Assay for evaluating ribonuclease H-mediated degradation of RNA-antisense oligonucleotide duplexes.

Ribonucleases H are complex enzymes whose functions are not clearly understood, further compounded by the fact that multiple forms of the enzyme are present in various organisms. They are known to recognize and degrade the ribonucleic acid (RNA) strand of numerous deoxyribonucleic acid (DNA)-RNA duplex substrates, and so may provide a unique mode of therapeutic intervention at the genetic level of virtually any disease. We have therefore set out detailed procedures for conducting routine assays with almost any one of this family of enzymes by a straightforward assay aimed at identifying novel enzyme-activating antisense oligonucleotides (AONs). The procedures described herein should enable easy identification of potent AON molecules, provided that the RNA is appropriately labeled for subsequent visualization following the guidelines set forth in this protocol.

Diversity-oriented solid-phase synthesis and biological evaluation of oligonucleotide hairpins as HIV-1 RT RNase H inhibitors.

The inhibitory potencies of several hairpins comprising DNA, RNA and 2',5'-linked RNA segments were assessed against the RNase H activity of the human immunodeficiency virus reverse transcriptase (HIV-1 RT), an indispensable enzyme for HIV genomic replication. The hairpin library was constructed via diversity-oriented nucleic-acid synthesis (DONAS), an approach inspired from traditional split-pool synthesis. DONAS provided access to an array of oligonucleotide hairpins possessing distinct conformational, structural and biological properties. The inhibitory potency of these compounds was highly specific towards HIV-1 RT RNase H and strongly depended on the structure of both the stem and tetraloop. Hairpins that have an overall A-type geometry are better inhibitors of RNase H activity than hairpins with 'intermediate' or B-type conformations, although interestingly, the inhibitory activity is quite sensitive to the nucleotide sequence in both the stem and loop regions of the hairpin. The most potent hairpins bear a 3',5'-linked rather than 2',5'-linked RNA loop, but the latter is necessary for activity of hairpins consisting of DNA stems. Inhibitory activity was essentially independent of hairpin thermal stability. The potent hairpins also demonstrated high nuclease resistance in biological media, particularly those bearing a 2',5'-linked tetraloop. These studies collectively bring into light a new class of nucleic acid aptamers that act exclusively upon the retroviral RNase H domain in vitro, and thus represent novel lead compounds for the development of specific and potent HIV-1 RT inhibitors.

Selective inhibition of HIV-1 reverse transcriptase (HIV-1 RT) RNase H by small RNA hairpins and dumbbells.

We present here the design of a novel class of RNA inhibitors of the RNase H domain of HIV-1 RT, a ribonuclease activity that is essential for viral replication in vivo. Specifically, we show that small RNA hairpins and dumbbells can selectively inhibit the RNase H activity of HIV-1 RT without affecting other cellular RNases H (e.g., E. coli and human RNase H). These results suggest that the inhibitors do not interact with the nucleic acid binding site of RT RNase H, as this region should be well conserved among the various enzymes. The most potent inhibitors displayed IC50 values in the 3-8 microM range. Remarkably, the DNA polymerase activity, an intrinsic property of HIV RT, was not inhibited by the hairpin and dumbbell aptamers, a property not previously observed for any nucleic acid aptamer directed against RT RNase H. The results described here suggest a noncompetitive binding mechanism, as outlined in the differential inhibitory characteristics of each of the nucleic acid aptamers against the bacterial, human, and viral RNase H homologues.

Synthesis and properties of oligonucleotide chimeras containing 5'-amino-2'-deoxy-2'-fluoroarabinonucleosides.

Oligonucleotide analogues comprised of 2'-deoxy-2'-fluoro-beta-D-arabinose units joined via P3'-N5' phosphoramidate linkages (2'F-ANA(5'N)) were prepared for the first time. Among the compounds prepared were a series of 2'OMe-RNA-[GAP]-2'OMe-RNA 'chimeras', whereby the "GAP" consisted of DNA, DNA(5'N), 2'F-ANA or 2'F-ANA(5'N) segments. The chimeras with the 2'F-ANA and DNA gaps exhibited the highest affinity towards a complementary RNA target, followed by the 5'-amino derivatives, i.e., 2'F-ANA > DNA > 2'F-ANA(5'N) > DNA(5'N). Importantly, hybrids between these chimeras and target RNA were all substrates of both human RNase HII and E. coli RNase HI. In terms of efficiency of the chimera in recruiting the bacterial enzyme, the following order was observed: gap DNA > 2'F-ANA > 2'F-ANA(5'N) > DNA(5'N). The corresponding relative rates observed with the human enzyme were: gap DNA > 2'F-ANA(5'N) > 2'F-ANA > DNA(5'N).

