Selection of RNA-Cleaving TNA Enzymes for Cellular Mg2+ Imaging

Catalytic DNA-based fluorescent sensors have enabled cellular imaging of metal ions such as Mg²⁺. However, natural DNA is prone to nuclease-mediated degradation. Here, we report the in vitro selection of threose nucleic acid enzymes (TNAzymes) with RNA endonuclease activities. One such TNAzyme, T17–22, catalyzes a site-specific RNA cleavage reaction with a k_cat of 0.017 min⁻¹ and K_M of 675 nM. A fluorescent sensor based on T17–22 responds to an increasing concentration of Mg²⁺ with a limit of detection at 0.35 mM. This TNAzyme-based sensor also allows cellular imaging of Mg²⁺. This work presents the first proof-of-concept demonstration of using a TNA catalyst in cellular metal ion imaging.     

Duplex formation of the simplified nucleic acid GNA

Glycol nucleic acid (GNA) has an acyclic backbone of propylene glycol nucleosides that are connected by phosphodiester bonds. This paper characterizes the duplex-formation properties of this simplified nucleic acid. Although single and multiple GNA nucleotides are highly destabilizing if incorporated into DNA duplexes, the two enantiomeric oligomers (S)-GNA and (R)-GNA form antiparallel homoduplexes that are thermally and thermodynamically significantly more stable than analogous duplexes of DNA and RNA. The salt-dependence and Watson-Crick-pairing fidelity of GNA duplexes are similar to those of DNA duplexes, but, apparently, the 2'-deoxyribonucleotide and the propylene glycol backbones are not compatible with each other. This conclusion is further supported by cross-pairing experiments. Accordingly, both (S)- and (R)-GNA strands do not generally pair with DNA. However, (S)-GNA, but not (R)-GNA, forms stable heteroduplexes with RNA in sequences that are low in G:C content. Altogether, the high stability and fidelity of GNA duplex formation in combination with the economical accessibility of propylene glycol building blocks for oligonucleotide synthesis render GNA an attractive candidate for the design of self-assembling materials. They further suggest that GNA could be considered as a potential candidate for a predecessor of RNA during the evolution of life on Earth.     

Thresholding DNA Nanomachine as a Highly Cooperative and Efficient Enzyme-Like System for Controlled RNA Cleavage

Therapeutic nucleic acid agents (TNA) can be activated by a marker RNA sequence followed by initiation of targeted RNA cleavage. This property can be used in conditional cell suppression, e. g., cancer marker-dependent cell death. However, healthy cells often express lower levels of cancer markers, thus jeopardizing TNA activation exclusively in cancer cells. Earlier, we developed a conditionally activated split deoxyribozyme construct (DNA thresholder or DTh) that can be activated by high but not by low concentrations of cancer markers. It's activity, however, was suppressed by very high marker concentrations. Herein, we combine the DTh functional units in a single DNA association (Thresholding DNA nanomachine or Th-DNM). Th-DNM maintains a high level of RNA cleavage activity in the presence of marker concentrations above the threshold level. Th-DNM differentiated fully complementary miR17 markers sequence from double base mismatched miR-20. Th-DNM can become a building block of DNA nanorobots for cancer treatment.     

Self-assembly nucleic acid-based biopolymers: learn from the nature

This review highlights the recent developments in nucleic acid-based based materials for biomedical applications and functional devices. DNA and RNA are anionic macromolecules composing sugar-phosphate backbone, which usually structure as rod-like double helix with base pair stacking. Electrostatic interactions are the main components in the complex formed between anionic nucleic acid and cationic molecule. These nucleic acid-based biopolymers have significant potential as functional materials for drug delivery, biosensors, and a scaffold for many biodegradable materials.     

