Nonenzymatic synthesis of RNA and DNA oligomers on hexitol nucleic acid templates: the importance of the A structure.

Hexitol nucleic acid (HNA) is an analogue of DNA containing the standard nucleoside bases, but with a phosphorylated 1,5-anhydrohexitol backbone. HNA oligomers form duplexes having the nucleic acid A structure with complementary DNA or RNA oligomers. The HNA decacytidylate oligomer is an efficient template for the oligomerization of the 5'-phosphoroimidazolides of guanosine or deoxyguanosine. Comparison of the oligomerization efficiencies on HNA, RNA, and DNA decacytidylate templates under various conditions suggests strongly that only nucleic acid double helices with the A structure support efficient template-directed synthesis when 5'-phosphoroimidazolides of nucleosides are used as substrates.     

Molecular‐Dynamics Studies of Single‐Stranded Hexitol,Altritol, Mannitol,and Ribose Nucleic Acids (HNA,MNA, ANA,and RNA,Resp.) and of the Stability of HNA⋅RNA,ANA⋅RNA,and MNA⋅RNA Duplexes

The influence of the orientation of a 3′‐OH group on the conformation and stability of hexitol oligonucleotides in complexes with RNA and as single strands in aqueous solution was investigated by molecular‐dynamics (MD) simulations with AMBER 4.1. The particle mesh Ewald (PME) method was used for the treatment of long‐range electrostatic interactions. An equatorial orientation of the 3′‐OH group in the single‐stranded D ‐mannitol nucleic acid (MNA) m(GCGTAGCG) and in the complex with the RNA r(CGCAUCGC) has an unfavorable influence on the helical stability. Frequent H‐bonds between the 3′‐OH group and the O−C(6′) of the phosphate backbone of the following nucleotide explain the distorted conformation of the MNA⋅RNA complex as well as that of the single MNA strand. This is consistent with experimental results that show lowered hybridization potentials for MNA⋅RNA complexes. An axial orientation of the 3′‐OH group in the D ‐altritol nucleic acid (ANA) a(GCGTAGCG) leads to a stable complex with the complementary RNA r(CGCAUCGC), as well as to a more highly preorganized single‐stranded ANA chain. The averaged conformation of the ANA⋅RNA complex is similar to that of A‐RNA, with only minor changes in groove width, helical curvature, and H‐bonding pattern. The relative stabilities of ANA⋅RNA vs. HNA⋅RNA (HNA=D ‐hexitol nucleic acid without 3′‐OH group) can be explained by differences in restricted movements, H‐bonds, and solvation effects.     

Effects of Six‐Membered Carbohydrate Rings on Structure,Stability, and Kinetics of G‐Quadruplexes

We have evaluated the conformational, thermal, and kinetic properties of d(TGGGGT) analogues with one or five of the ribose nucleotides replaced with the carbohydrate residues hexitol nucleic acid (HNA), cyclohexenyl nucleic acid (CeNA), or altritol nucleic acid (ANA). All of the modified oligonucleotides formed G‐quadruplexes, but substitution with the six‐membered rings resulted in a mixture of G‐quadruplex structures. UV and CD melting analyses showed that the structure formed by d(TGGGGT) modified with HNA was stabilized whereas that modified with CeNA was destabilized, relative to the structure formed by the unmodified oligonucleotide. Substitution at the fourth base of the G‐tract with ANA resulted in a greater stabilization effect than substitution at the first G residue; substitution with five ANA residues resulted in significant stabilization of the G‐quadruplex. A single substitution with CeNA at the first base of the G‐tract or five substitutions with HNA resulted in striking deceleration or acceleration of G‐quadruplex formation, respectively. Our results shed light on the effect of the sugar moiety on the properties of G‐quadruplex structures.     

