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Structural effects of fluorine substitution in proteins

โœ Scribed by D. H. Gregory; J. T. Gerig

Publisher
John Wiley and Sons
Year
1991
Tongue
English
Weight
531 KB
Volume
12
Category
Article
ISSN
0192-8651

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โœฆ Synopsis

Abstract

The consequences of substitution of fluorine for the para hydrogen of a phenylalanine residue in ribonucleaseโ€S were investigated by conformational energy calculations using the AMBER force field. Both the fluorineโ€containing protein and the corresponding nonfluorinated material were subjected to conformational adjustment through energy minimization and the minimum energy structures so defined were compared. Fluorine substitution leads to small alterations in many atomic positions in the protein, with adjustments at at sites more than 0.5 nm from the fluorine appearing to be somewhat larger than those within the immediate vicinity of the fluorine. Several atoms proximate to the fluorine atom were observed to move toward the fluorine while others in the same vicinity move away. The greater bulk of the fluorine atom and the strongly different electronic properties of fluorine compared to hydrogen thus appear to be insufficient to cause a consistent, unidirectional change in nearestโ€neighbor interactions upon introduction of a fluorine atom into a protein structure. Virtually all changes in atomic positions that are predicted by these calculations would be barely detectable by a crystallographic study with a resolution of 0.2 nm.

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