Split Spinach Aptamer for Highly Selective Recognition of DNA and RNA at Ambient Temperatures

Split spinach aptamer (SSA) probes for fluorescent analysis of nucleic acids were designed and tested. In SSA design, two RNA or RNA/DNA strands hybridized to a specific nucleic acid analyte and formed a binding site for low‐fluorescent 3,5‐difluoro‐4‐hydroxybenzylidene imidazolinone (DFHBI) dye, which resulted in up to a 270‐fold increase in fluorescence. The major advantage of the SSA over state‐of‐the art fluorescent probes is high selectivity: it produces only background fluorescence in the presence of a single‐base‐mismatched analyte, even at room temperature. SSA is therefore a promising tool for label‐free analysis of nucleic acids at ambient temperatures.     

Conformationally constrained PNA analogues: structural evolution toward DNA/RNA binding selectivity

Since its discovery 12 years ago, aminoethylglycyl peptide nucleic acid (aeg-PNA) has emerged as one of the successful DNA mimics for potential therapeutic and diagnostic applications. An important requisite for in vivo applications that has received inadequate attention is engineering PNA analogues for able discrimination between DNA and RNA as binding targets. Our approach toward this aim is based on structural preorganization of the backbone to hybridization-competent conformations to impart binding selectivity. This strategy has allowed us to design locked PNAs to achieve specific hybridization with DNA or RNA with aims to increase the binding strength without losing the binding specificity. This Account presents results of our rationale in design of different conformationally constrained PNA analogues, their synthesis, and evaluation of hybridization specificities.     

Single Labeled DNA FIT Probes for Avoiding False‐Positive Signaling in the Detection of DNA/RNA in qPCR or Cell Media

Oligonucleotide hybridization probes that fluoresce upon binding to complementary nucleic acid targets allow the real‐time detection of DNA or RNA in homogeneous solution. The most commonly used probes rely on the distance‐dependent interaction between a fluorophore and another label. Such duallabeled oligonucleotides signal the change of the global conformation that accompanies duplex formation. However, undesired nonspecific binding events and/or probe degradation also lead to changes in the label–label distance and, thus, to ambiguities in fluorescence signaling. Herein, we introduce singly labeled DNA probes, “DNA FIT probes”, that are designed to avoid false‐positive signals. A thiazole orange (TO) intercalator dye serves as an artificial base in the DNA probe. The probes show little background because the attachment mode hinders 1) interactions of the “TO base” in cis with the disordered nucleobases of the single strand, and 2) intercalation of the “TO nucleotide” with double strands in trans. However, formation of the probe–target duplex enforces stacking and increases the fluorescence of the TO base. We explored open‐chain and carbocyclic nucleotides. We show that the incorporation of the TO nucleotides has no effect on the thermal stability of the probe–target complexes. DNA and RNA targets provided up to 12‐fold enhancements of the TO emission upon hybridization of DNA FIT probes. Experiments in cell media demonstrated that false‐positive signaling was prevented when DNA FIT probes were used. Of note, DNA FIT probes tolerate a wide range of hybridization temperature; this enabled their application in quantitative polymerase chain reactions.     

Cationic peptides that increase the thermal stabilities of 2'-O-MeRNA/RNA duplexes but do not affect DNA/DNA melting

Several different cationic nonapeptides have been synthesized and investigated with respect to how they can influence the thermal melting of 2′‐O‐methylRNA/RNA and DNA/DNA duplexes. Each peptide has a C‐terminal L ‐phenylalanine unit and is otherwise uniformly composed of a sequence of a specific basic D ‐amino acid that in most cases will be largely charged at neutral pH. These N‐terminal octamer stretches are composed variously of the amino acids D ‐lysine, D ‐diaminobutyric acid (D ‐Dab), D ‐diaminopropionic acid (D ‐Dap), or D ‐histidine. None of the peptides substantially affected the thermal melting of DNA/DNA duplexes, which was in sharp contrast with their effects on 2′‐O‐methylRNA/RNA duplexes. In particular, the peptides based on diaminopropionic and diaminobutyric acid units had strong positive effects on the melting temperatures of the 2′‐O‐methylRNA duplexes (up to 16 °C higher with 1 equivalent of peptide) at pH 7, whereas at pH 6 the effect was even more drastic (ΔT_m up to +25 °C). The shorter R groups of the Dap and Dab groups appear to have a better length than lysine for enhancement of the thermal melting of the 2′‐O‐methylRNA/RNA duplex, an effect that is more pronounced at lower pH but substantial even at pH 7, although the Dap derivative is not likely to be fully protonated. The dramatic difference between the influence, or lack thereof, on the 2′‐O‐methylRNA/RNA and the DNA/DNA thermal meltings suggest that, although electrostatic interactions probably play a role, there is another major and structurally dependent component influencing the properties of the duplexes. This is also seen in the observation that the oligo‐Dap and oligo‐Dab peptides give greater melting point enhancements than both the lysine peptide (with a longer side chain) and a β‐linked Dap peptide with a shorter side chain and a longer backbone.     

