Inhibition of restriction endonuclease cleavage via triple helix formation by homopyrimidine oligonucleotides

Nucleosomes Stabilize ssRNA-dsDNA Triple Helices in Human Cells

Chromatin-associated non-coding RNAs modulate the epigenetic landscape and its associated gene expression program. The formation of triple helices is one mechanism of sequence-specific targeting of RNA to chromatin. With this study, we show an important role of the nucleosome and its relative positioning to the triplex targeting site (TTS) in stabilizing RNA-DNA triplexes in vitro and in vivo. Triplex stabilization depends on the histone H3 tail and the location of the TTS close to the nucleosomal DNA entry-exit site. Genome-wide analysis of TTS-nucleosome arrangements revealed a defined chromatin organization with an enrichment of arrangements that allow triplex formation at active regulatory sites and accessible chromatin. We further developed a method to monitor nucleosome-RNA triplexes in vivo (TRIP-seq), revealing RNA binding to TTS sites adjacent to nucleosomes. Our data strongly support an activating role for RNA triplex-nucleosome complexes, pinpointing triplex-mediated epigenetic regulation in vivo.

Therapeutic genome mutagenesis using synthetic donor DNA and triplex-forming molecules

Genome mutagenesis can be achieved in a variety of ways, though a select few are suitable for therapeutic settings. Among them, the harnessing of intracellular homologous recombination affords the safety and efficacy profile suitable for such settings. Recombinagenic donor DNA and mutagenic triplex-forming molecules co-opt this natural recombination phenomenon to enable the specific, heritable editing and targeting of the genome. Editing the genome is achieved by designing the sequence-specific recombinagenic donor DNA to have base mismatches, insertions, and deletions that will be incorporated into the genome when it is used as a template for recombination. Targeting the genome is similarly achieved by designing the sequence-specific mutagenic triplex-forming molecules to further recruit the recombination machinery thereby upregulating its activity with the recombinagenic donor DNA. This combination of extracellularly introduced, designed synthetic molecules and intercellularly ubiquitous, evolved natural machinery enables the mutagenesis of chromosomes and engineering of whole genomes with great fidelity while limiting nonspecific interactions. Herein, we demonstrate the harnessing of recombinagenic donor DNA and mutagenic triplex-forming molecular technology for potential therapeutic applications. These demonstrations involve, among others, utilizing this technology to correct genes so that they become physiologically functional, to induce dormant yet functional genes in place of non-functional counterparts, to place induced genes under regulatory elements, and to disrupt genes to abrogate a cellular vulnerability. Ancillary demonstrations of the design and synthesis of this recombinagenic and mutagenic molecular technology as well as their delivery and assayed interaction with duplex DNA reveal a potent technological platform for engineering specific changes into the living genome.

Triplex-mediated genome targeting and editing

Genome targeting and editing in vitro and in vivo can be achieved through an interplay of exogenously introduced molecules and the induction of endogenous recombination machinery. The former includes a repertoire of sequence-specific binding molecules for targeted induction and appropriation of this machinery, such as by triplex-forming oligonucleotides (TFOs) or triplex-forming peptide nucleic acids (PNAs) and recombinagenic donor DNA, respectively. This versatile targeting and editing via recombination approach facilitates high-fidelity and low-off-target genome mutagenesis, repair, expression, and regulation. Herein, we describe the current state-of-the-art in triplex-mediated genome targeting and editing with a perspective towards potential translational and therapeutic applications. We detail several materials and methods for the design, delivery, and use of triplex-forming and recombinagenic molecules for mediating and introducing specific, heritable, and safe genomic modifications. Furthermore we denote some guidelines for endogenous genome targeting and editing site identification and techniques to test targeting and editing efficiency.

Conjugation of a 3-(1H-phenanthro[9,10-d]imidazol-2-yl)-1H-indole intercalator to a triplex oligonucleotide and to a three-way junction

A new intercalating nucleic acid monomer M comprising a 4-(1-indole)-butane-1,2-diol moiety was synthesized via a classical alkylation reaction of indole-3-carboxaldehyde followed by a condensation reaction with phenanthrene-9,10-dione in the presence of ammonium acetate to form a phenanthroimidazole moiety linked to the indole ring. Insertion of the new intercalator as a bulge into a Triplex Forming Oligonucleotide resulted in good thermal stability of the corresponding Hoogsteen-type triplexes. Molecular modeling supports the possible intercalating ability of M. Hybridisation properties of DNA/DNA and RNA/DNA three-way junctions (TWJ) with M in the branching point were also evaluated by their thermal stability at pH 7. DNA/DNA TWJ showed increase in thermal stability compared to wild type oligonucleotides whereas this was not the case for RNA/DNA TWJ.

Calorimetric and spectroscopic studies of aminoglycoside binding to AT-rich DNA triple helices

Calorimetric and fluorescence techniques were used to characterize the binding of aminoglycosides-neomycin, paromomycin, and ribostamycin, with 5'-dA(12)-x-dT(12)-x-dT(12)-3' intramolecular DNA triplex (x = hexaethylene glycol) and poly(dA).2poly(dT) triplex. Our results demonstrate the following features: (1) UV thermal analysis reveals that the T(m) for triplex decreases with increasing pH value in the presence of neomycin, while the T(m) for the duplex remains unchanged. (2) The binding affinity of neomycin decreases with increased pH, although there is an increase in observed binding enthalpy. (3) ITC studies conducted in two buffers (sodium cacodylate and MOPS) yield the number of protonated drug amino groups (Deltan) as 0.29 and 0.40 for neomycin and paromomycin interaction with 5'-dA(12)-x-dT(12)-x-dT(12)-3', respectively. (4) The specific heat capacity change (DeltaC(p)) determined by ITC studies is negative, with more negative values at lower salt concentrations. From 100 mM to 250 mM KCl, the DeltaC(p) ranges from -402 to -60 cal/(mol K) for neomycin. At pH 5.5, a more positive DeltaC(p) is observed, with a value of -98 cal/(mol K) at 100 mM KCl. DeltaC(p) is not significantly affected by ionic strength. (5) Salt dependence studies reveal that there are at least three amino groups of neomycin participating in the electrostatic interactions with the triplex. (6) FID studies using thiazole orange were used to derive the AC(50) (aminoglycoside concentration needed to displace 50% of the dye from the triplex) values. Neomycin shows a seven fold higher affinity than paromomycin and eleven fold higher affinity than ribostamycin at pH 6.8. (7) Modeling studies, consistent with UV and ITC results, show the importance of an additional positive charge in triplex recognition by neomycin. The modeling and thermodynamic studies indicate that neomycin binding to the DNA triplex depends upon significant contributions from charge as well as shape complementarity of the drug to the DNA triplex Watson-Hoogsteen groove.

