Single stand targeted triplex formation: physicochemical and biochemical properties of foldback triplexes

Simulative and Experimental Characterization of a pH-Dependent Clamp-like DNA Triple-Helix Nanoswitch

Here we couple experimental and simulative techniques to characterize the structural/dynamical behavior of a pH-triggered switching mechanism based on the formation of a parallel DNA triple helix. Fluorescent data demonstrate the ability of this structure to reversibly switch between two states upon pH changes. Two accelerated, half microsecond, MD simulations of the system having protonated or unprotonated cytosines, mimicking the pH 5.0 and 8.0 conditions, highlight the importance of the Hoogsteen interactions in stabilizing the system, finely depicting the time-dependent disruption of the hydrogen bond network. Urea-unfolding experiments and MM/GBSA calculations converge in indicating a stabilization energy at pH 5.0, 2-fold higher than that observed at pH 8.0. These results validate the pH-controlled behavior of the designed structure and suggest that simulative approaches can be successfully coupled with experimental data to characterize responsive DNA-based nanodevices.

Folding-upon-binding and signal-on electrochemical DNA sensor with high affinity and specificity

Here we investigate a novel signal-on electrochemical DNA sensor based on the use of a clamp-like DNA probe that binds a complementary target sequence through two distinct and sequential events, which lead to the formation of a triplex DNA structure. We demonstrate that this target-binding mechanism can improve both the affinity and specificity of recognition as opposed to classic probes solely based on Watson–Crick recognition. By using electrochemical signaling to report the conformational change, we demonstrate a signal-on E-DNA sensor with up to 400% signal gain upon target binding. Moreover, we were able to detect with nanomolar affinity a perfectly matched target as short as 10 bases (K_D = 0.39 nM). Finally, thanks to the molecular “double-check” provided by the concomitant Watson–Crick and Hoogsteen base pairings involved in target recognition, our sensor provides excellent discrimination efficiency toward a single-base mismatched target.

Thermodynamic basis for engineering high-affinity, high-specificity binding-induced DNA clamp nanoswitches

Naturally occurring chemoreceptors almost invariably employ structure-switching mechanisms, an observation that has inspired the use of biomolecular switches in a wide range of artificial technologies in the areas of diagnostics, imaging, and synthetic biology. In one mechanism for generating such behavior, clamp-based switching, binding occurs via the clamplike embrace of two recognition elements onto a single target molecule. In addition to coupling recognition with a large conformational change, this mechanism offers a second advantage: it improves both affinity and specificity simultaneously. To explore the physics of such switches we have dissected here the thermodynamics of a clamp-switch that recognizes a target DNA sequence through both Watson-Crick base pairing and triplex-forming Hoogsteen interactions. When compared to the equivalent linear DNA probe (which relies solely on Watson-Crick interactions), the extra Hoogsteen interactions in the DNA clamp-switch increase the probe's affinity for its target by ∼0.29 ± 0.02 kcal/mol/base. The Hoogsteen interactions of the clamp-switch likewise provide an additional specificity check that increases the discrimination efficiency toward a single-base mismatch by 1.2 ± 0.2 kcal/mol. This, in turn, leads to a 10-fold improvement in the width of the "specificity window" of this probe relative to that of the equivalent linear probe. Given these attributes, clamp-switches should be of utility not only for sensing applications but also, in the specific field of DNA nanotechnology, for applications calling for a better control over the building of nanostructures and nanomachines.

