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Constructing protein polyhedra via orthogonal chemical interactions

Author

Listed:
  • Eyal Golub

    (University of California, San Diego)

  • Rohit H. Subramanian

    (University of California, San Diego)

  • Julian Esselborn

    (University of California, San Diego)

  • Robert G. Alberstein

    (University of California, San Diego)

  • Jake B. Bailey

    (University of California, San Diego)

  • Jerika A. Chiong

    (University of California, San Diego)

  • Xiaodong Yan

    (University of California, San Diego)

  • Timothy Booth

    (University of California, San Diego)

  • Timothy S. Baker

    (University of California, San Diego)

  • F. Akif Tezcan

    (University of California, San Diego
    University of California, San Diego)

Abstract

Many proteins exist naturally as symmetrical homooligomers or homopolymers1. The emergent structural and functional properties of such protein assemblies have inspired extensive efforts in biomolecular design2–5. As synthesized by ribosomes, proteins are inherently asymmetric. Thus, they must acquire multiple surface patches that selectively associate to generate the different symmetry elements needed to form higher-order architectures1,6—a daunting task for protein design. Here we address this problem using an inorganic chemical approach, whereby multiple modes of protein–protein interactions and symmetry are simultaneously achieved by selective, ‘one-pot’ coordination of soft and hard metal ions. We show that a monomeric protein (protomer) appropriately modified with biologically inspired hydroxamate groups and zinc-binding motifs assembles through concurrent Fe3+ and Zn2+ coordination into discrete dodecameric and hexameric cages. Our cages closely resemble natural polyhedral protein architectures7,8 and are, to our knowledge, unique among designed systems9–13 in that they possess tightly packed shells devoid of large apertures. At the same time, they can assemble and disassemble in response to diverse stimuli, owing to their heterobimetallic construction on minimal interprotein-bonding footprints. With stoichiometries ranging from [2 Fe:9 Zn:6 protomers] to [8 Fe:21 Zn:12 protomers], these protein cages represent some of the compositionally most complex protein assemblies—or inorganic coordination complexes—obtained by design.

Suggested Citation

  • Eyal Golub & Rohit H. Subramanian & Julian Esselborn & Robert G. Alberstein & Jake B. Bailey & Jerika A. Chiong & Xiaodong Yan & Timothy Booth & Timothy S. Baker & F. Akif Tezcan, 2020. "Constructing protein polyhedra via orthogonal chemical interactions," Nature, Nature, vol. 578(7793), pages 172-176, February.
  • Handle: RePEc:nat:nature:v:578:y:2020:i:7793:d:10.1038_s41586-019-1928-2
    DOI: 10.1038/s41586-019-1928-2
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    Cited by:

    1. Pei-Ming Cheng & Tao Jia & Chong-Yang Li & Ming-Qiang Qi & Ming-Hao Du & Hai-Feng Su & Qing-Fu Sun & La-Sheng Long & Lan-Sun Zheng & Xiang-Jian Kong, 2024. "Bottom-up construction of chiral metal-peptide assemblies from metal cluster motifs," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    2. Sanahan Vijayakumar & Robert G. Alberstein & Zhiyin Zhang & Yi-Sheng Lu & Adriano Chan & Charlotte E. Wahl & James S. Ha & Deborah E. Hunka & Gerry R. Boss & Michael J. Sailor & F. Akif Tezcan, 2024. "Designed 2D protein crystals as dynamic molecular gatekeepers for a solid-state device," Nature Communications, Nature, vol. 15(1), pages 1-13, December.
    3. Mao Hori & Angela Steinauer & Stephan Tetter & Jamiro Hälg & Eva-Maria Manz & Donald Hilvert, 2024. "Stimulus-responsive assembly of nonviral nucleocapsids," Nature Communications, Nature, vol. 15(1), pages 1-10, December.

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