Triplex Binding Research Articles

Unraveling DNA Triplex Assembly: Mass Spectrometric Investigation of Modified Triplex Forming Oligonucleotides for Enhanced Gene Targeting.

Deoxyribonucleic acid triplexes have potential roles in a range of biological processes involving gene and transcriptional regulation. A major challenge in exploiting the formation of these higher-order structures to target genes in vivo is their low stability, which is dependent on many factors including the length and composition of bases in the sequence. Here, different DNA base modifications have been explored, primarily using native mass spectrometry, in efforts to enable stronger binding between the triplex forming oligonucleotide (TFO) and duplex target sites. These modifications can also be used to overcome pyrimidine interruptions in the duplex sequence in promoter regions of genomes, to expand triplex target sequences for antigene therapies. Using model sequences with a single pyrimidine interruption, triplex forming oligonucleotides containing locked nucleic acid base modifications were shown to have a higher triplex binding propensity than DNA-only and dSpacer-containing TFOs. However, the triplex forming ability of these systems was limited by the competitive formation of multiple higher order assemblies. Triplex forming sequences that correspond to specific gene targets from the Pseudomonas aeruginosa genome were also investigated, with LNA-containing TFOs the only variant able to form triplex using these sequences. This work indicates the advantages of utilizing synthetically modified TFOs to form triplex assemblies in vivo for potential therapeutic applications and highlights the advantages of native mass spectrometry for the study of their formation.

TRIPBASE: a database for identifying the human genomic DNA and lncRNA triplexes.

Long-non-coding RNAs (lncRNAs) are defined as RNA sequences which are >200 nt with no coding capacity. These lncRNAs participate in various biological mechanisms, and are widely abundant in a diversity of species. There is well-documented evidence that lncRNAs can interact with genomic DNAs by forming triple helices (triplexes). Previously, several computational methods have been designed based on the Hoogsteen base-pair rule to find theoretical RNA-DNA:DNA triplexes. While powerful, these methods suffer from a high false-positive rate between the predicted triplexes and the biological experiments. To address this issue, we first collected the experimental data of genomic RNA-DNA triplexes from antisense oligonucleotide (ASO)-mediated capture assays and used Triplexator, the most widely used tool for lncRNA-DNA interaction, to reveal the intrinsic information on true triplex binding potential. Based on the analysis, we proposed six computational attributes as filters to improve the in-silico triplex prediction by removing most false positives. Further, we have built a new database, TRIPBASE, as the first comprehensive collection of genome-wide triplex predictions of human lncRNAs. In TRIPBASE, the user interface allows scientists to apply customized filtering criteria to access the potential triplexes of human lncRNAs in the cis-regulatory regions of the human genome. TRIPBASE can be accessed at https://tripbase.iis.sinica.edu.tw/.

A universal model of RNA.DNA:DNA triplex formation accurately predicts genome-wide RNA-DNA interactions.

RNA.DNA:DNA triple helix (triplex) formation is a form of RNA-DNA interaction which regulates gene expression but is difficult to study experimentally in vivo. This makes accurate computational prediction of such interactions highly important in the field of RNA research. Current predictive methods use canonical Hoogsteen base pairing rules, which whilst biophysically valid, may not reflect the plastic nature of cell biology. Here, we present the first optimization approach to learn a probabilistic model describing RNA-DNA interactions directly from motifs derived from triplex sequencing data. We find that there are several stable interaction codes, including Hoogsteen base pairing and novel RNA-DNA base pairings, which agree with in vitro measurements. We implemented these findings in TriplexAligner, a program that uses the determined interaction codes to predict triplex binding. TriplexAligner predicts RNA-DNA interactions identified in all-to-all sequencing data more accurately than all previously published tools in human and mouse and also predicts previously studied triplex interactions with known regulatory functions. We further validated a novel triplex interaction using biophysical experiments. Our work is an important step towards better understanding of triplex formation and allows genome-wide analyses of RNA-DNA interactions.

