DNA Origami. Группа авторов
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Название: DNA Origami

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Отраслевые издания

Серия:

isbn: 9781119682585

isbn:

СКАЧАТЬ specific components in the assembled structures, while directly seeing their real‐time structural or spatial changes at nanoscale resolution.

      1 1 Hansma, P.K., Elings, V.B., Marti, O. et al. (1988). Scanning tunneling microscopy and atomic force microscopy: application to biology and technology. Science 242: 209–216.

      2 2 Hansma, H.G. (2001). Surface biology of DNA by atomic force microscopy. Annual Review of Physical Chemistry 52: 71–92.

      3 3 Yang, J., Takeyasu, K., and Shao, Z. (1992). Atomic force microscopy of DNA molecules. FEBS Letters 301: 173–176.

      4 4 Lyubchenko, Y.L., Gall, A.A., Shlyakhtenko, L.S. et al. (1992). Atomic force microscopy imaging of double stranded DNA and RNA. Journal of Biomolecular Structure & Dynamics 10: 589–606.

      5 5 Hansma, H.G., Vesenka, J., Siegerist, C. et al. (1992). Reproducible imaging and dissection of plasmid DNA under liquid with the atomic force microscope. Science 256: 1180–1184.

      6 6 Hansma, H.G., Sinsheimer, R.L., Li, M.Q. et al. (1992). Atomic force microscopy of single‐ and double‐stranded DNA. Nucleic Acids Research 20: 3585–3590.

      7 7 Allison, D.P., Bottomley, L.A., Thundat, T. et al. (1992). Immobilization of DNA for scanning probe microscopy. Proceedings of the National Academy of Sciences of the United States of America 89: 10129–10133.

      8 8 Lyubchenko, Y.L., Gall, A.A., and Shlyakhtenko, L.S. (2014). Visualization of DNA and protein‐DNA complexes with atomic force microscopy. Methods in Molecular Biology 1117: 367–384.

      9 9 Lyubchenko, Y.L., Jacobs, B.L., Lindsay, S.M. et al. (1995). Atomic force microscopy of nucleoprotein complexes. Scanning Microscopy, 9, 705–724; discussion 724–707.

      10 10 Lyubchenko, Y.L. and Shlyakhtenko, L.S. (2016). Imaging of DNA and protein‐DNA complexes with atomic force microscopy. Critical Reviews in Eukaryotic Gene Expression 26: 63–96.

      11 11 Winfree, E., Liu, F., Wenzler, L.A. et al. (1998). Design and self‐assembly of two‐dimensional DNA crystals. Nature 394: 539–544.

      12 12 Rothemund, P.W. (2006). Folding DNA to create nanoscale shapes and patterns. Nature 440: 297–302.

      13 13 Wei, B., Dai, M., and Yin, P. (2012). Complex shapes self‐assembled from single‐stranded DNA tiles. Nature 485: 623–626.

      14 14 Ando, T., Kodera, N., Takai, E. et al. (2001). A high‐speed atomic force microscope for studying biological macromolecules. Proceedings of the National Academy of Sciences of the United States of America 98: 12468–12472.

      15 15 Ando, T., Uchihashi, T., and Scheuring, S. (2014). Filming biomolecular processes by high‐speed atomic force microscopy. Chemical Reviews 114: 3120–3188.

      16 16 Rajendran, A., Endo, M., and Sugiyama, H. (2014). State‐of‐the‐art high‐speed atomic force microscopy for investigation of single‐molecular dynamics of proteins. Chemical Reviews 114: 1493–1520.

      17 17 Endo, M. and Sugiyama, H. (2014). Single‐molecule imaging of dynamic motions of biomolecules in DNA origami nanostructures using high‐speed atomic force microscopy. Accounts of Chemical Research 47: 1645–1653.

      18 18 Yurke, B., Turberfield, A.J., Mills, A.P. Jr. et al. (2000). A DNA‐fuelled molecular machine made of DNA. Nature 406: 605–608.

      19 19 Yan, H., Zhang, X., Shen, Z. et al. (2002). A robust DNA mechanical device controlled by hybridization topology. Nature 415: 62–65.

      20 20 Sherman, W.B. and Seeman, N.C. (2004). A precisely controlled DNA biped walking device. Nano Letters 4: 1801–1801.

