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.

Achiral, acyclic nucleic acids: synthesis and biophysical studies of a possible prebiotic polymer.

The search for prebiotic, nucleic acid precursors is, at its best, a speculative undertaking. Given the complex structure of RNA, it is not very likely that RNA was the first information system in the universe and thus finding possible precursor/s i.e. pre-RNA remains an open challenge. We, in this paper, have tried to construct nucleic acid polymers with a simple acyclic, achiral backbone. Such a linear, achiral backbone may have been formed from simple monomers that may have existed in the "prebiotic soup". We have shown that such polymers are capable of identifying the complementary "other self" and thus forming a potential system for information storage and transmission. This study thus involves investigation of nucleic acid analogues with a modified backbone that are likely to have formed in the prebiotic setting.

Imidazo[4,5-c]pyridines inhibit the in vitro replication of the classical swine fever virus and target the viral polymerase.

Selective inhibitors of the replication of the classical swine fever virus (CSFV) may have the potential to control the spread of the infection in an epidemic situation. We here report that 5-[(4-bromophenyl)methyl]-2-phenyl-5H-imidazo[4,5-c]pyridine (BPIP) is a highly potent inhibitor of the in vitro replication of CSFV. The compound resulted in a dose-dependent antiviral effect in PK(15) cells with a 50% effective concentration (EC(50)) for the inhibition of CSFV Alfort(187) (subgroup 1.1) of 1.6+/-0.4 microM and for CSFV Wingene (subgroup 2.3) 0.8+/-0.2 microM. Drug-resistant virus was selected by serial passage of the virus in increasing drug-concentration. The BPIP-resistant virus (EC(50): 24+/-4.0 microM) proved cross-resistant with VP32947 [3-[((2-dipropylamino)ethyl)thio]-5H-1,2,4-triazino[5,6-b]indole], an unrelated earlier reported selective inhibitor of pestivirus replication. BPIP-resistant CSFV carried a T259S mutation in NS5B, encoding the RNA-dependent RNA-polymerase (RdRp). This mutation is located near F224, a residue known to play a crucial role in the antiviral activity of BPIP against bovine viral diarrhoea virus (BVDV). The T259S mutation was introduced in a computational model of the BVDV RdRp. Molecular docking of BPIP in the BVDV polymerase suggests that T259S may have a negative impact on the stacking interaction between the imidazo[4,5-c]pyridine ring system of BPIP and F224.

Polymerase-catalyzed synthesis of DNA from phosphoramidate conjugates of deoxynucleotides and amino acids.

Some selected amino acids, in particular L-aspartic acid (L-Asp) and L-histidine (L-His), can function as leaving group during polymerase-catalyzed incorporation of deoxyadenosine monophosphate (dAMP) in DNA. Although L-Asp-dAMP and L-His-dAMP bind, most probably, in a different way in the active site of the enzyme, aspartic acid and histidine can be considered as mimics of the pyrophosphate moiety of deoxyadenosine triphosphate. L-Aspartic acid is more efficient than D-aspartic acid as leaving group. Such P-N conjugates of amino acids and deoxynucleotides provide a novel experimental ground for diversifying nucleic acid metabolism in the field of synthetic biology.

RNA as a target for drug design, the example of Tat-TAR interaction.

One of the new targets in the battle against HIV-1 infection is the interaction between the viral transactivator and the transactivation response (TAR) element, which is necessary for HIV-1 replication. After an overview of the most recent structural studies of the Tat-TAR system, new TAR-targeted inhibitors are presented in several classes: antisense oligonucleotides, cationic peptides, intercalators and a large class of small RNA binding molecules. The method of library screening of RNA binding ligands in the search for new inhibitors is explained in detail. Inhibition of Tat-TAR interaction is considered as a realistic approach to develop new anti-HIV compounds. The RNA binding molecules in this review also demonstrate that the development of drugs that target RNA will become a feasible goal and that such compounds will be added in the future to the therapeutic arsenal to combat several diseases.

Translational properties of mHNA, a messenger RNA containing anhydrohexitol nucleotides.