5-Substituted 3, 3′, 4′, 7-tetramethoxyflavonoids – A novel class of potent DNA triplex specific binding ligands

Herein, we present a class of potent triplex DNA binding ligands derived from the natural product quercetin, which is the first of its kind that has ever been reported in the literature. The binding of 5-substituted quercetin derivatives (3, 3′, 4′, 7-tetramethoxyflavonoids) to triplex and duplex DNA was investigated using several biophysical tools, including thermal denaturation monitored by UV, circular dichroism, differential scanning calorimetry, and isothermal titration calorimetry. Experimental data reveal that several 5-substituted 3, 3′, 4′, 7-tetramethoxyflavonoids have remarkable effects on binding to DNA triple helices, and they do not influence the double-helical DNA structures. A few derivatives such as compounds 5 and 7 have comparable (if not better) binding affinities to neomycin, a well-known DNA triplex binding ligand, under the same conditions. The amino-containing side chains at the 5-position of 3, 3′, 4′, 7-tetramethoxyflavonoids are crucial for the observed binding affinity and specificity.

An Oligo-Library-Based Approach for Mapping DNA-DNA Triplex Interactions In Vitro.

We present Triplex-seq, a deep-sequencing method that systematically maps the interaction space between an oligo library of ssDNA triplex-forming oligos (TFOs) and a particular dsDNA triplex target site (TTS). We demonstrate the method using a randomized oligo library comprising 67 million variants, with five TTSs that differ in guanine (G) content, at two different buffer conditions, denoted pH 5 and pH 7. Our results show that G-rich triplexes form at both pH 5 and pH 7, with the pH 5 set being more stable, indicating that there is a subset of TFOs that form triplexes only at pH 5. In addition, using information analysis, we identify triplex-forming motifs (TFMs), which correspond to minimal functional TFO sequences. We demonstrate, in single-variant verification experiments, that TFOs with these TFMs indeed form a triplex with G-rich TTSs, and that a single mutation in the TFM motif can alleviate binding. Our results show that deep-sequencing platforms can substantially expand our understanding of triplex binding rules and aid in refining the DNA triplex code.

Functional Prediction of Candidate MicroRNAs for CRC Management Using in Silico Approach.

Approximately 30–50% of malignant growths can be prevented by avoiding risk factors and implementing evidence-based strategies. Colorectal cancer (CRC) accounted for the second most common cancer and the third most common cause of cancer death worldwide. This cancer subtype can be reduced by early detection and patients’ management. In this study, the functional roles of the identified microRNAs were determined using an in silico pipeline. Five microRNAs identified using an in silico approach alongside their seven target genes from our previous study were used as datasets in this study. Furthermore, the secondary structure and the thermodynamic energies of the microRNAs were revealed by Mfold algorithm. The triplex binding ability of the oligonucleotide with the target promoters were analyzed by Trident. Finally, evolutionary stage-specific somatic events and co-expression analysis of the target genes in CRC were analyzed by SEECancer and GeneMANIA plugin in Cytoscape. Four of the five microRNAs have the potential to form more than one secondary structure. The ranges of the observed/expected ratio of CpG dinucleotides of these genes range from 0.60 to 1.22. Three of the candidate microRNA were capable of forming multiple triplexes along with three of the target mRNAs. Four of the total targets were involved in either early or metastatic stage-specific events while three other genes were either a product of antecedent or subsequent events of the four genes implicated in CRC. The secondary structure of the candidate microRNAs can be used to explain the different degrees of genetic regulation in CRC due to their conformational role to modulate target interaction. Furthermore, due to the regulation of important genes in the CRC pathway and the enrichment of the microRNA with triplex binding sites, they may be a useful diagnostic biomarker for the disease subtype.

Binding properties of ruthenium(II) complexes [Ru(phen)2(dicnq)]2+ and [Ru(bpy)2(dicnq)]2+ with the RNA triplex poly(U)·poly(A)*poly(U)

Using phen or bpy (phen = 1,10-phenanthroline, bpy = 2,2′-bipyridine) as ancillary ligands and dicnq (dicnq = 6,7-dicyanodipyrido[2,2-d:2′,3′-f]quinoxaline) as the main ligand, two new Ru(II) polypyridyl complexes containing cyano groups, [Ru(phen)2dicnq]2+ (Ru1) and [Ru(bpy)2dicnq]2+ (Ru2) have been synthesized as binders for poly(U)·poly(A)*poly(U) triplex. The binding properties of Ru1 and Ru2 with the triplex has been studied by spectroscopic methods and viscosity measurements. Analysis of the electronic absorption spectra suggests that the binding of intercalating Ru1 with the triplex is greater than that of Ru2, which is also supported by spectroscopic titrations and viscosity measurements. Thermal denaturation studies suggest that the two complexes stabilize the Watson-Crick base-paired duplex of the triplex structure almost without affecting the stability of the Hoogsteen base-paired third strand, suggesting that the electron-withdrawing effect of cyano group hardly increases the binding strengths of the third strand and the template duplex of the triplex under study here. Changes in the CD (CD = circular dichroism) spectra of the triplex indicate that the binding-induced CD perturbation of the triplex structure is more marked with Ru1. The main results obtained here indicate that small differences in the ancillary ligands play important roles in the triplex binding when ruthenium(II) complexes contain the same intercalative ligands.

