Direct visualization of abasic sites on a single DNA molecule using fluorescence microscopy

A new method was developed to allow direct visualization of damaged sites on individual DNA molecules. Fluorescence in situ hybridization on extended DNA molecules was modified to detect a single abasic site. Abasic sites were specifically labeled with a biotinylated aldehyde-reactive probe and fluorochrome-conjugated streptavidin. The light emitted by a single fluorochrome-DNA complex was calibrated. The number of abasic sites on the DNA molecule was estimated by counting each fluorochrome-DNA complex. The present study directly visualized and characterized the abasic sites of single DNA molecules.     

Nucleic acid structural engineering using pyrene-functionalized 2'-amino-alpha-L-LNA monomers and abasic sites

Oligonucleotides (ONs) modified with a 2'-N-(pyren-1-yl)acetyl-2'-amino-alpha-L-LNA thymine monomer Y flanked on the 3'-side by an abasic site Phi (i.e., YPhi-unit) exhibit unprecedented increases in thermal affinity (DeltaT(m) values) toward target strands containing abasic sites (DeltaT(m) per YPhi unit >+33.0 degrees C in 9-mer duplexes relative to unmodified ONs). Biophysical studies along with force field calculations suggest that the conformationally locked 2-oxo-5-azabicyclo[2.2.1]heptane skeleton of monomer Y, in concert with the short rigid acetyl linker, efficiently forces the thymine and pyrene moieties to adopt an interplanar distance of approximately 3.4 A. This precisely positions the pyrene moiety in the duplex core void formed by abasic sites (Phi:Phi pair) for optimal pi-pi overlap. Duplexes with multiple YPhi: APhi units separated by one base pair are tolerated extraordinarily well, as exemplified by a 13-mer duplex containing four separated YPhi: APhi units (8 abasic sites distributed over 13 "base pairs"), which exhibit a thermal denaturation temperature of 60.5 degrees C. The YPhi probes display up to 16-fold increases in fluorescence intensity at 380 nm upon hybridization with abasic target strands, whereby self-assembly of these complex architectures can be easily monitored. This study underlines the potential of N2'-functionalized 2'-amino-alpha-L-LNA as building blocks in nucleic acid based diagnostics and nanomaterial engineering.     

Strong and selective binding of amiloride to an abasic site in RNA duplexes: thermodynamic characterization and microRNA detection

Firmly tied: The binding affinity of amiloride for an abasic (AP) site-containing RNA duplex is two orders of magnitude superior to the affinity of the corresponding AP site-containing DNA duplex. The observed high binding affinity for the RNA duplex arises from a favorable enthalpy gain. The binding-induced fluorescence response of amiloride is applicable to microRNA detection.     

Targeting abasic sites and single base bulges in DNA with metalloinsertors

The site-specific recognition of abasic sites and single base bulges in duplex DNA by sterically expansive rhodium metalloinsertors has been investigated. Through DNA photocleavage experiments, Rh(bpy)2(chrysi)3+ is shown to bind both abasic sites and single base bulges site-specifically and, upon irradiation, to cleave the backbone of the defect-containing DNA. Photocleavage titrations reveal that the metal complex binds DNA containing an abasic site with high affinity (2.6(5) x 106 M-1), comparably to the metalloinsertor and a CC mismatch. The complex binds single base bulge sites with lower affinity (approximately 105 M-1). Analysis of cleavage products and the correlation of affinities with helix destabilization suggest that Rh(bpy)2(chrysi)3+ binds both lesions via metalloinsertion, as observed for Rh binding at mismatched sites, a binding mode in which the mismatched or unpaired bases are extruded from the helix and replaced in the base stack by the sterically expansive ligand of the metalloinsertor.     

Paramagnetic Particles and PNA Probe for Automated Separation and Electrochemical Detection of Influenza

Considerable efforts have been devoted to the development of rapid and sensitive methods allowing the detection of viral nucleic acid. We herein describe an assay for identification of a specific influenza sequence. The suggested method was based on isolation using paramagnetic particles coupled with electrochemical detection of isolated product. Peptide nucleic acid (PNA) was used as a probe for hybridization and identification of the influenza-derived specific sequence. The use of PNA can show numerous benefits: PNA probe is not degradable by enzymes and the duplex of PNA with RNA/DNA is more thermostable and more resistant to pH changes than DNA/DNA or RNA/RNA duplexes. This PNA probe assay can be applied as a magnetically guidable tool for detection of DNA/RNA samples under different conditions.     

The recognition of a noncanonical RNA base pair by a zinc finger protein.

