A Model of the Platelet Factor 4 Complex with Heparin

Overview

Journal Proteins

Date 1992 Oct 1

PMID 1409574

Citations 21

Authors

J A Stuckey

R St Charles

B F EDWARDS

Affiliations

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Abstract

A model of heparin bound to bovine platelet factor 4 (BPF4) was completed using a graphically designed heparin molecule and the crystallographic coordinates of the native bovine platelet factor 4 tetramer. The oligosaccharides had a chain length of at least eight disaccharide units with the major repeating disaccharide unit consisting of (1----4)-O-(alpha-L-idopyranosyluronic acid 2-sulfate)-(1----4)-(2-deoxy-2-sulfamino-2-D-glucopyranosyl 6-sulfate). Each disaccharide unit carried a -4.0 charge. The structure of BPF4 was solved to 2.6 A resolution with R = 0.237. Each monomer of BPF4 contains an alpha-helix lying across 3 strands of antiparallel beta-sheet. Each helix has four lysines, which have been implicated in heparin binding. These lysine residues are predominantly on one side of the helix and are solvent accessible. Electrostatic calculations performed on the BPF4 tetramer show a ring of strong, positive charge which runs perpendicularly across the helices. Included in this ring of density is His-38, which has been shown by NMR to have a large pKa shift when heparin binds to BPF4. Our model of heparin bound to PF4 has the anionic polysaccharide perpendicular to the alpha-helices, wrapped about the tetramer along the ring of positive charge, and salt linked to all four lysines on the helix of each monomer.

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