Synthesis, pharmacology, and cell biology of sn-2-aminooxy analogues of lysophosphatidic acid

An efficient enantioselective synthesis of sn-2-aminooxy (AO) analogues of lysophosphatidic acid (LPA) that possess palmitoyl and oleoyl acyl chains is presented. Both sn-2-AO LPA analogues are agonists for the LPA1, LPA2, and LPA4 G-protein-coupled receptors, but antagonists for the LPA3 receptor and inhibitors of autotaxin (ATX). Moreover, both analogues stimulate migration of intestinal epithelial cells in a scratch wound assay.

Triplex-mediated gene modification

Gene targeting with DNA-binding molecules such as triplex-forming oligonucleotides or peptide nucleic acids can be utilized to direct mutagenesis or induce recombination site-specifically. In this chapter, several detailed protocols are described for the design and use of triplex-forming molecules to bind and mediate gene modification at specific chromosomal targets. Target site identification, binding molecule design, as well as various methods to test binding and assess gene modification are described.

Design of sequence-specific bifunctional nucleic acid ligands

Homopyrimidine oligodeoxynucleotides have been covalently linked to intercalating agents. These bifunctional nucleic acid ligands bind to the major groove of DNA at homopurine.homopyrimidine sequences, where they form triple helices. The homopyrimidine oligonucleotide binds parallel to the purine strand of the double helix. Two hydrogen bonds are formed between bases of the oligonucleotide and the purines engaged in Watson-Crick base pairs. The intercalating agent inserts its aromatic ring at the triplex-duplex junction, resulting in a strong stabilization of the triple helical structure. Bifunctional oligonucleotide-intercalator conjugates provide new tools for a selective control of gene expression. In addition, irreversible reactions can be targeted to the oligonucleotide recognition sequence. Cleavage reactions can be induced by a copper-phenanthroline chelate or an ellipticine derivative covalently linked to the triple helix-forming oligonucleotide.

PNA/dsDNA complexes: site specific binding and dsDNA biosensor applications

The ability of peptide nucleic acids (PNA) to form specific higher-order (i.e., three- and four-stranded) complexes with DNA makes it an ideal structural probe for designing strand-specific dsDNA biosensors. Higher-order complexes are formed between a dye-labeled charge-neutral PNA probe and complementary dsDNA. Addition of a light-harvesting cationic conjugated polymer (CCP) yields supramolecular structures held together by electrostatic forces that incorporate the CCP and the dye-labeled PNA/DNA complexes. Optimization of optical properties allows for excitation of the CCP and subsequent fluorescence resonance energy transfer (FRET) to the PNA-bound dye. In the case of noncomplementary dsDNA, complexation between the probe and target does not occur, and dye emission is weak. The binding between PNA and noncomplementary and complementary dsDNA was examined by several methods. Gel electrophoresis confirms specificity of binding and the formation of higher-order complexes. Nano-electrospray mass spectrometry gives insight into the stoichiometric composition, including PNA/DNA, PNA(2)/DNA, PNA/DNA(2), and PNA(2)/DNA(2) complexes. Finally, structural characteristics and binding-site specificity were examined using ion mobility mass spectrometry in conjunction with molecular dynamics. These results give possible conformations for each of the higher-order complexes formed and show exclusive binding of PNA to the complementary stretch of DNA for all PNA/DNA complexes. Overall, the capability and specificity of binding indicates that the CCP/PNA assay is a feasible detection method for dsDNA and eliminates the need for thermal denaturing steps typically required for DNA hybridization probe assays.

High-affinity triplex-forming oligonucleotide target sequences in mammalian genomes

Site-specific recognition of duplex DNA by triplex-forming oligonucleotides (TFOs) provides a promising approach to manipulate mammalian genomes. A prerequisite for successful gene targeting using this approach is that the targeted gene must contain specific, high-affinity TFO target sequences (TTS). To date, TTS have been identified and characterized in only approximately 37 human or rodent genes, limiting the application of triplex-directed gene targeting. We searched the complete human and mouse genomes using an algorithm designed to identify high-affinity TTS. The resulting data set contains 1.9 million potential TTS for each species. We found that 97.8% of known human and 95.2% of known mouse genes have at least one potential high-affinity TTS in the promoter and/or transcribed gene regions. Importantly, 86.5% of known human and 83% of the known mouse genes have at least one TTS that is unique to that gene. Thus, it is possible to target the majority of human and mouse genes with specific TFOs. We found substantially more potential TTS in the promoter sequences than in the transcribed gene sequences or intergenic sequences in both genomes. We selected 12 mouse genes and 2 human genes critical for cell signaling, proliferation, and/or carcinogenesis, identified potential TTS in each, and determined TFO binding affinities to these sites in vitro. We identified at least one high-affinity, specific TFO binding site within each of these genes. Using this information, many genes involved in mammalian cell proliferation and carcinogenesis can now be targeted.

