An algorithm for determining the conformation of polypeptide segments in proteins by systematic search.

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TitleAn algorithm for determining the conformation of polypeptide segments in proteins by systematic search.
Publication TypeJournal Article
Year of Publication1986
AuthorsMoult, J, James, MN
JournalProteins
Volume1
Issue2
Pagination146-63
Date Published1986 Oct
ISSN0887-3585
KeywordsAlgorithms, Amino Acid Sequence, Models, Molecular, Molecular Sequence Data, Peptides, Protein Conformation, Research Design, Streptomyces griseus, Thermodynamics, Trypsin
Abstract

The feasibility of determining the conformation of segments of a polypeptide chain up to six residues in length in globular proteins by means of a systematic search through the possible conformations has been investigated. Trial conformations are generated by using representative sets of phi, psi, and chi angles that have been derived from an examination of the distributions of these angles in refined protein structures. A set of filters based on simple rules that protein structures obey is used to reduce the number of conformations to a manageable total. The most important filters are the maintenance of chain integrity and the avoidance of too-short van der Waals contacts with the rest of the protein and with other portions of the segment under construction. The procedure is intended to be used with approximate models so that allowance is made throughout for errors in the rest of the structure. All possible main chains are first constructed and then all possible side-chain conformations are built onto each of these. The electrostatic energy, including a solvent screening term, and the exposed hydrophobic area are evaluated for each accepted conformation. The method has been tested on two segments of chain in the trypsin like enzyme from Streptomyces griseus. It is found that there is a wide spread of energies among the accepted conformations, and the lowest energy ones have satisfactorily small root mean square deviations from the X-ray structure.

DOI10.1002/prot.340010207
Alternate JournalProteins
PubMed ID3130622