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Adenine oligomer directed synthesis of chiral gold nanoparticles

Author

Listed:
  • Nam Heon Cho

    (Seoul National University)

  • Young Bi Kim

    (Pohang University of Science and Technology (POSTECH))

  • Yoon Young Lee

    (Seoul National University)

  • Sang Won Im

    (Seoul National University)

  • Ryeong Myeong Kim

    (Seoul National University)

  • Jeong Won Kim

    (Seoul National University)

  • Seok Daniel Namgung

    (Seoul National University)

  • Hye-Eun Lee

    (Seoul National University)

  • Hyeohn Kim

    (Seoul National University)

  • Jeong Hyun Han

    (Seoul National University)

  • Hye Won Chung

    (Seoul National University)

  • Yoon Ho Lee

    (Seoul National University)

  • Jeong Woo Han

    (Pohang University of Science and Technology (POSTECH))

  • Ki Tae Nam

    (Seoul National University)

Abstract

Precise control of morphology and optical response of 3-dimensional chiral nanoparticles remain as a significant challenge. This work demonstrates chiral gold nanoparticle synthesis using single-stranded oligonucleotide as a chiral shape modifier. The homo-oligonucleotide composed of Adenine nucleobase specifically show a distinct chirality development with a dissymmetric factor up to g ~ 0.04 at visible wavelength, whereas other nucleobases show no development of chirality. The synthesized nanoparticle shows a counter-clockwise rotation of generated chiral arms with approximately 200 nm edge length. The molecular dynamics and density functional theory simulations reveal that Adenine shows the highest enantioselective interaction with Au(321)R/S facet in terms of binding orientation and affinity. This is attributed to the formation of sequence-specific intra-strand hydrogen bonding between nucleobases. We also found that different sequence programming of Adenine-and Cytosine-based oligomers result in chiral gold nanoparticles’ morphological and optical change. These results extend our understanding of the biomolecule-directed synthesis of chiral gold nanoparticles to sequence programmable deoxyribonucleic acid and provides a foundation for programmable synthesis of chiral gold nanoparticles.

Suggested Citation

  • Nam Heon Cho & Young Bi Kim & Yoon Young Lee & Sang Won Im & Ryeong Myeong Kim & Jeong Won Kim & Seok Daniel Namgung & Hye-Eun Lee & Hyeohn Kim & Jeong Hyun Han & Hye Won Chung & Yoon Ho Lee & Jeong W, 2022. "Adenine oligomer directed synthesis of chiral gold nanoparticles," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-31513-y
    DOI: 10.1038/s41467-022-31513-y
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    References listed on IDEAS

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    1. Hye-Eun Lee & Ryeong Myeong Kim & Hyo-Yong Ahn & Yoon Young Lee & Gi Hyun Byun & Sang Won Im & Jungho Mun & Junsuk Rho & Ki Tae Nam, 2020. "Cysteine-encoded chirality evolution in plasmonic rhombic dodecahedral gold nanoparticles," Nature Communications, Nature, vol. 11(1), pages 1-10, December.
    2. Hye-Eun Lee & Hyo-Yong Ahn & Jungho Mun & Yoon Young Lee & Minkyung Kim & Nam Heon Cho & Kiseok Chang & Wook Sung Kim & Junsuk Rho & Ki Tae Nam, 2018. "Amino-acid- and peptide-directed synthesis of chiral plasmonic gold nanoparticles," Nature, Nature, vol. 556(7701), pages 360-365, April.
    3. Assaf Ben-Moshe & Sharon Grayer Wolf & Maya Bar Sadan & Lothar Houben & Zhiyuan Fan & Alexander O. Govorov & Gil Markovich, 2014. "Enantioselective control of lattice and shape chirality in inorganic nanostructures using chiral biomolecules," Nature Communications, Nature, vol. 5(1), pages 1-9, September.
    4. Chao Zhou & Xiaoyang Duan & Na Liu, 2015. "A plasmonic nanorod that walks on DNA origami," Nature Communications, Nature, vol. 6(1), pages 1-6, November.
    5. Anton Kuzyk & Robert Schreiber & Zhiyuan Fan & Günther Pardatscher & Eva-Maria Roller & Alexander Högele & Friedrich C. Simmel & Alexander O. Govorov & Tim Liedl, 2012. "DNA-based self-assembly of chiral plasmonic nanostructures with tailored optical response," Nature, Nature, vol. 483(7389), pages 311-314, March.
    6. Hyeon-Ho Jeong & Andrew G. Mark & Mariana Alarcón-Correa & Insook Kim & Peter Oswald & Tung-Chun Lee & Peer Fischer, 2016. "Dispersion and shape engineered plasmonic nanosensors," Nature Communications, Nature, vol. 7(1), pages 1-7, September.
    7. Robert Schreiber & Ngoc Luong & Zhiyuan Fan & Anton Kuzyk & Philipp C. Nickels & Tao Zhang & David M. Smith & Bernard Yurke & Wan Kuang & Alexander O. Govorov & Tim Liedl, 2013. "Chiral plasmonic DNA nanostructures with switchable circular dichroism," Nature Communications, Nature, vol. 4(1), pages 1-6, December.
    8. Sung Yong Park & Abigail K. R. Lytton-Jean & Byeongdu Lee & Steven Weigand & George C. Schatz & Chad A. Mirkin, 2008. "DNA-programmable nanoparticle crystallization," Nature, Nature, vol. 451(7178), pages 553-556, January.
    9. Md. Abu Bakar & Mizuho Sugiuchi & Mitsuhiro Iwasaki & Yukatsu Shichibu & Katsuaki Konishi, 2017. "Hydrogen bonds to Au atoms in coordinated gold clusters," Nature Communications, Nature, vol. 8(1), pages 1-7, December.
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