DNA triplex structures in neurodegenerative disorder, Friedreich's ataxia

It is now established that a small fraction of genomic DNA does adopt the non-canonical B-DNA structure or 'unusual' DNA structure. The unusual DNA structures like DNA-hairpin, cruciform, Z-DNA, triplex and tetraplex are represented as hotspots of chromosomal breaks, homologous recombination and gross chromosomal rearrangements since they are prone to the structural alterations. Friedreich's ataxia (FRDA), the autosomal recessive degenerative disorder of nervous and muscles tissue, is caused by the massive expansion of (GAA) repeats that occur in the first intron of Frataxin gene X25 on chromosome 9q13-q21.1. The purine strand of the DNA in the expanded (GAA) repeat region folds back to form the (R.R*Y) type of triplex, which further inhibits the frataxin gene expression, and this clearly suggests that the shape of DNA is the determining factor in the cellular function. FRDA is the only disease known so far to be associated with DNA triplex. Structural characterization of GAA-containing DNA triplexes using some simple biophysical methods like UV melting, UV absorption, circular dichroic spectroscopy and electrophoretic mobility shift assay are discussed. Further, the clinical aspects and genetic analysis of FRDA patients who carry (GAA) repeat expansions are presented. The potential of some small molecules that do not favour the DNA triplex formation as therapeutics for FRDA are also briefly discussed.

Formation of stable triplexes between purine RNA and pyrimidine oligodeoxyxylonucleotides

Hybridization properties of oligodeoxyxylonucleotides (OXNs) built from pyrimidine monomers with an inverted 3'-OH group of the furanose have been studied using the gel mobility shift, UV melting and circular dichroism (CD) spectroscopy methods. Pyrimidine OXNs form triple helices with complementary purine RNA in which one OXN is parallel and another is antiparallel with respect to the RNA target. Surprisingly, no duplex formation between the pyrimidine OXNs and purine RNAs is detected. The modified triplexes are stable at pH 7. Their thermal stability depends on the number of C(G-C) triplets and, for G-rich RNA sequences, it is comparable with the stability of native DNA-RNA duplexes. The CD spectra of triplexes formed by OXNs with purine RNA targets are similar to spectra of A-type helices. A pyrimidine OXN having a clamp structure efficiently inhibits reverse transcription of murine pim-1 mRNA in vitro mediated by the Mo-MuLV reverse transcriptase.

Formation and thermodynamic stability of intermolecular (R*R*Y) DNA triplex in GAA/TTC repeats associated with Freidreich's ataxia

It is well established that GAA/TTC base triplet expansion is the cause of degenerative disorder in Freidreich's Ataxia. It is also known that these repeat sequences fold back to form the unusual intramolecular triple helix structures in DNA of the type Pyrimidine *Purine *Pyrimidine or Purine *Purine*Pyrimidine. In this paper we report on the stability of Purine *Purine*Pyrimidine intermolecular triple helix DNA containing GAA/TTC repeats under physiological conditions. Using the oligonucleotides 5' TCGC GAA GAA GAA GAA GAA CGCT 3', 5'-AGCG TTC TTC TTC TTC TTC GCGA-3' for duplex and 5'-AAG AAG AAG AAG AAG -3' as triplex forming strand (TFO), we have established the formation of triplex by UV-melting temperature (Tm), stoichiometry of mixing and circular dichroic spectra. This was further confirmed by gel-retardation assay. The thermodynamic parameters Delta G, Delta H and Delta S for both duplex and triplex formation were determined at different salt concentrations. The results suggest the formation of a stable intermolecular, anti - parallel triplex in GAA/TTC repeat sequences where each repeat unit contains two A*A*T and one G*G*C triplet. The therapeutic agents and TFOs, which competitively inhibit the in-vivo intra-molecular triplex by formation of a more stable inter-molecular triplex, could be used to reverse the transcription deficit in GAA/TTC expansions in Frataxin gene.

Downregulation of c-Ki-ras promoter activity by triplex-forming oligonucleotides endogenously generated in human 293 cells

