PNNL

Abstract

Amelogenin is the predominant protein found during enamel development and has been shown to be essential to proper enamel formation. LRAP is a naturally occurring splice variant that preserves the charged N- and C-termini of full length amelogenin, regions thought to be crucial in interacting with hydroxyapatite. Particularly, the highly charged C-terminal hexapeptide (KREEVD) is thought to be the region most intimately interacting with HAP. We investigated the structure of this charged region, as well as the proximity to the surface and the mobility of two of the residues. We found the structure to be consistent with a random coil or more extended structure, as has been found for more internalized residues in the C-terminus. The backbone K54(13C’), V58(13C’) and V58(15N) were all found to be very close to the surface of HAP, ~ 6.0 Å, suggesting a strong interaction and emphasizing the importance of these residues in interacting with HAP. However, both ends of the hexapeptide, at residues K54 and V58, experience significant mobility under hydrated conditions, implying that another portion of the protein helps to stabilize the strong LRAP-HAP interaction. Interestingly, the backbone of the C-terminal third of the protein is consistently 6.0 Å from the HAP surface, suggesting that this region of the protein is laying flat on the surface with no 3-dimensional folding. The combination of these features, i.e., a random coil structure, a significant mobility and a lack of three-dimensional folding in this region of the protein may be important in a functional role, allowing the C-terminus to effectively interact with HAP while at the same time allowing maximum crystal inhibition. The Pacific Northwest National Laboratory is operated by Battelle for the U.S. Department of Energy.