Exponential growth and selection in self-replicating materials from DNA origami rafts.

Self-replication and evolution under selective pressure are inherent phenomena in life, and but few artificial systems exhibit these phenomena. We have designed a system of DNA origami rafts that exponentially replicates a seed pattern, doubling the copies in each diurnal-like cycle of temperature and ultraviolet illumination, producing more than 7 million copies in 24 cycles. We demonstrate environmental selection in growing populations by incorporating pH-sensitive binding in two subpopulations. In one species, pH-sensitive triplex DNA bonds enable parent-daughter templating, while in the second species, triplex binding inhibits the formation of duplex DNA templating. At pH 5.3, the replication rate of species I is ∼1.3-1.4 times faster than that of species II. At pH 7.8, the replication rates are reversed. When mixed together in the same vial, the progeny of species I replicate preferentially at pH 7.8; similarly at pH 5.3, the progeny of species II take over the system. This addressable selectivity should be adaptable to the selection and evolution of multi-component self-replicating materials in the nanoscopic-to-microscopic size range.

Recognition Mechanisms and Applications of Peptide Nucleic Acids Targeting Double-stranded DNA.

Targeting double-stranded DNA (dsDNA) with high affinity and specificity has become a hot topic in biochemistry and molecular biology research. Gene diagnosis and therapy, DNA manipulation, and gene expression regulation could be achieved based on certain recognition principles through specific interactions between dsDNA and natural nucleotides or synthesized ligands. Some ligands (e.g., peptide nucleic acids (PNAs), triple helix-forming oligonucleotides (TFOs), oligopolyamides, and zinc-finger peptides) show sufficient affinity and specificity for targeting dsDNA sequences. PNA can simply synthesize and recognize dsDNA without sequence limitation under physiological conditions. This paper provides a review on the recognition mechanisms, influencing factors, and applications of the four recognition modes of PNA targeting dsDNA. These modes include triplex invasion, triplex binding, duplex invasion, and double duplex invasion. This paper also discusses the challenges to be addressed by future research to fully explore the potential of PNA probe design for specific dsDNA recognition.

The Lack of Mutagenic Potential of a Guanine-Rich Triplex Forming Oligonucleotide in Physiological Conditions.

Triplex forming oligonucleotides (TFOs) bind in the major groove of DNA duplex in a sequence-specific manner imparted by Hoogsteen hydrogen bonds. There have been several reports demonstrating the ability of guanine-rich TFOs to induce targeted mutagenesis on an exogenous plasmid or an endogenous chromosomal locus. In particular, a 30mer guanine-rich triplex forming oligonucleotide, AG30, optimally designed to target the supFG1 reporter gene was reported to be mutagenic in the absence of DNA reactive agents in cultured cells and in vivo Here, we investigated the mutagenic potential of AG30 using the supFG1 shuttle vector forward mutation assay under physiological conditions. We also assessed the triplex binding potential of AG30 alongside cytotoxic and mutagenic assessment. In a cell free condition, AG30 was able to bind its polypurine target site in the supFG1 gene in the absence of potassium chloride and also aligned with a 5-fold increase in the mutant frequency when AG30 was pre-incubated with the supFG1 plasmid in the absence of potassium prior to transfection into COS-7 cells. However, when we analyzed triplex formation of AG30 and the supFG1 target duplex at physiological potassium levels, triplex formation was inhibited due to the formation of competing secondary structures. Subsequent assessment of mutant frequency under physiological conditions, by pre-transfecting COS-7 cells with the supFG1 plasmid prior to AG30 treatment led to a very small increase (1.4-fold) in the mutant frequency. Transfection of cells with even higher concentrations of AG30 did result in an elevated mutagenic response but this was also seen with a scrambled sequence, and was therefore considered unlikely to be biologically relevant as an associated increase in cytotoxicity was also apparent. Our findings also provide further assurance on the low potential of triplex-mediated mutation as a consequence of unintentional genomic DNA binding by therapeutic antisense oligonucleotides.

