds preferentially to parallel nucleic acid complements through Watson-Crick duplex formation, with a preference for RNA over DNA. In comparison with natural DNA, alpha-tc-DNA shows equal to enhanced affinity to RNA and also pairs to antiparallel DNA or RNA complements, although with much lower affinity. In the mixed-base sequence these antiparallel duplexes are of the reversed Watson-Crick type, while in the homopurine/homopyrimidine sequences Hoogsteen and/or reversed Hoogsteen pairing is observed. Antiparallel duplex formation of two alpha-tc-oligonucleotides was also observed, although the thermal stability of this duplex was surprisingly low. The base-pairing properties of alpha-tc-DNA are discussed in the context of alpha-DNA, alpha-RNA, and alpha-LNA.     

Hoogsteen-based parallel-stranded duplexes of DNA. Effect of 8-amino-purine derivatives

The structure of parallel-stranded duplexes of DNA-containing a mixture of guanines (G) and adenines (A) is studied by means of molecular dynamics (MD) simulation, as well as NMR and circular dichroism (CD) spectroscopy. Results demonstrate that the structure is based on the Hoogsteen motif rather than on the reverse Watson-Crick one. Molecular dynamics coupled to thermodynamic integration (MD/TI) calculations and melting experiments allowed us to determine the effect of 8-amino derivatives of A and G and of 8-amino-2'-deoxyinosine on the stability of parallel-stranded duplexes. The large stabilization of the parallel-stranded helix upon 8-amino substitution agrees with a Hoogsteen pairing, confirming MD, NMR, and CD data, and suggests new methods to obtain DNA triplexes for antigene and antisense purposes.     

Circular dichroism signatures of features simultaneously present in structured guanine-rich oligonucleotides: a combined spectroscopic and electrophoretic approach

In order to identify possible signatures of the most typical structures adopted by guanine-rich oligonucleotides, we submitted them to the crossed fire of circular dichroism (CD) and electrophoresis. These signatures show up in the circular dichroism spectra even when simultaneously present within the same molecule. Guanine-rich oligonucleotides, when structured, manifest themselves by CD contributions around 260 or 295 nm. For instance, positive bands at 264 nm and 295 nm, respectively, signal the parallel and antiparallel guanine quartets, while a positive band around 261 nm may indicate the presence of a (parallel?) Hoogsteen duplex. A positive band at 264 nm may also reflect the presence of rigidly and unusually oriented GpT and TpG steps within loops. The signatures are additive with those of other structural features of the same molecule, such as hairpins or Watson-Crick duplexes, whose bands are observed at 280 nm.     

Hydration regulates thermodynamics of G-quadruplex formation under molecular crowding conditions

The effect of molecular crowding on the structure and stability of biomolecules has become a subject of increasing interest because it can clarify how biomolecules behave under cell-mimicking conditions. Here, we quantitatively analyzed the effects of molecular crowding on the thermodynamics of antiparallel G-quadruplex formation via Hoogsteen base pairs and of antiparallel hairpin-looped duplex (HP duplex) formation via Watson-Crick base pairs. The free energy change at 25 degrees C for G-quadruplex formation decreased from -3.5 to -5.5 kcal mol(-1) when the concentration of poly(ethylene glycol) 200 was increased from 0 to 40 wt %, whereas that of duplex formation increased from -9.8 to -6.9 kcal mol(-1). These results showed that the antiparallel G-quadruplex is stabilized under molecular crowding conditions, but that the HP duplex is destabilized. Moreover, plots of stability (ln K(obs)) of the DNA structures versus water activity (ln a(w)) demonstrated that the ln K(obs) for G-quadruplex formation decreased linearly as the ln a(w) increased, whereas that for duplex formation increased linearly with the increase in ln a(w), suggesting that the slope approximately equals the number of water molecules released or taken up during the formation of these structures. Thus, molecular crowding affects the thermodynamics of DNA structure formation by altering the hydration of the DNA. The stabilization of the DNA structures with Hoogsteen base pairs and destabilization of DNA structures with Watson-Crick base pairs under molecular crowding conditions lead to structural polymorphism of DNA sequences regulated by the state of hydration.     