High‐Fidelity Recognition of RNA: Solution Structure of a DNA:RNA Hybrid Duplex with a Molecular Cap

Binding RNA targets, such as microRNAs, with high fidelity is challenging, particularly when the nucleobases to be bound are located at the terminus of the duplex between probe and target. Recently, a peptidyl chain terminating in a quinolone, called ogOA, was shown to act as a cap that enhances affinity and fidelity for RNAs, stabilizing duplexes with Watson–Crick pairing at their termini. Here we report the three‐dimensional structure of an intramolecular complex between a DNA strand featuring the ogOA cap and an RNA segment, solved by NMR and restrained torsion angle molecular dynamics. The quinolone stacks on the terminal base pair of the hybrid duplex, positioned by the peptidyl chain, whose prolinol residue induces a sharp bend between the 5′ terminus of the DNA chain and the glycine linked to the oxolinic acid residue. The structure explains why canonical base pairing is favored over hard‐to‐suppress mismatched base combinations, such as T:G and A:A, and helps to design improved high‐fidelity probes for RNA.     

A Lucifer‐Based Environment‐Sensitive Fluorescent PNA Probe for Imaging Poly(A) RNAs

Fluorescence‐based oligonucleotide (ON) hybridization probes greatly aid the detection and profiling of RNA sequences in cells. However, certain limitations such as target accessibility and hybridization efficiency in cellular environments hamper their broad application because RNAs can form complex and stable structures. In this context, we have developed a robust hybridization probe suitable for imaging RNA in cells by combining the properties of 1) a new microenvironment‐sensitive fluorescent nucleobase analogue, obtained by attaching the Lucifer chromophore ( 1,8‐naphthalimide) at the 5‐position of uracil, and 2) a peptide nucleic acid (PNA) capable of forming stable hybrids with RNA. The fluorescence of the PNA base analogue labeled with the Lucifer chromophore, when incorporated into PNA oligomers and hybridized to complementary and mismatched ONs, is highly responsive to its neighboring base environment. Notably, the PNA base reports the presence of an adenine repeat in an RNA ON with reasonable enhancement in fluorescence. This feature of the emissive analogue enabled the construction of a poly(T) PNA probe for the efficient visualization of polyadenylated [poly(A)] RNAs in cells—poly(A) being an important motif that plays vital roles in the lifecycle of many types of RNA. Our results demonstrate that such responsive fluorescent nucleobase analogues, when judiciously placed in PNA oligomers, could generate useful hybridization probes to detect nucleic acid sequences in cells and also to image them.     

Responsive Fluorescent PNA Analogue as a Tool for Detecting G‐quadruplex Motifs of Oncogenes and Activity of Toxic Ribosome‐Inactivating Proteins

Fluorescent oligomers that are resistant to enzymatic degradation and report their binding to target oligonucleotides (ONs) by changes in fluorescence properties are highly useful in developing nucleic‐acid‐based diagnostic tools and therapeutic strategies. Here, we describe the synthesis and photophysical characterization of fluorescent peptide nucleic acid (PNA) building blocks made of microenvironment‐sensitive 5‐(benzofuran‐2‐yl)‐ and 5‐(benzothiophen‐2‐yl)‐uracil cores. The emissive monomers, when incorporated into PNA oligomers and hybridized to complementary ONs, are minimally perturbing and are highly sensitive to their neighboring base environment. In particular, benzothiophene‐modified PNA reports the hybridization process with significant enhancement in fluorescence intensity, even when placed in the vicinity of guanine residues, which often quench fluorescence. This feature was used in the turn‐on detection of G‐quadruplex‐forming promoter DNA sequences of human proto‐oncogenes (c‐myc and c‐kit). Furthermore, the ability of benzothiophene‐modified PNA oligomer to report the presence of an abasic site in RNA enabled us to develop a simple fluorescence hybridization assay to detect and estimate the depurination activity of ribosome‐inactivating protein toxins. Our results demonstrate that this approach with responsive PNA probes will provide new opportunities to develop robust tools to study nucleic acids.     

