Paranemic Crossover DNA: There and Back Again

Wang, Xing; Chandrasekaran, Arun Richard; Shen, Zhiyong; Ohayon, Yoel P.; Wang, Tong; Kizer, Megan E.; Sha, Ruojie; Mao, Chengde; Yan, Hao; Zhang, Xiaoping; Liao, Shiping; Ding, Baoquan; Chakraborty, Biswanath; Jonoska, Nataša; Niu, Dong; Gu, Hongzhou; Chao, Jie; Gao, Xiang; Li, Yuhang; Ciengshin, Tanashaya; Seeman, Nadrian C.

doi:10.1021/acs.chemrev.8b00207

Cited by 76 publications

(56 citation statements)

References 118 publications

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“…To solve the structural instability and flexibility issues found in earlier DNA nanostructure assembly methods, Seeman and Fu constructed double crossover (DX) motifs as building blocks, in which a second strand exchange was introduced to make crossovers between two adjacent DNA helices, known as double Holliday junction structures, that constituted the foundation of structural DNA nanotechnology . In subsequent decades, many motifs have been developed for DNA nanotechnology, including triple crossover, paranemic crossover (PX), four‐stranded i‐motif, G‐quadruplexes, and other specific motifs . Furthermore, in addition to static hierarchical structures, dynamic nanomachines have also been achieved based on strand‐displacement reactions or configuration adjustment…”

Section: A Brief Review On the History Of Structural Dna Nanotechnolomentioning

confidence: 99%

DNA Origami as Scaffolds for Self‐Assembly of Lipids and Proteins

Dong

Mao

2019

ChemBioChem

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Since first being reported in 2006, the DNA origami approach has attracted increasing attention due to programmable shapes, structural stability, biocompatibility, and fantastic addressability. Herein, we provide an account of recent developments of DNA origami as scaffolds for templating the selfassembly of distinct biocomponents, essentially proteins and lipids, into a diverse spectrum of integrated supramolecular architectures. First, the historical development of the DNA origami concept is briefly reviewed. Next, various applications of DNA origami constructs in controllable directed assembly of soluble proteins are discussed. The manipulation and self‐assembly of lipid membranes and membrane proteins by using DNA origami as scaffolds are also addressed. Furthermore, recent progress in applying DNA origami in cryoelectron microscopy analysis is discussed. These advances collectively emphasize that the DNA origami approach is a highly versatile, fast evolving tool that may be integrated with lipids and proteins in a way that meets future challenges in molecular biology and nanomedicine.

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Section: A Brief Review On the History Of Structural Dna Nanotechnolomentioning

confidence: 99%

DNA Origami as Scaffolds for Self‐Assembly of Lipids and Proteins

Dong

Mao

2019

ChemBioChem

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“…In our recent research, we studied the biostability of a DNA motif called paranemic crossover (PX) DNA and explored the crossover-dependent biostability of DNA motifs by comparing PX DNA with similar motifs that contained lesser number of crossovers (Chandrasekaran et al, 2020). PX DNA is a four-stranded DNA structure that consists of two adjacent and connected double helical DNA domains (Shen et al, 2004;Wang et al, 2019) (Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

“…Each duplex domain of PX DNA contains alternating major (wide) groove (denoted by W) or a minor (narrow) groove separation (denoted by N) flanking the central dyad axis of the structure, with one helical repeat containing a mixture of four half turns. In our study, we used a PX DNA motif with major/minor groove separations (W:N) of 6 and 5 nucleotides, respectively (Shen et al, 2004;Wang et al, 2019). Using gel-based analysis, we reported degradation times, kinetics of nuclease digestion, enzyme-specific concentration gradients on DNA motifs, and evaluation of biostability enhancement factors (Chandrasekaran et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Nuclease Degradation Analysis of DNA Nanostructures Using Gel Electrophoresis

Chandrasekaran

Halvorsen

2020

CP Nucleic Acid Chemistry

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Custom-built DNA nanostructures are now used in applications such as biosensing, molecular computation, biomolecular analysis, and drug delivery. While the functionality and biocompatibility of DNA makes DNA nanostructures useful in such applications, the field faces a challenge in making biostable DNA nanostructures. Being a natural material, DNA is most suited for biological applications, but is also easily degraded by nucleases. Several methods have been employed to study the nuclease degradation rates and enhancement of nuclease resistance. This protocol describes the use of gel electrophoresis to analyze the extent of nuclease degradation of DNA nanostructures and to report degradation times, kinetics of nuclease digestion, and evaluation of biostability enhancement factors.

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“…4 Another less common DNA motif is paranemic crossover (PX) DNA, a four-stranded DNA structure that consists of two adjacent and connected double helical DNA domains (Figure 1a). 9,10 The motif is formed by creating crossovers between strands of the same polarity at every possible point between two side-by-side helices. 10 Each duplex domain of PX DNA contains alternating major (wide) groove (denoted by W) or a minor (narrow) groove separation (denoted by N) flanking the central dyad axis of the structure, with one helical repeat containing a mixture of four half turns.…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies have reported PX DNA with different major/minor groove separations (W:N), with the most stable complexes containing 6, 7 or 8 nucleotides in the major groove and 5 nucleotides in the minor groove (PX 6:5, 7:5 and 8:5 respectively). 9,10 In DNA nanotechnology, PX DNA has been used to construct objects such as an octahedron 11 and a triangle, 12 as well as one-and two-dimensional arrays. 13,14 PX DNA has also been a component of nanomechanical devices 15 that are used in molecular assembly lines 16 and DNA-based computation.…”

Section: Introductionmentioning

confidence: 99%

Exceptional biostability of paranemic crossover (PX) DNA, crossover-dependent nuclease resistance, and implications for DNA nanotechnology

Chandrasekaran

Vilcapoma

Dey

et al. 2019

Preprint

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Inherent nanometer-sized features and molecular recognition properties make DNA a useful material in constructing nanoscale objects, with alluring applications in biosensing and drug delivery. However, DNA can be easily degraded by nucleases present in biological fluids, posing a considerable roadblock to realizing the full potential of DNA nanotechnology for biomedical applications. Here we investigated the nuclease resistance and biostability of the multi-stranded motif called paranemic crossover (PX) DNA and discovered a remarkable and previously unreported resistance to nucleases. We show that PX DNA has more than an order of magnitude increased resistance to degradation by DNase I, serum, and urine compared to double stranded DNA. We further demonstrate that the degradation resistance decreases monotonically as DNA crossovers are removed from the structure, suggesting that frequent DNA crossovers disrupt either the binding or catalysis of nucleases or both. These results have important implications for building DNA nanostructures with enhanced biostability, either by adopting PX-based architectures or by carefully engineering crossovers. We contend that such crossover-dependent nuclease resistance could potentially be used to add "tunable biostability" to the many features of DNA nanotechnology.

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Paranemic Crossover DNA: There and Back Again

Cited by 76 publications

References 118 publications

DNA Origami as Scaffolds for Self‐Assembly of Lipids and Proteins

DNA Origami as Scaffolds for Self‐Assembly of Lipids and Proteins

Nuclease Degradation Analysis of DNA Nanostructures Using Gel Electrophoresis

Exceptional biostability of paranemic crossover (PX) DNA, crossover-dependent nuclease resistance, and implications for DNA nanotechnology

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