Stabilization by extra-helical thymines of a DNA duplex with Hoogsteen base pairs

We present the crystal structure of the DNA duplex formed by d(ATATATCT). The crystals contain seven stacked antiparallel duplexes in the asymmetric unit with A.T Hoogsteen base pairs. The terminal CT sequences bend over so that the thymines enter the minor groove and form a hydrogen bond with thymine 2 of the complementary strand in the Hoogsteen duplex. Cytosines occupy extra-helical positions; they contribute to the crystal lattice through various kinds of interactions, including a unique CAA triplet. The presence of thymine in the minor groove apparently contributes to the stability of the DNA duplex in the Hoogsteen conformation. These observations open the way toward finding under what conditions the Hoogsteen duplex may be stabilized in vivo. The present crystal structure also confirms the tendency of A.T-rich oligonucleotides to crystallize as long helical stacks of duplexes.     

An unusual mode of DNA duplex association: Watson-Crick interaction of all-purine deoxyribonucleic acids

Nucleic acid duplexes associating through purine-purine base pairing have been constructed and characterized in a remarkable demonstration of nucleic acids with mixed sequence and a natural backbone in an alternative duplex structure. The antiparallel deoxyribose all-purine duplexes associate specifically through Watson-Crick pairing, violating the nucleobase size-complementarity pairing convention found in Nature. Sequence-specific recognition displayed by these structures makes the duplexes suitable, in principle, for information storage and replication fundamental to molecular evolution in all living organisms. All-purine duplexes can be formed through association of purines found in natural ribonucleosides. Key to the formation of these duplexes is the N(3)-H tautomer of isoguanine, preferred in the duplex, but not in aqueous solution. The duplexes have relevance to evolution of the modern genetic code and can be used for molecular recognition of natural nucleic acids.     

Substituted 1,8-naphthyridin-2(1H)-ones are superior to thymine in the recognition of adenine in duplex as well as triplex structures

The synthesis and evaluation of a series of novel nucleobases based on substituted 1,8-naphthyridin-2(1H)-ones are reported. The nucleobases were designed to meet the requirements for incorporation into peptide nucleic acids (PNAs) and were evaluated as part of PNA duplex and triplex nucleic acid recognition systems. Of the various nucleobases tested, only the 7-chloro-1,8-naphthyridin-2(1H)-one (7-Cl-bT) nucleobase led to consistently increased affinity in all recognition systems, duplex (Watson-Crick) as well as triplex (Hoogsteen). For multiply modified systems, the increase in thermal stability per modification was dependent on the sequence context, ranging from 2.0 degrees C (in separate positions) to 3.5 degrees C (in adjacent positions) in PNA-DNA duplexes and from 1.2 degrees C (in separate positions) to 3.2 degrees C (in adjacent positions) in PNA-RNA duplexes. Singly mismatched oligonucleotide targets were employed to demonstrate uncompromised sequence discrimination. When part of multiply modified triplex (Hoogsteen) recognition systems, the 7-Cl-bT unit gave rise to increases in the thermal stability ranging from 2.7 to 3.5 degrees C when incorporated into separated and adjacent positions, respectively. Our results furthermore indicate that the duplex stabilization is predominantly enthalpic and therefore most likely not a consequence of single-strand preorganization. Finally, and most surprisingly, we find no direct correlation between the end-stacking efficiency of this type of nucleobase and its helix stabilization when involved in Watson-Crick base pairing within a helix.     

6-aza-2'-deoxyisocytidine: synthesis,properties of oligonucleotides,and base-pair stability adjustment of DNA with parallel strand orientation

6-Aza-5-methyl-2'-deoxyisocytidine (1a) and 6-aza-2'-deoxyisocytidine (1b) have been synthesized, converted into phosphoramidite building blocks, and incorporated into oligodeoxynucleotides. The glycosylic bond stability of 1a,b under acidic conditions increases compared to that of 5-methyl-2'-deoxyisocytidine (2a) and 2'-deoxyisocytidine (2b). Oligonucleotides incorporating 1a or 1b show an enhanced stability against the 3'-exonuclease snake-venom phosphodiesterase. The duplexes containing 6-azapyrimidine nucleosides 1a or 1b have lower T(m) values than duplexes containing 2a or 2b with either antiparallel or parallel chain orientation. This was used to adjust the stability of the tridentate m5iCd-dG base pair to the level of the bidentate reverse Watson-Crick dA-dT pair.     

