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Changing the charge distribution of beta-helical-based nanostructures can provide the conditions for charge transfer

  1. Author:
    Haspel, N.
    Zanuy, D.
    Zheng, J.
    Aleman, C.
    Wolfson, H.
    Nussinov, R.

  2. Author Address

    Tel Aviv Univ, Fac Exact Sci, Sch Comp Sci, IL-69978 Tel Aviv, Israel. Univ Barcelona, Dept Chem Engn, Escola Tech Super Engn Ind, Politecn Catalunya, E-08028 Barcelona, Spain. NCI, Natl Canc Inst, Ctr Canc Res Nanobiol Program, Basic Res Program Sci Applicat Int Corp Frederick, Frederick, MD 21701 USA. Tel Aviv Univ, Sackler Fac Med, Sackler Inst Mol Med, Dept Human Genet, IL-69978 Tel Aviv, Israel.;Zanuy, D, Tel Aviv Univ, Fac Exact Sci, Sch Comp Sci, IL-69978 Tel Aviv, Israel.;david.zanuy@upc.edu ruthn@ncifcrf.gov
    1. Year: 2007
    2. Date: Jul
  2. Journal: Biophysical Journal
    1. 93
    2. 1
    3. Pages: 245-253
  4. Type of Article: Article
  5. ISSN: 0006-3495
  1. Abstract:

    In this work we present a computational approach to the design of nanostructures made of structural motifs taken from left-handed beta-helical proteins. Previously, we suggested a structural model based on the self-assembly of motifs taken from Escherichia coli galactoside acetyltransferase (Protein Data Bank 1krr, chain A, residues 131-165, denoted krr1), which produced a very stable nanotube in molecular dynamics simulations. Here we modify this model by changing the charge distribution in the inner core of the system and testing the effect of this change on the structural arrangement of the construct. Our results demonstrate that it is possible to generate the proper conditions for charge transfer inside nanotubes based on assemblies of krr1 segment. The electronic transfer would be achieved by introducing different histidine ionization states in selected positions of the internal core of the construct, in addition to specific mutations with charged amino acids that altogether will allow the formation of coherent networks of aromatic ring stacking, salt-bridges, and hydrogen bonds.

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External Sources

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  2. DOI: 10.1529/biophysj.106.100644
  3. View record in Web of ScienceĀ®
  4. WOS: 000247061500028

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