Structure of the leech protein saratin and characterization of its binding to collagen.

The leech protein Saratin from Hirudo medicinalis prevents thrombocyte aggregation by interfering with the first binding step of the thrombocytes to collagen by binding to collagen. We solved the three-dimensional structure of the leech protein Saratin in solution and identified its collagen binding site by NMR titration experiments. The NMR structure of Saratin consists of one alpha-helix and a five-stranded beta-sheet arranged in the topology betabetaalphabetabetabeta. The C-terminal region, of about 20 amino acids in length, adopts no regular structure. NMR titration experiments with collagen peptides show that the collagen interaction of Saratin takes place in a kind of notch that is formed by the end of the alpha-helix and the beta-sheet. NMR data-driven docking experiments to collagen model peptides were used to elucidate the putative binding mode of Saratin and collagen. Mainly, parts of the first and the end of the fifth beta-strand, the loop connecting the alpha-helix and the third beta-strand, and a short part of the loop connecting the fourth and fifth beta-strand participate in binding.

C-mannosylation in the hypertrehalosaemic hormone from the stick insect Carausius morosus.

The hypertrehalosaemic hormone from the stick insect Carausius morosus (Cam-HrTH) contains a hexose covalently bound to the ring of the tryptophan, which is in the eighth position in the molecule. We show by solution NMR spectroscopy that the tryptophan is modified at its C(delta1)(C2) by an alpha-mannopyranose. It is the first insect hormone to exhibit C-glycosylation whose exact nature has been determined experimentally. Chemical shift analysis reveals that the unmodified as well as the mannosylated Cam-HrTH are not completely random-coil in aqueous solution. Most prominently, C-mannosylation strongly influences the average orientation of the tryptophan ring in solution and stabilizes it in a position clearly different from that found in the unmodified peptide. NMR diffusion measurements indicate that mannosylation reduces the effective hydrodynamic radius. It induces a change of the average peptide conformation that also diminishes the propensity for aggregation of the peptide.