NMR study on the interaction of the conserved CREX 'stem-loop' in the Hepatitis E virus genome with a naphthyridine-based ligand.

A 2-amino-1,8-naphthyridine derivative that is described to bind single guanine bulges in RNA-DNA and RNA-RNA duplexes was synthesized and its interaction with the single G bulge in the conserved CREX of the Hepatitis E Virus (HEV) genome was explored by NMR and molecular modeling. Results indicate that the ligand intercalates in the internal loop, though none of the expected hydrogen bonds with the single G in the bulge could be demonstrated.

Contribution of dihydrouridine in folding of the D-arm in tRNA.

Posttranscriptional modifications of transfer RNAs (tRNAs) are proven to be critical for all core aspects of tRNA function. While the majority of tRNA modifications were discovered in the 1970s, their contribution in tRNA folding, stability, and decoding often remains elusive. In this work an NMR study was performed to obtain more insight in the role of the dihydrouridine (D) modification in the D-arm of tRNAi(Met) from S. pombe. While the unmodified oligonucleotide adopted several undefined conformations that interconvert in solution, the presence of a D nucleoside triggered folding into a hairpin with a stable stem and flexible loop region. Apparently the D modification is required in the studied sequence to fold into a stable hairpin. Therefore we conclude that D contributes to the correct folding and stability of D-arm in tRNA. In contrast to what is generally assumed for nucleic acids, the sharp 'imino' signal for the D nucleobase at 10 ppm in 90% H2O is not indicative for the presence of a stable hydrogen bond. The strong increase in pKa upon loss of the aromatic character in the modified nucleobase slows down the exchange of its 'imino' proton significantly, allowing its observation even in an isolated D nucleoside in 90% H2O in acidic to neutral conditions.

Structural biology in drug development.

Structural biologists focus on the structure of biomolecules. Several techniques are available to study the structure adopted by a biomolecule and unravel how this structure is related to its constitution and function. For their biological role in a functioning cell or organism, biomolecules interact with each other and/or rather small molecules in their environment. Drugs can exploit interaction with biomolecules to manipulate their biological function to obtain a therapeutic effect. Structure determination of biomolecules that (could) serve as therapeutic target is an important starting point in rational drug design. Once the structure of a biological target is known, a potential binding site for drugs and possible interactions at this site have to be identified. In the stage of drug design this information is a valuable input for modeling experiments. They can virtually scan libraries of compounds by docking them into the binding site. This strategy ranks potential ligands that can be chemically modified to optimize their interaction at the binding site ('lead optimization') in order to improve affinity and selectivity for the biomolecular target. Modeling can also be used to virtually 'build' new molecules starting from possible interactions and shape of the target binding site ('de novo design'). Structural biology can contribute in different stages of drug development to direct the process or optimize existing compounds.

(D)- and (L)-cyclohexenyl-G, a new class of antiviral agents: synthesis, conformational analysis, molecular modeling, and biological activity.

(D)- and (L)-cyclohexeneyl-G were synthesized enantioselectively starting from (R)-carvone. Both show potent and selective anti-herpesvirus activity (HSV-1, HSV-2, VZV, CMV). Molecular modeling demonstrates that both isomers are bound in the active site of HSV-1 thymidine kinase in a high-energy conformation with the base moiety orienting in an equatorial position. It is believed that the flexibility of the cyclohexene ring is essential for their antiviral activity.

RNase H mediated cleavage of RNA by cyclohexene nucleic acid (CeNA).

Cyclohexene nucleic acid (CeNA) forms a duplex with RNA that is more stable than a DNA-RNA duplex (DeltaTm per modification: +2 degrees C). A cyclohexenyl A nucleotide adopts a 3'-endo conformation when introduced in dsDNA. The neighbouring deoxynucleotide adopts an O4'-endo conformation. The CeNA:RNA duplex is cleaved by RNase H. The Vmax and Km of the cleavage reaction for CeNA:RNA and DNA:RNA is in the same range, although the kcat value is about 600 times lower in the case of CeNA:RNA.

Alpha-homo-DNA and RNA form a parallel oriented non-A, non-B-type double helical structure.

Cross-talking between nucleic acids is a prerequisite for information transfer. The absence of observed base pairing interactions between pyranose and furanose nucleic acids has excluded considering the former type as a (potential) direct precursor of contemporary RNA and DNA. We observed that alpha-pyranose oligonucleotides (alpha-homo-DNA) are able to hybridize with RNA and that both nucleic acid strands are parallel oriented. Hybrids between alpha-homo-DNA and DNA are less stable. During the synthesis of alpha-homo-DNA we observed extensive conversion of N6-benzoyl-5-methylcytosine into thymine under the usual deprotection conditions of oligonucleotide synthesis. Alpha-homo-DNA:RNA represents the first hybridization system between pyranose and furanose nucleic acids. The duplex formed between alpha-homo-DNA and RNA was investigated using CD, NMR spectroscopy, and molecular modeling. The general rule that orthogonal orientation of base pairs prevents hybridization is infringed. NMR experiments demonstrate that the base moieties of alpha-homo-DNA in its complex with RNA, are equatorially oriented and that the base moieties of the parallel RNA strand are pseudoaxially oriented. Modeling experiments demonstrate that the duplex formed is different from the classical A- or B-type double stranded DNA. We observed 15 base pairs in a full helical turn. The average interphosphate distance in the RNA strand is 6.2 A and in the alpha-homo-DNA strand is 6.9 A. The interstrand P-P distance is much larger than found in the typical A- and B-DNA. Most helical parameters are different from those of natural duplexes.

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.

Studies on disaccharide nucleoside synthesis. Mechanism of the formation of trisaccharide purine nucleosides.

The unexpected formation of trisaccharide nucleosides during synthesis of purine 5'-O-beta-D-ribofuranosylnucleosides in the presence of Lewis acids was observed.

Base pairing of anhydrohexitol nucleosides with 2,6-diaminopurine, 5-methylcytosine and uracil asbase moiety.

Hexitol nucleic acids (HNAs) with modified bases (5-methylcytosine, 2,6-diaminopurine or uracil) were synthesized. The introduction of the 5-methylcytosine base demonstrates that N -benzoylated 5-methylcytosyl-hexitol occurs as the imino tautomer. The base pairing systems (G:CMe, U:D, T:D and U:A) obey Watson-Crick rules. Substituting hT for hU, hCMefor hC and hD for hA generally leads to increased duplex stability. In a single case, replacement of hC by hCMedid not result in duplex stabilization. This sequence-specific effect could be explained by the geometry of the model duplex used for carrying out the thermal stability study. Generally, polypurine HNA sequences give more stable duplexes with their RNA complement than polypyrimidine HNA sequences. This observation supports the hypothesis that, besides changes in stacking pattern, the difference in conformational stress between purine and pyrimidine nucleosides may contribute to duplex stability. Introduction of hCMeand hD in HNA sequences further increases the potential of HNA to function as a steric blocking agent.