Solution structure of a HNA-RNA hybrid

BACKGROUND: Synthetic nucleic acid analogues with a conformationally restricted sugar-phosphate backbone are widely used in antisense strategies for biomedical and biochemical applications. The modified backbone protects the oligonucleotides against degradation within the living cell, which allows them to form stable duplexes with sequences in target mRNAs with the aim of arresting their translation. The biologically most active antisense oligonucleotides also trigger cleavage of the target RNA through activation of endogenous RNase H. Systematic studies of synthetic oligonucleotides have also been conducted to delineate the origin of the chirality of DNA and RNA that are both composed of D-nucleosides. RESULTS: Hexitol nucleic acids (HNA) are the first example of oligonucleotides with a six-membered carbohydrate moiety that can bind strongly and selectively to complementary RNA oligomers. We present the first high resolution nuclear magnetic resonance structure of a HNA oligomer bound to a complementary RNA strand. The HNA-RNA complex forms an anti-parallel heteroduplex and adopts a helical conformation that belongs to the A-type family. Possibly, due to the rigidity of the rigid chair conformation of the six-membered ring both the HNA and RNA strand in the duplex are well defined. The observed absence of end-fraying effects also indicate a reduced conformational flexibility of the HNA-RNA duplex compared to canonical dsRNA or an RNA-DNA duplex. CONCLUSIONS: The P-P distance across the minor groove, which is close to A-form, and the rigid conformation of the HNA-RNA complex, explain its resistance towards degradation by Rnase H. The A-form character of the HNA-RNA duplex and the reduced flexibility of the HNA strand is possibly responsible for the stereoselectivity of HNA templates in non-enzymatic replication of oligonucleotides, supporting the theory that nucleosides with six-membered rings could have existed at some stage in molecular evolution.     

Crystal structure of double helical hexitol nucleic acids

A huge variety of chemically modified oligonucleotide derivatives has been synthesized for possible antisense applications. One such derivative, hexitol nucleic acid (HNA), is a DNA analogue containing the standard nucleoside bases, but with a phosphorylated 1',5'-anhydrohexitol backbone. Hexitol nucleic acids are some of the strongest hybridizing antisense compounds presently known, but HNA duplexes are even more stable. We present here the first high-resolution structure of a double helical nucleic acid with all sugars being hexitols. Although designed to have a restricted conformational flexibility, the hexitol oligomer h(GTGTACAC) is able to crystallize in two different double helical conformations. Both structures display a high x-displacement, normal Watson-Crick base pairing, similar base stacking patterns, and a very deep major groove together with a minor groove with increased hydrophobicity. One of the conformations displays a major groove which is wide enough to accommodate a second HNA double helix resulting in the formation of a double helix of HNA double helices. Both structures show most similarities with the A-type helical structure, the anhydrohexitol chair conformation thereby acting as a good mimic for the furanose C3'-endo conformation observed in RNA. As compared to the quasi-linear structure of homo-DNA, the axial position of the base in HNA allows efficient base stacking and hence double helix formation.     

Reinforced HNA backbone hydration in the crystal structure of a decameric HNA/RNA hybrid

The crystal structure of a decameric HNA/RNA (HNA = 2',3'-dideoxy-1',5'-anhydro-d-arabinohexitol nucleic acid) hybrid with the RNA sequence 5'-GGCAUUACGG-3' is the first crystal structure of a hybrid duplex between a naturally occurring nucleic acid and a strand, which is fully modified to contain a six-membered ring instead of ribose. The presence of four duplex helices in the asymmetric unit allows for a detailed discussion of hydration, which revealed a tighter spinelike backbone hydration for the HNA- than for the RNA-strands. The reinforced backbone hydration is suggested to contribute significantly to the exceptional stability of HNA-containing duplexes and might be one of the causes for the evolutionary preference for ribose-derived nucleic acids.     

Efficient transfer of information from hexitol nucleic acids to RNA during nonenzymatic oligomerization.

Hexitol nucleic acids (HNAs) are DNA analogues that contain the standard nucleoside bases attached to a phosphorylated 1,5-anhydrohexitol backbone. We find that HNAs support efficient information transfer in nonensymatic template-directed reactions. HNA heterosequences appeared to be superior to the corresponding DNA heterosequences in facilitating synthesis of complementary oligonucleotides from nucleoside-5'-phosphoro-2-methyl imidazolides.     

Theoretical analysis of antisense duplexes: determinants of the RNase H susceptibility

The structure and dynamic properties of different antisense related duplexes (DNA x RNA, 2'O-Me-DNA x RNA, 2'F-ANA x RNA, C5(Y)-propynyl-DNA x RNA, ANA x RNA, and control duplexes DNA x DNA and RNA x RNA) have been determined by means of long molecular dynamics simulations (covering more than 0.5 micros of fully solvated unrestrained MD simulation). The massive analysis presented here allows us to determine the subtle differences between the different duplexes, which in all cases pertain to the same structural family. This analysis provides information on the molecular determinants that allow RNase H to recognize and degrade some of these duplexes, whereas others with apparently similar conformations are not affected. Subtle structural and deformability features define the key properties used by RNase H to discriminate between duplexes.     