Base triplet nonisomorphism strongly influences DNA triplex conformation: Effect of nonisomorphic G∗︁ GC and A∗︁ AT triplets and bending of DNA triplexes

Structural understanding of DNA triplexes is grossly inadequate despite their efficacy as therapeutic agents. Lack of structural similarity (isomorphism) of base triplets that figure in different DNA triplexes brings in an added complexity. Recently, we have shown that the residual twist (Deltat degrees ) and the radial difference (Deltar A) adequately define base triplet nonisomorphism in structural terms and allow assessment of their role in conferring stability as well as sequence-dependent structural variations in DNA triplexes. To further corroborate these, molecular dynamics (MD) simulations are carried out on DNA triplexes comprising nonisomorphic G* GC and A* AT base triplets under different sequential contexts. Base triplet nonisomorphism between G* GC and A* AT triplets is dominated by Deltat degrees (9.8 degrees ), in view of small Deltar (0.2 A), and is in contrast to G* GC and T* AT triplets where both Deltat degrees (10.6 degrees ) and Deltar (1.1A) are prominent. Results show that Deltat degrees alone enforces mechanistic influence on the triplex-forming purine strand so as to favor a zigzag conformation with alternating conformational features that include high (40 degrees ) and low (20 degrees ) helical twists, and high anti(G) and anti(A) glycosyl conformation. Higher thermal stability of this triplex compared to that formed with G* GC and T* AT triplets can be traced to enhanced base-stacking and counterion interactions. Surprisingly, it is found for the first time that the presence of a nonisomorphic G* GC or A* AT base triplet interrupting an otherwise mini A* AT or G* GC isomorphic triplex can induce a bend/curvature in a DNA triplex. These observations should prove useful in the design of triplex-forming oligonucleotides and in the understanding the binding affinities of this triplex with proteins.

Enzymatic and mechanistic studies on the formation of N-phenylglycolohydroxamic acid from nitrosobenzene and pyruvate in spinach leaf homogenate

The biotransformation mechanism of an unknown metabolite formed enzymatically from nitrosobenzene (NOB) and pyruvate in spinach (Spinacea oleracea L.) was investigated using spinach leaf homogenate. The unknown metabolite was identified as N-phenylglycolohydroxamic acid (PGA). The activity of PGA formation was decreased by l-alanine, increased by l-serine, and completely inhibited by aminooxyacetic acid, an inhibitor of transaminases. These results indicate that the transaminase participates in PGA formation. Indeed, hydroxypyruvate and alanine were produced in the transamination between pyruvate and serine. Hydroxypyruvate served as a direct-acting glycoloyl donor for PGA formation. A good correlation between the activities of the 200 g supernatant of spinach homogenate and commercial yeast transketolase for PGA formation from several glycoloyl donors was obtained. These results suggest the following mechanism for PGA formation from NOB and pyruvate: transamination of l-serine into hydroxypyruvate, which serves as a glycoloyl donor to NOB.

Factors influencing resistance of UV-irradiated DNA to the restriction endonuclease cleavage

DNA molecules of pUC19, pBR322 and PhiX174 were irradiated by various doses of UV light and the irradiated molecules were cleaved by about two dozen type II restrictases. The irradiation generally blocked the cleavage in a dose-dependent way. In accordance with previous studies, the (A + T)-richness and the (PyPy) dimer content of the restriction site belongs among the factors that on average, cause an increase in the resistance of UV damaged DNA to the restrictase cleavage. However, we observed strong effects of UV irradiation even with (G + C)-rich and (PyPy)-poor sites. In addition, sequences flanking the restriction site influenced the protection in some cases (e.g. HindIII), but not in others (e.g. SalI), whereas neoschizomer couples SmaI and AvaI, or SacI and Ecl136II, cleaved the UV-irradiated DNA similarly. Hence the intrastrand thymine dimers located in the recognition site are not the only photoproduct blocking the restrictases. UV irradiation of the A-form generally made the irradiated DNA less resistant to restrictase cleavage than irradiation in the B-form and in some cases, the A-form completely protected the UV-irradiated DNA against the damage recognized by the restrictases. The present results also demonstrate that the UV irradiation approach used to generate partial digests in genomic DNA studies, can be extended to the (G + C)-rich and (PyPy)-poor restriction sites. The present extensive and quantitative data can be used in genomic applications of UV damage probing by restrictases.

Bimolecular triplex formation between 5'-d-(AG)nT4(CT)n and 5'-d-(TC)n as functions of helix length and buffer

It was observed that a group of unusually stable DNA hairpins (Hn: 5'-d-(AG)nT4(CT)n, n = 2-4) were directed to homopyrimidine sequences (Pn: 5'-d-(TC)n) by py x pu x py-type triplex formation, resulting in high binding affinity and specificity. The spectroscopic results (UV and CD) showed that the short bimolecular triplex Hn:Pn could be formed in acidic conditions (pH 4.5-6.0) as helix length n > 2, and further extending to neutral pH as n = 4. This hairpin strategy for recognition of a pyrimidine strand has a substantial binding advantage over either the conventional linear analog or simple Watson-Crick complement. Triplex stability of Hn with Pn is not only pH-dependent, as expected for triplexes involving C+. GC triads, but also sensitive to the buffer. The triplex H4:P4 was formed in the phosphate buffers of pH 6.0-7.0 but already dissociated above pH 6.5 in the buffer of cacodylate, MOPSO or PIPES. By contrast, the nature of a buffer had no major influence on stability of a hairpin duplex. Here we provide a simple triplex system, and the data presented here may be useful in defining the experimental conditions necessary to stabilize triplex DNA.

New insights into DNA triplexes: residual twist and radial difference as measures of base triplet non-isomorphism and their implication to sequence-dependent non-uniform DNA triplex

DNA triplexes are formed by both isomorphic (structurally alike) and non-isomorphic (structurally dissimilar) base triplets. It is espoused here that (i) the base triplet non-isomorphism may be articulated in structural terms by a residual twist (Delta(t) degrees), the angle formed by line joining the C1'...C1' atoms of the adjacent Hoogsteen or reverse Hoogsteen (RH) base pairs and the difference in base triplet radius (Delta(r) A), and (ii) their influence on DNA triplex is largely mechanistic, leading to the prediction of a high (t + Delta(t))degrees and low (t - Deltat)degrees twist at the successive steps of Hoogsteen or RH duplex of a parallel or antiparallel triplex. Efficacy of this concept is corroborated by molecular dynamics (MD) simulation of an antiparallel DNA triplex comprising alternating non-isomorphic G*GC and T*AT triplets. Conformational changes necessitated by base triplet non-isomorphism are found to induce an alternating (i) high anti and anti glycosyl and (ii) BII and an unusual BIII conformation resulting in a zigzag backbone for the RH strand. Thus, base triplet non-isomorphism causes DNA triplexes into exhibiting sequence-dependent non-uniform conformation. Such structural variations may be relevant in deciphering the specificity of interaction with DNA triplex binding proteins. Seemingly then, residual twist (Delta(t) degrees) and radial difference (Deltar A) suffice as indices to define and monitor the effect of base triplet non-isomorphism in nucleic acid triplexes.

