A colorimetric nanosensor based on a selective target-responsive aptamer kissing complex

Herein, we report a novel approach for the design of a colorimetric aptasensor based on functionalized gold nanoparticle probes. This approach relies on the conjugation of nanoparticles by two functional DNA and RNA hairpins that engage specific kissing (loop-loop) interactions in response to the addition of a small analyte ligand, leading to particle aggregation and then red-to-purple colour change of the colloidal solution.

Driving in vitro selection of anti-HIV-1 TAR aptamers by magnesium concentration and temperature

In vitro selection with either DNA or RNA libraries was performed against the TAR RNA element of HIV-1. The role of the selection conditions on the outcome of the selection was evaluated by varying the magnesium concentration and the temperature. The selection stringency was demonstrated to determine i) the affinity of the best identified aptamers for the TAR target, and ii) the type of interaction between the two partners. Selections performed with a DNA library under low (4 degrees C, 10 mM magnesium) and high stringency (23 degrees C, 3 mM magnesium) led to the emergence of "kissing aptamers"; but even if the motif interacting directly with the TAR loop were identical in the two kinds of aptamers, the consensus was extended from eight to thirteen nucleotides when the Mg(2+) concentration was decreased from 10 to 3 mM. Similar kissing aptamers were selected at 23 degrees C and 37 degrees C starting with two different RNA libraries under identical ionic conditions. In addition, selection performed at 37 degrees C yielded a significant proportion of antisense sequences. Only antisense RNAs complementary to the TAR loop competitively inhibited the association of a Tat peptide with TAR.

A method to select chemically modified aptamers directly

In vitro selection is a strategy to identify high-affinity ligands of a predetermined target among a large pool of randomized oligonucleotides. Most in vitro selections are performed with unmodified RNA or DNA sequences, leading to ligands of high affinity and specificity (aptamers) but of very short lifetime in the ex vivo and in vivo context. Only a very limited number of modified triphosphate nucleotides conferring nuclease resistance to the oligomer can be incorporated by polymerases. This encourages the development of alternative methods for the identification of nuclease-resistant aptamers. In this paper, we describe such a method. After selection of 2'O-methyl oligonucleotides against the TAR RNA structure of HIV-1, the complementary DNA sequences are fished out of a pool of randomized oligodeoxynucleotides by Watson-Crick hybridization. The DNA-fished sequences are amplified by PCR as double and single strands, the latter being used to fish back the chemically modified candidates from the initial library. This procedure allows an indirect amplification of the selected candidates. This enriched pool of modified sequences is then used for the next selection round against the target.

Modulation of RNA function by oligonucleotides recognizing RNA structure

Numerous RNA structures are responsible for regulatory processes either because they constitute a signal, like the hairpins or pseudoknots involved in ribosomal frameshifting, or because they are binding sites for proteins such as the trans-activating responsive RNA element of the human immunodeficiency virus whose binding to the viral protein Tat and cellular proteins allows full-length transcription of the retroviral genome. Selective ligands able to bind with high affinity to such RNA motifs may serve as tools for dissecting the molecular mechanisms in which they are involved. Such ligands might also constitute prototypes of therapeutic agents when RNA structures play a role in the expression of dysfunctional genes or in the multiplication of pathogens. Different classes of ligands (aminoglycosides, interacalating agents, peptides) are of interest to this aim. However, oligonucleotides deserve particular consideration. They have been extensively used in the frame of the antisense strategy. The apparent simplicity of this rational approach is, at first sight, very attractive. Indeed, numerous successful studies have been published describing the efficient inhibition of translation, splicing, or reverse transcription in cell-free systems, in cultured cells, or in vivo by oligomers complementary to an RNA region. However, RNA structures restrict the access of the target site to the antisense sequence: The competition between the intramolecular association of RNA regions weakens or even abolishes the antisense effect. Various possibilities have been developed to circumvent this limitation. This includes both rational and combinatorial strategies. High-affinity oligomers were designed to invade the RNA structure. Alternatively, triplex-forming oligonucleotides (TFO) and aptamers may recognize the folded RNA motif. Whereas the use of TFOs is rather limited owing to the strong sequence constraints for triple-helix formation, in vitro selection offers a way to explore vast oligoribo or oligodeoxyribo libraries to identify strong, selective oligonucleotide binders. The candidates (aptamers) selected against the TAR RNA element of HIV-1, which form stable loop-loop (kissing) complexes with the target, provide interesting examples of oligonucleotides recognizing a functional RNA structure through an important contribution of tertiary interactions.

DNA aptamers selected against the HIV-1 RNase H display in vitro antiviral activity

The DNA polymerase of the human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) is a target widely used to inhibit HIV-1 replication. In contrast, very few inhibitors of the RNase H activity associated with RT have been described, despite the crucial role played by this activity in viral proliferation. DNA ligands with a high affinity for the RNase H domain of HIV-1 RT were isolated by systematic evolution of ligands by an exponential enrichment strategy (SELEX), using recombinant RTs with or without the RNase H domain. The selected oligonucleotides (ODNs) were able to inhibit in vitro the HIV-1 RNase H activity, while no effect was observed on cellular RNase H. We focused our interest on two G-rich inhibitory oligonucleotides. Model studies of the secondary structure of these ODNs strongly suggested that they were able to form G-quartets. In addition to the inhibition of HIV-1 RNase H observed in a cell free system, these ODNs were able to strongly diminish the infectivity of HIV-1 in human infected cells. Oligonucleotides described here may serve as leading compounds for the development of specific inhibitors of this key retroviral enzyme activity.

RNA and N3'-->P5' kissing aptamers targeted to the trans-activation responsive (TAR) RNA of the human immunodeficiency virus-1

We used in vitro selection to identify RNA aptamers able to selectively bind to the TAR RNA motif of HIV-1, an unperfect RNA hairpin involved in the transcription of the retroviral genome. We selected aptameric RNA hairpins giving rise to kissing complexes with TAR. The N3'-->P5' phosphoramidate variant of the aptamer bind to TAR with a Kd in the low nanomolar range. However, only the RNA-RNA loop-loop complex is recognized by the Rop protein of E. coli which is specific for kissing complexes.

