Structural, in silico, and functional analysis of a Disabled-2-derived peptide for recognition of sulfatides

Disabled-2 (Dab2) is an adaptor protein that regulates numerous cellular processes. Among them, Dab2 modulates the extent of platelet aggregation by two mechanisms. In the first mechanism, Dab2 intracellularly downregulates the integrin IIb3 receptor, converting it to a low affinity state for adhesion and aggregation processes. In the second mechanism, Dab2 is released extracellularly and interacts with both the integrinIIb3 receptor and sulfatides, both of which are known to be pro-aggregatory mediators, blocking their association to fibrinogen and P-selectin, respectively. Our previous research indicated that a 35-amino acid region within Dab2, which we refer to as the sulfatide-binding peptide (SBP), contains two potential sulfatide-binding motifs represented by two consecutive polybasic regions. Using a combined methodology including molecular docking, nuclear magnetic resonance, lipid-binding assays, and surface plasmon resonance, this work identifies the critical Dab2 residues within SBP that are responsible for sulfatide binding. A hydrophilic region, primarily mediated by R42, is responsible for the interaction with the sulfatide headgroup, whereas the C-terminal polybasic region contributes to interactions with the acyl chains. Furthermore, we demonstrated that, in Dab2 SBP, R42 significantly contributes to the inhibition of platelet P-selectin surface expression. The interacting Dab2 SBP residues with sulfatide resemble those described for sphingolipid-binding in other proteins, suggesting that sulfatide-binding proteins share common binding mechanisms.