Interactions of cryptolepine and neocryptolepine with unusual DNA structures

Cryptolepine, the main alkaloid present in the roots of Cryptolepis sanguinolenta, presents a large spectrum of biological properties. It has been reported to behave like a DNA intercalator with a preference for GC-rich sequences. In this study, dialysis competition assay and mass spectrometry experiments were used to determine the affinity of cryptolepine and neocryptolepine for DNA structures among duplexes, triplexes, quadruplexes and single strands. Our data confirm that cryptolepine and neocryptolepine prefer GC over AT-rich duplex sequences, but also recognize triplex and quadruplex structures. These compounds are weak telomerase inhibitors and exhibit a significant preference for triplexes over quadruplexes or duplexes.

Inhibition of sequence-specific protein-DNA interaction and restriction endonuclease cleavage via triplex stabilization by poly(L-lysine)-graft-dextran copolymer

Triplex stabilization by poly(L-lysine)-graft-dextran copolymer within a mammalian gene promoter inhibits the DNA binding activity of nuclear proteins from HeLa cells as well as restriction endonuclease cleavage at physiological pH and ionic conditions in vitro. Electrophoretic mobility shift assays using a 30-mer homopurine-homopyrimidine stretch (located between -170 and -141 bp) of rat alpha 1 (I) collagen gene promoter reveal that the copolymer, at its wide range of charge ratio with DNA, stabilizes triplex DNA and enhances triplex-specific inhibition of the protein-DNA interaction. When the triplex-forming region (located between -165 and -146 bp) of the promoter is engineered at the Bam H1 and Pst 1 sites of a plasmid DNA, copolymer-mediated triplex stabilization also remarkably competes endonuclease activity of BamH1. Finally, the triplex-stabilizing efficiency of the copolymer is remarkably higher than that of spermine and benzo[e]pyridoindole. Our results indicate that the copolymer, regardless of the length of the target duplex, stabilizes triplexes for significant inhibition of protein-DNA interaction and endonuclease activity. Since stable triplex formation within a short region out of a long native duplex is a prerequisite to confer the therapeutic potential of antigene strategy, triplex stabilization on a long target duplex and inhibition of nuclear protein-DNA interaction may open the possible in vivo applicability of the copolymer.

Formation of DNA triple helix containing N(4)-(6-aminopyridin-2-yl)-2'-deoxycytidine

A cytidinyl derivative, N(4)-(6-aminopyridin-2-yl)- 2'-deoxycytidine ((p)C), could interact with a CG base pair to support the triple-helix (triplex) formation of oligodeoxyribonucleotides. Characteristics of (p)C in the formation of both intramolecular triplex, i.e., a "paper clip type" triplex ((P)CT) and intermolecular triplex, i.e., a "linear type" triplex (LT) was monitored by optical methods and isothermal titration calorimetric measurements. Experimental results revealed that the LT with (p)C*CG internally was independent of the solution pH. Only single substitution of (p)C, situated internally but not terminally, facilitated the (P)CT formation by the UV thermal melting study at the neutral pH. However, the best stabilization of the PCT in acidic conditions occurred when (p)C at the end of the triplex rather than internally. In addition, an LT, but not a (P)CT, containing an alternating (p)CT(p)CT(p)C sequence, could be formed in the conditions of 20 mM MgCl(2) and/or 5 mM spermine. Thus, the presence of several nucleotides of (p)C in proximity along the Hoogsteen strand may lead to structural distortion such that the more flexible LT with multiple substitutions is formed in favor of the more rigid PCT.

Chromosome targeting at short polypurine sites by cationic triplex-forming oligonucleotides

Triplex-forming oligonucleotides (TFOs) bind specifically to duplex DNA and provide a strategy for site-directed modification of genomic DNA. Recently we demonstrated TFO-mediated targeted gene knockout following systemic administration in animals. However, a limitation to this approach is the requirement for a polypurine tract (typically 15-30 base pairs (bp)) in the target DNA to afford high affinity third strand binding, thus restricting the number of sites available for effective targeting. To overcome this limitation, we have investigated the ability of chemically modified TFOs to target a short (10 bp) site in a chromosomal locus in mouse cells and induce site-specific mutations. We report that replacement of the phosphodiester backbone with cationic phosphoramidate linkages, either N,N-diethylethylenediamine or N,N-dimethylaminopropylamine, in a 10-nucleotide, psoralen-conjugated TFO confers substantial increases in binding affinity in vitro and is required to achieve targeted modification of a chromosomal reporter gene in mammalian cells. The triplex-directed, site-specific induction of mutagenesis in the chromosomal target was charge- and modification-dependent, with the activity of N,N-diethylethylenediamine > N,N-dimethylaminopropylamine phosphodiester, resulting in 10-, 6-, and <2-fold induction of target gene mutagenesis, respectively. Similarly, N,N-diethylethylenediamine and N,N-dimethylaminopropylamine TFOs were found to enhance targeting at a 16-bp G:C bp-rich target site in a chromatinized episomal target in monkey COS cells, although this longer site was also targetable by a phosphodiester TFO. These results indicate that replacement of phosphodiester bonds with positively charged N,N-diethylethylenediamine linkages enhances intracellular activity and allows targeting of relatively short polypurine sites, thereby substantially expanding the number of potential triplex target sites in the genome.