Efficient RNase H-directed cleavage of RNA promoted by antisense DNA or 2'F-ANA constructs containing acyclic nucleotide inserts.

The ability of modified antisense oligonucleotides (AONs) containing acyclic interresidue units to support RNase H-promoted cleavage of complementary RNA is described. Manipulation of the backbone and sugar geometries in these conformationally labile monomers shows great benefits in the enzymatic recognition of the nucleic acid hybrids, while highlighting the importance of local strand conformation on the hydrolytic efficiency of the enzyme more conclusively. Our results demonstrate that the duplexes support remarkably high levels of enzymatic degradation when treated with human RNase HII, making them efficient mimics of the native substrates. Furthermore, interesting linker-dependent modulation of enzymatic activity is observed during in vitro assays, suggesting a potential role for this AON class in an RNase H-dependent pathway of controlling RNA expression. Additionally, the butyl-modified 2'F-ANA AONs described in this work constitute the first examples of a nucleic acid species capable of eliciting high RNase H activity while possessing a highly flexible molecular architecture at predetermined sites along the AON.

A fluorescence-based high-throughput screening assay for inhibitors of human immunodeficiency virus-1 reverse transcriptase-associated ribonuclease H activity.

A fluorescence resonance energy transfer assay readily applicable to 96-well and 384-well microplate formats with robotic operation was developed to enable high-throughput screening for inhibitors of human immunodeficiency virus-1 (HIV-1) reverse transcriptase (RT)-associated RNase H activity, an underexplored target for antiretroviral development. The assay substrate is an 18-nucleotide 3'-fluorescein-labeled RNA annealed to a complementary 18-nucleotide 5'-Dabcyl-modified DNA. The intact duplex has an extremely low background fluorescent signal and provides up to 50-fold fluorescent signal enhancement following hydrolysis. The size and sequence of the duplex are such that HIV-1 RT-RNase H cuts the RNA strand close to the 3' end. The fluorescein-labeled ribonucleotide fragment readily dissociates from the complementary DNA at room temperature with immediate generation of a fluorescent signal. This assay is rapid, inexpensive, and robust, providing Z' factors of 0.8 and coefficients of variation of about 5%. The assay can be carried out both in real-time (continuous) and in "quench" modes; the latter requires only two addition steps with no washing and is thus suitable for robotic operation. Several chemical libraries totaling more than 106,000 compounds were screened with this assay in approximately 1 month.

Oligonucleotides comprised of alternating 2'-deoxy-2'-fluoro-beta-D-arabinonucleosides and D-2'-deoxyribonucleosides (2'F-ANA/DNA 'altimers') induce efficient RNA cleavage mediated by RNase H.

Chimeric oligonucleotides comprised of alternating residues of 2'-deoxy-2'-fluoro-D-arabinonucleic acid (2'F-ANA) and DNA were synthesized and evaluated for an important antisense property-the ability to elicit ribonuclease H (RNase H) degradation of complementary RNA. Experiments used both human RNase HII and Escherichia coli RNase HI. Mixed backbone oligomers comprising alternating three-nucleotide segments of 2'F-ANA and three-nucleotide segments of DNA were the most efficient at eliciting RNase H degradation of target RNA, and were significantly better than oligonucleotides entirely composed of DNA, suggesting that these mixed backbone oligonucleotides may be potent antisense agents.

Molecular requirements for degradation of a modified sense RNA strand by Escherichia coli ribonuclease H1.

The structural requirements for DNA/RNA hybrids to be suitable substrates for RNase H1 are well described; however the tolerance level of this enzyme towards modifications that do not alter the duplex conformation is not clearly understood, especially with respect to the sense RNA strand. In order to investigate the molecular requirements of Escherichia coli RNase H1 (termed RNase H1 here) with respect to the sense RNA strand, we synthesized a series of oligonucleotides containing 2'-deoxy-2'-fluoro-beta-D-ribose (2'F-RNA) as a substitute for the natural beta-D-ribose sugars found in RNA. Our results from a series of RNase H1 binding and cleavage studies indicated that 2'F-RNA/DNA hybrids are not substrates of RNase H1 and ultimately led to the conclusion that the 2'-hydroxyl moiety of the RNA strand in a DNA/RNA hybrid is required for both binding and hydrolysis by RNase H1. Through the synthesis of a series of chimeric sense oligonucleotides of mixed RNA and 2'F-RNA composition, the gap requirements of RNase H1 within the sense strand were examined. Results from these studies showed that RNase H1 requires at least five or six natural RNA residues within the sense RNA strand of a hybrid substrate for both binding and hydrolysis. The RNase H1-mediated degradation patterns of these hybrids agree with previous suggestions on the processivity of RNase H1, mainly that the binding site is located 5' to the catalytic site with respect to the sense strand. They also suggest, however, that the binding and catalytic domains of RNase H1 might be closer than has been previously suggested. In addition to the above, physicochemical studies have revealed the thermal stabilities and relative conformations of these modified heteroduplexes under physiological conditions. These findings offer further insights into the physical binding and catalytic properties of the RNase H1-substrate interaction, and have been incorporated into a general model summarizing the mechanism of action of this unique enzyme.

