TY - JOUR
T1 - Nanoscale packing of DNA tiles into DNA macromolecular lattices
AU - Baig, Mirza Muhammad Faran Ashraf
AU - Gao, Xiuli
AU - Khan, Muhammad Ajmal
AU - Farid, Awais
AU - Zia, Abdul Wasy
AU - Wu, Hongkai
N1 - Funding information:
The work was supported by Hong Kong Research Grant Council (RGC), General Research Fund (GRF) projects (GRF#16308818, GRF#16309920, and GRF#16309421), Hong Kong Innovation and Technology Commission (HKITC) funding project (MHP/003/19) and the Social Development Project of Department of Science and Technology of Guizhou Province ([No. 2020]4Y214).
PY - 2022/11/1
Y1 - 2022/11/1
N2 - Nanoscale double-crossovers (DX), antiparallel (A), and even half-turns-perimeter (E) DNA tiles (DAE-tiles) with rectangular shapes can be packed into large arrays of micrometer-scale lattices. But the features and mechanical strength of DNA assembly made from differently shaped large-sized DAE DNA tiles and the effects of various geometries on the final DNA assembly are yet to be explored. Herein, we focused on examining DNA lattices synthesized from DX bi-triangular, DNA tiles (T) with concave and convex regions along the perimeter of the tiles. The bi-triangular DNA tiles "T(A) and T(B)" were synthesized by self-assembling the freshly prepared short circular scaffold (S) strands "S(A) and S(B)", each of 106 nucleotides (NT) lengths. The tiles "T(A) and T(B)" were then coupled together to get assembled via sticky ends. It resulted in the polymerization of DNA tiles into large-sized DNA lattices with giant micrometer-scale dimensions to form the "T(A) + T(B)" assembly. These DNA macro-frameworks were visualized "in the air" under atomic force microscopy (AFM) employing tapping mode. We have characterized how curvature in DNA tiles may undergo transitions and transformations to adjust the overall torque, strain, twists, and the topology of the final self-assembly array of DNA tiles. According to our results, our large-span DX tiles assembly "T(A) + T(B)" despite the complicated curvatures and mechanics, was successfully packed into giant DNA lattices of the width of 30-500 nm and lengths of 500 nm to over 10 μm. Conclusively, the micrometer-scale "T(A) + T(B)" framework assembly was rigid, stable, stiff, and exhibited enough tensile strength to form monocrystalline lattices. [Abstract copyright: Copyright © 2022 Elsevier B.V. All rights reserved.]
AB - Nanoscale double-crossovers (DX), antiparallel (A), and even half-turns-perimeter (E) DNA tiles (DAE-tiles) with rectangular shapes can be packed into large arrays of micrometer-scale lattices. But the features and mechanical strength of DNA assembly made from differently shaped large-sized DAE DNA tiles and the effects of various geometries on the final DNA assembly are yet to be explored. Herein, we focused on examining DNA lattices synthesized from DX bi-triangular, DNA tiles (T) with concave and convex regions along the perimeter of the tiles. The bi-triangular DNA tiles "T(A) and T(B)" were synthesized by self-assembling the freshly prepared short circular scaffold (S) strands "S(A) and S(B)", each of 106 nucleotides (NT) lengths. The tiles "T(A) and T(B)" were then coupled together to get assembled via sticky ends. It resulted in the polymerization of DNA tiles into large-sized DNA lattices with giant micrometer-scale dimensions to form the "T(A) + T(B)" assembly. These DNA macro-frameworks were visualized "in the air" under atomic force microscopy (AFM) employing tapping mode. We have characterized how curvature in DNA tiles may undergo transitions and transformations to adjust the overall torque, strain, twists, and the topology of the final self-assembly array of DNA tiles. According to our results, our large-span DX tiles assembly "T(A) + T(B)" despite the complicated curvatures and mechanics, was successfully packed into giant DNA lattices of the width of 30-500 nm and lengths of 500 nm to over 10 μm. Conclusively, the micrometer-scale "T(A) + T(B)" framework assembly was rigid, stable, stiff, and exhibited enough tensile strength to form monocrystalline lattices. [Abstract copyright: Copyright © 2022 Elsevier B.V. All rights reserved.]
KW - Concave and convex surfaces
KW - Double-crossover bi-triangular DNA tiles
KW - Micrometer-scale monocrystalline lattices
KW - Nanoscale packing
KW - Variable geometries and shapes
UR - http://www.scopus.com/inward/record.url?scp=85136293683&partnerID=8YFLogxK
U2 - 10.1016/j.ijbiomac.2022.08.107
DO - 10.1016/j.ijbiomac.2022.08.107
M3 - Article
C2 - 35988727
SN - 0141-8130
VL - 220
SP - 520
EP - 527
JO - International Journal of Biological Macromolecules
JF - International Journal of Biological Macromolecules
ER -