More Like this

1. Mono- and bilayer smectic liquid crystal ordering in dense solutions of “gapped” DNA duplexes

   https://doi.org/10.1073/pnas.2019996118  

   Gyawali, Prabesh; Saha, Rony; Smith, Gregory P.; Salamonczyk, Miroslaw; Kharel, Prakash; Basu, Soumitra; Li, Ruipeng; Fukuto, Masafumi; Gleeson, James T.; Clark, Noel A.; et al (March 2021, Proceedings of the National Academy of Sciences)

   Although its mesomorphic properties have been studied for many years, only recently has the molecule of life begun to reveal the true range of its rich liquid crystalline behavior. End-to-end interactions between concentrated, ultrashort DNA duplexes—driving the self-assembly of aggregates that organize into liquid crystal phases—and the incorporation of flexible single-stranded “gaps” in otherwise fully paired duplexes—producing clear evidence of an elementary lamellar (smectic-A) phase in DNA solutions—are two exciting developments that have opened avenues for discovery. Here, we report on a wider investigation of the nature and temperature dependence of smectic ordering in concentrated solutions of various “gapped” DNA (GDNA) constructs. We examine symmetric GDNA constructs consisting of two 48-base pair duplex segments bridged by a single-stranded sequence of 2 to 20 thymine bases. Two distinct smectic layer structures are observed for DNA concentration in the range $\sim 230\text{to}\sim 280$mg/mL. One exhibits an interlayer periodicity comparable with two-duplex lengths (“bilayer” structure), and the other has a period similar to a single-duplex length (“monolayer” structure). The bilayer structure is observed for gap length ≳10 bases and melts into the cholesteric phase at a temperature between 30 °C and 35 °C. The monolayer structure predominates for gap length ≲10 bases and persists to $>40\hspace{0.17em}°$C. We discuss models for the two layer structures and mechanisms for their stability. We also report results for asymmetric gapped constructs and for constructs with terminal overhangs, which further support the model layer structures. 

   more » « less
2. Nanorings to Probe Mechanical Stress of Single-Stranded DNA Mediated by the DNA Duplex

   https://doi.org/10.3390/ijms232112916  

   Zagorski, Karen; Stormberg, Tommy; Hashemi, Mohtadin; Kolomeisky, Anatoly B.; Lyubchenko, Yuri L. (November 2022, International Journal of Molecular Sciences)

   The interplay between the mechanical properties of double-stranded and single-stranded DNA is a phenomenon that contributes to various genetic processes in which both types of DNA structures coexist. Highly stiff DNA duplexes can stretch single-stranded DNA (ssDNA) segments between the duplexes in a topologically constrained domain. To evaluate such an effect, we designed short DNA nanorings in which a DNA duplex with 160 bp is connected by a 30 nt single-stranded DNA segment. The stretching effect of the duplex in such a DNA construct can lead to the elongation of ssDNA, and this effect can be measured directly using atomic force microscopy (AFM) imaging. In AFM images of the nanorings, the ssDNA regions were identified, and the end-to-end distance of ssDNA was measured. The data revealed a stretching of the ssDNA segment with a median end-to-end distance which was 16% higher compared with the control. These data are in line with theoretical estimates of the stretching of ssDNA by the rigid DNA duplex holding the ssDNA segment within the nanoring construct. Time-lapse AFM data revealed substantial dynamics of the DNA rings, allowing for the formation of transient crossed nanoring formations with end-to-end distances as much as 30% larger than those of the longer-lived morphologies. The generated nanorings are an attractive model system for investigation of the effects of mechanical stretching of ssDNA on its biochemical properties, including interaction with proteins. 

   more » « less
3. Implementing Logic Gates by DNA Crystal Engineering

   https://doi.org/10.1002/adma.202302345  

   Zhang, Cuizheng; Paluzzi, Victoria_E; Sha, Ruojie; Jonoska, Natasha; Mao, Chengde (July 2023, Advanced Materials)

   Abstract DNA self‐assembly computation is attractive for its potential to perform massively parallel information processing at the molecular level while at the same time maintaining its natural biocompatibility. It has been extensively studied at the individual molecule level, but not as much as ensembles in 3D. Here, the feasibility of implementing logic gates, the basic computation operations, in large ensembles: macroscopic, engineered 3D DNA crystals is demonstrated. The building blocks are the recently developed DNA double crossover‐like (DXL) motifs. They can associate with each other via sticky‐end cohesion. Common logic gates are realized by encoding the inputs within the sticky ends of the motifs. The outputs are demonstrated through the formation of macroscopic crystals that can be easily observed. This study points to a new direction of construction of complex 3D crystal architectures and DNA‐based biosensors with easy readouts. 

   more » « less
4. Augmented DNA Nanoarchitectures: A Structural Library of 3D Self‐Assembling Tensegrity Triangle Variants

   https://doi.org/10.1002/adma.202206876  

   Woloszyn, Karol; Vecchioni, Simon; Ohayon, Yoel_P; Lu, Brandon; Ma, Yinglun; Huang, Qiuyan; Zhu, Eric; Chernovolenko, Daniel; Markus, Tiffany; Jonoska, Nataša; et al (October 2022, Advanced Materials)

   Abstract The DNA tensegrity triangle is known to reliably self‐assemble into a 3D rhombohedral crystalline lattice via sticky‐end cohesion. Here, the library of accessible motifs is expanded through covalent extensions of intertriangle regions and sticky‐end‐coordinated linkages of adjacent triangles with double helical segments using both geometrically symmetric and asymmetric configurations. The molecular structures of 18 self‐assembled architectures at resolutions of 3.32–9.32 Å are reported; the observed cell dimensions, cavity sizes, and cross‐sectional areas agree with theoretical expectations. These data demonstrate that fine control over triclinic and rhombohedral crystal parameters and the customizability of more complex 3D DNA lattices are attainable via rational design. It is anticipated that augmented DNA architectures may be fine‐tuned for the self‐assembly of designer nanocages, guest–host complexes, and proscriptive 3D nanomaterials, as originally envisioned. Finally, designer asymmetric crystalline building blocks can be seen as a first step toward controlling and encoding information in three dimensions. 

   more » « less
5. Automated sequence design of 2D wireframe DNA origami with honeycomb edges

   https://doi.org/10.1038/s41467-019-13457-y  

   Jun, Hyungmin; Wang, Xiao; Bricker, William P.; Bathe, Mark (November 2019, Nature Communications)

   Abstract Wireframe DNA origami has emerged as a powerful approach to fabricating nearly arbitrary 2D and 3D geometries at the nanometer-scale. Complex scaffold and staple routing needed to design wireframe DNA origami objects, however, render fully automated, geometry-based sequence design approaches essential for their synthesis. And wireframe DNA origami structural fidelity can be limited by wireframe edges that are composed only of one or two duplexes. Here we introduce a fully automated computational approach that programs 2D wireframe origami assemblies using honeycomb edges composed of six parallel duplexes. These wireframe assemblies show enhanced structural fidelity from electron microscopy-based measurement of programmed angles compared with identical geometries programmed using dual-duplex edges. Molecular dynamics provides additional theoretical support for the enhanced structural fidelity observed. Application of our top-down sequence design procedure to a variety of complex objects demonstrates its broad utility for programmable 2D nanoscale materials. 

   more » « less