Energetics of strand-displacement reactions in triple helices: a spectroscopic study

DNA triple helices offer exciting new perspectives toward oligonucleotide-directed inhibition of gene expression. Purine and GT triplexes appear to be the most promising motifs for stable binding under physiological conditions compared to the pyrimidine motif, which forms at relatively low pH. There are, however, very little data available for comparison of the relative stabilities of the different classes of triplexes under identical conditions. We, therefore, designed a model system which allowed us to set up a competition between the oligonucleotides of the purine and pyrimidine motifs targeting the same Watson-Crick duplex. Several conclusions may be drawn: (i) a weak hypochromism at 260 nm is associated with purine triplex formation; (ii) delta H degree of GA, GT and TC triplex formation (at pH 7.0) was calculated as -0.1, -2.5 and -6.1 kcal/mol per base triplet, respectively. This unexpectedly low delta H degree for the purine triple helix formation implies that its delta G degree is nearly temperature-independent and it explains why these triplexes may still be observed at high temperatures. In contrast, the pyrimidine triplex is strongly favoured at lower temperatures; (iii) as a consequence, in a system where two third-strands compete for triplex formation, displacement of the GA or GT strand by a pyrimidine strand may be observed at neutral pH upon lowering the temperature. This original purine-to-pyrimidine triplex conversion shows a significant hypochromism at 260 nm and a hyperchromism at 295 nm which is similar to the duplex-to-triplex conversion in the pyrimidine motif. Further evidence for this triplex-to-triplex conversion is provided by mung bean-nuclease foot-printing assay.

Towards a new concept of gene inactivation: specific RNA cleavage by endogenous ribonuclease P

In the first part of this chapter, general concepts for gene inactivation, antisense techniques and catalytic RNAs (ribozymes) are presented. The requirements for modified oligonucleotides are discussed with their effects on the stability of base-paired hybrids and on resistance against nuclease attack. This also includes the problems in the choice of an optimal target sequence within the inactivated RNA and the options of cellular delivery systems. The second part describes the recently introduced antisense concept based on the ubiquitous cellular enzyme ribonuclease P. This system is unique, since the substrate recognition requires the proper tertiary structure of the cleaved RNA. General properties and possible advantages of this approach are discussed.

Triple helices formed at oligopyrimidine*oligopurine sequences with base pair inversions: effect of a triplex-specific ligand on stability and selectivity

Oligonucleotide-directed triple helix formation is mostly restricted to oligopyrimidine*oligopurine sequences of double helical DNA. An interruption of one or two pyrimidines in the oligopurine target strand leads to a strong triplex destabilisation. We have investigated the effect of nucleotide analogues introduced in the third strand at the site opposite the base pair inversion(s). We show that a 3-nitropyrrole derivative (M) discriminates G*C from C*G, A*T and T*A in the presence of a triplex-specific ligand (a benzo[e]pyridoindole derivative, BePI). N6-methoxy-2,6-diaminopurine (K) binds to an A*T base pair better than a T*A, G*C or C*G base pair. Some discrimination is still observed in the presence of BePI and triplex stability is markedly increased. These findings should help in designing BePI-oligonucleotide conjugates to extend the range of DNA sequences available for triplex formation.

Triplex formation at physiological pH: comparative studies on DNA triplexes containing 5-Me-dC tethered at N4 with spermine and tetraethyleneoxyamine

Oligodeoxynucleotides with spermine conjugation at C4 of 5-Me-dC ( sp -ODN) exhibit triple helix formation with complementary Watson-Crick duplexes, and were optimally stable at physiological pH 7.3 and low salt concentration. This was attributed to a favored reassociation of the polycationic third strand with the anionic DNA duplex. To gain further insights into the factors that contribute to the enhancement of triplex stability and for engineering improved triplex systems, the spermine appendage at C4 of 5-Me-dC was replaced with 1,11-diamino-3,6,9-trioxaundecane to create teg -ODNs. From the triple helix forming abilities of these modified ODNs studied by hysteresis behaviour and the effect of salts on triplex stability, it is demonstrated here that teg- ODNs stabilise triplexes through hydrophobic desolvation while sp -ODNs stabilise triplexes by charge effects. The results imply that factors in addition to base stacking effects and interstrand hydrogen bonds are significantly involved in modulation of triplex stability by base modified oligonucleotides.

Extension of the range of DNA sequences available for triple helix formation: stabilization of mismatched triplexes by acridine-containing oligonucleotides

Triple helix formation usually requires an oligopyrimidine*oligopurine sequence in the target DNA. A triple helix is destabilized when the oligopyrimidine*oligopurine target contains one (or two) purine*pyrimidine base pair inversion(s). Such an imperfect target sequence can be recognized by a third strand oligonucleotide containing an internally incorporated acridine intercalator facing the inverted purine*pyrimidine base pair(s). The loss of triplex stability due to the mismatch is partially overcome. The stability of triplexes formed at perfect and imperfect target sequences was investigated by UV thermal denaturation experiments. The stabilization provided by an internally incorporated acridine third strand oligonucleotide depends on the sequences flanking the inverted base pair. For triplexes containing a single mismatch the highest stabilization is observed for an acridine or a propanediol tethered to an acridine on its 3'-side facing an inverted A*T base pair and for a cytosine with an acridine incorporated to its 3'-side or a guanine with an acridine at its 5'-side facing an inverted G*C base pair. Fluorescence studies provided evidence that the acridine was intercalated into the triplex. The target sequences containing a double base pair inversion which form very unstable triplexes can still be recognized by oligonucleotides provided they contain an appropriately incorporated acridine facing the double mismatch sites. Selectivity for an A*T base pair inversion was observed with an oligonucleotide containing an acridine incorporated at the mismatched site when this site is flanked by two T*A*T base triplets. These results show that the range of DNA base sequences available for triplex formation can be extended by using oligonucleotide intercalator conjugates.