NMR characterization of a kissing complex formed between the TAR RNA element of HIV-1 and a DNA aptamer

This work presents the first structural analysis of an RNA-DNA complex consisting of an 18 nt RNA hairpin and a 20 nt DNA aptamer. The DNA molecule was previously selected, from a randomly synthesized library, against the transactivation response element (TAR) involved in transcriptional regulation of the HIV genome. The DNA aptamer used in the present study is an imperfect stem-loop with the sequence 5'-ACTCCCAT-3', characteristic of the selected candidates, in the apical loop. This octameric motif contains five bases complementary to the TAR loop sequence 5'-CUGGGA-3'. The use of homo- and heteronuclear NMR spectroscopy allowed assignment of the complex resonances and resolution of its secondary structure. Evidence is given for a kissing complex fold, which consists of a quasi-continuous helix formed by one stem of DNA, one stem of RNA and a central hybrid helix comprising 5 bp. Two out of helices residues of DNA and one of RNA connect the DNA-RNA loop-loop helix to the stem of either partner in the complex. In addition, two thymines of the DNA stem are engaged in a non-canonical T.T base pair.

4-amino-1H-benzo[g]quinazoline-2-one: a fluorescent analog of cytosine to probe protonation sites in triplex forming oligonucleotides

We developed a new fluorescent analog of cytosine, the 4-amino-1H-benzo[g]quinazoline-2-one, which constitute a probe sensitive to pH. The 2'-O-Me ribonucleoside derivative of this heterocycle was synthesized and exhibited a fluorescence emission centered at 456 nm, characterized by four major excitation maxima (250, 300, 320 and 370 nm) and a fluorescence quantum yield of Phi = 0.62 at pH 7.1. The fluorescence emission maximum shifted from 456 to 492 nm when pH was decreased from 7.1 to 2.1. The pK(a) (4) was close to that of cytosine (4.17). When introduced in triplex forming oligonucleotides this new nucleoside can be used to reveal the protonation state of triplets in triple-stranded structures. Complex formation was detected by a significant quenching of fluorescence emission (approximately 88%) and the N-3 protonation of the quinazoline ring by a shift of the emission maximum from 485 to 465 nm. Using this probe we unambiguously showed that triplex formation of the pyrimidine motif does not require the protonation of all 4-amino-2-one pyrimidine rings.

Towards the selection of phosphorothioate aptamers optimizing in vitro selection steps with phosphorothioate nucleotides

The high affinity of a given nucleic acid for a protein ligand can be used to isolate specific inhibitors of enzymes involved in pathological situations. The latter property is the basis of the SELEX (systematic evolution of ligands by exponential enrichment) technique. Recently, several potent nucleic acids inhibitors of HIV-1 replication have been isolated using the SELEX approach. However, phosphodiester oligodeoxynucleotides (PO-ODNs) were not used as antiviral agents because of their sensitivity to nucleases. Our goal in this work was to explore the possibility of selecting, from a fully substituted phosphorothioate library, oligonucleotides having both a strong affinity for HIV-1 reverse transcriptase (RT) and nuclease resistance. HIV-1 RT initiates in vivo reverse transcription from the 3' end of a host tRNALys. Although phosphorothioate ODNs (PS-ODNs) have been claimed to bind unspecifically to proteins, we have shown previously that an ODN corresponding to the acceptor stem of tRNALys was able to inhibit specifically HIV-1 replication in HIV-1 infected cells, without showing cytotoxicity up to 10 microM. As the SELEX strategy requires 'in vitro' transcription and reverse transcription of the selected DNA, we have assayed the available PS precursors as a model system by using PS-dNTPs and rNTPs. We have also developed an experimental procedure to optimize the incorporation of four PS-dNTPs during the PCR step of the SELEX approach. In the course of this work, we have showed that the PS-dGTP is a strong inhibitor of thermostable DNA polymerases as well as of HIV-1 RT.

Aptamers: selected oligonucleotides for therapy

In vitro selection constitutes a unique way to explore vast libraries (up to 10(14) to 10(15) different molecules) of randomly synthesized nucleic acids. Selected RNA or DNA sequences (aptamers) may help to understand the molecular interactions and processes of interest for human diseases. Aptamers can be chemically-modified for improved efficiency and use in complex biological media. Moreover, aptamers selected in vitro may retain their activity in vivo and thus offer novel perspectives for gene therapy and the design of new drugs.

Inhibition of in vitro and ex vivo translation by a transplatin-modified oligo(2'-O-methylribonucleotide) directed against the HIV-1 gag-pol frameshift signal

A 2'-O-methylribooligonucleotide containing a G1.U.G3 triad modified by trans-diamminedichloro-platinum(II) was targeted to the RNA region responsible for the gag-pol frameshifting during translation of the HIV-1 mRNA. The binding of the platinated oligonucleotide to its target RNA induced a rearrangement of the (G1, G3)-intrastrand crosslink, leading to the formation of an intermolecular oligonucleotide-RNA G-A crosslink. This resulted in the selective arrest of translation of a luciferase gene placed downstream of the HIV-1 frameshift signal both in a cell-free extract (rabbit reticulocyte lysate) and in RNA-transfected cells. A specific inhibition of luciferase activity was still observed when the oligonucleotide-RNA complex was not pre-formed prior to either translation or transfection. Moreover, a selective inhibition was also observed when the oligonucleotide and the plasmid DNA encoding the luciferase and bearing the RNA gag- pol frameshifting signal were co-transfected in NIH 3T3 cultured cells. Therefore the intra-strand-->interstrand conversion of the platinum crosslink kinetically competes with the translation machinery and blocks the polypeptide elongation. These transplatin-modified oligonucleotides which operate within a live cell on a 'real-time' basis and do not need an external triggering signal constitute a promising new class of selective reactive probes.