Structural and binding study of modified siRNAs with the Argonaute 2 PAZ domain by NMR spectroscopy

By using high-resolution NMR spectroscopy, the structures of a natural short interfering RNA (siRNA) and of several altritol nucleic acid (ANA)-modified siRNAs were determined. The interaction of modified siRNAs with the PAZ domain of the Argonaute 2 protein of Drosophila melanogaster was also studied. The structures show that the modified siRNA duplexes (ANA/RNA) adopt a geometry very similar to the naturally occurring A-type siRNA duplex. All ribose residues, except for the 3' overhang, show 3'-endo conformation. The six-membered altritol sugar in ANA occurs in a chair conformation with the nucleobase in an axial position. In all siRNA duplexes, two overhanging nucleotides at the 3' end enhance the stability of the first neighboring base pair by a stacking interaction. The first overhanging nucleotide has a rather fixed position, whereas the second overhanging nucleotide shows larger flexibility. NMR binding studies of the PAZ domain with ANA-modified siRNAs demonstrate that modifications in the double-stranded region of the antisense strand have some small effects on the binding affinity as compared with the unmodified siRNA. Modification of the 3' overhang with thymidine (dTdT) residues shows a sixfold increase in the binding affinity compared with the unmodified siRNA (relative binding affinity of 17% compared with dTdT-modified overhang), whereas modification of the 3' overhang with ANA largely decreases the binding affinity.     

Multilabeled pyrene-functionalized 2'-amino-LNA probes for nucleic acid detection in homogeneous fluorescence assays

Homogeneous fluorescence assays for detection of nucleic acids are widely used in biological sciences. Typically, probes such as molecular beacons that rely on distance-dependent fluorescence quenching are used for such assays. Less attention has been devoted to tethering a single kind of fluorophores to oligonucleotides and exploiting hybridization-induced modulation of fluorescence intensity for nucleic acid detection. Herein, thermal denaturation experiments and fluorescence properties of oligodeoxyribonucleotides containing one or more 2'-N-(pyren-1-yl)carbonyl-2'-amino-LNA monomer(s) X are described. These pyrene-functionalized 2'-amino-LNAs display large increases in thermal stability against DNA/RNA complements with excellent Watson-Crick mismatch discrimination. Upon duplex formation of appropriately designed 2'-N-(pyren-1-yl)carbonyl-2'-amino-LNA probes and complementary DNA/RNA, intensive fluorescence emission with quantum yields between 0.28 and 0.99 are observed. Quantum yields of such magnitudes are unprecedented among pyrene-labeled oligonucleotides. Molecular modeling studies suggest that the dioxabicyclo[2.2.1]heptane skeleton and amide linkage of monomer X fix the orientation of the pyrene moiety in the minor groove of a nucleic acid duplex. Interactions between pyrene and nucleobases, which typically lead to quenching of fluorescence, are thereby reduced. Duplexes between multiple modified probes and DNA/RNA complements exhibit additive increases in fluorescence intensity, while the fluorescence of single stranded probes becomes increasingly quenched. Up to 69-fold increase in fluorescence intensity (measured at lambda(em) = 383 nm) is observed upon hybridization to DNA/RNA. The emission from duplexes of multiple modified probes and DNA/RNA at concentrations down to less than 500 nM can easily be seen by the naked eye using standard illumination intensities.     

NMR solution structure of an oligonucleotide hairpin with a 2'F-ANA/RNA stem: implications for RNase H specificity toward DNA/RNA hybrid duplexes.

The first structure of a 2'-deoxy-2'-fluoro-D-arabinose nucleic acid (2'F-ANA)/RNA duplex is presented. We report the structural characterization by NMR spectroscopy of a small hybrid hairpin, r(GGAC)d(TTCG)2'F-a(GTCC), containing a 2'F-ANA/RNA stem and a four-residue DNA loop. Complete (1)H, (13)C, (19)F, and (31)P resonance assignments, scalar coupling constants, and NOE constraints were obtained from homonuclear and heteronuclear 2D spectra. In the chimeric duplex, the RNA strand adopts a classic A-form structure having C3' endo sugar puckers. The 2'F-ANA strand is neither A-form nor B-form and contains O4' endo sugar puckers. This contrasts strongly with the dynamic sugar conformations previously observed in the DNA strands of DNA/RNA hybrid duplexes. Structural parameters for the duplex, such as minor groove width, x-displacement, and inclination, were intermediate between those of A-form and B-form duplexes and similar to those of DNA/RNA duplexes. These results rationalize the enhanced stability of 2'F-ANA/RNA duplexes and their ability to elicit RNase H activity. The results are relevant for the design of new antisense drugs based on sugar-modified nucleic acids.     