BACKGROUND: The zinc finger (ZF) is the most abundant nucleic-acid-interacting protein motif. Although the interaction of ZFs with DNA is reasonably well understood, little is known about the RNA-binding mechanism. We investigated RNA binding to ZFs using the Zif268-DNA complex as a model system. Zif268 contains three DNA-binding ZFs; each independently binds a 3 base pair (bp) subsite within a 9 bp recognition sequence. RESULTS: We constructed a library of phage-displayed ZFs by randomizing the alpha helix of the Zif268 central finger. Successful selection of an RNA binder required a noncanonical base pair in the middle of the RNA triplet. Binding of the Zif268 variant to an RNA duplex containing a G.A mismatch (rG.A) is specific for RNA and is dependent on the conformation of the mismatched middle base pair. Modeling and NMR analyses revealed that the rG.A pair adopts a head-to-head configuration that counterbalances the effect of S-puckered riboses in the backbone. We propose that the structure of the rG.A duplex is similar to the DNA in the original Zif268-DNA complex. CONCLUSIONS: It is possible to change the specificity of a ZF from DNA to RNA. The ZF motif can use similar mechanisms in binding both types of nucleic acids. Our strategy allowed us to rationalize the interactions that are possible between a ZF and its RNA substrate. This same strategy can be used to assess the binding specificity of ZFs or other protein motifs for noncanconical RNA base pairs, and should permit the design of proteins that bind specific RNA structures.     

C2'-pyrene-functionalized triazole-linked DNA: universal DNA/RNA hybridization probes

Development of universal hybridization probes, that is, oligonucleotides displaying identical affinity toward matched and mismatched DNA/RNA targets, has been a longstanding goal due to potential applications as degenerate PCR primers and microarray probes. The classic approach toward this end has been the use of "universal bases" that either are based on hydrogen-bonding purine derivatives or aromatic base analogues without hydrogen-bonding capabilities. However, development of probes that result in truly universal hybridization without compromising duplex thermostability has proven challenging. Here we have used the "click reaction" to synthesize four C2'-pyrene-functionalized triazole-linked 2'-deoxyuridine phosphoramidites. We demonstrate that oligodeoxyribonucleotides modified with the corresponding monomers display (a) minimally decreased thermal affinity toward DNA/RNA complements relative to reference strands, (b) highly robust universal hybridization characteristics (average differences in thermal denaturation temperatures of matched vs mismatched duplexes involving monomer W are <1.7 °C), and (c) exceptional affinity toward DNA targets containing abasic sites opposite of the modification site (ΔT(m) up to +25 °C). The latter observation, along with results from absorption and fluorescence spectroscopy, suggests that the pyrene moiety is intercalating into the duplex whereby the opposing nucleotide is pushed into an extrahelical position. These properties render C2'-pyrene-functionalized triazole-linked DNA as promising universal hybridization probes for applications in nucleic acid chemistry and biotechnology.     

Paramagnetic Particles and PNA Probe for Automated Separation and Electrochemical Detection of Influenza

Considerable efforts have been devoted to the development of rapid and sensitive methods allowing the detection of viral nucleic acid. We herein describe an assay for identification of a specific influenza sequence. The suggested method was based on isolation using paramagnetic particles coupled with electrochemical detection of isolated product. Peptide nucleic acid (PNA) was used as a probe for hybridization and identification of the influenza-derived specific sequence. The use of PNA can show numerous benefits: PNA probe is not degradable by enzymes and the duplex of PNA with RNA/DNA is more thermostable and more resistant to pH changes than DNA/DNA or RNA/RNA duplexes. This PNA probe assay can be applied as a magnetically guidable tool for detection of DNA/RNA samples under different conditions.

     

Effects of DNA secondary structure on oligonucleotide probe binding efficiency

Secondary structure motifs in nucleic acid probes generally impair intended hybridization reactions and so efforts to predict and avoid such structures are commonly employed in probe design schemes. Another key facet of probe design that has received much less attention, however, is that secondary structure at targeted probe binding site regions may also impair hybridization. Thus, evaluation of both probe and target site secondary structures together should improve hybridization prediction and design effectiveness. Several challenges confound this goal, including imperfect empirical rules and parameters underlying predictions and the fact that folding algorithms scale poorly with respect to sequence length. Here, we attempt to quantify the consequences of target site structure on predicted hybridization using sequences sampled from the human genome. We also provide a methodology for choosing a reasonable “window size” around target sites that is as small as possible without compromising folding algorithm prediction accuracy.     

