Direct Observation and Analysis of TET-mediated Oxidation Processes in a DNA Origami Nanochip

DNA methylation and demethylation play a key role in the epigenetic regulation of gene expression; however, a series of oxidation reactions of 5-methyl cytosine (5mC) mediated by ten-eleven translocation (TET) enzymes driving demethylation process are yet to be uncovered. To elucidate the relationship between the oxidative processes and structural factors of DNA, we analysed the behavior of TET-mediated 5mC-oxidation by incorporating structural stress onto a substrate double-stranded DNA (dsDNA) using a DNA origami nanochip. The reactions and behaviors of TET enzymes were systematically monitored by biochemical analysis and single-molecule observation using atomic force microscopy (AFM). A reformative frame-like DNA origami was established to allow the incorporation of dsDNAs as 5mC-containing substrates in parallel orientations. We tested the potential effect of dsDNAs present in the tense and relaxed states within a DNA nanochip on TET oxidation. Based on enzyme binding and the detection of oxidation reactions within the DNA nanochip, it was revealed that TET preferred a relaxed substrate regardless of the modification types of 5-oxidated-methyl cytosine. Strikingly, when a multi-5mCG sites model was deployed to further characterize substrate preferences of TET, TET preferred the fully methylated site over the hemi-methylated site. This analytical modality also permits the direct observations of dynamic movements of TET such as sliding and interstrand transfer by high-speed AFM. In addition, the thymine DNA glycosylase-mediated base excision repair process was characterized in the DNA nanochip. Thus, we have convincingly established the system's ability to physically regulate enzymatic reactions, which could prove useful for the observation and characterization of coordinated DNA demethylation processes at the nanoscale

DNA density-dependent uptake of DNA origami-based two-or three-dimensional nanostructures by immune cells

DNA nanostructures are expected to be applied for targeted drug delivery to immune cells. However, the structural properties of DNA nanostructures required for the delivery have not fully been elucidated. In this study, we focused on the DNA density that can be important for the their recognition and uptake by immune cells. To examine this, DNA nanostructures with almost identical molecular weights and structural flexibility, but with different shapes and DNA densities, were designed using DNA origami technology. We compared the following five types of DNA nanostructures, all of which consisted of ten DNA helices using an identical circular, single-stranded scaffold and staples. Rec180 had a rectangular-shaped, almost flat structure. Rec90, Rec50 and Rec0 were bent forms of Rec180 at the center by 90, 50 or 0 degrees, respectively. Rec50/50 has two bends of 50 degrees each so that the both ends stick together to form a triangular prism shape. The fluctuation, or flexibility, of these DNA nanostructures under solution conditions was estimated using CanDo software. The DNA density estimated from the average distance between any two of the ten DNA helices in the DNA nanostructures was different among them; Rec50, Rec0 and Rec50/50 had a higher density than Rec180 and Rec90. Agarose gel electrophoresis and atomic force microscopy showed that all of the nanostructures were prepared with high yield. Flow cytometry analysis revealed that the uptake of DNA nanostructures by murine macrophage-like RAW264.7 cells was higher for those with higher DNA density than those with low density. There was a positive correlation between the density and cellular uptake. These results indicate that DNA nanostructures with high DNA density are suitable for delivery to immune cells

Single-molecule observations of RNA-RNA kissing interactions in a DNA nanostructure

RNA molecules uniquely form a complex through specific hairpin loops, called a kissing complex. The kissing complex is widely investigated and used for the construction of RNA nanostructures. Molecular switches have also been created by combining a kissing loop and a ligand-binding aptamer to control the interactions of RNA molecules. In this study, we incorporated two kinds of RNA molecules into a DNA origami structure and used atomic force microscopy to observe their ligand-responsive interactions at the single-molecule level. We used a designed RNA aptamer called GTPswitch, which has a guanosine triphosphate (GTP) responsive domain and can bind to the target RNA hairpin named Aptakiss in the presence of GTP. We observed shape changes of the DNA/RNA strands in the DNA origami, which are induced by the GTPswitch, into two different shapes in the absence and presence of GTP, respectively. We also found that the switching function in the nanospace could be improved by using a cover strand over the kissing loop of the GTPswitch or by deleting one base from this kissing loop. These newly designed ligand-responsive aptamers can be used for the controlled assembly of the various DNA and RNA nanostructures