Exogenous triplex-forming oligodeoxynucleotides (TFO) have the capacity to modulate in vivo the expression of individual genes. As the administration of TFO to cells is not without problems, we analyzed the possibility of generating them directly in the cell, using specific expression vectors. We constructed three vectors, mU6-GA, mU6-CA, and mU6-CT, that direct the synthesis in human 293 cells of 76-mer CU, GU, and AG motif TFO (rTFO) potentially capable of binding to a critical poly (R x Y) sequence contained in the promoter of the Ki-ras proto-oncogene. The ability of the CU, GU, and AG motif rTFO to interact with the double helix of the c-Ki-ras target was investigated in vitro by footprinting and band-shift experiments, using both synthetic and endogenously synthesized oligoribonucleotides. The human 293 cells were transfected with DNA mixtures containing a plasmid, which bears the reporter chloramphenicol acetyltransferase (CAT) gene downstream from the c-Ki-ras promoter (pKRS-413), as well as an rTFO-generating vector (mU6-GA, mU6-CA, or mU6-CT). As control, the cells were transfected with DNA mixtures containing vector mU6-C1 or mU6-C2. These generated transcripts unable to form triple helices with the poly (R x Y) sequence of the c-Ki-ras promoter. Intracellular synthesis of the 76-mer CU, GU, and AG rTFO by mU6-GA, mU6-CA, and mU6-CT was checked by Northern blot hybridization. Through beta-gal and CAT ELISA immunoassays, we found that the 293 cells transfected with either mU6-GA, mU6-CA, or mU6-CT showed a significant inhibition of CAT expression compared with cells transfected with control plasmids mU6-C1 or mU6-C2. The results of five separate transient transfection experiments showed that endogenous GU and AG rTFO, generated by mU6-CA and mU6-CT, produce, respectively, 40% (+/- 4% SE) and 47% (+/- 8% SE) CAT inhibition, whereas CU rTFO, generated by mU6-GA, produces 38% (+/- 7% SE) CAT inhibition. In conclusion, this study suggests that it is possible to downregulate the expression of an individual gene through the use of recombinant vectors encoding the information for the intracellular synthesis of short triplex-forming RNA strands.

Targeting of single-stranded DNA and RNA containing adjacent pyrimidine and purine tracts by triple helix formation with circular and clamp oligonucleotides

The aim of this work was to construct an anti-messenger targeted to the pim-1 oncogene transcript, based on circular or clamp oligodeoxyribonucleotides. The formation of bimolecular triplexes by clamp or circular oligonucleotides was investigated using single-stranded targets of both DNA (5'-CCCTCCTTTGAAGAA-3') and RNA type (5'-CCCUCCUUUGAAGAA-3'). The third, 'Hoogsteen' strand of the triplex was represented by G,T-rich sequences. The secondary structures of the complexes were determined by thermal denaturation, circular dichroism and gel mobility shift experiments and shown to depend on the nature of the target strand. With DNA as target, the sequence of a clamp (or circular) oligonucleotide that formed the triple helix was 3'-GGGAGGAAACTTCTTTT-TTGTTGTTT-TT-GGTGGG-5', where the first TT dinucleotide (in italics) is a linker and the second TT (bold) represents the bridge through which the 'Hoogsteen' strand switches from one strand of the Watson-Crick duplex to the other, once the duplex is formed by the corresponding portion of the anti-messenger (underlined). The portion of the 'Hoogsteen' sequence of the triplex between the two TT dinucleotides binds to the 3' extremity of the target strand and runs parallel to it. The portion situated at the 5' end of the oligonucleotide switches to the purine tract of the complementary strand of the duplex and is antiparallel to it. In contrast, with RNA as target, for a branched clamp oligonucleotide that formed a triple helix over its entire length (5'-TTCTTCAAAGGAGGG-3' 3'-GGGTGGTTT-T-GTTGTT-5') the portion of the 'Hoogsteen' sequence that bound to the 3' extremity of the target strand had to be antiparallel to it.

Evidence from CD spectra and melting temperatures for stable Hoogsteen-paired oligomer duplexes derived from DNA and hybrid triplexes

The pyr*pur.pyr type of nucleic acid triplex has a purine strand that is Hoogsteen-paired with a parallel pyrimidine strand (pyr*pur pair) and that is Watson-Crick-paired with an antiparallel pyrimidine strand (pur.pyr pair). In most cases, the Watson-Crick pair is more stable than the Hoogsteen pair, although stable formation of DNA Hoogsteen-paired duplexes has been reported. Using oligomer triplexes of repeating d(AG)12 and d(CT)12 or r(CU)12 sequences that were 24 nt long, we found that hybrid RNA*DNA as well as DNA*DNA Hoogsteen-paired strands of triplexes can be more stable than the Watson-Crick-paired strands at low pH. The structures and relative stabilities of these duplexes and triplexes were evaluated by circular dichroism (CD) spectroscopy and UV absorption melting studies of triplexes as a function of pH. The CD contributions of Hoogsteen-paired RNA*DNA and DNA*DNA duplexes were found to dominate the CD spectra of the corresponding pyr*pur.pyr triplexes.