Probing Human Telomeric DNA and RNA Topology and Ligand Binding in a Cellular Model by Using Responsive Fluorescent Nucleoside Probes

The development of biophysical systems that enable an understanding of the structure and ligand‐binding properties of G‐quadruplex (GQ)‐forming nucleic acid sequences in cells or models that mimic the cellular environment would be highly beneficial in advancing GQ‐directed therapeutic strategies. Herein, the establishment of a biophysical platform to investigate the structure and recognition properties of human telomeric (H‐Telo) DNA and RNA repeats in a cell‐like confined environment by using conformation‐sensitive fluorescent nucleoside probes and a widely used cellular model, bis(2‐ethylhexyl) sodium sulfosuccinate reverse micelles (RMs), is described. The 2′‐deoxy and ribonucleoside probes, composed of a 5‐benzofuran uracil base analogue, faithfully report the aqueous micellar core through changes in their fluorescence properties. The nucleoside probes incorporated into different loops of H‐Telo DNA and RNA oligonucleotide repeats are minimally perturbing and photophysically signal the formation of respective GQ structures in both aqueous buffer and RMs. Furthermore, these sensors enable a direct comparison of the binding affinity of a ligand to H‐Telo DNA and RNA GQ structures in the bulk and confined environment of RMs. These results demonstrate that this combination of a GQ nucleoside probe and easy‐to‐handle RMs could provide new opportunities to study and devise screening‐compatible assays in a cell‐like environment to discover GQ binders of clinical potential.     

Triplex-Forming Peptide Nucleic Acids with Extended Backbones

Peptide nucleic acid (PNA) forms a triple helix with double-stranded RNA (dsRNA) stabilized by a hydrogen-bonding zipper formed by PNA's backbone amides (N−H) interacting with RNA phosphate oxygens. This hydrogen-bonding pattern is enabled by the matching ∼5.7 Å spacing (typical for A-form dsRNA) between PNA's backbone amides and RNA phosphate oxygens. We hypothesized that extending the PNA's backbone by one −CH₂− group might bring the distance between PNA amide groups closer to 7 Å, which is favourable for hydrogen bonding to the B-form dsDNA phosphate oxygens. Extension of the PNA backbone was expected to selectively stabilize PNA-DNA triplexes compared to PNA-RNA. To test this hypothesis, we synthesized triplex-forming PNAs that had the pseudopeptide backbones extended by an additional −CH₂− group in three different positions. Isothermal titration calorimetry measurements of the binding affinity of these extended PNA analogues for the matched dsDNA and dsRNA showed that, contrary to our structural reasoning, extending the PNA backbone at any position had a strong negative effect on triplex stability. Our results suggest that PNAs might have an inherent preference for A-form-like conformations when binding double-stranded nucleic acids. It appears that the original six-atom-long PNA backbone is an almost perfect fit for binding to A-form nucleic acids.     