In vitro selection identifies key determinants for loop-loop interactions: RNA aptamers selective for the TAR RNA element of HIV-1

We selected RNA aptamers specific for the trans-activation responsive (TAR) RNA, a stem-loop structure crucial for the transcription of the integrated genome of the human immunodeficiency virus. Most of the selected sequences could be folded as imperfect hairpins and displayed a 5'-GUCCCAGA-3' consensus motif constituting the apical loop. The six central bases of this consensus sequence are complementary to the entire TAR loop, leading to the formation of TAR RNA-aptamer "kissing" complexes. The consensus G and A residues closing the aptamer loop contributed to the high affinity (Kd = 30 nM at 23 degrees C) of the aptamers for the TAR RNA. This G A pair was shown to be crucial for binding to TAR at a low magnesium concentration. The selection also identified 5'-PuPy and 5'-PyPu base pairs at alpha and beta positions of the stem, next to the loop, respectively. This strategy offered a way to identify key determinants of loop-loop interactions and to generate high affinity ligands of TAR RNA structure.

Antisense effects of oligonucleotides complementary to the hairpin of the Leishmania mini-exon RNA

We investigated the binding and the translation inhibitory properties of hexadecamers complementary to the mini-exon sequence of the protozoan parasite Leishmania amazonensis. This targeted RNA region folds into a hairpin. Large differences were observed in the antisense properties of the different oligomers although their binding to RNA always requires the disruption of the stem region.

Binding of chemically-modified oligonucleotides to the double-stranded stem of an RNA hairpin

We monitored the binding of triplex-forming oligopyrimidines to the double-stranded stem of the RNA hairpin responsible for the gag-pol frameshift in HIV-1. Whereas the substitution of 5, propynyl-C for C had a limited effect, the use of a Peptide Nucleic Acid 12mer led to a drastic reduction in the stability of the oligomer/RNA complex.

DNA aptamers selected against the HIV-1 trans-activation-responsive RNA element form RNA-DNA kissing complexes

In vitro selection was performed in a DNA library, made of oligonucleotides with a 30-nucleotide random sequence, to identify ligands of the human immunodeficiency virus type-1 trans-activation-responsive (TAR) RNA element. Aptamers, extracted after 15 rounds of selection-amplification, either from a classical library of sequences or from virtual combinatorial libraries, displayed an imperfect stem-loop structure and presented a consensus motif 5'ACTCCCAT in the apical loop. The six central bases of the consensus were complementary to the TAR apical region, giving rise to the formation of RNA-DNA kissing complexes, without disrupting the secondary structure of TAR. The RNA-DNA kissing complex was a poor substrate for Escherichia coli RNase H, likely due to steric and conformational constraints of the DNA/RNA heteroduplex. 2'-O-Methyl derivatives of a selected aptamer were binders of lower efficiency than the parent aptamer in contrast to regular sense/antisense hybrids, indicating that the RNA/DNA loop-loop region adopted a non-canonical heteroduplex structure. These results, which allowed the identification of a new type of complex, DNA-RNA kissing complex, demonstrate the interest of in vitro selection for identifying non-antisense oligonucleotide ligands of RNA structures that are of potential value for artificially modulating gene expression.

Binding of oligopyrimidines to the RNA hairpin responsible for the ribosome gag-pol frameshift in HIV-1

The 12 bp stem of the RNA hairpin responsible for the gag-pol frameshifting of the ribosomes during translation of the polycistronic HIV-1 mRNA has a pyrimidine-rich 5' strand and, consequently, a purine-rich 3' strand. Electrophoretic mobility shift assays have shown that DNA oligopyrimidines, 12 and 20 nucleotides long (but not oligopurines or G,T-containing oligomers), designed to form triplexes actually bind to the double-stranded RNA target. RNase V1 footprinting studies have confirmed the interaction between the hairpin stem and the RNA and 2'-O-methyl oligoribonucleotide analogues of the 12-mer oligodeoxypyrimidine as well as 5 propynyl,cytosine, containing the 12-mer oligodeoxypyrimidine, bind more strongly to the RNA target than the unmodified parent DNA oligomer. The complexes formed by the RNA hairpin and either the 12-mer oligodeoxypyrimidine or the 20-mer oligopyrimidine are stable at a neutral pH and in the absence of Mg2+ but blocked neither the reverse transcription nor cell-free translation of a RNA template in which the gag-pol frameshifting hairpin was inserted at the 5' end of the luciferase open reading frame.

Antisense oligonucleotides containing modified bases inhibit in vitro translation of Leishmania amazonensis mRNAs by invading the mini-exon hairpin

Complementary oligodeoxynucleotides (ODNs) that contain 2-aminoadenine and 2-thiothymine interact weakly with each other but form stable hybrids with unmodified complements. These selectively binding complementary (SBC) agents can invade duplex DNA and hybridize to each strand (Kutyavin, I. V., Rhinehart, R. L., Lukhtanov, E. A., Gorn, V. V., Meyer, R. B., and Gamper, H. B. (1996) Biochemistry 35, 11170-11176). Antisense ODNs with similar properties should be less encumbered by RNA secondary structure. Here we show that SBC ODNs strand invade a hairpin in the mini-exon RNA of Leishmania amazonensis and that the resulting heteroduplexes are substrates for Escherichia coli RNase H. SBC ODNs either with phosphodiester or phosphorothioate backbones form more stable hybrids with RNA than normal base (NB) ODNs. Optimal binding was observed when the entire hairpin sequence was targeted. Translation of L. amazonensis mRNA in a cell-free extract was more efficiently inhibited by SBC ODNs complementary to the mini-exon hairpin than by the corresponding NB ODNs. Nonspecific protein binding in the cell-free extract by phosphorothioate SBC ODNs rendered them ineffective as antisense agents in vitro. SBC phosphorothioate ODNs displayed a modest but significant improvement of leishmanicidal properties compared with NB phosphorothioate ODNs.