Effects of minor and major groove-binding drugs and intercalators on the DNA association of minor groove-binding proteins RecA and deoxyribonuclease I detected by flow linear dichroism

Linear and circular dichroic spectroscopies have been employed to investigate the effects of small DNA ligands on the interactions of two proteins which bind to the minor groove of DNA, viz. RecA protein from Escherichia coli and deoxyribonuclease I (bovine pancreas). Ligands representing three specific non-covalent binding modes were investigated: 4',6-diamidino-2-phenylindole and distamycin A (minor groove binders), methyl green (major groove binder), and methylene blue, ethidium bromide and ethidium dimer (intercalators). Linear dichroism was demonstrated to be an excellent detector, in real time, of DNA double-strand cleavage by deoxyribonuclease I. Ligands bound in all three modes interfered with the deoxyribonuclease I digestion of dsDNA, although the level of interference varied in a manner which could be related to the ligand binding site, the ligand charge appearing to be less important. In particular, the retardation of deoxyribonuclease I cleavage by the major groove binder methyl green demonstrates that accessibility to the minor groove can be affected by occupancy of the opposite groove. Binding of all three types of ligand also had marked effects on the interaction of RecA with dsDNA in the presence of non-hydrolyzable cofactor adenosine 5'-O-3-thiotriphosphate, decreasing the association rate to varying extents but with the strongest effects from ligands having some minor groove occupancy. Finally, each ligand was displaced from its DNA binding site upon completion of RecA association, again demonstrating that modification of either groove can affect the properties and behaviour of the other. The conclusions are discussed against the background of previous work on the use of small DNA ligands to probe DNA-protein interactions.

Properties of triple helix formation with oligodeoxyribonucleotides containing 8-oxo-2'-deoxyadenosine and 2'-modified nucleoside derivatives

The ability of homopyrimidine oligonucleotides containing 8-oxo-2'-deoxyadenosine (dAOH), 2'-methoxyuridine (Um), 2'-fluorouridine (Uf), 2'-methoxycytidine (Cm), and 2'-fluorocytidine (Cf) to form stable, triple-helical structures with sequences containing the recognition site for the class II-S restriction enzyme, Ksp632-I, was studied as a function of pH. The 8-oxo-2'-deoxyadenosine substituted oligomers were shown to bind within the physiological pH range in a pH-independent fashion, without a compromise in specificity. In particular, the substitutions of three deoxycytidine residues with 8-oxo-2'-deoxyadenosine showed higher endonuclease inhibition than the substitution of either one or two deoxycytidine residues with 8-oxo-2'-deoxyadenosine. In contrast, the oligonucleotides containing 2'-modified nucleosides (Uf, Um, Uf-Cf, Um-Cm, dAOH-Uf, and dAOH-Um) bind in a pH-dependent manner to the target duplex.

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.

Effect of third strand composition on the triple helix formation: purine versus pyrimidine oligodeoxynucleotides

Exon 5 of the human aprt gene contains an oligo-purine-oligopyrimidine stretch of 17 bp (5'-CCCTCTTCTCTCTCCT-3') within the coding region. (T,C)-, (G,T)- and (G,A)-containing oligonucleotides were compared for their ability to form stable triple helices with their DNA target. (G,T) oligodeoxynucleotides, whether parallel or antiparallel, were unable to bind to this sequence. This is in contrast to (G,A) (purine) and (T,C) (pyrimidine) oligonucleotides, which bind to the duplex at near neutral pH. Binding was highly sequence specific, as unrelated competitors were unable to interfere with target recognition. A major difference between the purine and pyrimidine oligodeoxynucleotides was observed in the kinetics of binding: the (G,A) oligonucleotide binds to its target much faster than the (T,C) oligomer. With the purine oligonucleotide, complete binding was achieved in a matter of minutes at micromolar concentrations, whereas several hours were required with the pyrimidine oligomer. Thus, the general observation that triplex formation is slow with pyrimidine oligodeoxynucleotides does not hold for (G,A) oligodeoxynucleotides. Purine and pyrimidine oligodeoxynucleotides covalently linked to a psoralen group were able to induce crosslinks on the double-stranded DNA target upon UV irradiation. This study provides a detailed comparison of the different types of DNA triplexes under the same experimental conditions.

Sequence specificity of triplex DNA formation: Analysis by a combinatorial approach, restriction endonuclease protection selection and amplification

We have devised a combinatorial method, restriction endonuclease protection selection and amplification (REPSA), to identify consensus ligand binding sequences in DNA. In this technique, cleavage by a type IIS restriction endonuclease (an enzyme that cleaves DNA at a site distal from its recognition sequence) is prevented by a bound ligand while unbound DNA is cleaved. Since the selection step of REPSA is performed in solution under mild conditions, this approach is amenable to the investigation of ligand-DNA complexes that are either insufficiently stable or not readily separable by other methods. Here we report the use of REPSA to identify the consensus duplex DNA sequence recognized by a G/T-rich oligodeoxyribonucleotide under conditions favoring purine-motif triple-helix formation. Analysis of 47 sequences indicated that recognition between 13 bases on the oligonucleotide 3' end and the duplex DNA was sufficient for triplex formation and indicated the possible existence of a new base triplet, G.AT. This information should help identify appropriate target sequences for purine-motif triplex formation and demonstrates the power of REPSA for investigating ligand-DNA interactions.

Triplex formation at physiological pH by 5-Me-dC-N4-(spermine) [X] oligodeoxynucleotides: non protonation of N3 in X of X*G:C triad and effect of base mismatch/ionic strength on triplex stabilities

Oligodeoxynucleotide (ODN) directed triplex formation has therapeutic importance and depends on Hoogsteen hydrogen bonds between a duplex DNA and a third DNA strand. T*A:T triplets are formed at neutral pH and C+*G:C are favoured at acidic pH. It is demonstrated that spermine conjugation at N4 of 5-Me-dC in ODNs 1-5 (sp-ODNs) imparts zwitterionic character, thus reducing the net negative charge of ODNs 1-5. sp-ODNs form triplexes with complementary 24mer duplex 8:9 show foremost stability at neutral pH 7.3 and decrease in stability towards lower pH, unlike the normal ODNs where optimal stability is found at an acidic pH 5.5. At pH 7.3, control ODNs 6 and 7 carrying dC or 5-Me-dC, respectively, do not show any triple helix formation. The stability order of triplex containing 5-Me-dC-N4-(spermine) with normal and mismatched duplex was found to be X*G:C approximately X*A:T > X*C:G > X*T:A. The hysteresis curve of sp-ODN triplex 3*8:9 indicated a better association with complementary duplex 8:9 as compared to unmodified ODN 6 in triplex 6*8:9. pH-dependent UV difference spectra suggest that N3 protonation is not a requirement for triplex formation by sp-ODN and interstrand interaction of conjugated spermine more than compensates for loss in stability due to absence of a single Hoogsteen hydrogen bond. These results may have importance in designing oligonucleotides for antigene applications.

