A case of cytophagic histiocytic panniculitis: successful treatment of recurrent attacks with steroid pulse therapy and oral cyclosporin A

Basic fibroblast growth factor (bFGF) is implicated in the pathogenesis of several vascular and connective diseases. A key step in the discovery of bFGF receptor antagonists to mitigate these actions is to define the functional epitope required for receptor binding of the growth factor. In previous studies, we identified Glu96 as an essential residue in this epitope using site-directed mutagenesis. Here we examined the role of solvent accessible neighboring residues of Glu96 of bFGF on receptor binding affinity. Wild-type bFGF and its muteins were cloned and expressed in Escherichia coli and evaluated for FGF receptor binding affinity. Replacement of Asn104 of bFGF by alanine reduced receptor binding affinity over 400-fold compared with wild-type bFGF. We next explored the effect of neighboring residues of Asn104 on receptor binding affinity-Muteins in which Arg97, Leu98, Glu99, Asn101, Asn102, Thr105 and Pro141 were individually replaced by alanine exhibited receptor binding similar to wild-type bFGF. By contrast, substitution of Tyr103 or Leu140 by alanine reduced receptor binding affinity about 400- and 150-fold, respectively, in accord with a previous report. We conclude that at least six solvent-accessible residues in bFGF are crucial for high-affinity receptor binding, as evidenced by at least a 10-fold diminution in the affinity of the corresponding alanine muteins. The polar residues Glu96 and Asn104 appear to form an area important for facilitating the initial contact between ligand and receptor, whereas Tyr24, Tyr103, Leu140 and Met142 form a hydrophobic patch that may stabilize the complex. The detailed structure of this functional epitope can be employed in the discovery and design of bFGF antagonists using computational methods.