A simple glycol nucleic acid

A glycol nucleic acid (GNA) with an acyclic propylene glycol phosphodiester backbone forms stable antiparallel duplexes following the Watson-Crick base pairing rules.     

Bicyclo-DNA: a Hoogsteen-selective pairing system

Background: The natural nucleic acids (DNA and RNA) can adopt a variety of structures besides the antiparallel double helix described by Watson and Crick, depending on base sequence and solvent conditions. Specifically base-paired DNA structures with regular backbone units include left-handed and parallel duplexes and triple and quadruple helical arrangements. Given the base-pairing pattern of the natural bases, preferences for how single strands associate are determined by the structure and flexibility of the sugar-phosphate backbone. We set out to determine the role of the backbone in complex formation by designing DNA analogs with well defined modifications in backbone structure.Results: We recently developed a DNA analog (bicyclo-DNA) in which one (γ) of the six torsion angles (a-ζ) describing the DNA-backbone conformation is fixed in an orientation that deviates from that observed in B-DNA duplexes by about +100°, a shift from the synclinal to the antiperiplanar range. Upon duplex formation between homopurine and homopyrimidine sequences, this analog preferentially selects the Hoogsteen and reversed Hoogsteen mode, forming A-T and G-C⁺ base pairs. Base-pair formation is highly selective, but degeneracy is observed with respect to strand orientation in the duplex.Conclusions: The flexibility and orientation of the DNA backbone can influence the preferences of the natural bases for base-pairing modes, and can alter the relative stability of duplexes and triplexes.     

Crystal structure of a partly self-complementary peptide nucleic acid (PNA) oligomer showing a duplex-triplex network

The X-ray structure of a partly self-complementary peptide nucleic acid (PNA) decamer (H-GTAGATCACT-l-Lys-NH(2)) to 2.60 A resolution is reported. The structure is mainly controlled by the canonical Watson-Crick base pairs formed by the self-complementary stretch of four bases in the middle of the decamer (G(4)A(5)T(6)C(7)). One right- and one left-handed Watson-Crick duplex are formed. The two PNA units C(9)T(10) change helical handedness, so that each PNA strand contains both a right- and a left-handed section. The changed handedness in C(9)T(10) allows formation of Hoogsteen hydrogen bonding between C(9)T(10) and G(4)A(5) of a PNA strand in an adjacent Watson-Crick double helix of the same handedness. Thereby, a PNA-PNA-PNA triplex is formed. The PNA unit A(3) forms a noncanonical base pair with A(8) in a symmetry-related strand of opposite handedness; the base pair is of the A-A reverse Hoogsteen type. The structural diversity of this PNA demonstrates how the PNA backbone is able to adapt to structures governed by the stacking and hydrogen-bonding interactions between the nucleobases. The crystal structure further shows how PNA oligomers containing limited sequence complementarity may form complex hydrogen-bonding networks.     

Parallel DNA double helices incorporating isoG or m5isoC bases studied by FTIR, CD and molecular modeling

FTIR spectroscopy has been used to follow the formation of parallel stranded DNA duplexes incorporating isoG or m5isoC bases and determine their base pairing scheme. The results are discussed in comparison with data concerning anti-parallel duplexes with comparable base composition and sequence. In duplexes containing A-T and isoG-C or m5isoC-G base pairs shifts of the thymine C2=O2 and C4=O4 carbonyl stretching vibrations (to lower and higher wavenumbers, respectively, when compared to their positions in classical cis Watson-Crick (WC) base pairs) reflect the formation of trans Watson-Crick A-T base pairs. All carbonyl groups of cytosines, m5isocytosines, guanines and isoguanines are found to be involved in hydrogen bonds, indicative of the formation of isoG-C and m5isoC-G base pairs with three hydrogen bonds. Molecular modeling shows that both structures form regular right handed helices with C2'endo sugar puckers. The role of the water content on the helical conformation of the parallel duplexes has been studied by FTIR and CD. It is found that a conformational transition similar to the B --> A transition observed for anti-parallel duplexes induced by a decrease of the water content of the samples can occur for these parallel duplexes. Their helical flexibility has been evidenced by FTIR studies on hydrated films by the emergence of absorption bands characteristic of A type geometry, in particular by an S-type --> N-type repuckering of the deoxyribose. All sugars in the parallel duplex with alternating d(isoG-A)/d(C-T) sequence can adopt an N-type geometry in low water content conditions. The conformational transition of the parallel hairpin duplex with alternating d(isoG-A)/d(C-T) sequence was followed by circular dichroism in water/trifluoroethanol solutions and its free energy at 0 degrees C was estimated to be 6.6 +/- 0.3 kcal mol(-1).     

