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Self-assembly of amphiphilic dendritic dipeptides into helical pores

Nature volume 430pages 764–768 (2004)Cite this article

Abstract

Natural pore-forming proteins act as viral helical coats1 and transmembrane channels2,3,4, exhibit antibacterial activity5 and are used in synthetic systems, such as for reversible encapsulation6 or stochastic sensing7. These diverse functions are intimately linked to protein structure1,2,3,4. The close link between protein structure and protein function makes the design of synthetic mimics a formidable challenge, given that structure formation needs to be carefully controlled on all hierarchy levels, in solution and in the bulk. In fact, with few exceptions8,9, synthetic pore structures capable of assembling into periodically ordered assemblies that are stable in solution and in the solid state10,11,12,13 have not yet been realized. In the case of dendrimers, covalent14 and non-covalent15 coating and assembly of a range of different structures15,16,17 has only yielded closed columns18. Here we describe a library of amphiphilic dendritic dipeptides that self-assemble in solution and in bulk through a complex recognition process into helical pores. We find that the molecular recognition and self-assembly process is sufficiently robust to tolerate a range of modifications to the amphiphile structure, while preliminary proton transport measurements establish that the pores are functional. We expect that this class of self-assembling dendrimers will allow the design of a variety of biologically inspired systems with functional properties arising from their porous structure.

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Figure 1: Structure, conformation and hydrogen-bonding of (4-3,4-3,5)12G2-CH2-Boc-l-Tyr-l-Ala-OMe and (4-3,4-3,5)12G2-CH2-Boc-l-Tyr-d-Ala-OMe during self-assembly.
Figure 2: Spectroscopic analysis of dendritic dipeptide self-assembly in solvophobic solution.
Figure 3: Structural analysis of dedritic dipeptide pore in bulk.
Figure 4: Molecular models of the helical porous columns self-assembled from (4-3,4-3,5)12G2-CH2-Boc-l-Tyr-l-Ala-OMe (for simplicity n = 12 was replaced with n = 1).
Figure 5: Proton transport through (4-3,4-3,5)12G2-CH2-(Boc-l-Tyr-l-Ala-OMe) pores reconstituted in phospholipid liposomes (pH-jump experiments).

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Acknowledgements

Financial support by the National Science Foundation, the Office of Naval Research and the P. Roy Vagelos Chair at the University of Pennsylvania is acknowledged. J.S. thanks the Isabel and Alfred Bader Foundation for a graduate fellowship, and U.E. acknowledges a Hans Werthén scholarship for postdoctoral studies. We also thank S.Z.D. Cheng for density measurements, and G. Ungar for reading the draft manuscript and for suggestions.

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Authors and Affiliations

  1. Roy & Diana Vagelos Laboratories, Department of Chemistry, University of Pennsylvania, Philadelphia, Pennsylvania, 19104-6323, USA

    Virgil Percec, Andrés E. Dulcey, Venkatachalapathy S. K. Balagurusamy, Yoshiko Miura, Jan Smidrkal, Mihai Peterca, Sami Nummelin & Ulrica Edlund

  2. Department of Physics and Astronomy, University of Pennsylvania, Philadelphia, Pennsylvania, 19104-6396, USA

    Venkatachalapathy S. K. Balagurusamy, Mihai Peterca & Paul A. Heiney

  3. National Institute of Standards and Technology, Gaithersburg, Maryland, 20899-8544, USA

    Steven D. Hudson & Hu Duan

  4. Digital Instruments, Veeco Metrology Group, Santa Barbara, California, 93110, USA

    Sergei N. Magonov

  5. Department of Biochemistry and Biophysics, University of Pennsylvania, Philadelphia, Pennsylvania, 19104-6059, USA

    Sergei A. Vinogradov

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  1. Virgil Percec
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Correspondence to Virgil Percec.

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Percec, V., Dulcey, A., Balagurusamy, V. et al. Self-assembly of amphiphilic dendritic dipeptides into helical pores. Nature 430, 764–768 (2004). https://doi.org/10.1038/nature02770

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