Kinetics of Strand Displacement Reaction with Acyclic Artificial Nucleic Acids.

Toehold-mediated strand displacement (TMSD) reaction, one of the DNA nanotechnologies, has great potential as s biological programmable platform in the cellular environment. Various artificial nucleic acids have been developed to improve stability and affinity for biological applications. However, the lack of understanding of the kinetics of TMSD reaction among artificial nucleic acids has limited their applications. We herein systematically characterized the kinetics of TMSD reactions with acyclic xeno nucleic acids (XNAs): serinol nucleic acid (SNA), acyclic D-threoninol nucleic acid (D-aTNA), and acyclic L-threoninol nucleic acid (L-aTNA). We found that the strand displacement reactions by D-aTNA and by L-aTNA were highly dependent on temperature. D-aTNA and L-aTNA systems were orthogonal to each other, and chirality of the input can be switched by using SNA as an interface. We also applied TMSD reactions of XNAs to a seesaw gate amplification system which utilizes the orthogonality. This work will contribute to the developments of thermoresponsive and bioorthogonal nucleic acid circuits.

Color-Changing Fluorescent Barcode Based on Strand Displacement Reaction Enables Simple Multiplexed Labeling.

Fluorescence imaging techniques have contributed to our understanding of various biological phenomenon; however, fluorescence spectral overlap significantly restricts multiplexing capability. Several strategies have been reported to overcome this limitation by utilizing the superior programmability of DNA technologies and nanostructures, but in practice, it remains challenging to achieve broad adoption of these multiplexed detection methods due to the complexities of these DNA designs. Here we report a color-changing fluorescent barcode (CCFB) approach that enables multiple labeling with simple and small nucleic acid structure design based on sequential toehold-mediated strand displacement reaction. The emission color of CCFB can vary in the predetermined sequence so that multiple targets can be detected simultaneously. The CCFB complex is composed of several oligonucleotides, and its color sequence can be easily expanded further. The CCFB approach is easy and time-saving to operate since the irreversible color-changing reaction occurs by simply adding complementary oligonucleotide. We herein developed 27 different CCFB labels, which required only 14 oligonucleotides. We demonstrated that the CCFB system can be used to label multiple targets by attaching CCFB label to polystyrene beads. Moreover, the CCFB can be used to detect intracellular proteins simultaneously when it is attached to antibodies. We expect that this practical platform will be adopted for comprehensive biomolecular imaging in cells.

Preparation of Artificial Hexaplex Composed of Non-Natural Nucleic Acid.

This article describes synthetic procedures for acyclic D-threoninol nucleic acid tethering of bifacial nucleobases. Because these nucleobases have complementary hydrogen bonding sites on both sides, their oligomers can form a hexaplex. These hexaplexes are suitable for use as metal or pH sensors and as supramolecular motifs. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Synthesis of D-threoninol backbone Basic Protocol 2: Synthesis of D-aTNA tethering cyanuric acid Basic Protocol 3: Synthesis of D-aTNA tethering a 2-aminopyrimidine moiety Basic Protocol 4: Synthesis of D-aTNA tethering a 2,4,6-triaminopyrimidine moiety Basic Protocol 5: Synthesis of D-aTNA oligomer tethering cyanuric acid, 2-aminopyrimidine, or 2,4,6-triaminopyrimidine.

Microheater-integrated zinc oxide nanowire microfluidic device for hybridization-based detection of target single-stranded DNA.

Detection of cell-free DNA (cfDNA) has an impact on DNA analysis in liquid biopsies. However, current strategies to detect cfDNA have limitations that should be overcome, such as having low sensitivity and requiring much time and a specialized instrument. Thus, non-invasive and rapid detection tools are needed for disease prevention and early-stage treatment. Here we developed a device having a microheater integrated with zinc oxide nanowires (microheater-ZnO-NWs) to detect target single-stranded DNAs (ssDNAs) based on DNA probe hybridization. We confirmed experimentally that our device realizedin-situannealed DNA probes by which we subsequently detected target ssDNAs. We envision that this device can be utilized for fundamental studies related to nanobiodevice-based DNA detection.

Bifurcated synthesis of methylene-lactone- and methylene-lactam-fused spirolactams via electrophilic amide allylation of γ-phenylthio-functionalized γ-lactams.

New synthetic methods for spirolactams bearing an α-methylene-γ-butyrolactone or its analogous methylene-lactam have been developed. The allylation of γ-phenylthio-functionalized γ-lactams with 2-(acetoxy)methyl acrylamides was accomplished by using 2.5 equivalents of NaH to give the corresponding adducts in excellent yields. The remaining phenylthio group was substituted with a hydroxy group by treatment with CuBr, and the resulting γ-hydroxyamides were cyclized under acidic conditions to afford the corresponding methylene-lactam-fused spirolactams in high yields. On the other hand, methylene-lactone-fused spirolactams could be delivered from the allyl adducts in high yields through a sequential N-Boc protection/desulfinative lactonization.

Selective binding of nucleosides to gapped DNA duplex revealed by orientation and distance dependence of FRET.

Herein we used orientation and distance dependence of Förster resonance energy transfer (FRET) to analyze the binding of nucleosides to a gapped DNA duplex. Binding isotherms and information on the structures of the complexes were obtained by monitoring FRET between pyrene and perylene, which were introduced into the DNA through d-threoninol. FRET efficiency significantly changed upon formation of a duplex with a 1-nucleotide gap and a nucleoside. The FRET plot indicated that the complex has a double helical structure similar to a nicked duplex. Cooperative binding of two nucleosides to a duplex with a 2-nucleotide gap was also revealed using FRET. Various drug-nucleic acids interactions could be investigated using this sensitive and facile method.