DNA origami

被引:0
|
作者
Swarup Dey
Chunhai Fan
Kurt V. Gothelf
Jiang Li
Chenxiang Lin
Longfei Liu
Na Liu
Minke A. D. Nijenhuis
Barbara Saccà
Friedrich C. Simmel
Hao Yan
Pengfei Zhan
机构
[1] Arizona State University,Center for Molecular Design and Biomimetics, The Biodesign Institute, School of Molecular Sciences
[2] Shanghai Jiao Tong University,School of Chemistry and Chemical Engineering, Frontiers Science Center for Transformative Molecules, National Center for Translational Medicine
[3] Shanghai Jiao Tong University,Institute of Molecular Medicine, Shanghai Key Laboratory for Nucleic Acids Chemistry and Nanomedicine, Renji Hospital, School of Medicine
[4] Aarhus University,Interdisciplinary Nanoscience Center (iNANO)
[5] Aarhus University,Department of Chemistry
[6] Chinese Academy of Sciences,Bioimaging Center, Shanghai Synchrotron Radiation Facility, Zhangjiang Laboratory, Shanghai Advanced Research Institute
[7] Yale University School of Medicine,Department of Cell Biology
[8] Yale University,Nanobiology Institute
[9] University of Stuttgart,2nd Physics Institute
[10] Max Planck Institute for Solid State Research,Centre for Medical Biotechnology (ZMB)
[11] University of Duisburg–Essen,Physics Department
[12] Technische Universität München,undefined
来源
Nature Reviews Methods Primers | / 1卷
关键词
D O I
暂无
中图分类号
学科分类号
摘要
Biological materials are self-assembled with near-atomic precision in living cells, whereas synthetic 3D structures generally lack such precision and controllability. Recently, DNA nanotechnology, especially DNA origami technology, has been useful in the bottom-up fabrication of well-defined nanostructures ranging from tens of nanometres to sub-micrometres. In this Primer, we summarize the methodologies of DNA origami technology, including origami design, synthesis, functionalization and characterization. We highlight applications of origami structures in nanofabrication, nanophotonics and nanoelectronics, catalysis, computation, molecular machines, bioimaging, drug delivery and biophysics. We identify challenges for the field, including size limits, stability issues and the scale of production, and discuss their possible solutions. We further provide an outlook on next-generation DNA origami techniques that will allow in vivo synthesis and multiscale manufacturing.
引用
收藏
相关论文
共 50 条
  • [1] DNA origami
    Halford, B
    CHEMICAL & ENGINEERING NEWS, 2006, 84 (12) : 10 - 10
  • [2] DNA origami
    Dey, Swarup
    Fan, Chunhai
    Gothelf, Kurt, V
    Li, Jiang
    Lin, Chenxiang
    Liu, Longfei
    Liu, Na
    Nijenhuis, Minke A. D.
    Sacca, Barbara
    Simmel, Friedrich C.
    Yan, Hao
    Zhan, Pengfei
    NATURE REVIEWS METHODS PRIMERS, 2021, 1 (01):
  • [3] DNA origami
    Nature Reviews Methods Primers, 1 (1):
  • [4] DNA origami
    Gross, Michael
    CHEMISTRY & INDUSTRY, 2012, 76 (08) : 51 - 51
  • [5] DNA Origami Nanopores
    Bell, Nicholas
    Hernandez-Ainsa, Silvia
    Engst, Christian
    Liedl, Tim
    Keyser, Ulrich
    BIOPHYSICAL JOURNAL, 2013, 104 (02) : 517A - 517A
  • [6] DNA Origami Tessellations
    Tang, Yue
    Liu, Hao
    Wang, Qi
    Qi, Xiaodong
    Yu, Lu
    Sulc, Petr
    Zhang, Fei
    Yan, Hao
    Jiang, Shuoxing
    JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, 2023, 145 (25) : 13858 - 13868
  • [7] An origami chip of DNA
    Kaganman, Irene
    NATURE METHODS, 2008, 5 (03) : 222 - 222
  • [8] Origami from DNA
    Choi, CQ
    SCIENTIFIC AMERICAN, 2006, 294 (05) : 28 - 28
  • [9] Design of DNA origami
    Rothemund, PWK
    ICCAD-2005: INTERNATIONAL CONFERENCE ON COMPUTER AIDED DESIGN, DIGEST OF TECHNICAL PAPERS, 2005, : 471 - 478
  • [10] DNA Origami Nanomachines
    Endo, Masayuki
    Sugiyama, Hiroshi
    MOLECULES, 2018, 23 (07):
12345