HBD1 protein with a tandem repeat of two HMG-box domains is a DNA clip to organize chloroplast nucleoids in Chlamydomonas reinhardtii

葉緑体核様体をコンパクトに折りたたむ「DNAクリップ」の発見 --ミトコンドリアとも共通する普遍的なしくみの解明--. 京都大学プレスリリース. 2021-05-12.Compaction of bulky DNA is a universal issue for all DNA-based life forms. Chloroplast nucleoids (chloroplast DNA–protein complexes) are critical for chloroplast DNA maintenance and transcription, thereby supporting photosynthesis, but their detailed structure remains enigmatic. Our proteomic analysis of chloroplast nucleoids of the green alga Chlamydomonas reinhardtii identified a protein (HBD1) with a tandem repeat of two DNA-binding high mobility group box (HMG-box) domains, which is structurally similar to major mitochondrial nucleoid proteins transcription factor A, mitochondrial (TFAM), and ARS binding factor 2 protein (Abf2p). Disruption of the HBD1 gene by CRISPR-Cas9–mediated genome editing resulted in the scattering of chloroplast nucleoids. This phenotype was complemented when intact HBD1 was reintroduced, whereas a truncated HBD1 with a single HMG-box domain failed to complement the phenotype. Furthermore, ectopic expression of HBD1 in the mitochondria of yeast Δabf2 mutant successfully complemented the defects, suggesting functional similarity between HBD1 and Abf2p. Furthermore, in vitro assays of HBD1, including the electrophoretic mobility shift assay and DNA origami/atomic force microscopy, showed that HBD1 is capable of introducing U-turns and cross-strand bridges, indicating that proteins with two HMG-box domains would function as DNA clips to compact DNA in both chloroplast and mitochondrial nucleoids

Characterization of a Conformation-Restricted Amyloid β Peptide and Immunoreactivity of Its Antibody in Human AD brain.

Characterization of amyloid β (Aβ) oligomers, the transition species present prior to the formation of Aβ fibrils and that have cytotoxicity, has become one of the major topics in the investigations of Alzheimer\u27s disease (AD) pathogenesis. However, studying pathophysiological properties of Aβ oligomers is challenging due to the instability of these protein complexes in vitro. Here, we report that conformation-restricted Aβ42 with an intramolecular disulfide bond at positions 17 and 28 (SS-Aβ42) formed stable Aβ oligomers in vitro. Thioflavin T binding assays, nondenaturing gel electrophoresis, and morphological analyses revealed that SS-Aβ42 maintained oligomeric structure, whereas wild-type Aβ42 and the highly aggregative Aβ42 mutant with E22P substitution (E22P-Aβ42) formed Aβ fibrils. In agreement with these observations, SS-Aβ42 was more cytotoxic compared to the wild-type and E22P-Aβ42 in cell cultures. Furthermore, we developed a monoclonal antibody, designated TxCo-1, using the toxic conformation of SS-Aβ42 as immunogen. X-ray crystallography of the TxCo-1/SS-Aβ42 complex, enzyme immunoassay, and immunohistochemical studies confirmed the recognition site and specificity of TxCo-1 to SS-Aβ42. Immunohistochemistry with TxCo-1 antibody identified structures resembling senile plaques and vascular Aβ in brain samples of AD subjects. However, TxCo-1 immunoreactivity did not colocalize extensively with Aβ plaques identified with conventional Aβ antibodies. Together, these findings indicate that Aβ with a turn at positions 22 and 23, which is prone to form Aβ oligomers, could show strong cytotoxicity and accumulated in brains of AD subjects. The SS-Aβ42 and TxCo-1 antibody should facilitate understanding of the pathological role of Aβ with toxic conformation in AD

Non‐invasive Regulation of Cellular Morphology Using a Photoswitchable Mechanical DNA Polymer

The extracellular matrix (ECM) in which the cells reside provides a dynamic and reversible environment. Spatiotemporal cues are essential when cells are undergoing morphogenesis, repair and differentiation. Emulation of such an intricate system with reversible presentation of nanoscale cues can help us better understand cellular processes and can allow the precise manipulation of cell function in vitro. Herein, we formulated a photoswitchable DNA mechanical nanostructure containing azobenzene moieties and dynamically regulated the spatial distance between adhesion peptides using a photoswitchable DNA polymer with photoirradiation. We found that the DNA polymer reversibly forms two different structures, a relaxed linear and shrunken compact form, observed by AFM. Using the mechanical properties of this DNA polymer, UV and visible light irradiation induced a significant morphology change of the cells between a round shape and spindle shape, thus providing a tool to decipher the language of the ECM better

Preparation of chemically modified RNA origami nanostructures.