作保灵对长残效除草剂的解毒效应

利用田间试验方法研究保护剂长残效除草剂解毒效应。不同保护剂对豆磺隆解毒效应有差异，作保灵解毒效应最明显，但在除草剂高残留量时解毒作用下降。作保灵对三种长残效除草剂都具有明显的解毒作用，作物的出苗率可恢复80％～100％。解毒效应顺序为油莱＞白菜＞甜菜。     

2-Methoxypyridine as a Thymidine Mimic in Watson–Crick Base Pairs of DNA and PNA: Synthesis,Thermal Stability,and NMR Structural Studies

The development of nucleic acid base-pair analogues that use new modes of molecular recognition is important both for fundamental research and practical applications. The goal of this study was to evaluate 2-methoxypyridine as a cationic thymidine mimic in the A–T base pair. The hypothesis was that including protonation in the Watson–Crick base pairing scheme would enhance the thermal stability of the DNA double helix without compromising the sequence selectivity. DNA and peptide nucleic acid (PNA) sequences containing the new 2-methoxypyridine nucleobase (P) were synthesized and studied by using UV thermal melting and NMR spectroscopy. Introduction of P nucleobase caused a loss of thermal stability of ≈10 °C in DNA–DNA duplexes and ≈20 °C in PNA–DNA duplexes over a range of mildly acidic to neutral pH. Despite the decrease in thermal stability, the NMR structural studies showed that P–A formed the expected protonated base pair at pH 4.3. Our study demonstrates the feasibility of cationic unnatural base pairs; however, future optimization of such analogues will be required.     

Reducing Product Inhibition in Nucleic Acid‐Templated Ligation Reactions: DNA‐Templated Cycligation

Programmable interactions allow nucleic acid molecules to template chemical reactions by increasing the effective molarities of appended reactive groups. DNA/RNA‐triggered reactions can proceed, in principle, with turnover in the template. The amplification provided by the formation of many product molecules per template is a valuable asset when the availability of the DNA or RNA target is limited. However, turnover is usually impeded by reaction products that block access to the template. Product inhibition is most severe in ligation reactions, where products after ligation have dramatically increased template affinities. We introduce a potentially generic approach to reduce product inhibition in nucleic acid‐programmed ligation reactions. A DNA‐triggered ligation–cyclization sequence (“cycligation”) of bifunctional peptide nucleic acid (PNA) conjugates affords cyclic ligation products. Melting experiments revealed that product cyclization is accompanied by a pronounced decrease in template affinity compared to linear ligation products. The reaction system relies upon haloacetylated PNA‐thioesters and isocysteinyl‐PNA‐cysteine conjugates, which were ligated on a DNA template according to a native chemical ligation mechanism. Dissociation of the resulting linear product‐template duplex (induced by, for example, thermal cycling) enabled product cyclization through sulfur‐halide substitution. Both ligation and cyclization are fast reactions (ligation: 86 % yield after 20 min, cyclization: quantitative after 5 min). Under thermocycling conditions, the DNA template was able to trigger the formation of new product molecules when fresh reactants were added. Furthermore, cycligation produced 2–3 times more product than a conventional ligation reaction with substoichiometric template loads (0.25–0.01 equiv). We believe that cyclization of products from DNA‐templated reactions could ultimately afford systems that completely overcome product inhibition.     

Unlocked Nucleic Acids with a Pyrene‐Modified Uracil: Synthesis,Hybridization Studies,Fluorescent Properties and i‐Motif Stability

The synthesis of two new phosphoramidite building blocks for the incorporation of 5‐(pyren‐1‐yl)uracilyl unlocked nucleic acid (UNA) monomers into oligonucleotides has been developed. Monomers containing a pyrene‐modified nucleobase component were found to destabilize an i‐motif structure at pH 5.2, both under molecular crowding and noncrowding conditions. The presence of the pyrene‐modified UNA monomers in DNA strands led to decreases in the thermal stabilities of DNA*/DNA and DNA*/RNA duplexes, but these duplexes' thermal stabilities were better than those of duplexes containing unmodified UNA monomers. Pyrene‐modified UNA monomers incorporated in bulges were able to stabilize DNA*/DNA duplexes due to intercalation of the pyrene moiety into the duplexes. Steady‐state fluorescence emission studies of oligonucleotides containing pyrene‐modified UNA monomers revealed decreases in fluorescence intensities upon hybridization to DNA or RNA. Efficient quenching of fluorescence of pyrene‐modified UNA monomers was observed after formation of i‐motif structures at pH 5.2. The stabilizing/destabilizing effect of pyrene‐modified nucleic acids might be useful for designing antisense oligonucleotides and hybridization probes.