Synthesis of abasic locked nucleic acid and two seco-LNA derivatives and evaluation of their hybridization properties compared with their more flexible DNA counterparts

To investigate the structural basis of the unique hybridization properties of LNA (locked nucleic acid) three novel LNA derivatives with modified carbohydrate parts were synthesized and evaluated with respect to duplex stabilities. The abasic LNA monomer (X(L), Figure 1) with the rigid carbohydrate moiety of LNA but no nucleobase attached showed no enhanced duplex stabilities compared to its more flexible abasic DNA counterpart (X, Figure 1). These results suggest that the exceptional hybridization properties of LNA primarily originate from improved intrastrand nucleobase stacking and not backbone preorganization. Two monocyclic seco-LNA derivatives, obtained by cleavage of the C1'-O4' bond of an LNA monomer or complete removal of the O4'-furanose oxygen atom (Z(L) and dZ(L), respectively, Figure 1), were compared to their acyclic DNA counterpart (Z, Figure 1). Even though they are more constrained than Z, the seco-LNA derivatives Z(L) and dZ(L) destabilize duplex formation even more than the flexible seco-DNA monomer Z.     

Three-Dimensional DNA Crystals with pH-Responsive Noncanonical Junctions

Three-dimensional (3D) DNA crystals have been envisioned as programmable biomaterial scaffolds for creating ordered arrays of biological and nonbiological molecules. Despite having excellent programmable properties, the linearity of the Watson-Crick B-form duplex imposes limitations on 3D crystal design. Predictable noncanonical base pairing motifs have the potential to serve as junctions to connect linear DNA segments into complex 3D lattices. Here, we designed crystals based on a template structure with parallel-stranded noncanonical base pairs. Depending on pH, the structures we determined contained all but one or two of the designed secondary structure interactions. Surprisingly, a conformational change of the designed Watson-Crick duplex region resulted in crystal packing differences between the predicted and observed structures. However, the designed noncanonical motif was virtually identical to the template when crystals were grown at pH 5.5, highlighting the motif's predictability. At pH 7.0 we observed a structurally similar variation on this motif that contains a previously unobserved C-G?G-C quadruple base pair. We demonstrate that these two variants can interconvert in crystallo in response to pH perturbations. This study spotlights several important considerations in DNA crystal design, describes the first 3D DNA lattice composed of A-DNA helical sheets, and reveals a noncanonical DNA motif that has adaptive features that may be useful for designing dynamic crystals or biomaterial assemblies.     

Selective Chemical Modification to the Higher-Order Structures of Nucleic Acids

DNA and RNA can adopt a variety of stable higher-order structural motifs, including G-quadruplex (G4 s), mismatches, and bulges. Many of these secondary structures are closely related to the regulation of gene expression. Therefore, the higher-order structure of nucleic acids is one of the candidate therapeutic targets, and the development of binding molecules targeting the higher-order structure of nucleic acids has been pursued vigorously. Furthermore, as one of the methodologies for detecting the higher-order structures of these nucleic acids, developing techniques for the selective chemical modification of the higher-order structures of nucleic acids is also underway. In this personal account, we focus on the following higher-order structures of nucleic acids, double-stranded DNA containing the abasic site, T−T/U−U mismatch structure, and G-quadruplex structure, and describe the development of molecules that bind to and chemically modify these structures.     

Atomic detail investigation of the structure and dynamics of DNA.RNA hybrids: a molecular dynamics study

DNA.RNA hybrid duplexes are biologically important molecules and are shown to have potential therapeutic properties. To investigate the relationship between structures, energetics, solvation and RNase H activity of hybrid duplexes in comparison with pure DNA and RNA duplexes, a molecular dynamics study using the CHARMM27 force field was undertaken. The structural properties of all four nucleic acids considered are in very good agreement with the experimental data. The backbone dihedral angles and the puckering of the (deoxy)ribose indicate that the purine rich strands retain their A-/B-like properties but the pyrimidine rich DNA strand undergoes A-B conformational transitions. The minor groove widths of the hybrid structures are narrower than those in the RNA duplex, a requirement for RNase H binding. In addition, sampling of noncanonical phosphodiester backbone dihedrals by the DNA strands, differential solvation properties and helical properties, most notably rise, are suggested to contribute to hybrids being RNase H substrates. Differential RNase H activity toward hybrids containing purine versus pyrimidine rich RNA strands is suggested to be due to sampling of values of the phosphodiester backbone dihedrals in the DNA strands. Notably, the present results indicate that hybrids have decreased flexibility as compared to RNA, in contrast to previous reports.     

DNA-duplexes containing abasic sites: correlation between thermostability and acoustic wave properties

Aldehydic apurinic or apyrimidinic sites that lack a nucleobase moiety are one of the most common forms of toxic lesions in DNA. In the present study, a close structural analog of such a site, the 2-(hydroxymethyl) tetrahydrofuranyl residue, was synthesized in order to act as a model for damaged nucleic acid probes. Prepared oligodeoxyribonucleotides containing one, two or three abasic sites were hybridized to complementary sequences immobilized on a gold surface using the neutravidin-biotin interaction for study by thickness shear mode acoustic wave detector. Measurement of the complex electrical impedance of an AT-cut quartz device with immobilized biotinylated nucleotide allowed the detection of changes of series resonance frequency, Deltafs, and motional resistance, Rm, associated with duplex formation. The changes as detected by the acoustic wave method correlated well with the thermostability of DNA duplexes in solution. With respect to the latter, UV-monitored melting curves indicate that both the number of sites and their localization in the double-stranded structure influence the amount by which a 19 b.p. duplex is destabilized. The presence of 3 abasic sites completely destabilized the DNA duplex.     