A fluorescent base analog for probing triple helix formation

Benzo[g]quinazoline-2,4-(1H,3H)-dione (BgQ), a fluorescent thymine analog, was incorporated into an oligopyrimidine (III) able to give rise to a triple-stranded structure by clamping a purine 11-mer (I). The formation of the I-III complex resulted in both a shift of the fluorescence emission maximum and a decreased fluorescence intensity. No such variations were observed on the formation of a Watson-Crick duplex between I and the complementary strand in which a T residue was substituted for BgQ. Therefore, the fluorescence emission of BgQ can be used to selectively monitor the formation of triple helices.

Modified (PNA, 2'-O-methyl and phosphoramidate) anti-TAR antisense oligonucleotides as strong and specific inhibitors of in vitro HIV-1 reverse transcription

Natural beta-phosphodiester 16mer and 15mer antisense oligonucleotides targeted against the HIV-1 and HIV-2 TAR RNAs respectively were previously described as sequence-specific inhibitors of in vitro retroviral reverse transcription. In this work, we tested chemically modified oligonucleotide analogues: alpha-phosphodiester, phosphorothioate, methylphosphonate, peptide nucleic acid or PNA, 2'- o -methyl and (N3'-P5') phosphoramidate versions of the 16mer anti-TAR oligonucleotide. PNA, 2'- O -methyl and (N3'-P5') phosphoramidate oligomers showed a strong inhibitory effect compared with the unmodified 16mer, with reverse transcription inhibition (IC50) values in the nanomolar range. The inhibition was sequence-specific, as scrambled and mismatched control oligonucleotides were not able to inhibit cDNA synthesis. No direct binding of the 2'- O -methyl, PNA or (N3'-P5') phosphoramidate anti-TAR oligonucleotides to the HIV-1 reverse transcriptase was observed. The higher T m obtained with 2'- O -methyl, (N3'-P5') phosphoramidate and PNA molecules concerning the annealing with the stem-loop structure of the TAR RNA, in comparison with the beta-phosphodiester oligonucleotides, is correlated with their high inhibitory effect on reverse transcription.

Benzoquinazoline derivatives as substitutes for thymine in nucleic acid complexes. Use of fluorescence emission of benzo[g]quinazoline-2,4-(1H,3H)-dione in probing duplex and triplex formation

Triple helix formation obeys structural features that do not allow accommodation of every double-stranded sequence; it requires the occurrence of homopurine stretches. A further constraint comes from the weak energy of interaction between the third strand and the double-stranded target. In an attempt to design bases leading to increased stability of triplexes, we explored the ability of modified bases with an extended aromatic domain to increase third strand binding through stacking interactions. We report here the use of benzo[g]- and benzo[f]quinazoline-2,4-dione-(1H,3H)-dione as substitutes for thymine in the canonical TAT triplet. The synthesis and characterization of the beta nucleoside derivatives of benzoquinazolines are described. Triplex-forming oligonucleotides containing these modified bases have been prepared, and their ability to form triplexes has been evaluated by UV absorption-monitored thermal denaturation measurements. Benzo[g]quinazoline and benzo[f]quinazoline formed triple-stranded structures with slightly decreased stabilities. In addition, benzo[g]quinazoline revealed strong fluorescence emission properties which can be used to monitor selectively the formation of triple-helical structures. Annealing of benzo[g]quinazoline to complementary strands did not produce any fluorescence modification. But when it was introduced into the Hoogsteen strand of PyPuPy complexes, the fluorescence intensity was reduced and the emission maximum was shifted to short wavelengths.

Mapping of a minimal AU-rich sequence required for lipopolysaccharide-induced binding of a 55-kDa protein on tumor necrosis factor-alpha mRNA

In monocyte/macrophage cells, the translation of tumor necrosis factor-alpha (TNF-alpha) mRNA is tightly controlled. In unstimulated cells, TNF-alpha mRNA is translationally repressed. However, upon stimulation of the cells with various agents (e.g. lipopolysaccharides (LPS) and viruses), this repression is overcome and translation occurs. The key element in this regulation is the AU-rich sequence present in the 3'-untranslated region of TNF-alpha mRNA. Several groups have described the binding of proteins on AU-rich elements (AREs). We have previously reported the binding of two cytosolic protein complexes (1 and 2) to the TNF-alpha mRNA ARE, one of which (complex 2) is observed only following induction of TNF-alpha production by LPS. In this report, we have demonstrated that complex 1 involves a long fragment of the ARE, whereas the formation of the LPS-inducible complex 2 requires a minimal sequence which corresponds to the nonanucleotide UUAUUUAUU. Furthermore, we show that the RNA-binding protein involved in complex 2 has an apparent molecular mass of 55 kDa. Finally, we tested other AREs for their ability to form complex 2. We observed that the ARE derived from granulocyte/macrophage colony-stimulating factor mRNA, which does contain the nonanucleotide, is able to sustain the LPS-induced binding of the 55-kDa protein. However, c-myc mRNA, which does not contain the nonanucleotide, is unable to promote the formation of any LPS-induced complex.

Selective inhibition of cell-free translation by oligonucleotides targeted to a mRNA hairpin structure

Using an in vitro selection approach we have previously isolated oligodeoxy aptamers that can bind to a DNA hairpin structure without disrupting the double-stranded stem. We report here that these oligomers can bind to the RNA version of this hairpin, mostly through pairing with a designed 6 nt anchor. The part of the aptamer selected against the DNA hairpin did not increase stability of the RNA-aptamer complex. However, it contributed to the binding site for Escherichia coli RNase H, leading to very efficient cleavage of the target RNA. In addition, a 2'- O -methyloligoribonucleotide analogue of one selected sequence selectively blocked in vitro translation of luciferase in wheat germ extract by binding to the hairpin region inserted upstream of the initiation codon of the reporter gene. Therefore, non-complementary oligomers can exhibit antisense properties following hybridization with the target RNA. Our study also suggests that in vitro selection might provide a means to extend the repertoire of sequences that can be targetted by antisense oligonucleotides to structured RNA motifs of biological importance.

