| Literature DB >> 29911864 |
Xing Wang1, Arun Richard Chandrasekaran2, Zhiyong Shen3, Yoel P Ohayon4, Tong Wang4, Megan E Kizer1, Ruojie Sha4, Chengde Mao5, Hao Yan6, Xiaoping Zhang4, Shiping Liao4, Baoquan Ding4, Banani Chakraborty4, Natasha Jonoska7, Dong Niu4, Hongzhou Gu4, Jie Chao4, Xiang Gao4, Yuhang Li4, Tanashaya Ciengshin4, Nadrian C Seeman4.
Abstract
Over the past 35 years, DNA has been used to produce various nanometer-scale constructs, nanomechanical devices, and walkers. Construction of complex DNA nanostructures relies on the creation of rigid DNA motifs. Paranemic crossover (PX) DNA is one such motif that has played many roles in DNA nanotechnology. Specifically, PX cohesion has been used to connect topologically closed molecules, to assemble a three-dimensional object, and to create two-dimensional DNA crystals. Additionally, a sequence-dependent nanodevice based on conformational change between PX and its topoisomer, JX2, has been used in robust nanoscale assembly lines, as a key component in a DNA transducer, and to dictate polymer assembly. Furthermore, the PX motif has recently found a new role directly in basic biology, by possibly serving as the molecular structure for double-stranded DNA homology recognition, a prominent feature of molecular biology and essential for many crucial biological processes. This review discusses the many attributes and usages of PX-DNA-its design, characteristics, applications, and potential biological relevance-and aims to accelerate the understanding of PX-DNA motif in its many roles and manifestations.Entities:
Year: 2018 PMID: 29911864 DOI: 10.1021/acs.chemrev.8b00207
Source DB: PubMed Journal: Chem Rev ISSN: 0009-2665 Impact factor: 60.622