Short messenger RNAs (mRNAs) with hexitol residues in two codons were constructed and their properties were studied in an Escherichia coli in vitro translation system. The replacement of the natural ribonucleotides of mRNA in the AUG start codon and the UUC second codon by hexitol nucleotides did not influence the main steps of translation, as indicated by the same level of binding of mRNA with or without hexitol residues under P-site conditions, and the same yield of tRNA binding to the P- and A-sites. Moreover, both peptide formation and translocation took place on mRNAs with hexitol residues. The presence of an A-type messenger hexitol nucleic acid (mHNA)-transfer RNA (tRNA) duplex is important for efficient translation and the 2'-OH function in mRNA is not necessary for binding and movement through the ribosome. Groove shape recognition of the codon-anticodon complex, more than hydrogen-bond interactions of ribose residues in mRNA, is an important factor for correct translation.

(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.

Cyclohexene nucleic acids (CeNA) form stable duplexes with RNA and induce RNase H activity.

Cyclohexene nucleic acids (CeNA) were synthesized using classical phosporamidite chemistry. Incorporation of a cyclohexene nucleo-side in a DNA chain leads to an increase in stability of the DNA/RNA duplex. CeNA is stable against degradation in serum. A CeNA/RNA hybrid is able to activate E. Coli RNase H. resulting in cleavage of the RNA strand.

Reverse transcriptase incorporation of 1,5-anhydrohexitol nucleotides.

Several reverse transcriptases were studied for their ability to accept anhydrohexitol triphosphates, having a conformationally restricted six-membered ring, as substrate for template-directed synthesis of HNA. It was found that AMV, M-MLV, M-MLV (H(-)), RAV2 and HIV-1 reverse transcriptases were able to recognise the anhydrohexitol triphosphate as substrate and to efficiently catalyse the incorporation of one non-natural anhydrohexitol nucleotide opposite a natural complementary nucleotide. However, only the dimeric enzymes, the RAV2 and HIV-1 reverse transcriptases, seemed to be able to further extend the primer with another anhydrohexitol building block. Subsequently, several HIV-1 mutants (4xAZT, 4xAZT/L100I, L74V, M184V and K65A) were likewise analysed, resulting in selection of K65A and, in particular, M184V as the most succesful mutant HIV-1 reverse transcriptases capable of elongating a DNA primer with several 1,5-anhydrohexitol adenines in an efficient way. Results of kinetic experiments in the presence of this enzyme revealed that incorporation of one anhydrohexitol nucleotide of adenine or thymine gave an increased (for 1,5-anhydrohexitol-ATP) and a slightly decreased (for 1,5-anhydrohexitol-TTP) K(m) value in comparison to that of their natural counterparts. However, no more than four analogues could be inserted under the experimental conditions required for selective incorporation. Investigation of incorporation of the altritol anhydrohexitol nucleotide of adenine in the presence of M184V and Vent (exo(-)) DNA polymerase proved that an adjacent hydroxyl group on C3 of 1,5-anhydrohexitol-ATP has a detrimental effect on the substrate activity of the six-ring analogue. These results could be rationalised based on the X-ray structure of HIV-1 reverse transcriptase.

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.

The cyclohexene ring system as a furanose mimic: synthesis and antiviral activity of both enantiomers of cyclohexenylguanine.

Both enantiomers of cyclohexenylguanine were synthesized in a stereospecific way starting from the same starting material: R-(-)-carvone. Both compounds showed potent and selective anti-herpesvirus activity (HSV-1, HSV-2, VZV, CMV). The binding of both cyclohexene nucleosides in the active site of HSV-1 thymidine kinase was investigated, and a model for the binding of both enantiomers is proposed. The amino acids involved in binding of the optical antipodes are the same, but the interaction energy of both enantiomers is slightly different. This may be attributed to the interaction of the secondary hydroxyl function of the nucleoside analogues with Glu-225. Structural analysis has demonstrated the flexibility of the cyclohexenyl system, and this may be considered as an important conformational characteristic explaining the potent antiviral activity.

Experimental and theoretical study of electrostatic effects on the isoelectric pH and the pKa of the catalytic residue His-102 of the recombinant ribonuclease from Bacillus amyloliquefaciens (barnase).