Rational and combinatorial strategies for designing oligonucleotides targeted to RNA structures

Many RNA structures play a key role in the regulation of gene expression. We designed synthetic oligonucleotides able to interact with folded RNA regions (see Toulmé et al., Biochimie (1996) 78, 663-673, for a review). We have demonstrated that a decanucleotide can form a triple helix with the stem of the hairpin responsible for ribosomal frame-shifting of the gag-pro message of HTLV-I, leading to the inhibition of translation. We have isolated, through an in vitro selection procedure, from a library composed of oligonucleotides with a random part of 30 nucleotides, sequences able to bind to the TAR RNA element of HIV-1 with a dissociation constant of 20-50 nM. The association between the two partners involve non-canonical interactions. This extends the range of potential targets for antisense sequences to functional RNA structures.

Control of gene expression in viruses and protozoan parasites by antisense oligonucleotides

Chemically-modified oligonucleotides are now routinely used to prevent gene expression in cell-free media and in cultured cells. The binding of an antisense sequence to a complementary RNA target may lead to the selective inhibition of the encoded information. This may occur at different levels: splicing; transport of the mature RNA from the nucleus to the cytoplasm; translation. Antisense oligonucleotides constitute an interesting tool to shed some light on gene function. They are also potential new therapeutic agents against pathogenic organisms. This review discusses the rules that guide the design of an antisense oligomer and the choice of a target sequence. Examples of the potential use of antisense oligonucleotides in the fields of virology and parasitology, in particular in relation to trypanosomatids, are described.

Identification of aptamers against the DNA template for in vitro transcription of the HIV-1 TAR element

We have extracted from a random population of about 10(9) oligodeoxynucleotides a series of 21-mers that are able to bind to a folded DNA 76-mer used as a template for in vitro transcription of the TAR element of the retrovirus HIV-1, by the T7 RNA polymerase. Five aptastrucs, that is, aptamers able to bind to the structure, out of 15 analyzed sequences, share the consensus motif 5'-PyGGG(TG)PyC, complementary in part to a weak double-stranded region of the target. (The parentheses indicate that either T or G is missing in one of these aptastrucs.) A dissociation constant of about 3 microM was evaluated by electrophoretic mobility shift assay for the winner sequence. Interactions between the aptastruc and the target sequences involve more than Watson-Crick base pairing of the consensus octamer. The binding is chemistry dependent. Phosphorothioate oligodeoxyribonucleotides and 2'-O-methyl oligoribonucleotides derived from the selected aptastrucs exhibit a weak if any affinity for the target.

Targeting nucleic acid secondary structures by antisense oligonucleotides designed through in vitro selection

Using an in vitro selection approach, we have isolated oligonucleotides that can bind to a DNA hairpin structure. Complex formation of these oligonucleotides with the target hairpin involves some type of triple-stranded structure with noncanonical interaction, as indicated by bandshift assays and footprinting studies. The selected oligomers can block restriction endonuclease cleavage of the target hairpin in a sequence-specific manner. We demonstrate that in vitro selection can extend the antisense approach to functional targeting of secondary structure motifs. This could provide a basis for interfering with regulatory processes mediated by a variety of nucleic acid structures.

Double hairpin complexes allow accommodation of all four base pairs in triple helices containing both DNA and RNA strands

We investigated the binding of an antisense oligodeoxynucleotide to a stem-loop structure corresponding to the mini-exon sequence of the protozoan parasite Leishmania amazonensis. This oligomer was designed to anneal to the single-stranded region adjacent to the bottom of the hairpin and to fold back on itself, giving rise to a "double-hairpin" complex that involved a local triplex. This imposed the recognition, by the third strand, of a "purine" strand containing 6 interspersed pyrimidines out of 15 nucleic acid bases. The sequence of the complementary oligonucleotide was derived from the so-called pyrimidine motif; the third strand of the anti-mini-exon oligomer was parallel to the purine strand of the target. Electrophoretic mobility shift assays and footprinting studies demonstrated that such an antisense oligomer was able to bind to both the DNA and RNA versions of the Leishmania hairpin. These double hairpin complexes allowed the formation at pH 6.0 of a triple-stranded structure, despite the presence of 4 A:T*G and 2 G:C*T triplets out of 15.

Triplex-forming oligonucleotides trigger conformation changes of a target hairpin sequence

We used a DNA duplex formed between the 5' end of a 69mer (69T) and an 11mer (OL7) as a substrate for BamHI. The former oligonucleotide folds into a hairpin structure, the stem of which contains a stretch of pyrimidines in one strand and consequently a stretch of purines in the other strand. The oligomer 69T was used as a target for complementary oligodeoxypyrimidines made of 10 nt (OL1), 16 nt (OL5) or 26 nt (OL2) which can engage the same 10 pyrimidine-purine-pyrimidine triplets with the 69T hairpin stem. Although the binding site of OL7 did not overlap that of OL1, OL2 or OL5, the BamHI activity on 69T-OL7 complexes was drastically modified in the presence of these triplex-forming oligomers: OL1 abolished the cleavage by BamHI whereas OL5 and OL2 strongly increased it. Using footprinting assays and point-mutated oligonucleotides we demonstrated that these variations were due to different conformations of the 69T-OL7 complex induced by the binding of oligomers OL1, OL2 or OL5. Therefore, oligonucleotides can act as structural switchers, offering one additional mode for modulating gene expression.