Gas-phase Watson-Crick and Hoogsteen isomers of the nucleobase mimic 9-methyladenine x 2-pyridone.

2-Pyridone (pyridin-2-one) is a mimic of the uracil and thymine nucleobases, with only one N--H and C==O group. It provides a single H-bonding site, compared to three for the canonical pyrimidine nucleobases. Employing the supersonically cooled 9-methyladenine2-pyridone (9MAd x 2PY) complex, which is the simplest base pair to mimic adenine-uracil or adenine-thymine, we show that its gas-phase UV spectrum consists of contributions from two isomers. Based on the H-bonding sites of 9-methyladenine, these are the Watson-Crick and Hoogsteen forms. Combining two-color two-photon ionisation (2C-R2PI), UV-UV depletion and laser-induced fluorescence spectroscopies allows separation of the two band systems, revealing characteristic intermolecular in-plane vibrations of the two isomers. The calculated S(0) and S(1) intermolecular frequencies are in good agreement with the experimental ones. Ab initio calculations predict the Watson-Crick isomer to be slightly more stable (D(0)=-16.0 kcal mol(-1)) than the Hoogsteen isomer (D(0)=-15.0 kcal mol(-1)). The calculated free energies Delta(f)G(0) of the Watson-Crick and Hoogsteen isomers agree qualitatively with the experimental isomer concentration ratio of 3:1.     

A Highly Stabilizing Silver(I)‐Mediated Base Pair in Parallel‐Stranded DNA

The first parallel‐stranded DNA duplex with Hoogsteen base pairing that readily incorporates an Ag⁺ ion into an internal mispair to form a metal‐mediated base pair has been created. Towards this end, the highly stabilizing 6 FP ‐Ag⁺‐ 6 FP base pair comprising the artificial nucleobase 6‐furylpurine ( 6 FP ) was devised. A combination of temperature‐dependent UV spectroscopy, CD spectroscopy, and DFT calculations was used to confirm the formation of this base pair. The nucleobase 6 FP is capable of forming metal‐mediated base pairs both by the Watson–Crick edge (i.e. in regular antiparallel‐stranded DNA) and by the Hoogsteen edge (i.e. in parallel‐stranded DNA), depending on the oligonucleotide sequence and the experimental conditions. The 6 FP ‐Ag⁺‐ 6 FP base pair within parallel‐stranded DNA is the most strongly stabilizing Ag⁺‐mediated base pair reported to date for any type of nucleic acid, with an increase in melting temperature of almost 15 °C upon the binding of one Ag⁺ ion.     

On the structure and dynamics of duplex GNA

Glycol nucleic acid (GNA), with a nucleotide backbone comprising of just three carbons and the stereocenter derived from propylene glycol (1,2-propanediol), is a structural analog of nucleic acids with intriguing biophysical properties, such as formation of highly stable antiparallel duplexes with high Watson-Crick base pairing fidelity. Previous crystallographic studies of double stranded GNA (dsGNA) indicated two forms of backbone conformations, an elongated M-type (containing metallo-base pairs) and the condensed N-type (containing brominated base pairs). A herein presented new crystal structure of a GNA duplex at 1.8 ? resolution from self-complementary 3'-CTC(Br)UAGAG-2' GNA oligonucleotides reveals an N-type conformation with alternating gauche-anti torsions along its (O3'-C3'-C2'-O2') backbone. To elucidate the conformational state of dsGNA in solution, molecular dynamic simulations over a period of 20 ns were performed with the now available repertoire of structural information. Interestingly, dsGNA adopts conformational states in solution intermediate between experimentally observed backbone conformations: simulated dsGNA shows the all-gauche conformation characteristic of M-type GNA with the higher helical twist common to N-type GNA structures. The so far counterintuitive, smaller loss of entropy upon duplex formation as compared to DNA can be traced back to the conformational flexibility inherent to dsGNA but missing in dsDNA. Besides extensive interstrand base stacking and conformational preorganization of single strands, this flexibility contributes to the extraordinary thermal stability of GNA.     