Potent gene-specific inhibitory properties of mixed-backbone antisense oligonucleotides comprised of 2'-deoxy-2'-fluoro-D-arabinose and 2'-deoxyribose nucleotides.

Phosphorothioate deoxyribonucleotides (PS-DNA) are among the most widely used antisense inhibitors. PS-DNA exhibits desirable properties such as enhanced nuclease resistance, improved bioavailability, and the ability to induce RNase H mediated degradation of target RNA. Unfortunately, PS-DNA possesses a relatively low binding affinity for target RNA that impacts on its potency in antisense applications. We recently showed that phosphodiester-linked oligonucleotides comprised of 2'-deoxy-2'-fluoro-D-arabinonucleic acid (FANA) exhibit both high binding affinity for target RNA and the ability to elicit RNase H degradation of target RNA [Damha et al. (1998) J. Am. Chem. Soc. 120, 12976]. In the present study, we evaluated the antisense activity of phosphorothioate-linked FANA oligonucleotides (PS-FANA). Oligonucleotides comprised entirely of PS-FANA were somewhat less efficient in directing RNase H cleavage of target RNA as compared to their phosphorothioate-linked DNA counterparts, and showed only weak antisense inhibition of cellular target expression. However, mixed-backbone oligomers comprised of PS-FANA flanking a central core of PS-DNA were found to possess potent antisense activity, inhibiting specific cellular gene expression with EC(50) values of less than 5 nM. This inhibition was a true antisense effect, as indicated by the dose-dependent decrease in both target protein and target mRNA. Furthermore, the appearance of mRNA fragments was consistent with RNase H mediated cleavage of the mRNA target. We also compared a series of PS-[FANA-DNA-FANA] mixed-backbone oligomers of varying PS-DNA core sizes with the corresponding 2'-O-methyl oligonucleotide chimeras, i.e., PS-[2'meRNA-DNA-2'meRNA]. Both types of oligomers showed very similar binding affinities toward target RNA. However, the antisense potency of the 2'-O-methyl chimeric compounds was dramatically attenuated with decreasing DNA core size, whereas that of the 2'-fluoroarabino compounds was essentially unaffected. Indeed, a PS-FANA oligomer containing a single deoxyribonucleotide residue core retained significant antisense activity. These findings correlated exactly with the ability of the various chimeric antisense molecules to elicit RNase H degradation of the target RNA in vitro, and suggest that this mode of inhibition is likely the most important determinant for potent antisense activity.

Mutational analysis of Tyr-501 of HIV-1 reverse transcriptase. Effects on ribonuclease H activity and inhibition of this activity by N-acylhydrazones.

N-(4-tert-Butylbenzoyl)-2-hydroxynaphthaldehyde hydrazone (BBNH) is a potent inhibitor of the ribonuclease H (RNase H) activity of human immunodeficiency virus (HIV)-1 reverse transcriptase (RT). Molecular modeling predicted that BBNH binds to the HIV-1 RT RNase H active site via two major interactions, coordination to the metal ion cofactor (Mg(2+) or Mn(2+)) in the enzyme active site and aromatic ring-stacking interaction between the naphthyl ring of BBNH and amino acid Tyr-501. The latter residue equivalent is conserved in virtually all RNases H, suggesting the need for an aromatic or pi-stacking interaction in this region. To assess the importance of Tyr-501 in the binding of BBNH for the inhibition of RT RNase H activity, we used site-specific mutagenesis to generate RT with a variety of substitutions at this position. Most substitutions resulted virtually in a complete loss of RNase H activity. However, three mutants, Y501F, Y501W, and Y501R, possessed RNase H activities comparable with wild-type enzyme. Whereas BBNH inhibited Y501F RT RNase H activity with potency equivalent to wild-type RT, the Y501W mutant showed a 6-fold resistance to inhibition by BBNH, and the Y501R mutant was completely resistant to inhibition by BBNH. The replication "fitness" of HIV molecular clones with the Y501W or Y510R mutation was significantly compromised compared with wild-type virus. Importantly, BBNH was an effective inhibitor of the DNA polymerase activity of all Y501X mutants tested. Our results highlight the importance of Tyr-501 in RT RNase H activity and in N-acylhydrazone inhibitor binding and suggest that drugs that target critical residues in HIV-1 proteins may be a useful approach in new antiviral development.