Single-stranded DNA and RNA targeted triplex-formation: UV, CD and molecular modeling studies of foldback triplexes containing different RNA, 2'-OMe-RNA and DNA strand combinations

We studied the influence of different 2'-OMe-RNA and DNA strand combinations on single strand targeted foldback triplex formation in the Py.Pu:Py motif using ultraviolet (UV) and circular dichroism (CD) spectroscopy, and molecular modeling. The study of eight combinations of triplexes (D.D:D, R*.D:D, D.D:R*, R*.D:R*, D.R:D, R*.R:D, D.R:R*, and R*.R:R*; where the first, middle, and last letters stand for the Hoogsteen Pyrimidine, Watson-Crick [WC] purine and WC pyrimidine strands, respectively, and D, R and R* stand for DNA, RNA and 2'-OMe-RNA strands, respectively) indicate more stable foldback triplex formation with a DNA purine strand than with an RNA purine strand. Of the four possible WC duplexes with RNA/DNA combinations, the duplex with a DNA purine strand and a 2'-O-Me-RNA pyrimidine strand forms the most thermally stable triplex, although its thermal stability is the lowest of all four duplexes. Irrespective of the duplex combination, a 2'-OMe-RNA Hoogsteen pyrimidine strand forms a stable foldback triplex over a DNA Hoogsteen pyrimidine strand confirming the earlier reports with conventional and circular triplexes. The CD studies suggest a B-type conformation for an all DNA homo-foldback triplex (D.D:D), while hetero-foldback triplex spectra suggest intermediate conformation to both A-type and B-type structures. A novel molecular modeling study has been carried out to understand the stereochemical feasibility of all the combinations of foldback triplexes using a geometric approach. The new approach allows use of different combinations of chain geometries depending on the nature of the chain (RNA vs. DNA).

Hoogsteen DNA duplexes of 3'-3'- and 5'-5'-linked oligonucleotides and trip formation with RNA and DNA pyrimidine single strands: experimental and molecular modeling studies

DNA oligonucleotide sequences containing two parallel complementary strands attached through 3'-3' and 5'-5' linkages were synthesized. These oligonucleotides from Hoogsteen base-paired parallel-stranded (PS) hairpin duplexes under appropriate conditions [Kandimalla, E. R., Agrawal, S., Venkataraman, G., & Sasisekharan, V. (1995a) J. Am. Chem. Soc. 117, 6416-6417]. UV melting experiments show that these Hoogsteen hairpin duplexes have a lower thermal stability than that of the Watson-Crick (WC) hairpin duplex (antiparallel) of the same sequence. The circular dichroism (CD) spectrum of the Hoogsteen duplex is different from the canonical B-DNA WC duplex spectrum. The formation of the Hoogsteen duplex is pH-dependent since protonation of cytosine requires lower pH conditions. Studies with oligonucleotides of different loop sizes revel that three- and two-base loops are optimum for the formation of stable Hoogsteen duplexes with 3'-3' and 5'-5' linkages, respectively. The guanine residues in the loop stabilize the duplex as a result of G-G interactions as confirmed by molecular modeling studies. The new PS Hoogsteen duplexes form stable triplexes with complementary (antiparallel to the purine domain) single-stranded RNA and DNA pyrimidine sequences in Py.Pu:Py (pyrimidine third strand-purine WC strand:pyrimidine WC strand) motif. The thermal stability of the resulting triplexes is much higher than that of the conventional triplex (binding of a Hoogsteen pyrimidine third strand to a WC duplex) of the same sequence. The CD spectra of the new triplexes are similar to those of conventional triplexes, suggesting that no conformational change occurs as a result of 3'-3' or 5'-5' linkage. A molecular modeling study was carried out to examine the stereochemical feasibility of the Hoogsteen duplexes and formation of triplexes with single-stranded pyrimidine complementary strands.