Quinazoline-2,4(1H,3H)-dione as a substitute for thymine in triple-helix forming oligonucleotides: a reassessment

A major limitation in triple-helix formation arises from the weak energy of interaction between the third strand and the double-stranded target. We tried to increase the stacking interaction contribution within the third strand by extending the aromatic domain of thymine. We report here the use of 2,4-quinazolinedione as a substitute for thymine in the canonical TA*T triplet. The synthesis and the characterization of the quinazoline beta nucleoside Q and of its phosphoramidite derivative is described. Triple-helix- forming oligonucleotides incorporating Q have been prepared and their ability to form triplexes has been evaluated by UV-monitored thermal denaturation measurements. The introduction of one or multiple Q residues, either contiguous or remote from each other, slightly destabilized triple-stranded structures, whatever the nucleic acid base composition (pyrimidine or GT) of the third strand.

Antisense oligonucleotides inhibit in vitro cDNA synthesis by HIV-1 reverse transcriptase

The inhibition of reverse transcription by various chemically modified antisense oligonucleotides was studied in a cell-free system, composed of an RNA template, a primer oligodeoxynucleotide, and the HIV-1 reverse transcriptase (RT). Different mechanisms of inhibition were observed depending on the chemical structure of the antisense molecule. (1) The hybridization of 2'-O-allyl oligonucleotide to the RNA template promotes a physical arrest of the polymerase. (2) The antisense effect of phosphodiester or phosphorothioate oligonucleotides is essentially due to the RNase H-mediated cleavage of the RNA. (3) A third mechanism was observed with phosphorothioate oligonucleotides that directly interact with the enzyme. Chimeric oligonucleotides, composed of an unmodified region flanked by 2'-O-methyl groups, led to less efficient inhibition than the parent unmodified oligomer, although the inhibitory mechanism was the same. No inhibitory effect was detected when alpha or methylphosphonate oligomers were used.

Targeting RNA structures by antisense oligonucleotides

The presence of folded regions in RNA competes with the binding of a complementary oligonucleotide, resulting in a weak antisense effect. Due to the key role played by a number of RNA structures in the natural regulation of gene expression it might be of interest to design antisense sequences able to selectively interact with such motifs in order to interfere with the biological processes they mediate. Different possibilities have been explored. A high affinity oligomer will disrupt the structure; if the target structure is solved one can take advantage of unpaired bases (bulges, loops) to minimize the thermodynamic cost of the binding. Alternatively, the folded structure can be accommodated within the complex via the formation of a local triple helix. Oligomers able to adapt to the RNA structure (aptamers) can be extracted by in vitro selection from randomly synthesized libraries comprising several billions of sequences.

Improved leishmanicidal effect of phosphorotioate antisense oligonucleotides by LDL-mediated delivery

We have designed antisense oligonucleotides that can interact with lipoproteins in order to use them as vectors to facilitate the uptake by those cells expressing the corresponding receptor. Phosphorothioate (PS) oligonucleotides were linked at the 5' end to a palmityl group giving rise to PSPal conjugates. Such a modification enables the oligonucleotide to form a stable non-covalent complex with low density lipoproteins (LDL) through hydrophobic interactions. The antisense effect of LDL-oligonucleotide complexes was assayed by targeting the mini-exon sequence of Leishmania amazonensis in infected mouse peritoneal macrophages. A 16-mer antisense PSPal oligonucleotide/LDL complex exerted a more pronounced sequence-specific effect than the free oligomer: about 25% and 10% of infected macrophages were cured by a 48 h incubation in the presence of 2.5 microM of the complexed and the free oligomer, respectively. When oxidized LDL was used instead of the native one for complexation, a further 2-fold increase in the antisense effect was observed suggesting that alternative (unregulated) scavenger receptor can be used for more efficient delivery of antisense oligonucleotides into macrophages. In addition, a significant reduction of the parasitic load was observed in those cells that were not fully cured.

RNase H is responsible for the non-specific inhibition of in vitro translation by 2'-O-alkyl chimeric oligonucleotides: high affinity or selectivity, a dilemma to design antisense oligomers

Ribonuclease H (RNase H) which recognizes and cleaves the RNA strand of mismatched RNA-DNA heteroduplexes can induce non-specific effects of antisense oligonucleotides. In a previous paper [Larrouy et al. (1992), Gene, 121, 189-194], we demonstrated that ODN1, a phosphodiester 15mer targeted to the AUG initiation region of alpha-globin mRNA, inhibited non-specifically beta-globin synthesis in wheat germ extract due to RNase H-mediated cleavage of beta-globin mRNA. Specificity was restored by using MP-ODN2, a methylphosphonate-phosphodiester sandwich analogue of ODN1, which limited RNase H activity on non-perfect hybrids. We report here that 2'-O-alkyl RNA-phosphodiester DNA sandwich analogues of ODN1, with the same phosphodiester window as MP-ODN2, are non-specific inhibitors of globin synthesis in wheat germ extract, whatever the substituent (methyl, allyl or butyl) on the 2'-OH. These sandwich oligomers induced the cleavage of non-target beta-globin RNA sites, similarly to the unmodified parent oligomer ODN1. This is likely due to the increased affinity of 2'-O-alkyl-ODN2 chimeric oligomers for both fully and partly complementary RNA, compared to MP-ODN2. In contrast, the fully modified 2'-O-methyl analogue of ODN1 was a very effective and highly specific antisense sequence. This was ascribed to its inability (i) to induce RNA cleavage by RNase H and (ii) to physically prevent the elongation of the polypeptide chain.