Discovering protein-binding RNA motifs with a generative model of RNA sequences

Recent advances in high-throughput experimental technologies have generated a huge amount of data on interactions between proteins and nucleic acids. Motivated by the big experimental data, several computational methods have been developed either to predict binding sites in a sequence or to determine if an interaction exists between protein and nucleic acid sequences. However, most of the methods cannot be used to discover new nucleic acid sequences that bind to a target protein because they are classifiers rather than generators. In this paper we propose a generative model for constructing protein-binding RNA sequences and motifs using a long short-term memory (LSTM) neural network. Testing the model for several target proteins showed that RNA sequences generated by the model have high binding affinity and specificity for their target proteins and that the protein-binding motifs derived from the generated RNA sequences are comparable to the motifs from experimentally validated protein-binding RNA sequences. The results are promising and we believe this approach will help design more efficient in vitro or in vivo experiments by suggesting potential RNA aptamers for a target protein.     

Binary malachite green aptamer for fluorescent detection of nucleic acids

A new probe that can fluorescently report the presence of specific nucleic acids in solution with extremely high selectivity was developed. The probe consists of malachite green-a triphenylmethane dye-and two short RNA strands, each of which comprises a fragment complementary to an analyte molecule and a fragment of a malachite green aptamer (MGA). The two RNA strands form MGA upon hybridization to the adjacent positions of the nucleic acid analyte. MGA is able to bind malachite green and enhance the fluorescence of the dye, thus monitoring the presence of the nucleic acid in solution. The probe reliably discriminates against 41 out of 42 possible single nucleotide substitutions in 14-mer DNA analyte at room temperature in physiological buffer. Consisting of unmodified RNA strands, which can be expressed in living cells, binary MGA probe represents a promising instrument for real-time nucleic acid monitoring in vivo.     

MVF Sensor Enables Analysis of Nucleic Acids with Stable Secondary Structures

One major challenge in nucleic acids analysis by hybridization probes is a compromise between the probe's tight binding and sequence‐selective recognition of nucleic acid targets folded into stable secondary structures. We have been developing a four‐way junction (4WJ)‐based sensor that consists of a universal stem‐loop (USL) probe immobilized on an electrode surface and two adaptor strands (M and F). The sensor was shown to be highly selective towards single base mismatches at room temperature, able to detect multiple targets using the same USL probe, and have improved ability to detect folded nucleic acids. However, some nucleic acid targets, including natural RNA, are folded into very stable secondary and tertiary structures, which may represent a challenge even for the 4WJ sensors. This work describes a new sensor, named MVF since it uses three probe stands M, V and F, which further improves the performance of 4WJ sensors with folded targets. The MVF sensor interrogating a 16S rRNA NASBA amplicon with calculated folding energy of ?32.82 kcal/mol has demonstrated 2.5‐fold improvement in a signal‐to‐background ratio in comparison with a 4WJ sensor lacking strand V. The proposed design can be used as a general strategy in the analysis of folded nucleic acids including natural RNA.     

Red/NIR G‐Quadruplex Sensing,Harvesting Blue Light by a Coumarin–Naphthalene Diimide Dyad

A conceptually new light‐up nucleic acid fluorescent probe resulting from the conjugation of a coumarin to a naphthalene diimide exhibits a single wavelength emission at 498 nm when free in solution and an additional red/NIR emission when bound to G‐quadruplex DNA. The light‐up response centred at 666 nm is highly specific for quadruplex DNA when compared to duplex DNA or to RNA quadruplexes.     

Site‐Directed,On‐Surface Assembly of DNA Nanostructures

Two‐dimensional DNA lattices have been assembled from DNA double‐crossover (DX) motifs on DNA‐encoded surfaces in a site‐specific manner. The lattices contained two types of single‐stranded protruding arms pointing into opposite directions of the plane. One type of these protruding arms served to anchor the DNA lattice on the solid support through specific hybridization with surface‐bound, complementary capture oligomers. The other type of arms allowed for further attachment of DNA‐tethered probe molecules on the opposite side of the lattices exposed to the solution. Site‐specific lattice assembly and attachment of fluorophore‐labeled oligonucleotides and DNA–protein conjugates was demonstrated using DNA microarrays on flat, transparent mica substrates. Owing to their programmable orientation and addressability over a broad dynamic range from the nanometer to the millimeter length scale, such supramolecular architecture might be used for presenting biomolecules on surfaces, for instance, in biosensor applications.