Barnase, the guanine specific ribonuclease of Bacillus amyloliquefaciens, was subjected to mutations in order to alter the electrostatic properties of the enzyme. Ser-85 was mutated into Glu with the goal to introduce an extra charge in the neighborhood of His-102. A double mutation (Ser-85-Glu and Asp-86-Asn) was introduced with the same purpose but without altering the global charge of the enzyme. A similar set of mutations was made using Asp at position 85. For all mutants the pI was determined using the technique of isoelectric focusing and calculated on the basis of the Tanford-Kirkwood theory. When Glu was used to replace Ser-85, the correlation between the experimental and the calculated values was perfect. However, in the Ser-85-Asp mutant, the experimental pI drop is bigger than the calculated one, and in the double mutant (Ser-85-Asp and Asp-86-Asn) the compensation is not achieved. The effect of the mutations on the pKa of His-102 can be determined from the pH dependence of the kcat/KM for the hydrolysis of dinucleotides, e.g., GpC. The effect can also be calculated using the the method of Honig. In this case the agreement is very good for the Glu-mutants and the single Asp-mutant, but less for the double Asp-mutant. The global stability of the Asp-mutants is, however, the same as the wild type, as shown by stability studies using urea denaturation. Molecular dynamics calculations, however, show that in the double Asp-mutant His-102 (H+) swings out of its pocket to make a hydrogen bridge with Gin-104 which should cause an additional pKa rise. The effect of the Glu-mutations was also tested on all the kinetic parameters for GpC and the cyclic intermediate G > p at pH 6.5, for RNA at pH 8.0, and for poly(A) at pH 6.2. The effect of the mutations is rather limited for the dinucleotide and the cyclic intermediate, but a strong increase of the KM is observed in the case of the single mutant (extra negative charge) with polymeric substrates. These results indicate that the extra negative charge has a strong destabilizing effect on the binding of the polymeric substrates in the ground state and the transition state complex. A comparison with the structure of bound tetranucleotides (Buckle, A.M. and Fersht, A.R., Biochemistry 33:1644-1653, 1994) shows that the extra negative charge points towards the P2 site.

Determination of the excited-state lifetimes of the tryptophan residues in barnase, via multifrequency phase fluorometry of tryptophan mutants.

A multifrequency phase fluorometric study is described for wild-type barnase and engineered mutant proteins in which tryptophan residues have been replaced by less fluorescent residues which do not interfere with the determination of the tryptophan emission spectra and lifetimes. The lifetimes of the three tryptophans in the wild-type protein have been resolved. Trp-35 has a single fluorescence lifetime, which varies in the different proteins between 4.3 and 4.8 ns and is pH-independent between pH 5.8 and 8.9. Trp-71 and Trp-94 behave as an energy-transfer couple with both forward and reverse energy transfer. The couple shows two fluorescence lifetimes: 2.42 (+/-0.2) and 0.74 (+/-0.1) ns at pH 8.9, and 0.89 (+/-0.05) and 0.65 (+/-0.05) ns at pH 5.8. In the mutant Trp-94----Phe the lifetime of Trp-71 is 4.73 (+/-0.008) ns at high pH and 4.70 (+/-0.004) ns at low pH. In the mutant Trp-71----Tyr, the lifetime of Trp-94 is 1.57 (+/-0.01) ns at high pH and 0.82 (+/-0.025) ns at low pH. From these lifetimes, one-way energy-transfer efficiencies can be calculated according to Porter [Porter, G.B. (1972) Theor. Chim. Acta 24, 265-270]. At pH 8.9, a 71% efficiency was found for forward transfer (from Trp-71 to Trp-94) and 36% for reverse transfer. At pH 5.8 the transfer efficiency was 86% for forward and 4% for reverse transfer (all +/-2%). These transfer efficiencies correspond fairly well with the ones calculated according to the theory of Förster [Förster, T. (1948) Ann. Phys. (Leipzig) 2, 55-75].(ABSTRACT TRUNCATED AT 250 WORDS)