i-Motif在分子拥挤条件下的性质

本文用人端粒富含C的序列[C₃TA₂]₃C₃作为模型, 利用惰性分子PEG 200作为模拟体内分子的拥挤试剂, 通过圆二色光谱和紫外吸收光谱研究了i-Motif在分子拥挤条件下的性质. 结果表明, PEG的存在对i-Motif的结构没有明显影响, 但是可以提高i-Motif的热稳定性.     

Recognition properties of donor- and acceptor-modified biphenyl-DNA

The recognition properties of DNA duplexes containing single or triple incorporations of eight different donor-modified (OMe, NH(2)) and acceptor-modified (NO(2)) biphenyl residues as base replacements in opposite positions were probed by UV-melting and by CD and fluorescence spectroscopy. We found a remarkable dependence of duplex stability on the natures of the substituents (donor vs. acceptor). The stabilities of duplexes with one biphenyl pair increase in the order donor/donor < acceptor/donor < acceptor/acceptor substitution. The most stable biphenyl pairs stabilize duplexes by up to 6 degrees C in T(m). In duplexes with three consecutive biphenyl pairs the stability increases in the inverse order (acceptor/acceptor < donor/acceptor < donor/donor) with increases in T(m), relative to an unmodified duplex, of up to 10 degrees C. A thermodynamic analysis, combined with theoretical calculations of the physical properties of the biphenyl substituents, suggests that in duplexes with single biphenyl pairs the affinity is dominated by electrostatic forces between the biphenyl/nearest neighbor natural base pairs, whereas in the triple-modified duplexes the increase in thermal stability is predominantly determined by hydrophobic interactions of the biphenyl residues with each other. Oligonucleotides containing amino biphenyl residues are fluorescent. Their fluorescence is largely quenched when they are paired with themselves or with nitrobiphenyl-containing duplex partners.     

1-, 2-, and 4-ethynylpyrenes in the structure of twisted intercalating nucleic acids: structure, thermal stability, and fluorescence relationship

A postsynthetic, on-column Sonogashira reaction was applied on DNA molecules modified by 2- or 4-iodophenylmethylglycerol in the middle of the sequence, to give the corresponding ortho- and para-twisted intercalating nucleic acids (TINA) with 1-, 2-, and 4-ethynylpyrene residues. The convenient synthesis of 2- and 4-ethynylpyrenes started from the hydrogenolysis of pyrene that has had the sulfur removed and separation of 4,5,9,10-tetrahydropyrene and 1,2,3,6,7,8-hexahydropyrene, which were later converted to the final compounds by successive Friedel-Crafts acetylation, aromatization by 2,3-dichloro-5,6-dicyano-1,4-benzoquinone, and a Vilsmeier-Haack-Arnold transformation followed by a Bodendorf fragmentation. Significant alterations in thermal stability of parallel triplexes and antiparallel duplexes were observed upon changing the attachment of ethynylpyrenes from para to ortho in homopyrimidine TINAs. Thus, for para-TINAs the bulge insertion of an intercalator led to high thermal stability of Hoogsteen-type parallel triplexes and duplexes, whereas Watson-Crick-type duplexes were destabilized. In the case of ortho-TINA, both Hoogsteen and Watson-Crick-type complexes were stabilized. Alterations in the thermal stability were highly influenced by the ethynylpyrene isomers used. This also led to TINAs with different changes in fluorescence spectra depending on the secondary structures formed. Stokes shift of approximately 100 nm was detected for pyren-2-ylethynylphenyl derivatives, whereas values for 1- and 4-ethynylpyrenylphenyl conjugates were 10 and 40 nm, respectively. In contrast with para-TINAs, insertion of two ortho-TINAs opposite each other in the duplex as a pseudo-pair resulted in formation of an excimer band at 505 nm for both 1- and 4-ethynylpyrene analogues, which was also accompanied with higher thermal stability.