Antisense 2'-O-alkyl oligoribonucleotides are efficient inhibitors of reverse transcription

Reverse transcription is one step of the retroviral development which can be inhibited by antisense oligonucleotides complementary to the RNA template. 2'-O-Alkyl oligoribonucleotides are of interest due to their nuclease resistance, and to the high stability of the hybrids they form with RNA. Oligonucleotides, either fully or partly modified with 2'-O-alkyl residues, were targeted to an RNA template to prevent cDNA synthesis by the Avian Myeloblastosis Virus reverse transcriptase (AMV RT). Fully-modified 2'-O-allyl 17mers were able to specifically block reverse transcription via an RNase H-independent mechanism, with efficiencies comparable to those observed with phosphodiester (PO) and phosphorothioate oligonucleotides. Sandwich 2'-O-alkyl/PO/2'-O-alkyl oligonucleotides, supposed to combine the properties of 2'-O-alkyl modifications (physical blocking of the RT) to those of the PO window (RNase H-mediated cleavage of the RNA) were quasi-stoichiometric inhibitors when adjacent to the primer, but remained without any effect when non-adjacent. They were not able to compete with the polymerase and inhibited reverse transcription only through RNase H-mediated cleavage of the target.

Purification and characterization of human ribonuclease HII

A ribonuclease H activity from human placenta has been separated by ion exchange chromatography from the major RNase HI enzyme. Additional chromatographic steps allowed further purification, more than 3,000 fold compared to the crude extract in which it represents about 15% of the total RNase H activity. The enzyme requires Mg2+ ions for its activity, is strongly inhibited by the addition of Mn2+ ions or other divalent transition metal ions, and exhibits a pH optimum between 8.5 and 9. It shows a strong sensitivity to the SH-blocking agent N-ethylmaleimide. It has a strict specificity for double-stranded RNA-DNA duplexes and exhibits neither single-stranded nor double-stranded RNase (or DNase) activities. Therefore, this enzyme displays the characteristics of class II RNase H and is now termed RNase HII. Renaturation gel assays and gel filtration experiments proved a monomeric structure for the active enzyme with a native molecular weight of about 33 kDa. The human RNase HII acts as an endonuclease and releases oligoribonucleotides with 3'-OH and 5'-phosphate ends. It is therefore a candidate for the RNase H-mediated effect of antisense oligodeoxynucleotides.

In vitro selection of antisense oligonucleotides targeted to a hairpin structure

Antisense oligonucleotides are widely used to selectively prevent pre-RNA splicing, mRNA translation or cDNA synthesis from a retroviral RNA template. However, intramolecular folding of the RNA chain can sequester the target sequence into a stable structure. Consequently, the antisense effect can be greatly reduced or even abolished. Hydrogen donor and acceptor sites are still available on nucleic acid bases involved in secondary structures. However, the rational design of antisense sequences able to recognize the three dimensional array of these sites is not available. We used an in vitro selection procedure to fish out aptastrucs, i.e., oligomers able ("apte") to bind to a structure. A population of randomly synthesized oligonucleotides was mixed with the structure of interest and oligodeoxynucleotide sequences bound to the target were selected and amplified. The selection involves the destruction of the unbound candidates by a restriction enzyme. This procedure can be used both for RNA and DNA target structures and does not require the purification of the bound oligonucleotides at each cycle of selection. Several cycles of selection-amplification, followed by cloning and sequencing, allowed us to identify three oligonucleotides able to form a complex with a DNA hairpin. Due to the sequence of the selected candidates, these aptastruc-hairpin complexes involve very likely non-canonical interactions between the two partners.

Relative contribution of photo-addition, helper oligonucleotide and RNase H to the antisense effect of psoralen-oligonucleotide conjugates, on in vitro translation of Leishmania mRNAs

We investigated the properties of two antisense oligonucleotides, 11 alpha Pso and 14TMP, 11 and 14 nucleotides long, respectively, and conjugated to psoralen derivatives. These oligonucleotides were complementary to the mini-exon sequence of Leishmania amazonensis. Upon ultraviolet (UV) irradiation these oligomers were selectively cross-linked to DNA or RNA target sequences, either 14 or 35 nucleotides long. The yield of photo-addition was much lower on the longer targets than on the shorter ones, due to the presence of a hairpin structure. The co-addition of a helper oligonucleotide, whose binding site, on the 35-mer, was adjacent to that of the psoralen-derivatized antisense oligomer, improved the cross-linking efficiency. We then determined the effect of 14TMP on in vitro translation of Leishmania mRNA in cell-free extracts. Non-irradiated antisense oligonucleotide/mRNA complexes reduced the protein synthesis in wheat germ extract but not in rabbit reticulocyte lysate. Conversely, UV irradiation induced a 14TMP-dependent reduction of translation in reticulocyte lysate whereas the inhibition was not improved in the wheat germ extract. These results are discussed with respect to the involvement of RNase-H in the oligonucleotide-mediated effect on protein synthesis.

Antisense phosphorothioate oligonucleotides: selective killing of the intracellular parasite Leishmania amazonensis

We targeted the mini-exon sequence, present at the 5' end of every mRNA of the protozoan parasite Leishmania amazonensis, by phosphorothioate oligonucleotides. A complementary 16-mer (16PS) was able to kill amastigotes--the intracellular stage of the parasite--in murine macrophages in culture. After 24 hr of incubation with 10 microM 16PS, about 30% infected macrophages were cured. The oligomer 16PS acted through antisense hybridization in a sequence-dependent way; no effect on parasites was observed with noncomplementary phosphorothioate oligonucleotides. The antisense oligonucleotide 16PS was a selective killer of the protozoans without any detrimental effect to the host macrophage. Using 16PS linked to a palmitate chain, which enabled it to complex with low density lipoproteins, improved the leishmanicidal efficiency on intracellular amastigotes, probably due to increased endocytosis. Phosphorothioate oligonucleotides complementary to the intron part of the mini-exon pre-RNA were also effective, suggesting that antisense oligomers could prevent trans-splicing in these parasites.

A phosphorothioate oligonucleotide blocks reverse transcription via an antisense mechanism

We have studied the inhibition by a phosphorothioate oligodeoxynucleotide (17PScap) of cDNA synthesis performed by either avian or murine reverse transcriptase. Three different mechanisms of inhibition were identified: at low concentrations (< 100 nM), the cleavage of the RNA template by the retroviral RNase H at the level of the RNA/17PScap duplex accounted for most of the effect, whereas hybrid-arrested cDNA synthesis by an RNase H-independent mechanism marginally contributed to the inhibition. Both mechanisms were sequence-specific. Above 100 nM, the overall cDNA synthesis was reduced in a non-specific manner.