Triplex-mediated, in vitro targeting of psoralen photoadducts within the genome of a transgenic mouse

Light-activated psoralens can covalently modify DNA and are widely used to study nucleic acid secondary structure and mutagenesis. Sequence specificity can be added to the photoaddition reaction by attaching the psoralen to an oligonucleotide designed to recognize a double-stranded DNA binding site through formation of a triple helix. We have previously used this strategy to study targeted psoralen modification of a triplex binding site within the bacterial supF gene carried in viral genomes. In the present work we report the targeting of psoralen photoadducts in vitro to a specific site in the genome of a transgenic mouse. Both 10 base and 16 base oligonucleotide-psoralen conjugates were capable of sequence-specific modification of genomic mouse DNA, while a truncated 8 base conjugate was not. Light activation was necessary, and a dose dependence was demonstrated for target site modification and mutagenesis. The 10 base conjugate rapidly found its target, with sequence-specific binding occurring after just 10 min incubation in the presence of mouse DNA. The ability to target psoralen photoadducts within mammalian genomes may prove useful in the study of chromatin structure and DNA repair. Moreover, this work may lead to potential in vivo applications of targeted psoralen modification.

Prospects for the therapeutic use of antigene oligonucleotides

An outgrowth of classic nucleic acid interaction studies, oligonucleotide-directed triple helix formation is a unique method for creating highly specific chemical ligands that recognize and bind to particular sequences of duplex DNA. Under permissive conditions, these oligonucleotide-based compounds can approach or exceed the binding affinity and sequence specificity of natural DNA-binding proteins. Triple helix recognition has been found to be useful in certain cell-free applications including precise chromosome fragmentation. It has been proposed that such oligonucleotides could also form the basis for gene-targeted (antigene) drugs that might repress transcription from undesired genes in living cells. However, current strategies for oligonucleotide-directed triple helix formation suffer from important constraints involving requirements for stabilizing binding conditions, restrictions on permitted target sequences, and inefficient nuclear delivery of oligonucleotides. Implementation of oligonucleotide-directed triple helix formation as a viable approach to cancer therapy must therefore await clever solutions to a series of fascinating problems.

Binding of RecA to anti-parallel poly(dA).2poly(dT) triple helix DNA

Binding of RecA protein to conventional anti-parallel poly(dA).2poly(dT) triplex DNA has been studied using flow linear dichroism spectroscopy. The association requires the presence of cofactor analog adenosine 5'-O-3-thiotriphosphate (ATP gamma S) and occurs with a rate similar to that for the association of RecA to double-stranded poly(dA).poly(dT) DNA. The binding of RecA to DNA stiffens the nucleotide chain, as evidenced from high orientation already at low shear rates, and the complex with triplex DNA appears to be at least as stiff as that with the duplex DNA. Therefore, the observation of a lower magnitude of the LD spectrum at 260 nm, in the triplex-RecA compared to the duplex-RecA complex, but retained magnitude of protein LD at 280 nm, indicates a markedly impaired orientation of nucleo-bases, possibly reflecting a perturbation by RecA on the third strand making its bases deviate strongly from perpendicularity. The circular dichroism spectrum, appearing immediately after dissociation of RecA by SDS, suggests an intact triplex structure, meaning that complexation with RecA has not dissociated the third strand. In conclusion, binding of RecA to triplex DNA does not modify the main organisation of the strands, but could affect the base-base interactions between them. Tilted bases could reflect a conformational change that RecA imposes also on the biological intermediate triplex structure to relax the base-base hydrogen bonding between the DNA strands.

Altered repair of targeted psoralen photoadducts in the context of an oligonucleotide-mediated triple helix

Oligonucleotides can bind as third strands of DNA in a sequence-specific manner to form triple helices. Psoralen-conjugated, triplex-forming oligonucleotides (TFOs) have been used for the site-specific modification of DNA to inhibit transcription and to target mutations to selected genes. Such strategies, however, must take into account the ability of the cell to repair the triplex-directed lesion. We report experiments showing that the pattern of mutations produced by triplex-targeted psoralen adducts in an SV40 shuttle vector in monkey COS cells can be influenced by the associated third strand. Mutations induced by psoralen adducts in the context of a TFO of length 10 were the same as those generated by isolated adducts but were found to be different from those generated in the presence of a TFO of length 30 at the same target site. In complementary experiments, HeLa whole cell extracts were used to directly assess repair of the TFO-directed psoralen adducts in vitro. Excision of the damaged DNA was inhibited in the context of the 30-mer TFO, but not the 10-mer. These results suggest that an extended triple helix of length 30, which exceeds the typical size of the nucleotide excision repair patch in mammalian cells, can alter repair of an associated psoralen adduct. We present a model correlating these results and proposing that the incision steps in nucleotide excision repair in mammalian cells can be blocked by the presence of a third strand of sufficient length and binding affinity, thereby changing the pattern of mutations. These results may have implications for the use of triplex-forming oligonucleotides for genetic manipulation, and they may lead to the use of such oligonucleotides as tools to probe DNA repair pathways.