Fluorescently Sensing of DNA Triplex Assembly Using an Isoquinoline Alkaloid as Selector, Stabilizer, Inducer, and Switch-On Emitter.

DNA triplex assembly has attracted a variety of interest in the regulation of genetic expression, drug screening, molecular switches, and sensors. However, these achievements are essentially dependent on the formation and stability of the triplex assembly. Herein, the recognition of DNA triplex assembly with various isoquinoline alkaloids was investigated. We found that natural chelerythrine (CHE) exhibits the highest selectivity in recognizing the triplex structure. The DNA triplex stability is substantially increased upon CHE binding, as opposed to the invariance in the stability of the duplex counterpart. CHE also favors the assembly of the triplex-forming oligonucleotide (TFO) with its duplex counterpart. The triplex binding switches CHE to a strong fluorescent emitter, which suggests CHE as a useful probe in following triplex assembly. As a unique triplex selector, inducer, and emitter, CHE successfully reports the wide pH- and metal-ion-dependent tunability of the triplex nanoswitch in a label-free manner.

MicroRNAs Form Triplexes with Double Stranded DNA at Sequence-Specific Binding Sites; a Eukaryotic Mechanism via which microRNAs Could Directly Alter Gene Expression.

MicroRNAs are important regulators of gene expression, acting primarily by binding to sequence-specific locations on already transcribed messenger RNAs (mRNA) and typically down-regulating their stability or translation. Recent studies indicate that microRNAs may also play a role in up-regulating mRNA transcription levels, although a definitive mechanism has not been established. Double-helical DNA is capable of forming triple-helical structures through Hoogsteen and reverse Hoogsteen interactions in the major groove of the duplex, and we show physical evidence (i.e., NMR, FRET, SPR) that purine or pyrimidine-rich microRNAs of appropriate length and sequence form triple-helical structures with purine-rich sequences of duplex DNA, and identify microRNA sequences that favor triplex formation. We developed an algorithm (Trident) to search genome-wide for potential triplex-forming sites and show that several mammalian and non-mammalian genomes are enriched for strong microRNA triplex binding sites. We show that those genes containing sequences favoring microRNA triplex formation are markedly enriched (3.3 fold, p<2.2 × 10−16) for genes whose expression is positively correlated with expression of microRNAs targeting triplex binding sequences. This work has thus revealed a new mechanism by which microRNAs could interact with gene promoter regions to modify gene transcription.

Spectroscopic studies on the binding interaction of novel 13-phenylalkyl analogs of the natural alkaloid berberine to nucleic acid triplexes

In this study we have characterized the capability of six 13-phenylalkyl analogs of berberine to stabilize nucleic acid triplex structures, poly(rA)⋅2poly(rU) and poly(dA)⋅2poly(dT). Berberine analogs bind to the RNA and DNA triplexes non-cooperatively. As the chain length of the substitution increased beyond CH2, the affinity enhanced up to critical length of (CH2)4, there after which the binding affinity decreased for both the triplexes. A remarkably stronger intercalative binding of the analogs compared to berberine to the triplexes was confirmed from ferrocyanide fluorescence quenching, fluorescence polarization and viscosity results. Circular dichroism results had indicated strong conformational changes in the triplexes on binding of the analogs. The analogs enhanced the stability of the Hoogsteen base paired third strand of both the triplexes while no significant change in the high-temperature duplex-to-single strand transitions was observed. Energetics of the interaction revealed that as the alkyl chain length increased, the binding was more entropy driven. This study demonstrates that phenylalkyl substitution at the 13-position of berberine increased the triplex binding affinity of berberine but a threshold length of the side chain is critical for the strong intercalative binding to occur.

