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PNAS | July 1, 1987 | vol. 84 | no. 13 | 4470-4474
Copyright © 1987 by the National Academy of Sciences

Theoretically Determined Three-Dimensional Structure for the Repeating Tetrapeptide Unit of the Circumsporozoite Coat Protein of the Malaria Parasite Plasmodium falciparum

Bernard R. Brooks, Richard W. Pastor, and Frederick W. Carson

A model for the three-dimensional structure of the repeating Asn-Pro-Asn-Ala tetrapeptide of the immunodominant circumsporozoite protein of Plasmodium falciparum has been developed. A trial structure in the form of a type I ß turn with asparagine side chains hydrogen-bonded to the backbone peptide linkages was used as a starting point. A repeating oligomer of this trial structure was modeled using energy minimization and molecular dynamics computer simulations in conjunction with image boundary conditions. The most stable structure generated is a right-handed 12₃₈ helix, which is unlike any previously identified protein secondary structure. The helix has 12 residues per turn, corresponding to an angle of twist of 120 degrees per tetrapeptide unit, and a pitch of 4.95 angstrom, corresponding to a rise of 1.65 angstrom per tetrapeptide unit. It is highly stabilized by extensive hydrogen bonding, with each tetrapeptide unit acting as an acceptor for five hydrogen bonds and as a donor for five hydrogen bonds to residues in adjacent turns as well as having four weak internal hydrogen bonds. A number of nearly isoenergetic variations on the most stable structure that still retained the basic 12₃₈ helical motif were also discovered. The implications of these structures for vaccine development are discussed.
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