In nucleic acid nanotechnology, designed RNA molecules are widely explored because of their usability originating from RNA's structural and functional diversity. Herein, a method to design and prepare RNA nanostructures by employing DNA origami strategy was developed. A single-stranded RNA scaffold and staple RNA strands were used for the formation of RNA nanostructures. After the annealing of the mixtures, 7-helix bundled RNA tile and 6-helix bundled RNA tube structures were observed as predesigned shapes. These nanostructures were easily functionalized by introducing chemical modification to the RNA scaffolds. The DNA origami method is extended and utilized to construct RNA nanostructures

Direct observation and analysis of the dynamics of the photoresponsive transcription factor GAL4

Herein, the direct visualization of the dynamic interaction between a photoresponsive transcription factor fusion, GAL4–VVD, and DNA using high‐speed atomic force microscopy (HS‐AFM) is reported. A series of different GAL4–VVD movements, such as binding, sliding, stalling, and dissociation, was observed. Inter‐strand jumping on two double‐stranded (ds) DNAs was also observed. Detailed analysis using a long substrate DNA strand containing five GAL4‐binding sites revealed that GAL4–VVD randomly moved on the dsDNA using sliding and hopping to rapidly find specific binding sites, and then stalled to the specific sites to form a stable complex formation. These results suggest the existence of different conformations of the protein to enable sliding and stalling. This single‐molecule imaging system with nanoscale resolution provides an insight into the searching mechanism used by DNA‐binding proteins

Direct observation and analysis of the dynamics of the photoresponsive transcription factor GAL4

Herein, the direct visualization of the dynamic interaction between a photoresponsive transcription factor fusion, GAL4–VVD, and DNA using high‐speed atomic force microscopy (HS‐AFM) is reported. A series of different GAL4–VVD movements, such as binding, sliding, stalling, and dissociation, was observed. Inter‐strand jumping on two double‐stranded (ds) DNAs was also observed. Detailed analysis using a long substrate DNA strand containing five GAL4‐binding sites revealed that GAL4–VVD randomly moved on the dsDNA using sliding and hopping to rapidly find specific binding sites, and then stalled to the specific sites to form a stable complex formation. These results suggest the existence of different conformations of the protein to enable sliding and stalling. This single‐molecule imaging system with nanoscale resolution provides an insight into the searching mechanism used by DNA‐binding proteins

Controlling the stoichiometry and strand polarity of a tetramolecular G-quadruplex structure by using a DNA origami frame.

Guanine-rich oligonucleotides often show a strong tendency to form supramolecular architecture, the so-called G-quadruplex structure. Because of the biological significance, it is now considered to be one of the most important conformations of DNA. Here, we describe the direct visualization and single-molecule analysis of the formation of a tetramolecular G-quadruplex in KCl solution. The conformational changes were carried out by incorporating two duplex DNAs, with G-G mismatch repeats in the middle, inside a DNA origami frame and monitoring the topology change of the strands. In the absence of KCl, incorporated duplexes had no interaction and laid parallel to each other. Addition of KCl induced the formation of a G-quadruplex structure by stably binding the duplexes to each other in the middle. Such a quadruplex formation allowed the DNA synapsis without disturbing the duplex regions of the participating sequences, and resulted in an X-shaped structure that was monitored by atomic force microscopy. Further, the G-quadruplex formation in KCl solution and its disruption in KCl-free buffer were analyzed in real-time. The orientation of the G-quadruplex is often difficult to control and investigate using traditional biochemical methods. However, our method using DNA origami could successfully control the strand orientations, topology and stoichiometry of the G-quadruplex