Highly constrained cyclic (S,S) -CXaaC- peptides as inhibitors of fibrinogen binding to platelets.

The Arg-Gly-Asp RGD motif of adhesive proteins is recognized by the activated platelet integrin alpha(IIb)beta3. Binding of fibrinogen (Fg) to activated alpha(IIb)beta3 causes platelet aggregation and thrombus formation. Highly constraint cyclic (S,S) -CXaaC- containing peptides incorporating the (S,S) -CDC- and (S,S) -CRC- motifs were tested for their ability to inhibit platelet aggregation and Fg binding. Our results suggest that the above cyclic scaffolds stabilize a favorable structure for the antiaggregatory activity (IC50-values ranged from 1.7 to 570 microm). The peptides inhibited Fg binding with IC50-values up to 30-fold lower than those determined for the inhibition of the adenosine diphosphate (ADP)-induced platelet aggregation. Importantly, peptides (S,S) PSRCDCR-NH2 (peptide 11) and (S,S) PRCDCK-NH2 (peptide 10) did not inhibit PAC-1 binding to the activated platelets at a concentration in which they completely inhibited Fg binding. Moreover, (S,S) PSRCDCR-NH(2) (peptide 11), one of the more active peptides, inhibited ADP-induced P-selectin exposure. By contrast, peptide (S,S) Ac-RWDCRC-NH2, incorporating the inverse (S,S) -DCRC- sequence (peptide 16), failed to inhibit P-selectin exposure whereas at the same concentration, it effectively inhibited PAC-1 and Fg binding. It is concluded that peptides containing the (S,S) -CDC- as well the (S,S) -CRC- sequences, exhibit a broad range of activities toward platelets, and could be helpful tools for elucidating the structural interaction of Fg with the integrin receptor alpha(IIb)beta3, in its activated form. Furthermore, the (S,S) -RCDC- sequence can be used as a scaffold for developing potent non-RGD-like Fg-binding inhibitors.

A three-residue cyclic scaffold of non-RGD containing peptide analogues as platelet aggregation inhibitors: design, synthesis, and structure--function relationships.

Antagonists of fibrinogen at the GPIIb/IIIa receptor, which is the most abundant membrane protein on the platelet surface, are under active investigation as potential antithrombotics. The critical interaction between GPIIb/IIIa and fibrinogen can be inhibited by either linear or cyclic RGDS-containing peptides, which have been proved as lead compounds in the design of platelet aggregation inhibitors. In this study we present the design and construction of a new class of cyclic (S,S) non-RGD containing peptide sequences, using two Cys as a structural scaffold for the development of antiaggregatory agents. The (S,S)-CDC- sequence was incorporated as a conformational constraint, in molecules bearing at least one positive charge with the general formula (S,S)XCDCZ, where X = Ac-Arg, Pro-Arg, Pro-Ser-Lys, and Pro-Ser-Arg, and Z = -NH(2) and Arg-NH(2). Investigation of the structure-function relationships was performed on the basis of (a) the local conformation induced by the (S,S)-CDC motif, (b) the distance of the positively (R-C(zeta) or K-N(zeta)) and negatively (D-C(gamma)) charged centers, (c) the presence of a second positive or negative charge on the molecule, and (d) the orientation of the basic and acidic side chains defined by the pseudo dihedral angle (Pdo), which is formed by the R-C(zeta), R-C(alpha), D-C(alpha), and D-C(gamma) atoms in the case of (S,S)-RCDC and by the K-N(zeta), K-C(alpha), D-C(alpha), and D-C(gamma) atoms in the case of (S,S)-KCDC.