The structure of a TNA-TNA complex in solution: NMR study of the octamer duplex derived from alpha-(L)-threofuranosyl-(3'-2')-CGAATTCG

TNA (alpha-( l)-threofuranosyl-(3'-2') nucleic acid) is a nucleic acid in which the ribofuranose building block of the natural nucleic acid RNA is replaced by the tetrofuranose alpha-( l)-threose. This shortens the repetitive unit of the backbone by one bond as compared to the natural systems. Among the alternative nucleic acid structures studied so far in our laboratories in the etiological context, TNA is the only one that exhibits Watson-Crick pairing not only with itself but also with DNA and, even more strongly, with RNA. Using NMR spectroscopy, we have determined the structure of a duplex consisting entirely of TNA nucleotides. The TNA octamer (3'-2')-CGAATTCG forms a right-handed double helix with antiparallel strands paired according to the Watson-Crick mode. The dominant conformation of the sugar units has the 2'- and 3'-phosphodiester substituents in quasi-diaxial position and corresponds to a 4'-exo puckering. With 5.85 A, the average sequential P i -P i+1 distances of TNA are shorter than for A-type DNA (6.2 A). The helix parameters, in particular the slide and x-displacement, as well as the shallow and wide minor groove, place the TNA duplex in the structural vicinity of A-type DNA and RNA.     

Determination of nucleic acids in acidic medium by enhanced light scattering of large particles

The large particle light scattering technique was first developed as a sensitive and convenient analysis method for microdetermination of nucleic acids by using a common spectrofluorometer. In 0.1 mol l(-1) HCl, H(2)SO(4), or HNO(3) solution, the nucleic acids can aggregate to form large particles whose dimensions are comparable to the wavelength of UV-Vis light. The large particles can result in very strong light scattering which is well proportional to the concentration of nucleic acids in the range of 0.06-100.0 mug ml(-1) for calf thymus DNA, 0.05-60.0 mug ml(-1) for fish sperm DNA, and 0.6-90.0 mug ml(-1) for yeast RNA. The detection limits (3sigma) are 18.0 ng ml(-1) for calf thymus DNA, 16.0 ng ml(-1) for fish sperm DNA, and 57.6 ng ml(-1) for yeast RNA, respectively. Six synthetic samples were determined with satisfactory results.     

Solution Structure of a Hexitol Nucleic Acid Duplex with Four Consecutive T⋅T Base Pairs

The structure of the hexitol nucleic acid (HNA) h(GCGCTTTTGCGC) was determined by NMR spectroscopy. This unnatural nucleic acid was developed as a mimic for A‐RNA. In solution, the studied sequence is forming a symmetric double‐stranded structure with four central consecutive T⋅T wobble pairs flanked by G⋅C Watson‐Crick base pairs. The stem regions adopt an A‐type helical structure. Discrete changes in backbone angles are altering the course of the helix axis in the internal loop region. Two H‐bonds are formed in each wobble pair, and base stacking is preserved in the duplex, explaining the stability of the duplex. This structure elucidation provides information about the influence of a (T)₄ fragment on local helix geometries as well as on the nature of the T⋅T mismatch base pairing in a TTTT tract.     

Determination of nucleic acids with a near infrared cyanine dye using resonance light scattering technique

A new method for the determination of nucleic acids has been developed based on the enhancement effect of resonance light scattering (RLS) with a cationic near infrared (NIR) cyanine dye. Under the optimal conditions, the enhanced RLS intensity at 823 nm is proportional to the concentration of nucleic acids in the range of 0-400 ng mL-1 for both calf thymus DNA (CT DNA) and fish sperm DNA (FS DNA), 0-600 ng mL-1 for snake ovum RNA (SO RNA). The detection limits are 3.5 ng mL-1, 3.4 ng mL-1 and 2.9 ng mL-1 for CT DNA, FS DNA and SO RNA, respectively. Owing to performing in near infrared region, this method not only has high sensitivity endowed by RLS technique but also avoids possible spectral interference from background. It has been applied to the determination of nucleic acids in synthetic and real samples and satisfactory results were obtained.     