133 Designed DNA crystals with a triple-helix veneer

DNA has been used as a tool for the self-assembly of nano-sized objects and arrays in two and three-dimensions. Triplex-forming oligonucleotides (TFOs) can be exploited to recognize and introduce functionality at precise duplex regions within these DNA nanostructures (Rusling et al., 2012). Here we have examined the feasibility of using TFOs to bind to specific locations within a 3-turn DNA tensegrity triangle motif. The tensegrity triangle is a rigid DNA motif with three-fold rotational symmetry, consisting of three helices directed along three linearly independent directions (Liu et al., 2004). The triangles form a three-dimensional crystalline lattice stabilized via sticky-end cohesion (Zheng et al., 2009). The TFO 5′-TTCTTTCTTCTCT was used to target the tensegrity motif containing an appropriately embedded oligopurine–oligopyrimidine binding site. Formation of DNA triplex in the motif was characterized by an electrophoretic mobility shift assay (EMSA), UV melting studies and FRET analysis. Non-denaturing gel analysis of annealed DNA motifs showed a band with slower mobility only in the presence of TFO and only when the DNA motif contained the triplex binding site. Experiments were undertaken at pH 5.0, since the formation of a triplex with cytidine-containing TFOs requires slightly acidic conditions (pH< 6.0). TFOs with modified C-analogs and T-analogs having a higher pK a worked at a more neutral pH, also evidenced by EMSA. UV melting studies revealed that the melting point of the 3-turn triangle was 64 °C and the TFO binding increased the melting point to 80 °C. FRET analysis was done by labeling the triangle with fluorescein and the TFO with a cyanine dye (Cy5). The FRET melting curve revealed that a signal was observed only when the TFO was bound to the DNA motif and the results were consistent with UV melting studies. These results indicate that a TFO can be specifically targeted to the tensegrity triangle motif.

Spectroscopic and Calorimetric Studies on the Binding of an Indoloquinoline Drug to Parallel and Antiparallel DNA Triplexes

11-Phenyl-substituted indoloquinolines have been found to exhibit significant antiproliferative potency in cancer cells but to show only moderate affinity toward genomic double-helical DNA. In this study, parallel as well as antiparallel triple-helical DNA targets are employed to evaluate the triplex binding of these ligands. UV melting experiments with parallel triplexes indicate considerable interactions with the drug and a strong preference for TAT-rich triplexes in line with an increasing number of potential intercalation sites of similar binding strength between two TAT base triads. Via substitution of a singly charged aminoethylamine side chain by a longer and doubly charged bis(aminopropyl)amine substituent at the ligand, binding affinities increase and also start to exhibit long-range effects as indicated by a strong correlation between the binding affinity and the overall length of the TAT tract within the triplex stem. Compared to parallel triplexes, an antiparallel triplex with a GT-containing third strand constitutes a preferred target for the indoloquinoline drug. On the basis of pH-dependent titration experiments and corroborated by a Job analysis of continuous variation, binding of the drug to the GT triplex not only is strongly enhanced when the solution pH is lowered from 7 to 5 but also reveals a pH-dependent stoichiometry upon formation of the complex. Calorimetric data demonstrate that stronger binding of a protonated drug at acidic pH is associated with a more exothermic binding process. However, at pH 7 and 5, binding is enthalpically driven with additional favorable entropic contributions.

Binding and NMR Structural Studies on Indoloquinoline–Oligonucleotide Conjugates Targeting Duplex DNA

An 11-phenyl-indolo[3,2-b]quinoline (PIQ) was tethered through an aminoalkyl linker to the 5'-end of four pyrimidine oligonucleotides with T/C scrambled sequences at their two 5'-terminal positions. Binding to different double-helical DNA targets formed parallel triple helices with a PIQ-mediated stabilization that strongly depends on pH and the terminal base triad at the 5'-triplex-duplex junction. The most effective stabilization was observed with a TAT triplet at the 5'-junction under low pH conditions, pointing to a protonated ligand with a high triplex binding affinity and unfavorable charge repulsions in the case of a terminal C(+)GC triplet at the junction. The latter preference of the PIQ ligand for TAT over CGC is alleviated yet still preserved at higher pH. Intercalation of PIQ at the 5'-triplex-duplex junction as suggested by the triplex melting experiments was confirmed by homonuclear and heteronuclear NMR structural studies on a specifically isotope-labeled triplex. The NMR analysis revealed two coexisting species that only differ by a 180° rotation of the indoloquinoline within the intercalation pocket. NOE-derived molecular models indicate extensive stacking interactions of the indoloquinoline moiety with the TAT base triplet and CG base pair at the junction and a phenyl substituent that is positioned in the major groove and oriented almost perpendicular to the plane of the indoloquinoline.

Strand invasion of mixed-sequence, double-helical B-DNA by γ-peptide nucleic acids containing G-clamp nucleobases under physiological conditions.

