Histidine-DNA nanoarchitecture as laccase mimetic DNAzymes

Herein, we report on the construction of Cu-histidine (His)-DNA hybrids as laccase-mimetic DNAzymes. Cu-His-DNAzymes showed remarkable activity in a colorimetric oxidation reaction between 2,4-dichlorophenol and 4-aminoantipyrine. Our results provide new insights for the systematic construction of tailor-made active sites for biomimetics.

Harnessing DNA as a Designable Scaffold for Asymmetric Catalysis: Recent Advances and Future Perspectives

Since the first report of DNAzyme by in vitro selection in 1994, catalytic DNA has investigated extensively, and their application has expanded continually in virtue of rapid advances in molecular biology and biotechnology. Nowadays, DNA is in the second prime time by way of DNA-based hybrid catalysts and DNA metalloenzymes in which helical chirality of DNA serves to asymmetric catalysis. DNA-based hybrid catalysts are attractive system to respond the demand of the times to pursuit green and sustainable society beyond traditional catalytic systems that value reaction efficiency. Herein, we highlight the recent advances and perspective of DNA-based hybrid catalysts with various aspects of DNA as a versatile scaffold for asymmetric synthesis. We hope that scientists in a variety of fields will be encouraged to join and promote remarkable evolution of this interesting research.

Photo-Cross-Linking between Br U and Pyrene Residues in an RNA/DNA Hybrid

In this study, we investigated the photoreaction of Br U in a pyrene-labeled DNA duplex, RNA duplex, and DNA/RNA hybrids. We found that the photoreactivity of Br U changed dramatically from hydrogen abstraction to cross-linking by changing the conformation of the duplex from the B-form to the A-form. Among three A-form structures, the largest amount of cross-linked products was observed when Br U was incorporated into the RNA strand and the pyrene was conjugated to the 5' end of the DNA. These results indicate that the contact manner of pyrene was different between A- and B-form duplexes. This is a rare example of the use of the reactivity of bromouracil to analyze the contact between a small molecule with a weak binding affinity and a nucleic acid.

Enhanced Immunostimulatory Activity of Covalent DNA Dendrons

The present study focused on the design and synthesis of covalent DNA dendrons bearing multivalent cytosine-phosphate-guanine oligodeoxynucleotides (CpG ODNs) that can stimulate the immune system through the activation of TLR9. These dendrons were synthesized using branching trebler phosphoramidite containing three identical protecting groups that enabled the simultaneous synthesis of multiple strands on a single molecule. Compared with linear ODNs, covalent DNA dendrons were found to be more resistant to nuclease degradation and were more efficiently taken up by macrophage-like RAW264.7 cells. Cellular uptake was suggested to be mediated by macrophage scavenger receptors. The covalent DNA dendrons composed of multivalent immunostimulatory branches enhanced the secretion of proinflammatory cytokines TNF-α and IL-6 from RAW264.7 cells, and 9-branched DNA dendrons showed the highest enhancement. Given their enhanced efficacy, we expect covalent DNA dendrons to be useful structures of oligonucleotide medicines.

Photo-Controllable Phase Transition of Arylazopyrazole-Conjugated Oligonucleotides

Phase transition is a promising aspect of DNA as biopolymers. Anionic DNA oligonucleotides easily form complexes with cationic polypeptides such as polylysine, and duplex formation significantly influences their complexation and resulting microcompartments. In this study, phase transition of microcompartments containing DNA and polylysine was systematically induced by modulating duplex formation of arylazopyrazole-conjugated oligonucleotides with light. We demonstrated that UV irradiation destabilized DNA duplex and generated isotropic coacervates, while duplex stabilization by visible light irradiation caused the formation of liquid crystalline coacervates. This photocontrol of phase transition was highly repeatable, and similar changes were observed even after ten cycles of light irradiation. Our approach would provide a robust control layer to the development of tailor-made microcompartments.

Synthesis and application of a 19F-labeled fluorescent nucleoside as a dual-mode probe for i-motif DNAs

Because of their stable orientations and their minimal interference with native DNA interactions and folding, emissive isomorphic nucleoside analogues are versatile tools for the accurate analysis of DNA structural heterogeneity. Here, we report on a bifunctional trifluoromethylphenylpyrrolocytidine derivative (FPdC) that displays an unprecedented quantum yield and highly sensitive 19F NMR signal. This is the first report of a cytosine-based dual-purpose probe for both fluorescence and 19F NMR spectroscopic DNA analysis. FPdC and FPdC-containing DNA were synthesized and characterized; our robust dual probe was successfully used to investigate the noncanonical DNA structure, i-motifs, through changes in fluorescence intensity and 19F chemical shift in response to i-motif formation. The utility of FPdC was exemplified through reversible fluorescence switching of an FPdC-containing i-motif oligonucleotide in the presence of Ag(i) and cysteine.

Systematic Approach to DNA Aptamer Design Using Amino Acid-Nucleic Acid Hybrids (ANHs) Targeting Thrombin

Chemical modifications of innate DNA/RNA aptamers facilitate the improvement of their function. Herein, we report our modular strategy to manipulate a thrombin-binding DNA aptamer (TBA) to improve its anticoagulation activity and binding affinity. A set of amino acid conjugates, termed amino acid-nucleic acid hybrids or ANHs, was synthesized and incorporated into a TBA loop sequences. We found that substitutions with hydrophobic amino acids in the loop region possessed significantly enhanced antithrombin activity, up to 3-fold higher than the native TBA. We investigated the correlations between thrombin-binding affinity and the features of our amino-acid conjugates using experimental techniques including circular dichroism spectroscopy, surface plasmon resonance assay, and molecular modeling. The present study demonstrates a systematic approach to aptamer design based on amino-acid characteristics, allowing the development of advanced aptamers.