DNA analysis by mass spectrometry-past, present and future

The analysis of deoxyribose nucleic acid (DNA) by mass spectrometry (MS) has evolved to where it can be used to analyze most known types of DNA and ribose nucleic acid (RNA) situations. It can efficiently deal with the analysis of DNA polymorphisms, sequences, haplotypes, human leukocyte antigen (HLA) typing, DNA methylation and RNA expression. Implementations of MS for these forms of DNA analyses are reviewed. The use of DNA analysis by MS is compared with competing technologies. Finally, an overview is given of worthwhile applications where the know-how gained so far could be used for future developments.     

Crystal structure of a B-form DNA duplex containing (L)-alpha-threofuranosyl (3'-->2') nucleosides: a four-carbon sugar is easily accommodated into the backbone of DNA

(L)-alpha-Threofuranosyl-(3'-->2')-oligonucleotides (TNA) containing vicinally connected phosphodiester linkages undergo informational base pairing in an antiparallel strand orientation and are capable of cross-pairing with RNA and DNA. TNA is derived from a sugar containing only four carbon atoms and is one of the simplest potentially natural nucleic acid alternatives investigated thus far in the context of a chemical etiology of nucleic acid structure. Compared to DNA and RNA that contain six covalent bonds per repeating nucleotide unit, TNA contains only five. We have determined the atomic-resolution crystal structure of the B-form DNA duplex [d(CGCGAA)Td(TCGCG)](2) containing a single (L)-alpha-threofuranosyl thymine (T) per strand. In the modified duplex base stacking interactions are practically unchanged relative to the reference DNA structure. The orientations of the backbone at the TNA incorporation sites are slightly altered in order to accommodate fewer atoms and covalent bonds. The conformation of the threose is C4'-exo with the 2'- and 3'-substituents assuming quasi-diaxial orientation.     

Single-molecule studies on DNA and RNA.

DNA and RNA are the most individual molecules known. Therefore, single-molecule experiments with these nucleic acids are particularly useful. This review reports on recent experiments with single DNA and RNA molecules. First, techniques for their preparation and handling are summarised including the use of AFM nanotips and optical or magnetic tweezers. As important detection techniques, conventional and near-field microscopy as well as fluorescence resonance energy transfer (FRET) and fluorescence correlation spectroscopy (FCS) are touched on briefly. The use of single-molecule techniques currently includes force measurements in stretched nucleic acids and in their complexes with binding partners, particularly proteins, and the analysis of DNA by restriction mapping, fragment sizing and single-molecule hybridisation. Also, the reactions of RNA polymerases and enzymes involved in DNA replication and repair are dealt with in some detail, followed by a discussion of the transport of individual nucleic acid molecules during the readout and use of genetic information and during the infection of cells by viruses. The final sections show how the enormous addressability in nucleic acid molecules can be exploited to construct a single-molecule field-effect transistor and a walking single-molecule robot, and how individual DNA molecules can be used to assemble a single-molecule DNA computer.     

Improving metal ion specificity during in vitro selection of catalytic DNA

Metal ions play important roles in both the structure and function of catalytic DNA and RNA. While most natural catalytic RNA molecules (ribozymes) are active in solutions containing Mg(2+), in vitro selection makes it possible to search for new catalytic DNA/RNA that are specific for other metal ions. However, previous studies have indicated that the in vitro selection protocols often resulted in catalytic DNA/RNA that were equally active or sometimes even more active with metal ions other than the metal ion of choice. To improve the metal ion specificity during the in vitro selection process, we implemented a negative selection strategy where the nucleic acid pool was subjected to a solution containing competing metal ions. As a result, those nucleic acids that were active with those metal ions are discarded. To demonstrate the effectiveness of the negative selection strategy, we carried out two parallel in vitro selections of Co(2+)-dependent catalytic DNA. When no negative selection was used in the selection process, the resulting catalytic DNA molecules were more active in solutions of Zn(2+) and Pb(2+) than in Co(2+). On the other hand, when the negative selection steps were inserted between the normal positive selection steps, the resulting catalytic DNA molecules were much more active with Co(2+) than in other metal ions including Zn(2+) and Pb(2+). These results suggest strongly that in vitro selection can be used to obtain highly active and specific transition metal ion-dependent catalytic DNA/RNA, which hold great promise as versatile and efficient endonucleases as well as sensitive and selective metal ion sensors.     

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.