Peptide nucleic acids (PNAs) make up the only class of nucleic acid mimics developed to date that has been shown to be capable of invading double-helical B-form DNA. Recently, we showed that sequence limitation associated with PNA recognition can be relaxed by utilizing conformationally preorganized γ-peptide nucleic acids (γPNAs). However, like all the previous studies, with the exception of triplex binding, DNA strand invasion was performed at relatively low salt concentrations. When physiological ionic strengths were used, little to no binding was observed. On the basis of this finding, it was not clear whether the lack of binding is due to the lack of base pair opening or the lack of binding free energy, either of which would result in no productive binding. In this work, we show that it is the latter. Under simulated physiological conditions, the DNA double helix is sufficiently dynamic to permit strand invasion by the designer oligonucleotide molecules provided that the required binding free energy can be met. This finding has important implications for the design oligonucleotides for recognition of B-DNA via direct Watson-Crick base pairing.

Triplex-forming MicroRNAs Form Stable Complexes With HIV-1 Provirus and Inhibit its Replication

One of the most fascinating discoveries in biology in recent years is unquestionably the identification of the family of small, noncoding RNAs known as microRNAs (miRNAs). Each miRNA targets multiple mRNA species through recognition of complementary sequences, typically located at multiple sites within the 3 untranslated region. In animals, single-stranded miRNA binds specific messenger RNA (mRNA) by a mechanism that is yet to be fully characterized. The bound mRNA remains untranslated resulting in reduced levels of the corresponding protein; however, if the sequence match between the miRNA and its target is precise, the bound mRNA can be degraded resulting in reduced levels of the corresponding transcript. Eukaryotic genes are also regulated by triplex formation between double helix and a third small RNA or DNA molecule. Thousands of triplex-forming (TF) islands in human genomes are mapped. However, the role of TF miRNAs within the hairpin structures of miRNA and the target mRNA has not been reported. We have explored TF complexes between human miRNAs (hsa-miR) that are complementary to human immunodeficiency virus (HIV)-1 and their antiviral potential as therapeutic agents. We downloaded mature miRNA sequences from the human miRBase Sequence Database (http://microrna.sanger.ac.uk/sequences/), and computationally analyzed miRNAs that have significant homologies to HIV-1 genome (pNL 4-3 Accession #AF324493). We developed an algorithm to look for triplex-binding motifs (C+CG and T AT) and selected 4 miRNAs with 3 negative controls. TF stability was tested by using fluorophore-labeled duplexes connected by a single hexaethylene glycol moiety, representing HIV-1 proviral motifs, and black-hole quencher-1 labeled oligonucleotides, representing miRNA. Fifty miRNAs were discovered that showed greater than 80% homology to HIV-1, of which 4 hsa-miR that exhibited an ability to form stable triplex with double stranded-HIV-1 sequences were selected. Three negative controls were used. The TF stability of the 4 hsa-miRs and the negative controls were confirmed and measured. Stably transfected Hela-CD4+ cell lines expressing each of the hsa-miR were developed. All 4 miRNAs exhibited a significant inhibition of HIV-1 as measured by HIV-1 p24 enzyme-linked immunosorbent assay (>90%; P>0.001) when compared with the 3 negative controls. By using immunohistochemical staining with triplex binding monoclonal antibodies, significant expression of TF miRNAs was detected in the cell lines, but not in the negative controls (P<0.001). In this study, we demonstrated for the first time that besides the well-established post-transcriptional silencing based on mRNA degradation, miRNAs may be responsible for long-term latency of HIV-1 by TF, a different mechanism. We provide a possible molecular mechanism by which HIV-1 homologous miRNAs may impart resistance to HIV-1 and suggest a new miRNA-based therapeutic strategy for HIV-1.

Modulating PNA/DNA Hybridization by Light

Turn it on! Hybridization of peptide nucleic acids with DNA can be efficiently manipulated by modifying the PNA with a single azobenzene photoswitch. The effect is remarkably strong in the triplex binding mode and can be exploited for the photocontrol of transcription by T7 RNA polymerase (Pol T7).

Probing the Molecular Recognition of a DNA⋅RNA Hybrid Duplex

Curiouser and curiouser! A biarylpyrimidine ligand (see picture: N blue, H cyan, S yellow) shows a marked structure and sequence selectivity for the poly(dA)⋅poly(rU) hybrid duplex. An intercalative binding site was discovered where the ligand occupies a surprising ten base pairs. A strong correlation between hybrid duplex and DNA triplex binding indicates new directions for ligand design.