Using α-Helical Coiled-Coils to Design Nanostructured Metalloporphyrin Arrays

Karen A. McAllister; Hongling Zou; Frank V. Cochran; Gretchen M. Bender; Alessandro Senes; H. Christopher Fry; Vikas Nanda; Patricia A. Keenan; James D. Lear; Jeffery G. Saven; Michael J. Therien; J. Kent Blasie; William F. DeGrado

doi:10.1021/ja800697g

Using α-Helical Coiled-Coils to Design Nanostructured Metalloporphyrin Arrays

Karen A. McAllister(Johnson Foundation), Hongling Zou(Johnson Foundation), Frank V. Cochran(University of Pennsylvania), Gretchen M. Bender(University of Pennsylvania), Alessandro Senes(University of Pennsylvania), H. Christopher Fry(University of Pennsylvania), Vikas Nanda(University of Pennsylvania), Patricia A. Keenan(University of Pennsylvania), James D. Lear(University of Pennsylvania), Jeffery G. Saven(University of Pennsylvania), Michael J. Therien(Johnson Foundation), J. Kent Blasie(Johnson Foundation), William F. DeGrado(Johnson Foundation)

Journal of the American Chemical Society

August 19, 2008

10.1021/ja800697g

Cited by 63

Abstract

We have developed a computational design strategy based on the alpha-helical coiled-coil to generate modular peptide motifs capable of assembling into metalloporphyrin arrays of varying lengths. The current study highlights the extension of a two-metalloporphyrin array to a four-metalloporphyrin array through the incorporation of a coiled-coil repeat unit. Molecular dynamics simulations demonstrate that the initial design evolves rapidly to a stable structure with a small rmsd compared to the original model. Biophysical characterization reveals elongated proteins of the desired length, correct cofactor stoichiometry, and cofactor specificity. The successful extension of the two-porphyrin array demonstrates how this methodology serves as a foundation to create linear assemblies of organized electrically and optically responsive cofactors.

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