The binding of an antisense oligonucleotide to a hairpin structure via triplex formation inhibits chemical and biological reactions

We have investigated the binding of a 26-mer antisense oligodeoxynucleotide to a 69-mer DNA hairpin with a 13 base pair stem, bearing an Rsa1 restriction site. The 5' part of the 26-mer annealed to a stretch of six purines at the bottom of the hairpin. The 3' part was designed to fold back to form a triplex with both the stem of the hairpin and with the sequence paired to its own 5' region. Using non-denaturing polyacrylamide gel electrophoresis, melting curves (Tm) and chemical footprinting, we were able to show the formation of a 'double-hairpin' complex between the 69-mer and the 26-mer antisense oligopyrimidines. The association was both sequence and pH-dependent. The formation of a double hairpin complex was shown to prevent the alkylation of the 69-mer DNA target by an oligonucleotide-nitrogen mustard conjugate and to selectively inhibit the action of Rsa1.

Sensitive detection of low levels of ribonuclease H activity by an improved renaturation gel assay

Renaturation gel assays are good tools to assign enzymatic activities to protein bands. First, proteins are separated by denaturating electrophoresis on substrate-containing gels. Then, following the elimination of the denaturing agent, polypeptides are allowed to renature, thus leading to the degradation of the embedded substrate at positions at which the corresponding activity has moved. Nevertheless, this in situ technique does not only reflect a certain amount of enzyme activity, it also depends upon the ability of an enzyme to renature. Here we present a renaturation gel assay procedure with an improved sensitivity and discuss the detection of E. coli and human ribonuclease H activities as an example.

Antisense effect of oligodeoxynucleotides complementary to the mini-exon sequence of the protozoan parasite Leishmania amazonensis

We have targeted the mini-exon of Leishmania amazonensis, the sequence present at the 5' end of every mRNA of this protozoan parasite, with a complementary 12-mer, either unmodified (12 Le II) or linked to an acridine derivative (12 Le II Acr). Physical measurements performed either in solution or on nitrocellulose filters showed that the two oligomers exhibited the same affinity for both DNA and RNA target sequences. Furthermore, the two oligomers 12 Le II and 12 Le II Acr inhibited in vitro translation of L amazonensis mRNAs, in a wheat germ extract, to the same extent. Those results indicated that the intercalating agent did not stabilize the duplex formed by the antisense oligomer and its target sequence.

RNase H-mediated inhibition of translation by antisense oligodeoxyribonucleotides: use of backbone modification to improve specificity

A sequence of the rabbit alpha-globin mRNA is the primary target for ODN1, an unmodified 15-nucleotide (nt) antisense oligodeoxyribonucleotide (oligo). ODN1 prevented in vitro translation of both alpha- and beta-globin mRNAs in wheat germ extract. Nine secondary sites exhibiting more than 60% complementarity with ODN1 were present in the beta-globin message. The ODN1 inhibition of beta-globin synthesis was shown to be mediated by RNase H cleavage of the beta-globin mRNA at three partially complementary sites. Sandwich-type oligos consisting of a stretch of unmodified nt with a few methylphosphonate residues at both 5' and 3' ends were derived from ODN1. We have demonstrated that one such analogue (ODN2), with five phosphodiester linkages in the central region, exhibited improved specificity for alpha-globin mRNA compared with the unmodified parent 15-mer, due to a reduced ability of RNase H to cleave beta-mRNA/ODN2 mismatched duplexes.

Effect of the terminal phosphate derivatization of beta- and alpha-oligodeoxynucleotides on their antisense activity in protein biosynthesis, stability and uptake by eucaryotic cells

Inhibition of polypeptide chain elongation with the mRNA-complementary (antisense) oligonucleotide has been realized through a RNase H independent mechanism. Nuclease resistant complementary non-natural alpha-17-mer oligonucleotide did not inhibit cell-free protein biosynthesis of beta-globin in the wheat germ system because it did not elicit RNase H activity. Linkage of alkylating group [4-(N-2-chloroethyl-N-methyl)-aminobenzyl]-methylamine to the 5'-terminus of the alpha-oligomer led to the formation of its covalent adduct with mRNA which could not be translated in vitro. Linkage of hydrophobic residues to the terminal phosphates of natural oligonucleotides increased their stability against nucleases and uptake by human cancer cells. A porphyrin, substituted in the meso-position by aromatic groups, gave a rise to an approximately six-fold increase of uptake and cholesterol a 30-100-fold increase. Eighty percent of bound derivatives were found in cytoplasmic cellular fractions.

Mechanisms of the inhibition of reverse transcription by antisense oligonucleotides

We have demonstrated that the synthesis of cDNA by avian myeloblastosis virus and Moloney murine leukemia virus reverse transcriptases can be prevented by oligonucleotides bound to the RNA template approximately 100 nucleotides remote from the 3' end of the primer. The RNA was truncated at the level of the antisense oligonucleotide-RNA duplex during the reverse transcription. The key role played by the reverse transcriptase-associated RNase H activity in the inhibition process was shown by the use of (i) inhibitors of RNase H (NaF or dAMP), (ii) Moloney murine leukemia virus reverse transcriptase devoid of RNase H activity, or (iii) alpha-analogues of oligomers that do not elicit RNase H-catalyzed RNA degradation. In all three cases the inhibitory effect was either reduced (NaF, dAMP) or totally abolished. However, an alpha-oligomer bound to the sequence immediately adjacent to the primer-binding site prevented reverse transcription. Therefore, initiation of polymerization can be blocked by means of an RNase H-independent mechanism, whereas arrest of a growing cDNA strand can be achieved only by an oligonucleotide mediating cleavage of the template RNA.