A study of triplex formatin of 5'-d-T-(C-T-)2C-(T-)4C-(T-C-)2T with 5'-d-A-(G-A-)2G A hairpin triplex with three T.A.T and three C+.G.C bases triads

The UV mixing titration, gel electrophoresis, and CD measurements indicate that oligomers with a basic sequence of 5'-d-T-(C-T-)2C-(T-)4C-(T-C-)2T form a hairpin type triplex with the target 5'-d-A-(G-A-)2G. The stability, measured UV melting temperatures, were studied in aqueous solution as functions of mC (5-methylcytidine) replacement of C, pH (4 to 7), and salt concentrations (up to 1 M). The order of stability is 5'-d-A-(G-A-)2G + 5'-d-T-(C-T-)2C-(T-)4C-(T-C-)2T < 5'-d-A-(G-A-)2G + 5'-d-T-(mC-T-)2mC-(T-)4C-(T-C-)2T approximately 5'-d-A-(G-A-)2G + 5'-d-T-(C-T-)2C-(T-)4 mC-(T-mC-)2T < 5'-d-A-(G-A-)2G + 5'-d-T-(mC-T-)2mC-(T-)4mC-(T-mC-)2T at pH 4. These results indicate that (a) a stable triplex is formed with three T.A.T and three C+.G.C base triads and (b) mC is more effective than C to stablize the triplex formation in acidic condition. Thus, this provides a simple system for further studies of triplex.

DNA triple-helix formation: an approach to artificial gene repressors?

Certain sequences of double-helical DNA can be recognized and tightly bound by oligonucleotides. The effects of such triple-helical structures on DNA binding proteins have been studied. Stabilities of DNA triple-helices at or near physiological conditions are sufficient to inhibit DNA binding proteins directed to overlapping sites. Such proteins include restriction endonucleases, methylases, transcription factors, and RNA polymerases. These and other results suggest that oligonucleotide-directed triple-helix formation could provide the basis for designing artificial gene repressors. The general question of whether biological systems employ RNA molecules for recognition and regulation of double-helical DNA is discussed.

Antigene, ribozyme and aptamer nucleic acid drugs: progress and prospects

Nucleic acids are increasingly being considered for therapeutic uses, either to interfere with the function of specific nucleic acids or to bind specific proteins. Three types of nucleic acid drugs are discussed in this review: aptamers, compounds which bind specific proteins; triplex forming (antigene) compounds; which bind double stranded DNA; and ribozymes (catalytic RNA), which bind and cleave RNA targets. The binding of aptamers to protein may involve specific sequence recognition, although this is not always the case. The interaction of triplex forming oligonucleotides or ribozymes with their targets always involves specific sequence recognition and hybridization. Early optimism concerning the possibility of designing drugs without a priori knowledge of the structure of the target (except a nucleotide sequence) has been tempered by the finding that target structure has a dramatic effect upon the hybridization potential of the nucleic acid drug. Other obstacles to the creation of effective nucleic acid drugs are their relative high molecular weight (> 3300) and their sensitivity to degradation. The molecular weight of these compounds has created a significant delivery problem which needs to be solved if nucleic acid drugs are to become effective therapies.

Recognition of duplex DNA by RNA polynucleotides

We are interested in creating artificial gene repressors based on duplex DNA recognition by nucleic acids. Homopyrimidine RNA oligonucleotides bind to duplex DNA at homopurine/homopyrimidine sequences under slightly acidic conditions. Recognition is sequence-specific, involving rU.dA.dT and rC+.dG.dC base triplets. Affinities were determined for folded polymeric RNAs (ca. 100-200 nt) containing 0, 1 or 3 copies of a 21 nt RNA sequence that binds duplex DNA by triple helix formation. When this recognition sequence was inserted into the larger folded RNAs, micromolar concentrations of the resulting RNA ligands bound a duplex DNA target at pH 5. However, these binding affinities were at least 20-fold lower than the affinity of an RNA oligonucleotide containing only the recognition sequence. Enzymatic probing of folded RNAs suggests that reduced affinity arises from unfavorable electrostatic, structural and topological considerations. The affinity of a polymeric RNA with three copies of the recognition sequence was greater than that of a polymeric RNA with a single copy of the sequence. This affinity difference ranged from 2.6- to 13-fold, depending on pH. Binding of duplex DNA by polymeric RNA might be improved by optimizing the RNA structure to efficiently present the recognition sequence.

Inhibition of T7 RNA polymerase transcription by phosphate and phosphorothioate triplex-forming oligonucleotides targeted to a R.Y site downstream from the promoter

The effect of triplex-forming oligonucleotides (TFO) on the transcription activity of T7 RNA polymerase has been investigated by an in vitro assay. The TFOs, either containing only phosphate (PO2) or phosphate and phosphorothioate (POS) internucleotide linkages, were targeted to a 30-bp homopurine. homopyrimidine (R.Y) site cloned in plasmid Bluescript KS+ about four helical turns downstream from the T7 RNA promoter. Band-shift and ultraviolet absorption melting experiments showed that the designed pyrimidine PO2 and POS TFOs form stable triple-helical complexes with the R.Y target duplex (the delta GTFO values of triplex formation vary from -42 to -63 kJ/mol). The triple-helical complexes resulting from POS oligonucleotides were less stable (by 4-12 kJ/mol) than those obtained with PO2 analogues, the magnitude of destabilization being dependent on the number of POS groups present in the third strand. The designed TFOs were shown to efficiently repress bacteriophage T7 RNA polymerase transcription under different experimental conditions. The repression depended on pH, TFO concentration and temperature. When the TFO/template ratio was fixed to 100, a strong repressive effect was observed with normal and phosphorothioate pyrimidine TFOs, also under physiological conditions. In contrast, a purine-rich oligonucleotide containing 44% of guanine residues promoted only a weak transcription inhibition, even at a TFO/template ratio as high as 750. Both PO2- and POS-containing pyrimidine TFOs produced their strong repressive effect on T7 RNA polymerase transcription even when they were added to the reaction mixture simultaneously with the polymerase. A mechanism of transcription repression is discussed. The data reported in this paper are useful for designing oligonucleotides acting as artificial repressors in the antigene strategy and indicate that the R.Y target need not to be precisely confined to the promoter.