Modular quadruplex-duplex hybrids as biomolecular scaffolds for asymmetric Michael addition reactions

Asymmetric synthesis based on DNA scaffolds has been actively exploited because of the advantages of DNA such as diverse tertiary structures, chemical stability, and easy handling. Since duplex DNA-based hybrid catalysts have demonstrated this remarkable capability, efforts have been made to investigate new biomolecular scaffolds. Herein, we report modular quadruplex-duplex (QD) hybrid DNA catalysts containing bipyridine ligands and hydrogen donor moieties. The conformation, thermal stability, and metal-binding ability of modified QD hybrid DNA were characterized using spectroscopy. The QD hybrid-based DNA catalysts were successfully applied to asymmetric Michael addition reactions (86% conversion and 76% ee). This study describes a new type of DNA hybrid catalyst produced by the construction of a cooperative active site with a Lewis acid and a H-bond donor.

Histidine-conjugated DNA as a biomolecular depot for metal ions

Histidine is a versatile amino acid residue that plays a critical role in the active sites of many metalloenzymes. DNA is an attractive biomolecular scaffold owing to its chemical and thermal stability and easy accessibility. Herein, we report histidine-conjugated DNA oligonucleotides, which were synthesized by combining DNA alphabets and natural metal-binding amino acids, as novel biohybrid materials and demonstrate their use as molecular depots for various metal ions. Moreover, histidine-conjugated DNA oligonucleotides could be successfully used in asymmetric catalysis (up to 90% conversion and 95% ee) as DNA metalloenzymes and in 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) oxidation reactions as horseradish-peroxidase (HRP)-mimicking DNAzymes with suitable metal cofactors. Nature-inspired histidine-DNA hybrids will become an attractive strategy to construct fine-tuned coordination environments as an alternative to bioremediation and the development of multimetal enzymes.

Histidine is a versatile amino acid residue that plays a critical role in the active sites of many metalloenzymes.

Modular DNA-based hybrid catalysts as a toolbox for enantioselective hydration of α,β-unsaturated ketones

The direct addition of water to a carbon-carbon double bond remains a challenge, but such a reaction is essential for the development of efficient catalysts that enable direct access to chiral alcohols. We now report on the enantioselective hydration of α,β-unsaturated ketones, catalyzed by modular DNA-based hybrid catalysts, affording β-hydroxy ketones with up to 87% enantiomeric excess. Oligonucleotides containing an intrastrand bipyridine ligand were readily synthesized by a straightforward process using an automated solid-phase synthesis. A library of DNA-based hybrid catalysts could be systematically generated based on the composition of nucleobases, and the incorporation of a binding ligand and a nonbinding steric moiety. This study demonstrates the potential of modular DNA-based hybrid catalysts as a toolbox to accomplish the challenging enantioselective hydration reaction.

G-quadruplexes as versatile scaffolds for catalysis

This review summarizes the beginning, progress, and prospects of non-canonical DNA-based hybrid catalysts focusing on G-quadruplexes as versatile scaffolds for catalysis.

Effect of coadsorbent on the photovoltaic performance of squaraine sensitized nanocrystalline solar cells

The effect of chenodeoxycholic acid as the coadsorbent with a squaraine sensitizer on TiO(2) nanocrystalline solar cells was investigated, and it was found that the coadsorbent prevents the squaraine sensitizer from aggregating on the TiO(2) nanoparticles but reduces dye loading leading to an interdependent photovoltaic performance. Analysis of the absorption spectra, and incident monochromatic photon-to-current conversion efficiency data showed that the load of squaraine sensitizer as well as the appearance of H-aggregates is strongly dependent on the molar concentration of chenodeoxycholic acid coadsorbent. The open circuit voltage of the solar cells with chenodeoxycholic acid increases due to the enhanced electron lifetime in the TiO(2) nanoparticles coupled with the band edge shift of TiO(2) to negative potentials.

Evaluation of the Hodge test and the imipenem-EDTA double-disk synergy test for differentiating metallo-beta-lactamase-producing isolates of Pseudomonas spp. and Acinetobacter spp

Gram-negative bacilli with acquired metallo-beta-lactamase (MBL) production have been increasingly reported in some countries, necessitating their detection. The aim of this study was to evaluate the performance of the Hodge test and those of the imipenem (IPM)-EDTA, ceftazidime (CAZ)-mercaptopropionic acid (MPA), and CAZ-sodium mercaptoacetic acid (SMA) double-disk synergy tests (DDSTs). The efficiencies of testing CAZ-resistant and IPM-nonsusceptible isolates were also compared. Strains used for the evaluation were known IMP-1 and VIM-2 MBL-producing isolates and consecutive and CAZ-nonsusceptible isolates of pseudomonads and acinetobacters. The performance of the Hodge test was improved by addition of zinc sulfate (140 microg/disk) to an IPM disk. In DDSTs, EDTA (ca. 1,900 microg) disks were better at detecting MBL-producing strains among pseudomonads, while MPA (3 microl) and SMA (3 mg) disks performed better for acinetobacters. EDTA (ca. 750 microg)-plus-SMA (ca. 2 mg) disks performed better than EDTA, MPA, or SMA disks with both organisms. CAZ-SMA DDSTs failed to detect 22 of 80 (28%) MBL-producing acinetobacters. In conclusion, use of an IPM disk and an EDTA (750 microg)-plus-SMA (2 mg) disk improves performance, and testing IPM-nonsusceptible isolates rather than CAZ-resistant isolates could reduce screening work. Further evaluation of the test is required for the detection of other types of MBL-producing gram-negative bacilli.