      21 21 Omabegho, T., Sha, R., and Seeman, N.C. (2009). A bipedal DNA Brownian motor with coordinated legs. Science 324: 67–71.

      22 22 Douglas, S.M., Dietz, H., Liedl, T. et al. (2009). Self‐assembly of DNA into nanoscale three‐dimensional shapes. Nature 459: 414–418.

      23 23 Dietz, H., Douglas, S.M., and Shih, W.M. (2009). Folding DNA into twisted and curved nanoscale shapes. Science 325: 725–730.

      24 24 Nummelin, S., Shen, B., Piskunen, P. et al. (2020). Robotic DNA nanostructures. ACS Synthetic Biology 9: 1923–1940.

      25 25 Andersen, E.S., Dong, M., Nielsen, M.M. et al. (2009). Self‐assembly of a nanoscale DNA box with a controllable lid. Nature 459: 73–76.

      26 26 Takenaka, T., Endo, M., Suzuki, Y. et al. (2014). Photoresponsive DNA nanocapsule having an open/close system for capture and release of nanomaterials. Chemistry 20: 14951–14954.

      27 27 Ijas, H., Hakaste, I., Shen, B. et al. (2019). Reconfigurable DNA origami nanocapsule for pH‐controlled encapsulation and display of cargo. ACS Nano 13: 5959–5967.

      28 28 Douglas, S.M., Bachelet, I., and Church, G.M. (2012). A logic‐gated nanorobot for targeted transport of molecular payloads. Science 335: 831–834.

      29 29 Kuzuya, A., Sakai, Y., Yamazaki, T. et al. (2011). Nanomechanical DNA origami 'single‐molecule beacons' directly imaged by atomic force microscopy. Nature Communications 2: 449.

      30 30 Marras, A.E., Zhou, L., Su, H.J. et al. (2015). Programmable motion of DNA origami mechanisms. Proceedings of the National Academy of Sciences of the United States of America 112: 713–718.

      31 31 Tomaru, T., Suzuki, Y., Kawamata, I. et al. (2017). Stepping operation of a rotary DNA origami device. Chemical Communications (Camb) 53: 7716–7719.

      32 32 Wang, J., Yue, L., Li, Z. et al. (2019). Active generation of nanoholes in DNA origami scaffolds for programmed catalysis in nanocavities. Nature Communications 10: 4963.

      33 33 Kuzuya, A., Watanabe, R., Yamanaka, Y. et al. (2014). Nanomechanical DNA origami pH sensors. Sensors (Basel) 14: 19329–19335.

      34 34 Willner, E.M., Kamada, Y., Suzuki, Y. et al. (2017). Single‐molecule observation of the photoregulated conformational dynamics of DNA origami nanoscissors. Angewandte Chemie International Edition in English 56: 15324–15328.

      35 35 Gerling, T., Wagenbauer, K.F., Neuner, A.M. et al. (2015). Dynamic DNA devices and assemblies formed by shape‐complementary, non‐base pairing 3D components. Science 347: 1446–1452.

      36 36 Suzuki, Y., Kawamata, I., Mizuno, K. et al. (2020). Large deformation of a DNA‐origami nanoarm induced by the cumulative actuation of tension‐adjustable modules. Angewandte Chemie International Edition in English 59: 6230–6234.

      37 37 Zhong, H. and Seeman, N.C. (2006). RNA used to control a DNA rotary nanomachine. Nano Letters 6: 2899–2903.

      38 38 Chakraborty, B., Sha, R., and Seeman, N.C. (2008). A DNA‐based nanomechanical device with three robust states. Proceedings of the National Academy of Sciences of the United States of America 105: 17245–17249.

      39 39 Kuzyk, A., Schreiber, R., Zhang, H. et al. (2014). Reconfigurable 3D plasmonic metamolecules. Nature Materials 13: 862–866.

      40 40 Mao, C., Sun, W., Shen, Z. et al. (1999). A nanomechanical device based on the B‐Z transition of DNA. Nature 397: 144–146.

      41 41 Lu, C.H., Cecconello, A., Elbaz, J. et al. (2013). A three‐station DNA catenane rotary motor with controlled directionality. СКАЧАТЬ